Enriching ANY.RUN’s TI Feeds with Unique IOCs: How It Works

Threat Intelligence Feeds from ANY.RUN provide a continuously-updated stream of the latest indicators of compromise. They enable SOC teams to quickly detect and mitigate attacks, including the emerging malware and persistent threats.

But how do ANY.RUN’s feeds get enriched with fresh and, most importantly, unique indicators that cannot be found elsewhere?

Let’s find out.

About ANY.RUN’s Threat Intelligence Feeds

ANY.RUN’s Threat Intelligence (TI) Feeds offer an extensive collection of Indicators of Compromise (IOCs) designed to enhance the threat detection capabilities of security systems. These feeds provide detailed information beyond the basics, including malicious IPs, URLs, domains, file hashes, and links to actual analysis sessions. This comprehensive data helps you understand how threats operate and behave in real-world scenarios.

Where does this data come from?

An international community of over 500,000 researchers and cybersecurity pros who upload and analyze real-world malware and phishing samples every day to ANY.RUN’s Public submissions repository.

With TI Feeds from ANY.RUN, organizations can:

  • Expand and speed up threat hunting with enriched up-to-date data 
  • Enhance alert triage and prioritize most urgent issues. 
  • Improve incident response thanks to better understanding threats and their behaviors. 
  • Proactively defend against new and evolving threats.   

Give TI Feeds from ANY.RUN a try
Start with a free demo sample in STIX or MISP 



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IOCs Provided by ANY.RUN TI Feeds 

TI Feeds contain indicators along with additional info like the threat score, which signals the reliability:

  • 100: Highly reliable
  • 50: Suspicious
  • 75: Trustworthy

Here are the indicators you can find in ANY.RUN’s TI Feeds.

IP addresses

Compromised IPs instantly signal of cybercriminal operations, they are often linked to Command-and-Control (C2) servers or phishing campaigns. By analyzing IP addresses, cybersecurity teams can proactively block suspicious traffic and analyze attack patterns and tactics.  

Domains  

They provide a higher-level view of malicious activity, often connecting multiple IPs or malware instances within a single campaign.  

ANY.RUN’s TI feeds provide comprehensive information about domains, including all the details available for IP addresses, such as threat names, types, detection timestamps, and related file hashes. 

URLs  

URL addresses serve as gateways to distribute malware, execute phishing campaigns, or redirect users to malicious content.   

By analyzing URLs, cybersecurity teams can uncover attack patterns, block harmful traffic, and prevent unauthorized access to systems and data. 

How ANY.RUN’s TI Feeds Are Enriched with Unique IOCs 

There are several features of Threat Intelligence Feeds stand out, but the one of the key factors is the way we collect indicators. Here are the two methods we use to get the latest and the most accurate indicators.

IOCs Extracted from Malware Configurations 

TI Feeds are fueled by the data from ANY.RUN’s Interactive Sandbox. Which provides, among others, the option to extract malware configurations from memory dumps.

Configurations are crucial for understanding malware’s behavior and functions, tying it to a family and an adversary, and identifying all types of Indicators of Compromise (IOCs), which are then used for detection purposes. Such IOCs are particularly valuable as they contain hardcoded details such as command and control (C2) server addresses, encryption keys, and specific attack parameters.

Take a look at this sandbox session.

By opening the MalConf tab we can observe the extracted configuration of an AsyncRAT sample. One of the pieces of data found here is the malicious IP address used by the malware for communication with its C2 server.

ANY.RUN automatically extracts this crucial indicator and sends it to TI Feeds, which then get fed into the clients’ detection systems. This helps them identify the threat early and minimize its potential impact.

Want to integrate TI Feeds from ANY.RUN?
Reach out to us and we’ll help you set it up 



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IOCs Detected with Suricata IDS Rules 

Indicators detected with Suricata rules are valuable because they focus on identifying patterns in network traffic rather than specific details like IP addresses or domains. This means Suricata can recognize threats even when attackers change their infrastructure.

Thanks to ANY.RUN’s extensive integration of Suricata rules for traffic analysis, we can consistently extract fresh network indicators of numerous malware families and cyber threats.

Check out this report, which shows analysis of a FormBook sample.

Suricata rule triggered after detecting FormBook’s C2 traffic

When we navigate to the Threats tab and then click on one of the triggered Suricata rules, we can see that the system has detected connection to domain controlled by the attackers.

You can see the domain name used by FormBook

As you expect, this domain is sent directly to TI Feeds, strengthening our clients’ defense capabilities.

Integrate ANY.RUN’s TI Feeds 

ANY.RUN offers demo feeds samples in STIX and MISP formats 

You can test ANY.RUN’s Threat Intelligence Feeds in STIX and MISP formats completely for free by getting a free demo sample here

ANY.RUN also runs a dedicated MISP instance that you can syncronize your server with or connect to your security solutions. To get started, contact our team via this page

About ANY.RUN  

ANY.RUN helps more than 500,000 cybersecurity professionals worldwide. Our interactive sandbox simplifies malware analysis of threats that target both Windows and Linux systems. Our threat intelligence products, TI LookupYARA Search and Feeds, help you find IOCs or files to learn more about the threats and respond to incidents faster.  

Get a 14-day free trial of ANY.RUN’s Threat Intelligence service →

The post Enriching ANY.RUN’s TI Feeds with Unique IOCs: How It Works appeared first on ANY.RUN’s Cybersecurity Blog.

ANY.RUN’s Cybersecurity Blog – ​Read More

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

  • Cisco Talos discovered multiple cyber espionage campaigns that target government, manufacturing, telecommunications and media, delivering Sagerunex and other hacking tools for post-compromise activities. 
  • Talos attributes these attacks to the threat actor known as Lotus Blossom. Lotus Blossom has actively conducted cyber espionage operations since at least 2012 and continues to operate today. 
  • Based on our examination of the tactics, techniques, and procedures (TTPs) utilized in these campaigns, alongside the deployment of Sagerunex, a backdoor family used exclusively by Lotus Blossom, we attribute these campaigns to the Lotus Blossom group with high confidence.  
  • We also observed Lotus Blossom gain persistence using specific commands to install their Sagerunex backdoor within the system registry and configuring it to run as a service on infected endpoints.  
  • Lotus Blossom has also developed new variants of Sagerunex that not only use traditional command and control (C2) servers but also use legitimate, third-party cloud services such as Dropbox, Twitter, and the Zimbra open-source webmail as C2 tunnels. 

A multi-campaign, multi-variant backdoor operation  

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

Talos assesses with high confidence that Lotus Blossom (also referred to as Spring Dragon, Billbug, Thrip) threat actors are responsible for these campaigns. The group was previously publicly disclosed as an active espionage group operating since 2012. Our assessment is based on the TTPs, backdoors, and victim profiles associated with each activity. Our observations indicate that Lotus Blossom has been using the Sagerunex backdoor since at least 2016 and is increasingly employing long-term persistence command shells and developing new variants of the Sagerunex malware suite. The operation appears to have achieved significant success, targeting organizations in sectors such as government, manufacturing, telecommunications and media in areas including the Philippines, Vietnam, Hong Kong and Taiwan.  

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

Our investigation uncovered two new variants of the Sagerunex backdoor, which were detected during attacks on telecommunications and media companies, as well as many Sagerunex variants persistent in the government and manufacturing industries. These new variants no longer rely on the original Virtual Private Server (VPS) for their C2 servers. Instead, they use third-party cloud services such as Dropbox, Twitter, and the Zimbra open-source webmail service as C2 tunnels to evade detection. In our malware analysis section, we will delve into the technical specifics of each Sagerunex backdoor variant and illustrate their configurations. Some configurations reveal the possible original file paths of the malware, providing insights into the threat actor’s host paths. 

  

We also compiled a timeline for the evolution of Sagerunex by analyzing data from the campaigns we observed, third-party reports, malware compilation timestamps, and the timestamps of victim uploads on the C2 service: 

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

Attributing the attacks to Lotus Blossom 

Talos has identified strong evidence to attribute these campaigns to the Lotus Blossom group, primarily due to the presence of the Sagerunex backdoor within these operations. Sagerunex is a remote access tool (RAT) assessed to be an evolution of an older Billbug tool known as Evora. Sagerunex is designed to be dynamic link library (DLL) injected into an infected endpoint and executed directly in memory.  

 

We also observed the Sagerunex backdoor employ various network connection strategies to ensure it remains under the actor’s control. Despite the development of three distinct variants, the foundational structures and core functionalities of the backdoor remain consistent. These consistent elements enable us to confidently categorize all identified variant backdoors as part of the Sagerunex family.  

 

Moreover, the consistent patterns in victimology and the TTPs identified across these campaigns strongly support our attribution to the Lotus Blossom espionage group. This consistency, seen in the selection of targets and the methods employed, aligns with the known operational characteristics of Lotus Blossom, providing compelling evidence that these campaigns are orchestrated by this specific threat actor. 

Lotus Blossom’s latest attack chain  

We conducted research into the main elements of the attack including the specific functions of each malware strain and how Lotus Blossom managed to evade detection  for several months. We also observed the threat actor leverage a number of hacking and open-source tools to achieve their objectives. 

  • Cookie stealer tool: Pyinstaller bundle of a Chrome cookie stealer which is an open-source tool from github. Lotus Blossom used it to harvest Chrome browser credentials.   
Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

  • Venom proxy tool: A proxy tool developed for penetration testers using Go language. The threat actor customized this Venom tool and hardcoded the destination IP address in each activity. 
Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

  • Adjust privilege tool: Enabled the threat actor to retrieve another process token and adjust privilege for the launch process.  
Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

  • Archiving tool: A customized compressed and encrypted tool which enabled the attacker to steal each file or entire folder to the specific file path with protection. For example, the tool archived Chrome and Firefox browser cookies folders. 
Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

  • Port relay tool: The threat actor named this tool “mtrain V1.01” which is a modified proxy relay tool from HTran. The tool allowed the threat actor to relay the connection from the victim machine to the internet. 
Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

  • RAR tool: An archive manager that the threat actor used to archive or zip files. 

Extended persistence   

Lotus Blossom frequently utilizes the Impacket tool to execute remote processes and commands within the victim’s environment, consistent with known Lotus Blossom TTPs. Once they gain access to a target, their operations typically unfold over multiple stages. Each stage is carefully executed, indicating a well-planned strategy aimed at achieving long-term objectives. This multi-stage approach enables them to maintain a presence in the network for extended periods, often going undetected for several months. Below is an example of overall attack chain visualization.  

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

In the compromised environment, the threat actor executes various commands such as “net,” “tasklist,” “quser,” “ipconfig,” “netstat,” and “dir.” These commands are used to gather detailed information about user accounts, directory structures, process activities, and network configurations. Following the initial reconnaissance, the actor assesses whether the compromised machine can connect to the internet. If internet access is restricted, then the actor has two strategies: using the target’s proxy settings to establish a connection or using the Venom proxy tool to link the isolated machines to internet-accessible systems. Additionally, we have noticed that the actor frequently deposits backdoor and hacking tools in the “publicpictures” subfolder. This location is publicly accessible to all users and, unlike system folders, is not hidden or protected, making it a strategic choice for evasion and continued access. 

 

Besides running commands for discovery and lateral movement, we also observed Lotus Blossom use specific commands to install their notorious Sagerunex backdoor within the system registry, configuring it to run as a service. Presented below are the command lines the actor used to install the backdoor as a service. 

reg add HKLMSYSTEMCurrentControlSetServicestapisrvParameters /v ServiceDll /t REG_EXPAND_SZ /d c:windowstapisrv.dll /f 

reg add HKLMSYSTEMCurrentControlSetServicestapisrv /v Start /t REG_DWORD /d 2 /f 

reg add HKLMSYSTEMCurrentControlSetServicesswprvParameters /v ServiceDll /t REG_EXPAND_SZ /d c:windowsswprv.dll /f 

reg add HKLMSYSTEMCurrentControlSetServicesswprvParameters /v ServiceDll /t REG_EXPAND_SZ /d c:windowssystem32swprv.dll /f 

reg add HKLMSYSTEMCurrentControlSetServicesappmgmtParameters /v ServiceDll /t REG_EXPAND_SZ /d c:windowsswprv.dll /f 

reg add HKLMSYSTEMCurrentControlSetServicesappmgmt /v Start /t REG_DWORD /d 2 /f 

reg add HKLMSYSTEMCurrentControlSetServicesappmgmtParameters /v ServiceDll /t REG_EXPAND_SZ /d c:windowssystem32appmgmts.dll /f 

 

The actor used the following commands to verify that the backdoor can successfully run as a service.  

reg query HKLMSYSTEMCurrentControlSetServicesswprvParameters 

reg query HKLMSYSTEMCurrentControlSetServicestapisrvParameters 

reg query HKLMSYSTEMCurrentControlSetServicesappmgmtParameters 

 

Sagerunex malware analysis 

In this section, we provide in-depth technical analysis of the multiple variants of the Sagerunex backdoor. Our exploration will begin with a detailed examination of a particular Sagerunex backdoor variant that exhibits a high degree of code similarity and workflow resemblance to those described in other vendors’ blog posts. This analysis will help establish connections and highlight the shared characteristics observed across different Sagerunex variants.  

 

Next, we will shift our focus to another intriguing variant of the Sagerunex backdoor, which utilizes Dropbox as its C2 server. This unconventional choice of a third-party cloud service illustrates the threat actor’s adaptability and efforts to evade detection. Additionally, we have identified another variant of the Sagerunex backdoor that leverages the Zimbra open-source webmail service for its C2 operations. This finding further underscores the diverse strategies Lotus Blossom employs to maintain control and persist within compromised environments. 

 

We examined the loader code similarity to identify numerous variants of the Sagerunex backdoor. By analyzing the loader and the behavior of the Sagerunex backdoor, we can classify the malware into the Sagerunex family. Despite the loader’s compact size and primary function of injecting the Sagerunex backdoor into memory, we have identified two distinct loader patterns. The first pattern involves the decryption algorithm: the loader embeds and encrypts the Sagerunex backdoor, utilizing a customized decryption process to extract it. The second pattern is the “servicemain” function, where the loader verifies its environment, ensuring it can only be executed as a service.  

 

Furthermore, we also observed the actor employ VMProtect, a software protection tool, to obfuscate Sagerunex code and evade detection by antivirus products. These sophisticated techniques are used to maintain the persistence of Sagerunex backdoor variants. 

 

Sagerunex malware similarity 

During its initial execution, Sagerunex conducts several checks before sending a beacon to its C2 server. These verification functions are present across all Sagerunex variants. The initial check involves searching for a debug log file in the temp folder. Regardless of whether this debug log file is present, all Sagerunex variants will proceed with execution. If the debug log is found, the backdoors will encrypt the debug strings along with a timestamp and store them in the log file. Below is a screenshot displaying the debug file names for all Sagerunex variants. From left to right, the versions include: the “Beta” version, featuring clear debug strings within its code flow; the original version, previously discussed in another blog post and the code flow is same as Beta version; the Dropbox and Twitter versions, which utilize these third-party cloud services as C2 channels; and finally, the Zimbra version, which employs the Zimbra webmail service for C2 purposes. 

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

The second check involves verifying the existence of the backdoor configuration file within a specific directory and under a designated filename. Below, we provide examples of different versions of the Sagerunex configuration file paths and filenames uncovered during our research. We suspect there may be additional directories that remain undiscovered. These are likewise ordered in the same manner as the preceeding paragraph.  

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

Subsequently, the Sagerunex backdoor examines the system time to decide whether to execute its main function immediately or delay its execution. Each Sagerunex variant possesses its own time-check logic. For example, one variant checks if it operates during working hours (e.g. 10:00 am to 7:00 pm), while another ensures that the system hours do not exceed the system minutes. Despite these slight variations in check strategies among the Sagerunex backdoors, they all utilize the same pause API, “WaitForSingleObject,” and uniformly wait for 300,000 milliseconds before proceeding again with time-check logic. 

 

A final shared feature among all Sagerunex variants is their approach to proxy configuration, which enables the backdoor to successfully connect to the C2 server. While the malware includes several proxy-related functions, not all variants utilize every available option. Some rely solely on web proxy “autodiscovery” for accessing proxy services. Additionally, we identified hardcoded proxy servers, along with proxy usernames and passwords, within the Sagerunex configuration files. This discovery strongly supports our assessment that Lotus Blossom’s activities are intended for espionage purposes.  

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

Beta version of Sagerunex 

The Beta version of Sagerunex closely resembles the Sagerunex backdoor discussed previously in this post. However, this Beta version includes additional debug strings featuring more complete sentences, which is why we have called it the Beta version of Sagerunex. For example, as shown in the screenshot below, while typical Sagerunex debug strings often use “0x00” as a prefix followed by error or behavior shortcut strings, the Beta version offers more detailed information, such as “Online Fail! Wait for %d minsrn.” Furthermore, this Beta version also provides us with a clearer understanding of Sagerunex workflow. 

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

Fig. The left side is the Beta version of Sagerunex and the right side is typical Sagerunex. 

 

Once all the checks are bypassed, the Beta version of Sagerunex gathers information from the target host, including the hostname, MAC address, and IP address. It also queries the public IP address using “api.ipaddress[.]com.” This collected information is then encrypted and sent back to the C2 server. Upon receiving the encrypted data, Sagerunex decrypts it, successfully bringing the backdoor online and enabling the threat actor to control the target. Below are the debug strings indicating successful online status and the backdoor command functions. 

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

Fig. The left side is the online debug strings, and the right side is backdoor command functions.  

The Beta version of Sagerunex backdoor overall infection chain is visualized below. 

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

Dropbox & Twitter version of Sagerunex 

Talos also discovered another variant of Sagerunex backdoor that uses Dropbox and Twitter API as C2 services. After bypassing the initial checking steps, this backdoor variant retrieves the necessary Dropbox or Twitter tokens to successfully bring the backdoor online. Once the backdoor sends a beacon message and receives a response ID, it evaluates the ID number to determine subsequent actions. If the ID is less than 16, the function will return, prompting the backdoor to send another beacon message and wait for a new ID. If the ID is between 16 and 32, the backdoor proceeds to collect host information and execute paired backdoor command functions. After gathering the information and executing the commands, the backdoor encrypts and archives all collected data, then transmits it back to Dropbox or Twitter. When the ID received equals 39, the backdoor retrieves data from Dropbox files or Twitter status updates to confirm the status of the backdoor service. Below are the screenshots of Dropbox and Twitter connection testing function and this variant’s command functions. 

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

Fig. The left side is the online debug strings, and the right side is backdoor command functions. 

 

Additionally, our reverse engineering of this version of the Sagerunex backdoor revealed one intriguing finding. We discovered that the configuration file for this version not only includes Dropbox tokens and Twitter tokens but also reveals its original file path, which we believe may originate from the actor’s machine. Below, we provide a list of all the file paths we identified, along with a screenshot of the configuration file. 

  • C:UsersaaDesktopdpst.dll 
  • C:Users3DesktopDT-1-64-Gmsiscsii.dll 
  • C:UsersbalabalaDesktopswprve64.dll 
  • C:Userstest04Desktopadtsvc32.dll 
  • C:UsersUSERDocumentsdtj32dj32.dll 
Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

Moreover, our observations of the timestamps on Dropbox files and Twitter content indicate that this version of the backdoor was predominantly active between 2018 and 2022, and we assess this version of backdoor might still be active now. This timeframe suggests a consistent pattern of use over several years, highlighting the longevity and persistence of this threat in the wild. Below is an example where we extract the file details from one of the Dropbox accounts. 

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

The Dropbox & Twitter version of Sagerunex backdoor infection chain is visualized below. 

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

Zimbra webmail version of Sagerunex 

The final variant of the Sagerunex backdoor Talos discovered employs the Zimbra API to connect to a legitimate Zimbra mail service, using it as a C2 channel to exfiltrate victim information. Like other versions, this Sagerunex variant performs all the necessary checks before establishing its initial beacon connection. It uses the Zimbra webmail URL, along with a username and password, to login and obtain an authentication token. Upon successfully acquiring this token, the backdoor synchronizes the account’s folders and documents and utilizes the search function API to verify the connection’s functionality. Once the connection and synchronization processes are complete, the backdoor gathers host information, encrypts the information, and saves the data as “mail_report.rar”. The rar file is being attached to a draft email the user’s email account draft folder. With these steps finalized, the beacon connection is successfully established. 

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

The Zimbra webmail version of Sagerunex is not only designed to collect victim information and send it to the Zimbra mailbox but also to allow the actor to use Zimbra mail content to give orders and control the victim machine. If there is a legitimate command order content in the mail box, the backdoor will download the content and extract the command, otherwise the backdoor will delete the content and wait for a legitimate command. Once finished executing the command, the backdoor will package the command result and also save the data as “mail_report.rar”. The rar file is being attached to a draft email the user’s email account trash folder. 

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

Fig. The left side is the Zimbra status path, and the right side are the backdoor command functions.  

Talos observed that this version of the Sagerunex backdoor has been active since 2019, and there are still several Zimbra mailboxes receiving the compromised machine beacon information.  

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools
Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

The Zimbra version of Sagerunex backdoor infection chain is visualized below. 

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

Coverage 

Lotus Blossom espionage group targets multiple industries with different versions of Sagerunex and hacking tools

 

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 Web Appliance web scanning prevents access to malicious websites and detects malware used in these attacks. 

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 Malware Analytics (Threat Grid) identifies malicious binaries and builds protection into all Cisco Secure products. 

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. Sign up for a free trial of Umbrella here

Cisco Secure Web Appliance (formerly Web Security Appliance) automatically blocks potentially dangerous sites and tests suspicious sites before users access them. 

Additional protection 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 this threat are 64511, 64510, 64509. 

ClamAV detections are also available for this threat: 

Win.Backdoor.Sagerunex-10041845-0 

Win.Tool.Mtrain-10041846-0 

Win.Tool.Ntfsdump-10041854-0 

Win.Backdoor.Sagerunex-10041857-0 

 

Indicators of compromise (IOCs) 

Campaign code 

 st
qaz
test
cmhk
dtemp
0305
4007
4007_new
Jf_b64_t1
Ber_64
0817-svc64
NSX32-0710
Nsx32-0419
NJX32-0710
WS1x321014
pccw-svc32
CTMsx32-0712

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

Cisco Talos Blog – ​Read More

How smartphones actually track you | Kaspersky official blog

You’ve probably heard the rumor — our smartphones are always listening. But the truth is, they don’t need to. The information shared with data brokers by virtually every app on your smartphone — from games to weather apps  is more than enough to create a detailed profile on you. For a long time, “online tracking” had meant that search engines, ad systems, and advertisers all knew which websites you visited. But since smartphones appeared on the scene, the situation has become much worse: now advertisers know where you go physically and how often. So, how do they do it?

Every time any mobile app prepares to show an ad, a lightning-fast auction takes place to determine which specific ad you’ll see based on the data sent from your smartphone. And although you only see the winning ad, all the participants in the auction receive data about the potential viewer — that is, you. A recent experiment showed just how many companies receive this information, how detailed it is, and how ineffective built-in smartphone features like “Do Not Track” and “Opt Out of Personalized Ads” are at protecting users. Nevertheless, we still recommend some protection methods!

What data do advertisers receive?

Every mobile app is built differently, but most start “leaking” data to ad networks even before displaying any ads. In the experiment mentioned earlier, a mobile game immediately sent an extensive array of data to the Unity Ads network upon launch:

  • Information about the smartphone, including OS version, battery level, brightness and volume settings, and available memory
  • Data about the network operator
  • Type of internet connection
  • Full IP address of the device
  • Vendor code (the game developer’s identifier)
  • Unique user code (IFV) — an identifier linked to the game developer and used by an ad system
  • Another unique user code (IDFA/AAID) — an ad identifier shared by all apps on the smartphone
  • Current location
  • Consent for ad tracking (yes/no)

Interestingly, the location is transmitted even if the service is disabled on the smartphone. It’s approximate though, calculated based on the IP address. However, with publicly available databases matching physical and internet addresses, this approximation can be surprisingly accurate — down to the city district or even the building. If location services are enabled and allowed for the app, precise location data is transmitted.

In the same experiment, the consent for ad tracking was marked as “User Agreed”, even though the experiment’s author did not provide such consent.

Who gets the data, and how often?

The data stream is sent to all ad platforms integrated into the app. There are often several such platforms, and a complex algorithm determines which one will be used to show the ad. However, some data is shared with all connected networks — even those that aren’t currently showing ads. In addition to the above-mentioned Unity (whose ad platform generates 66% of revenue for developers using this game engine), other major platforms include those of Facebook, Microsoft, Google, Apple, Amazon, and dozens of specialized companies like ironSource.

Next, the ad network currently displaying ads in the app sends a large set of user-data to a real-time bidding system (RTB). Here, various advertisers analyze the data and bid to display their ads, all at lightning-fast speeds. You view the winning ad, but information about your location, combined with the exact time, IP address, and all other data, is shared with every auction participant. According to the experiment’s author, this data is collected by hundreds of obscure firms, some of which may be shell companies owned by intelligence agencies.

This video from the experiment shows how connections to ad servers were made dozens of times per second, and even Facebook received data despite the fact that no Meta apps were installed on the experimenter’s smartphone.

The illusion of anonymity

Ad-network owners love to claim that they use anonymous and depersonalized data for ad targeting. In reality, advertising systems go to great lengths to accurately identify users across different apps and devices.

In the data set mentioned above, two different user codes are listed: IFV and IDFA/AAID (IDFA for Apple, AAID for Android). A separate IFV is assigned to your device by each app developer. If you have three games from the same developer, each of these games will send the same IFV when showing ads. Meanwhile, apps from other developers will send their own IFVs. The IDFA/AAID, on the other hand, is a unique advertising identifier assigned to the entire smartphone. If you’ve agreed to “ad personalization” in your phone’s settings, all games and apps on your device will use the same IDFA/AAID.

If you disable ad personalization, or decline consent, the IDFA/AAID is replaced with zeros. But IFVs will continue to be sent. By combining the data transmitted with each ad display, advertising networks can piece together a detailed dossier on “anonymous” users, linking their activity across different apps through these identifiers. And as soon as the user enters their email address, phone number, payment details, or home address anywhere — such as when making an online purchase — the anonymous identifier can be linked to this personal information.

As we discussed in our article on the Gravy Analytics data leak, location data is so valuable that some companies posing as ad brokers are created solely to collect it. Thanks to IFV — especially IDFA/AAID — it’s possible to map out the movements of “Mr. X” and often de-anonymize him using just this data.

Sometimes, complex movement analysis isn’t even necessary. Databases linking ad identifiers to full names, home addresses, emails, and other highly personal details can be simply sold by unscrupulous brokers. In such cases, detailed personal data and a comprehensive location history form a complete dossier on the user.

How to protect yourself from ad tracking

In practice, neither strict laws like the GDPR nor built-in privacy settings provide complete protection against the tracking methods described above. Simply pressing a button in an app to disable ad personalization is not even a half-measure — it’s more like a tenth of a measure. The fact is, this only removes one identifier from the telemetry data, while the rest of your data is still sent to advertisers.

Cases like the Gravy Analytics data leak and the scandal involving the Datastream data broker demonstrate the scale of the problem. The ad-tracking industry is enormous, and exploits most any apps — not just games. Moreover, location data is purchased by a wide range of entities — from advertising firms to intelligence agencies. Sometimes, hackers obtain this information for free if a data broker fails to adequately protect their databases. To minimize the exposure of your data to such leaks, you’ll need to take some significant precautions:

  • Only allow location access for apps that genuinely need it for their primary function (e.g., navigation apps, maps, or taxi services). For example, delivery services or banking apps don’t actually need your location to function — let alone games or shopping apps. You can always manually enter a delivery address.
  • In general, grant apps the minimum permissions necessary. Do not allow them to track your activity in other apps, and do not grant full access to your photo gallery. Malware has been developed that can analyze photo data using AI, and unscrupulous app developers could potentially do the same. Additionally, all photos taken on your smartphone include geotags by default, among other information.
  • Configure a secure DNS service with ad-filtering functionality on your smartphone. This will block a significant amount of advertising telemetry.
  • Try to use apps that don’t contain ads. These are typically either FOSS (Free Open Source Software) apps or paid applications.
  • On iOS, disable the use of the advertising identifier. On Android, delete or reset it at least once a month (unfortunately, it cannot be completely disabled). Remember, these actions reduce the amount of information collected about you but don’t entirely eliminate tracking.
  • Where possible, avoid using “Sign in with Google” or other similar services in apps. Try to use apps without creating an account. This makes it harder for advertisers to collate your activity across different apps and services into a unified advertising profile.
  • Minimize the number of apps you have on your smartphone, and regularly delete unused apps — they can still track you even if you’re not actively using them.
  • Use robust security solutions on all your devices, such as Kaspersky Premium. This helps protect you from more aggressive apps, whose advertising modules can be as malicious as spyware.
  • In the Kaspersky settings in your smartphone, activate the Anti-Banner and Private Browsing options on iOS, or Safe Browsing on Android. This makes it significantly more difficult to track you.

If smartphone surveillance doesn’t concern you yet, here are some chilling stories about who is spying on us and how:

Kaspersky official blog – ​Read More

How to scan huge file storage | Kaspersky official blog

Scanning the hard drives of work computers is a simple daily procedure that happens without impacting the user or requiring any manual action. In the case of servers, however, things are more complex — especially if done in response to an incident, after which all company storage (perhaps tens of terabytes worth) need an unscheduled scan. What’s more, you need to ensure absolute data security and no noticeable drop in performance for users.

We’ve compiled a list of tips and precautions to save you time and prevent further incidents. All tips related to our products are using Kaspersky Endpoint Security as an example, but the same logic applies to other EPP/EDR security products.

Preliminary checks

Check the configuration of the computer that will perform the scan. Make sure that the OS is updated to the latest version and can connect to all disks being scanned and process the data correctly — that is: read long Unicode file names, handle very large files and files on case-sensitive partitions, and so on. To speed up the scan, use a computer with a powerful multicore CPU, generous memory, and fast local storage for temporary files.

Make sure that disk-access is fast. The computer should connect to all storage either directly (local storage) or through a fast network interface using a high-performance protocol (preferably SAN-type).

Check your backups. Although scanning should not affect stored data, it’s important to have a plan B in case of malware infection or file corruption. Therefore, carefully check the date and contents of the most recent backup of all data, consider when data-recovery drills were last performed, and generally make sure the current backup versions are usable. If current backups aren’t available, assess the risks and time frames, and possibly back up critical data before scanning.

Clarify the nature of the data on the disks and the storage specifications. This is to optimize the scan settings. Are the disks arranged in a RAID array? If so, what type? You need to decide whether to scan different disks in parallel, and whether this will boost performance. If the disks are accessible independently, consider parallel scanning from multiple computers. Here again, both access speed and server capacity are key. For a powerful computer limited mainly by access speed to different disks, you can run parallel scanning tasks on a single machine.

The nature of the data will greatly affect your decision. If the disks contain many heterogeneous files, or archives with a large number of files, scanning will require significant resources of all types: CPU, memory, temporary folders, etc. The load will be lower if large files in a safe format (video editing sources, database tables, backups/archives known to be untouched) make up a major part of what’s being stored.

Preparing for scanning

Schedule the scan time. Ideally, a weekend, nighttime, or other period when few users access the data. Then you can either completely remove the disks and servers to be scanned from public access, or warn users about possible system slowdown and be sure that only a very small group of people will be affected.

Make sure there’s enough free space on the disks. Scanning may involve unpacking archives and images, which sometimes requires a lot of space.

Check quarantine storage settings. If many infected and suspicious files are found, quarantine may overflow and older samples will be deleted. So it’s worth allocating plenty of space for quarantine.

Agree and enforce an exclusion policy. To reduce scan time, exclude resources that pose no risk and would take a very long time to scan. This category typically includes very large files (with the cutoff ranging from hundreds of megabytes to several gigabytes, depending on the situation), distribution kits, backups, other files that haven’t been modified since previous scans, and files that are known to be non-executable. However, the last category is not so clear-cut, as there can be malicious fragments hidden in plain text files and images. So it’s better to be safe than sorry and scan images as well.

 Delete temporary files and folders so you don’t waste time on them.

Scan settings

These recommendations should be adjusted in line with your prior assessments and the nature of the data, but the basic advice is:

  • Set the maximum amount of memory and CPU time for scanning, taking into account the server usage profile. If the server is unavailable to users during scanning, you can allocate up to 80% of CPU and memory resources — any higher and the computer may become sluggish. For servers that remain under normal load, these numbers should be significantly lower.
  • In our product settings enable iChecker and iSwift. These technologies speed up scanning of some file formats and exclude data that’s been unchanged since the last scan.
  • Here, you can also enable additional options to prevent overloading the system: ” Do not run multiple scan tasks at the same time” and “Scan only new and modified files”.
  • Disable scanning of password-protected archives; otherwise, password requests will cause the application to stop scanning.
  • Set the maximum size of files for scanning in accordance with what we discussed above.
  • Set the heuristic analysis level to medium.
  • Select actions for infected objects; quarantine will likely be the best choice.
  • Set the logging settings so that the logs contain sufficiently detailed information about scanned objects and scan results.

Performance settings are described in more detail on our support site: for Windows and for Linux.

Running the scan

Start by scanning a small partition or subset of files weighing no more than a terabyte. Evaluate the impact of the scan on server performance (especially important if it continues to serve users) as well as the total time taken, and check the logs for errors. If the scan seems to take too long, try to figure out from the logs what caused the bottleneck. Using this data, adjust the settings accordingly and schedule a “big scan”.

Even after the test, we don’t advise running a full scan of the entire data volume in one task. It’s better to create multiple scan tasks — each targeting only one of the many storage fragments, such as individual disks. This reduces the risk of a prohibitively long scan time, or a failed scan that has to be restarted from scratch.

In the basic scenario, these subtasks are run sequentially as they’re completed. But if the system configuration allows it, dividing the scan into multiple tasks will let you scan independent disks in parallel.

During scanning, monitor the system load and the scan progress so as to intervene in time in case of abnormal situations. And after each task is completed, be sure to drill down into the logs!

Kaspersky official blog – ​Read More

Learn to Analyze Real-World Cyber Threats with Security Training Lab

If you are a student, you might be several years away from getting a degree and a profession – and about a month away from becoming a malware analyst. The latter is made possible by ANY.RUN’s Security Training Lab.

There is no point in advertising a career in cybersecurity nowadays. Money talks louder: ransom sums, possible financial costs of operational disruption, and reputational losses hint that investing in cybersecurity teams is a wise solution for any business.   

Security Training Lab can be a step towards a specter of career paths that imply cybersecurity literacy and understanding of malware analysis. It also can be a valuable addition to an academic course on threat detection, malware analysis or other cybersecurity subjects.

So, let’s take a closer look at the program.  

What is Security Training Lab  

It is an interactive digital course on malware analysis produced by ANY.RUN. It comprises 30 hours of academic content on cyber threats, including written materials, video lectures, tasks and tests.

Learn more about Security Training Lab
 
ANY.RUN is a cybersecurity company with 9 years of experience in providing malware analysis and threat intelligence services to individual security researchers, Managed Security Service Providers (MSSPs), and SOC departments of the largest companies around the world. 

Security Training Lab stands out from other courses on malware analysis by focusing on teaching you practical skills with real-world examples of the latest cyber threats.

  • Comprehensive Learning: 30 hours of academic content with written materials, video lectures, interactive tasks, and tests.
  • Hands-On Experience: Full sandbox access with special plans for teachers and team licenses for students.
  • Real-World Practice: Learn through real-world threat samples and labs.
  • User-Friendly Platform: Easy-to-use and fast management system.
  • Community Support: Private Discord community with tips, lifehacks, and news

Try Security Training Lab
Get an individual quote or for your team 



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What Security Training Lab is Not 

Security Training Lab is not just a manual for ANY.RUN’s Interactive Sandbox. As part of the program, a student gets acquainted with a variety of professional tools and more importantly, with the key concepts and methods of cyber threat analysis and research.  

Skills You’ll Learn to Analyze Real-World Threats 

STL’s contents and structure 

In the course of Security Training Lab, you’ll acquire several key analytical skills, including, but not limited to, the following. 

Conducting Advanced Static Analysis

Static analysis examines a suspicious file without executing it. You will learn to understand the structure and the source code of executable files, the functions of Windows API, use file hashes to identify and track threats, and evaluate files’ entropy.

You will learn to use static analysis tools like DiE

This data defines whether a file is malicious, what its real functions are, how it behaves, and how exactly it threatens the target. 

Advanced static analysis implies disassembling malware’s code to see its structure, variables, loops, conditional operators, and other elements of the program, which helps to better understand the logic of its operation. 

During the course, you will practice using a free tool for advanced static analysis and will become able to navigate through the code, set breakpoints for debugging, change values in memory and registers, gaining full control over the program being analyzed. 

📋 Static Analysis Skills You’ll Learn
  • Dissecting binaries to extract indicators of compromise (IOCs)
  • Understanding and modifying assembly code for deeper analysis
  • Using disassemblers and decompilers to reconstruct malware logic

Dealing with Encryption in Malware 

The course will teach you to perform analysis of encrypted traffic

While encryption is a reliable shield to protect confidential data, it is also a tool in hackers’ hands that allows them to hide malicious activity and bypass protective mechanisms.  

You will learn to identify encryption and decrypt malware with practical examples 

You’ll discover the principles of encryption, different approaches to its implementation, the most popular encryption algorithms from XOR to RSA and RC4 with their strengths and weaknesses, and the basics of decryption. 
 
The acquaintance with encryption algorithms helps to detect the signs of software’s malicious nature: code obfuscation, encrypting network traffic for hiding activity or data for extortion. Knowing how data is decrypted allows one to bypass malware’s protection against analysis. 

🗝 Malware Decryption Skills You’ll Learn
  • Identifying and analyzing obfuscated and encrypted payloads
  • Extracting encryption keys and decrypting malicious payloads
  • Bypassing malware encryption techniques to reveal hidden threats

Identifying Malicious Behavior 

Understanding and predicting malware behavior is the main task of malware analysis. The more we know about the stack of current malicious capabilities, the easier it is to deal with future threats. 

A malware’s tactics and techniques shown in Interactve Sandbox

When executed, the malware generates files, establishes connections, and modifies processes. It also takes measures to avoid detection and analysis, maintain persistence, to hide its launch, and enhance its privileges.

These actions are traceable and can help to identify an ongoing attack, assist in the analysis process, or develop a cybersecurity strategy to protect against known malware strains. 

You will explore MITRE ATT&CK — a constantly updated database of attacker tactics and techniques — and practice using it in malware behavior analysis.  

🎯 Malware Behavior Analysis Skills You’ll Learn
  • Mapping malware actions to MITRE ATT&CK techniques
  • Detecting persistence mechanisms and evasion tactics
  • Using sandbox environments to log and analyze malware activity

Performing In-depth Dynamic Analysis 

Dynamic Malware Analysis module will teach you to use tools like x32/x64dbg

For dynamic analysis we need to watch malware in action, so we let it loose within a safe virtual machine environment. Basic dynamic analysis gives us a first glimpse of how the malware interacts with the system. Advanced dynamic analysis is like examining the behavior of a malware under a microscope: we get into the intricacies of the malicious code to understand its algorithms and find weaknesses.

One of the tasks on understanding dynamic analysis 

Security Training Lab will equip you with powerful tools for advanced dynamic analysis (API Monitor and x64dbg) and guide you through debugging and anti-debugging techniques. You will learn to combine debugging with static analysis to maximize its efficiency.

⚙ Dynamic Malware Analysis Skills You’ll Learn
  • Utilizing debugging tools to trace malware execution
  • Bypassing anti-analysis techniques used by advanced threats
  • Extracting runtime indicators and identifying malicious system modifications

Analyzing Script- and Macro-Based Attacks 

Malicious scripts require our close attention: they have become incredibly popular with attackers in recent years, mainly because they effectively bypass traditional endpoint defenses and are easy to obfuscate.  
 
Macros are small programs written in scripting languages and embedded in other applications. They get direct access to the Windows API, making them incredibly powerful both for legitimate use and for hackers. 

You will learn to analyze macros in malicious documents 

You will get to know the two main approaches to dissecting scripts — viewing the source code or dynamically executing it and observing it — and master ANY.RUN’s built-in tools for analyzing script-based malware and compiled malware that uses scripts. 

Malicious macros are given special attention since they are used in a number of real-world attack scenarios, and their code usually is heavily obfuscated which complicates analysis. You will learn to use tools like ANY.RUN can help you identify their behavior without resorting to tedious deobfuscation.

📄 Scripts and Macros Analysis Skills You’ll Learn
  • De-obfuscating malicious scripts to extract payloads
  • Analyzing PowerShell and JavaScript-based malware
  • Detecting macro-based threats in Office documents and emails

Get Access to Security Training Lab 

Interested in trying Security Training Lab yourself or bringing it to your educational institution?  

Send us a message and our team will get in touch to discuss your specific needs and provide a customized quote.

Get in touch with us
to learn more about Security Training Lab 



Contact us


Conclusion

Security Training Lab provides a comprehensive and hands-on learning experience for mastering malware analysis. Completing this course will equip you with essential skills to detect, analyze, and mitigate real-world cyber threats.

With in-depth knowledge and practical exercises, you will gain the confidence to navigate the ever-evolving landscape of cybersecurity threats and contribute effectively to digital defense strategies. 

For students looking to begin a career in cybersecurity, this course serves as a solid foundation. The skills you acquire will prepare you for roles such as malware analyst, security researcher, or SOC analyst, helping you take the first step toward a successful and impactful career in the field.

By mastering real-world threat analysis techniques, you will stand out in the job market and be ready to face the challenges of modern cybersecurity. 

About ANY.RUN

ANY.RUN helps more than 500,000 cybersecurity professionals worldwide. Our interactive sandbox simplifies malware analysis of threats that target both Windows and Linux systems. Our threat intelligence products, TI Lookup, YARA Search, and Feeds, help you find IOCs or files to learn more about the threats and respond to incidents faster.

Request free trial of ANY.RUN’s services → 

The post Learn to Analyze Real-World Cyber Threats with Security Training Lab appeared first on ANY.RUN’s Cybersecurity Blog.

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Malware Traffic Analysis in Linux: Hands-on Guide with Examples

Network traffic analysis is one of the most effective ways to detect and investigate malware infections. By analyzing communication patterns, researchers and security teams can uncover signs of malicious activity, such as command-and-control (C2) connections, data exfiltration, or DDoS attacks. 

In this guide, we’ll explore how traffic analysis helps detect malware, the key tools used for this purpose, and real-world examples of Linux malware analyzed in ANY.RUN’s Interactive Sandbox

How Traffic Analysis Helps Detect Malware 

Some types of malware rely on network communication to receive commands, exfiltrate stolen data, spread across systems, or launch attacks. That’s why network traffic analysis is one of the most effective ways to detect and investigate malware infections. 

By looking at how data flows in and out of a system, you can reveal a variety of malicious activities that might otherwise go unnoticed. 

1. Distributed Denial-of-Service (DDoS) Attacks 

Some malware turns infected devices into zombies within a botnet, instructing them to flood a target server with requests. This can cause service disruptions, slow down websites, or even take entire networks offline. 

☝ Signs in network traffic
  • Unusually high volumes of outgoing traffic
  • Sudden bursts of connections to multiple IPs
  • Large numbers of SYN packets

2. Command and Control (C2) Communication 

Many malware strains, from trojans to ransomware, rely on C2 servers to receive instructions from attackers. These communications can include downloading additional payloads, executing commands, or transmitting stolen data. 

☝ Signs in network traffic
  • Repeated communication with suspicious or newly registered domains
  • Encrypted traffic over unusual ports
  • Beaconing patterns

3. Data Exfiltration & Credential Theft 

Some malware is designed to steal sensitive data, such as login credentials, financial information, or intellectual property. This data is often encrypted and sent to an attacker-controlled server. 

☝ Signs in network traffic
  • Outbound traffic to unknown foreign IPs
  • Unusual spikes in file transfer protocols (FTP, SFTP) 
  • Large volumes of outbound DNS queries

4. Exploitation Attempts & Lateral Movement 

Advanced malware doesn’t just infect one machine. It looks for vulnerabilities to move laterally across a network, escalating privileges and compromising more devices. 

☝ Signs in network traffic
  • Repeated login attempts from a single source (brute-force attacks)
  • SMB traffic spikes
  • Use of internal IP scanning tools like Nmap

5. Malware Download & Dropper Activity 

Many infections start with a simple download: malware that acts as a dropper, pulling additional payloads from the internet. 

☝ Signs in network traffic
  • Downloads from unusual or newly registered domains
  • Traffic to known malware-hosting services
  • Execution of PowerShell or wget/curl commands from unknown sources

What Tools to Use for Traffic Analysis 

Various tools help security professionals inspect network traffic and identify suspicious activities. Here are some of the most widely used ones: 

Malware Sandboxes 

Real-time network analysis inside ANY.RUN Linux VM 

A dynamic analysis environment like ANY.RUN allows users to observe malware behavior, including network communications, in a controlled setting. The sandbox logs network requests, DNS queries, and protocol usage, making it easier to detect malicious patterns. 

Analyze Linux and Windows threats inside the safe and secure ANY.RUN Interactive Sandbox 



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Wireshark 

A powerful packet analysis tool that enables deep inspection of network activity. Analysts use it to capture live traffic or examine PCAP files for suspicious network behavior. 

tcpdump 

A command-line tool for packet capturing and analysis. It provides a lightweight method to monitor network traffic directly from Linux terminals. With tcpdump, analysts can capture packets that flow through a network interface, apply filters to focus on specific traffic, and save captures for later analysis. 

mitmproxy 

An interactive, SSL-capable proxy for analyzing and modifying HTTP/HTTPS traffic in real time. It’s useful for inspecting malicious web traffic generated by malware. 

Analyzing Linux Malware Traffic with a Sandbox 

ANY.RUN’s Interactive Sandbox provides a real-time, dynamic analysis environment that helps researchers and security teams uncover malicious network activities associated with Linux malware. 

Let’s discover how ANY.RUN can make Linux malware traffic analysis more effective: 

Real-time network monitoring: Observe malware’s network behavior live and view outbound HTTP, HTTPS, and DNS traffic, detect hardcoded C2 servers, and spot encrypted connections on unusual ports. 

Interactive analysis: Engage with the infected environment to trigger malware behaviors, bypassing sandbox evasion tactics and uncovering hidden threats. 

Packet capture (PCAP) export: Capture and export all network traffic for deeper analysis in Wireshark or other packet inspection tools. 

Suricata-driven threat detection inside ANY.RUN sandbox 

Suricata-driven threat detection: The sandbox automatically flags malicious network behavior, including botnet communications, exploit attempts, and data exfiltration. 

Network activity displayed inside ANY.RUN Linux sandbox 

Faster investigations: Reduce time spent on manual traffic analysis with live, actionable insights and automated reporting. 

Real-World Linux Malware Analyzed in ANY.RUN Sandbox 

To demonstrate the power of ANY.RUN’s Linux Sandbox for malware traffic analysis, let’s examine three real-world Linux malware cases: 

Case 1: Gafgyt (BASHLITE) – Massive DDoS Attack 

Gafgyt, also known as BASHLITE, is a notorious Linux botnet malware that infects IoT devices and servers to launch DDoS attacks.  

View analysis session with Gafgyt 

Gafgyt malware analyzed inside ANY.RUN 

After examining it inside ANY.RUN’s sandbox, we can see that the malware hijacked the VM, turning it into a botnet. It then attempted to establish connections with over 700 different IP addresses, flooding the network with malicious traffic. 

Network connections observed inside ANY.RUN Linux VM 

After examining it inside ANY.RUN’s sandbox, we can see that the malware hijacked the VM, turning it into a botnet. It then attempted to establish connections with over 700 different IP addresses, flooding the network with malicious traffic. 

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The malware established connections with botnet C2 servers, triggering a Suricata alert due to suspicious network behavior.  

You can observe this detection in the “Threats” section under Network Activity Analysis in ANY.RUN: 

Suricata rule triggered by Gafgyt malware 

ANY.RUN provides a PCAP export feature, allowing you to analyze captured network traffic in Wireshark or other specialized tools by exporting the packet capture file for deeper inspection and threat analysis. 

PCAP export feature for deeper analysis 

Case 2: Mirai – Detecting Malicious Network Behavior  

Mirai is a notorious Linux-based malware that primarily targets IoT devices, such as routers, cameras, and other connected systems. It infects devices by exploiting weak or default credentials, turning them into botnet nodes used for large-scale DDoS attacks. 

Once infected, these compromised devices begin scanning the internet for other vulnerable systems to expand the botnet. 

View analysis session with Mirai attack 

Mirai malware detected by ANY.RUN sandbox 

In this analysis session, we observe a Mirai attack within a controlled environment using ANY.RUN’s Interactive Sandbox.  

The malware’s behavior was automatically detected, as it triggered a Suricata rule, confirming its presence through network traffic analysis.  

The session shows how Mirai communicates, spreads, and attempts to establish connections with remote servers.  

Suricata rule triggered by Mirai malware  

Case 3: Exploit – Behavioral Detection in Network Traffic 

Exploits are a common attack vector used by threat actors to gain initial access to Linux systems. These attacks take advantage of system vulnerabilities, often unpatched software or misconfigurations, to execute malicious payloads, escalate privileges, or establish persistence.  

Once inside, attackers can deploy additional malware, steal sensitive data, or take full control of the compromised machine. 

View analysis session with Exploit 

Exploit detected by ANY.RUN 

In this analysis session, you can observe the exploit in a controlled environment as it attempts to manipulate system processes. 


Learn to analyze malware in a sandbox

Learn to analyze cyber threats

See a detailed guide to using ANY.RUN’s Interactive Sandbox for malware and phishing analysis



As you can see, the exploit was automatically flagged by Suricata, providing clear evidence of an active attack. 

Suricata rule triggered by Exploit 

Why Businesses & Security Teams Should Use ANY.RUN for Linux Malware Detection 

By examining network traffic inside ANY.RUN’s Linux Sandbox, businesses and security teams can: 

  • Detect threats faster: Real-time analysis exposes malware behavior instantly. 
  • Reduce investigation time: Automated Suricata alerts streamline detection. 
  • Improve network security: Identify and block malicious traffic before it spreads. 
  • Get deeper insights: PCAP exports and interactive analysis allow teams to get deeper insights.

About ANY.RUN

ANY.RUN helps more than 500,000 cybersecurity professionals worldwide. Our interactive sandbox simplifies malware analysis of threats that target both Windows and Linux systems. Our threat intelligence products, TI Lookup, YARA Search, and Feeds, help you find IOCs or files to learn more about the threats and respond to incidents faster.

Request free trial of ANY.RUN’s services → 

The post Malware Traffic Analysis in Linux: Hands-on Guide with Examples appeared first on ANY.RUN’s Cybersecurity Blog.

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Your item has sold! Avoiding scams targeting online sellers

  • There are many risks associated with selling items on online marketplaces that individuals and organizations should be aware of when conducting business on these platforms. 
  • Many of the general recommendations related to the use of these platforms are tailored towards purchasing items; however, there are several threats to those selling items as well.
  • Recent phishing campaigns targeting sellers on these marketplaces have leveraged the platforms’ direct messaging feature(s) to attempt to steal credit card details for sellers’ payout accounts.
  • Shipment detail changes, pressure to conduct off-platform transactions, and attempted use of “friends and family” payment options are commonly encountered scam techniques, all of which seek to remove the seller protections usually afforded by these platforms.
  • There are several steps that sellers can take to help protect themselves and their data from these threats. Being mindful of the common scams and threats targeting sellers can help sellers identify when they may be being targeted by malicious buyers while it is occurring so that they can take defensive actions to protect themselves.

Your item has sold! Avoiding scams targeting online sellers

The emergence of online marketplaces has facilitated the convenient exchange of goods between individuals and organizations around the world. It has also provided a means for people to easily resell items, enabling them to recapture value from assets they may not otherwise wish to maintain ownership of. The type of new and used items sold via marketplaces varies widely, and platforms such as Ebay, Facebook Marketplace, Reverb, and others are extremely popular avenues for selling everything from $15 vintage tissue boxes to $40,000 Gibson Les Paul guitars. You can even find $70,000,000 domains targeting affluent individuals with above-average BMIs being sold on online marketplaces.

Your item has sold! Avoiding scams targeting online sellers

When we think about online safety in the context of these platforms, we often concentrate the majority of our efforts and recommendations on the threats targeting buyers. In many cases, scammers are also actively targeting the people selling items on these platforms as well. From an adversarial perspective, it makes sense to target sellers, as these are likely to be individuals with large amounts of cash sitting in their accounts as they frequently receive payments for items they sell. Likewise, adversaries can easily monitor the public listings of seller accounts to identify when high-value items are listed, as well as when they are sold, so that they can identify when a target could reasonably be expected to receive an influx of cash into their accounts. 

Likewise, many platforms train their sellers to expect frequent, unsolicited account verification prompts delivered in any number of ways, which provides the perfect pretext for scammers seeking to take advantage of this pool of targets. From a detection and analysis standpoint, these types of attacks are often difficult to effectively combat, as platform providers, intelligence analysts, and law enforcement agencies are forced to primarily rely on self-reporting from victims to quantify the scope and impact of these types of threats. Let’s break down a few examples of some of the most common scams that target the individuals or organizations selling products on online marketplaces.

Phishing and malware scams

While some scams attempt to fraudulently steal items, others are primarily aimed at stealing financial information from sellers by leveraging the platform’s messaging feature(s) as a mechanism to directly communicate with them for the purposes of phishing or malware distribution. In some cases, phishing is used to compromise the seller account itself, enabling the attacker to manipulate listings, shipments, modify automated payout settings, and communicate with current and previous buyers to conduct additional fraudulent activities. In other cases, phishing is used to obtain financial information, such as bank account or credit card information, that can be used to steal money from the seller.

Payout account verification scams

In a recent example, a /r/guitarpedals user reported that they had received a suspicious direct message on their Reverb seller account. The message was crafted to appear as if it was sent from the Reverb team itself. It informs the seller that their item has sold and prompts them to complete account verification to ensure that they receive payment for the item(s) they have sold.

A hyperlink, present in the message (and shown below), attempts to leverage Reverb’s own redirection functionality to direct victims who click on the hyperlink to a malicious web server under the attacker’s control.

Your item has sold! Avoiding scams targeting online sellers

This technique uses percent encoding, an obfuscation technique, to mask the destination of the redirect and make it appear as if the link is pointing to the legitimate Reverb website.

Your item has sold! Avoiding scams targeting online sellers

This URL, when accessed, returns an HTTP/302 redirection to another attacker-controlled web server, but ultimately the victim receives the following landing page. The attacker has put effort into making sure it appears legitimate and mimics what the victim expects to see. A chat message prompts the victim to complete the verification process by following the on-screen instructions.

Your item has sold! Avoiding scams targeting online sellers

A “Receive Funds” button has been positioned behind the chat popup shown in the previous screenshot. When the victim clicks this button, they are presented an input form and prompted to provide the credit card information necessary to verify their desired payout account. Throughout this process, additional chat message popups are delivered to lend credibility to the process.

Your item has sold! Avoiding scams targeting online sellers

Since this is the account the seller would like to use to receive payments for items sold on the platform, it likely also contains any funds associated with previous sales, and will likely frequently receive lump sums when future items are sold, presenting a myriad of opportunities for attackers to monetize the account and assets within it, now or in the future. For example, if a threat actor successfully obtains credit card details for a seller account with multiple high-value items actively listed, they can simply wait until an item sells before attempting to monetize it.

Assuming the victim enters valid credit card details, a message will be displayed requesting additional information.

Your item has sold! Avoiding scams targeting online sellers

The additional information in this case is the balance of the account that is being “verified.” A new chat message appears, prompting the user to enter the balance in their account, presumably so that the attacker can more effectively prioritize which accounts to empty first.

Your item has sold! Avoiding scams targeting online sellers

Assuming the victim enters their balance information, they are presented with the following message letting them know that it will take a period of time before they notice any changes to their accounts.

Your item has sold! Avoiding scams targeting online sellers

At this point, the adversary has obtained credit card details that they can then monetize however they choose. It’s important to note that while this particular example targeted sellers using the Reverb platform, most other online marketplaces experience similar threats as well. We have also observed Reverb often taking rapid response actions when attempting to send messages containing percent-encoded hyperlinks, indicating that the platform is aware of the issue and has put in place some mechanisms to help reduce the frequency and quantity of these types of messages on the platform.

Reverb also presents warning messages to let users know when they are being redirected to a third-party domain, as shown in the screenshot below. 

Your item has sold! Avoiding scams targeting online sellers

It is important to always validate the destination of hyperlinks received from unsolicited sources and to limit access to off-platform resources when conducting business on online marketplaces.

It is also important to note that direct messaging within marketplaces is not the only mechanism used for this type of scam. Below is a screenshot of an email received by a Shopify storefront owner attempting to convince them to verify their payout account information, similar to the previous example described above.

Your item has sold! Avoiding scams targeting online sellers

Below is another example. In this case, the threat actor has sent an email claiming that the seller has received a chargeback claim from a customer and prompting them to take action. Since chargebacks are often received for a variety of reasons, sellers may be more easily convinced to provide account or credit card information when prompted with a claim related to a chargeback.

Your item has sold! Avoiding scams targeting online sellers

If an email is received from an online marketplace, the platform will typically also provide warning messages, banners, and other mechanisms to alert sellers of the same issue. In the case that a seller receives an unexpected email related to payment issues, sellers should attempt to resolve issues directly on the platform rather than accessing content or responding to the email. 

Scams to remove seller protection

When selling new or used items using online marketplaces, one of the most important elements influencing platform and payment method selection for many people are the seller protection policies in place. These policies often provide protection from common types of fraudulent claims that may be made by buyers, such as non-receipt, damage, etc. In order to remain in effect, they generally require both the buyer and seller to perform the transaction following certain requirements that enable proper resolution should an issue arise. 

In an effort to remove these protections and make it easier to successfully monetize their scam(s), scammers posing as buyers will often attempt to convince sellers to conduct portions of the transaction “off-platform,” as this will void the protection policy that would otherwise be in place using a variety of different pretexts and themes. Likewise, some scammers target the shipping part of the transaction process, attempting to convince sellers to modify the shipping to void the seller protection policy afforded by the platform. By removing the ability for the seller to leverage the protection policy afforded by the platform used to sell the item, many of the normal recourse steps usually taken when dealing with fraudulent buyers are no longer available to the seller.

Off-platform transactions

Scammers also frequently use a variety of pretexts to attempt to convince sellers to perform the financial transaction associated with an item purchase using third-party platforms separate from the one on which an item was originally listed. They will attempt to trick victims into moving to an alternative mechanism for performing the transaction so that the seller loses most of the protection(s) afforded by the marketplace. 

In many cases, scammers will use additional pressures, such as time sensitivity, urgency, or manipulated screenshots showing failed transaction attempts, to convince sellers to perform transactions using alternative means, such as wire transfers or money transfer platforms, where seller protections are limited and—in the case of fraud—most recourse options are no longer available. 

There are countless examples of different pretexts being used in varying capacities, all ultimately for the same purpose, to convince sellers to leave the marketplace to perform the transaction elsewhere so that seller protections against fraudulent activity on the part of the buyer are removed.

Shipment detail changes

Since a seller account’s past and current item listings are easily accessible from the seller’s profile, it is easy for adversaries to leverage information contained within these listings (including photos) when building pretexts that are used to target the individual operating the seller account. One common way that adversaries leverage this information is by tailoring their messaging to account for both active and recently sold listings related to the seller they are communicating with. 

In the screenshot below, a scammer is contacting sellers on Ebay claiming to be an individual who purchased an item recently sold by the seller(s). The scammer hopes that by timing their message properly, they can take advantage of sellers who may not be paying close attention to the username listed in the message. For many sellers who are managing large numbers of listings, it can often be overwhelming to maintain many different streams of communication and/or multiple transactions simultaneously, leading them to respond quickly or otherwise take action (like modifying shipping instructions) without properly validating the content of the message.

Your item has sold! Avoiding scams targeting online sellers

Online reports indicate that it is not uncommon to receive these types of unsolicited messages, regardless of whether a seller has recently sold an item, which may be due to some level of automation being used to generate and transmit the messages. 

If the seller is convinced to change the destination address for the shipment due to receipt of one of these scam messages, the item that was sold may be shipped to an address under the attacker’s control. The attacker is then able to monetize the item while the original buyer does not receive the item that they purchased. Many of the protections afforded by online marketplace are lost when the shipping address used does not reflect what was present on the order at time of purchase, opening the seller to additional exposure as the buyer’s loss will still need to be resolved.

The “friends and family” option

Social media sites like Reddit have become very popular for posting used items to solicit interest from other users of a given subreddit. In some subreddits, there are even official or unofficial “Want to Buy / Want to Sell” (WTB/WTS) threads, where users can list items they are selling or items they would like to purchase. This creates an ideal pool of potential victims for scammers seeking to target users of these platforms.

Since Reddit is not an online marketplace, the transactions associated with this activity typically take place using money transfer platforms, such as Paypal, Zelle, or Venmo. Scammers will often leverage compromised accounts on these money transfer platforms when communicating with sellers (or buyers), often attempting to convince them to use the “friends and family” (or equivalent) payment option available on many of these platforms. Often, sending or receiving money with this option enabled removes many of the mechanisms in place to protect sellers from chargebacks and other fraudulent activity. Sellers should never enable this option when processing payments for goods they may sell via online marketplaces, social media sites, or in any transaction where protection against fraud is desired. 

In some cases, this method may be combined with other methods seeking to convince sellers to perform transactions outside of established platforms, then once the seller has agreed, scammers can leverage this option to further remove seller protections.

Recommendations

Most of the online literature related to defending against the scams pervasive on online marketplaces is geared towards the buyer experience. Recent trends in social media reporting indicate that sellers are also being increasingly targeted. While some of the scams faced by sellers resemble those faced by buyers, there are many that are unique. It is important that individuals or organizations leveraging online storefronts and/or marketplaces be aware of these threats so that they can prevent themselves from falling victim. 

It is extremely important that online marketplace accounts be protected with multi-factor authentication (MFA) whenever the platform supports this capability. This will provide an enhanced layer of security in cases where the account credentials are compromised as an additional authentication factor will still be needed to successfully access the account. 

When posting listings for items, be mindful of any photos that accompany the listing. Not unlike posting images to other social media platforms, items or objects in the background may unintentionally disclose sensitive information that could be used for malicious purposes. The information provided could also be leveraged to create more convincing or effective pretexts for later scam activities targeting the seller(s).

Avoid using third party services or platforms when conducting business transactions on online marketplaces. Take advantage of the protections afforded by the platform and avoid taking any actions that may jeopardize them. Reasonable buyers will be willing and able to conduct business following the standard platform transaction process. Sellers should avoid feeling pressured or worried about losing a sale and insist that the transaction take place in accordance with the policies of the online marketplace platform.

Verify the account associated with any messages received on online marketplaces. Always spend the time to validate that the message was actually received from the account of the buyer who purchased any recently sold items. Likewise, most platform support teams will not contact users via direct messaging for account verification or other sensitive processes as most of the time, these processes are directly supported by the platform itself. If a seller receives a direct message purporting to be from the platform itself, caution should be exercised and the message should be validated by contacting the support team separately using the information published on the marketplace website.

Sellers should also avoid modifying destination shipping addresses after orders have been placed. If a buyer asks to change the shipping address for an item they recently purchased, sellers should consider suggesting that they change their address using the online marketplace itself and contact support facilitate the change prior to shipping. This helps ensure that the seller is not deviating from the order that was placed, and helps ensure that they do not lose the seller protections afforded by the platform.

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Coverage

Ways our customers can detect and block this threat are listed below.

Your item has sold! Avoiding scams targeting online sellers

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 Web Appliance web scanning prevents access to malicious websites and detects malware used in these attacks.

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 Malware Analytics (Threat Grid) identifies malicious binaries and builds protection into all Cisco Secure products.

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. Sign up for a free trial of Umbrella here.

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.

Indicators of Compromise

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

Cisco Talos Blog – ​Read More

Malicious code in fake GitHub repositories | Kaspersky official blog

Can you imagine a world where, every time you wanted to go somewhere, you had to reinvent the wheel and build a bicycle from scratch? We can’t either. Why reinvent something that already exists and works perfectly well? The same logic applies to programming: developers face routine tasks every day, and instead of inventing their own wheels and bicycles (which might even be not up to par), they simply grab ready-made bicycles code from open-source GitHub repositories.

This solution is available to anyone —  including criminals who use the world’s best free open-source code as bait for attacks. There’s plenty of evidence to back this up, and here’s the latest: our experts have uncovered an active malicious campaign, GitVenom, targeting GitHub users.

What is GitVenom?

GitVenom is what we named this malicious campaign, in which unknown actors created over 200 repositories containing fake projects with malicious code: Telegram bots, tools for hacking the game Valorant, Instagram automation utilities, and Bitcoin wallet managers. At first glance, all the repositories look legitimate. Especially impressive is the well-designed README.MD file — a guide on how to work with the code — with detailed instructions in multiple languages. In addition to that, attackers added multiple tags to their repositories.

Attackers used AI to write detailed instructions in multiple languages

Attackers used AI to write detailed instructions in multiple languages

Another indicator reinforcing the apparent legitimacy of these repositories is the large number of commits. The attackers’ repositories have tons of them — tens of thousands. The attackers weren’t, of course, manually updating each of the 200 repositories to maintain authenticity, but simply used timestamp files that updated every few minutes. The combination of detailed documentation and numerous commits creates the illusion that the code is genuine and safe to use.

GitVenom: Two years of activity

The campaign started a long time ago: the oldest fake repository we found is about two years old. In the meantime, GitVenom has affected developers in Russia, Brazil, Turkey, and other countries. The attackers covered a wide range of programming languages: malicious code was found in Python, JavaScript, C, C#, and C++ repositories.

Regarding the functionality of these projects, the features described in the README file didn’t even match the actual code — in reality, the code doesn’t do half of what it claims. But “thanks” to it, victims end up downloading malicious components. These include:

  • A Node.js stealer that collects usernames and passwords, crypto wallet data, and browser history, packages the stolen data into a .7z archive, and sends it to the attackers through Telegram.
  • AsyncRAT — an open-source remote administration Trojan, which can also function as a keylogger.
  • Quasar — an open-source backdoor.
  • A clipper that searches the clipboard for crypto wallet addresses and replaces them with attacker-controlled addresses. Notably, in November 2024, the hacker wallet used in this attack received a one-time deposit of about 5 BTC (approximately US$485,000 at the time of the study).

You can read more about the details of this malicious campaign in our full research published on SecureList.

How to protect yourself from malicious code on GitHub

In short, the best defense is vigilance. Since over 100 million developers use GitHub, attackers will likely continue to spread malicious code through this popular platform. The only question is how they’ll do it — a decade ago, no one imagined that attackers would be able to conduct campaigns like GitVenom for so long and with such persistence. Therefore, every developer should maintain their cybersecurity hygiene when working with GitHub.

  • Analyze code before integrating it into an existing project.
  • Use malware protection on both computers and smartphones.
  • Check less obvious indicators carefully: contributor accounts, the number of stars (likes), and the project creation date. If the account was created three days ago, the repository two days ago, and it only has one star, there’s a good chance the project is fake and the code is malicious.
  • Don’t download files from direct links to GitHub shared in chats, suspicious channels, or on unverified websites.
  • If you find a suspicious repository, report it to GitHub — this could save others’ devices not protected with a Kaspersky Premium.

Kaspersky official blog – ​Read More

Auto-Woodpecker’s anniversary! | Kaspersky official blog

We live in the age of AI hype. Artificial intelligence is here, there, and everywhere – so promising, slightly mysterious, but undeniably guiding humanity toward a brighter future of technological singularity that’s still somewhat incomprehensible and potentially a black hole.

Some readers might detect sarcasm in this statement – but that would be a mistake. Machine learning-driven automation (ML), neural networks, and other AI technologies have already taken over many industries. And there’s more to come in the evolution of Homo sapiens. If you’re interested in diving deeper into this topic, check out the history of the various industrial revolutions: first, second, third, and even fourth.

In line with this trend, cybersecurity was perhaps one of the pioneers in adopting new, smart technologies. And what makes me particularly proud of this process is that our company was one of the first in the industry to successfully implement this bright AI-driven future. How else could we possibly handle nearly half a million new malicious programs emerging every single day as of early 2025? No educational system in the world can produce enough experts to keep up with that. The only solution is to create intelligent systems capable of independently and highly accurately neutralizing cyberattacks. Experts are then left with only the most complex cases – and, of course, the challenging task of inventing and continuously improving these systems.

A few days ago, we celebrated an exciting anniversary. Twenty years ago was born the prototype of our first AI/ML technology for automatic malware analysis and the creation of “detections” – antivirus updates that protect computers, gadgets, and other devices from new attacks.

The technology was given a name that’s rather odd at first glance – Avtodyatel, which translates as Auto-Woodpecker! But there’s a simple explanation for it: within our team, security analysts were affectionately referred to as woodpeckers – tirelessly pecking away at viruses and processing streams of suspicious files. And then we added the “Auto” to “Woodpecker” for the name of the tech designed to do this job automatically (incidentally, I was a woodpecker myself back then).

After digging through our archives, we found not only the birthdate of this first automation baby, but also some fascinating photos of the original plans for its creation. We even recalled its birthplace – the 14th floor of the Radiophysics building near the Planernaya metro station in northwest Moscow where we rented office space at the time. So get comfy, and I’ll tell you a fascinating story. It all started kinda like this…

A quarter of a century ago, malicious programs were much rarer – and, paradoxically, much more advanced – than today’s typical malware, despite being written by pioneering enthusiasts, inventive lone programmers, and cyber pranksters. This made researching them a real pleasure – each new virus taught you something new. Back then, like my fellow woodpeckers, I manually analyzed the stream of malicious programs – what would now be called “malware research”.

By that time, it was already difficult to compile all existing malware into a single reference book as had been done back in 1992. But we still managed the flow, and at the end of each work week, I manually compiled antivirus database updates.

However, over time, malware creation evolved from mere mischief and boundary-pushing into a full-fledged criminal industry. Cybercriminals no longer just wanted to infect as many computers as possible – they sought to profit from it. For example, they harvested email addresses from infected machines and sold them for spam distribution.

Sensing profit, these bad actors triggered exponential growth in malware production. But instead of inventing fundamentally new threats, they started mass-producing slightly modified versions of existing ones. And I realized we couldn’t keep up manually; if we were to continue down this path, we’d drown in an endless flood of cyber-garbage.

Fortunately, technological advancements at the time required much smaller investment and less development time. You could just buy some pizza (pineapple-topped, of course!), gather a few brilliant minds in a meeting room, and spend a couple of hours brainstorming project ideas. And so, on February 22, 2005, I assembled my colleagues to develop plans for automating our malware analyst work.

Just take a look at this beauty!

Plans for automating our malware analyst.

Plans for automating our malware analyst work.

We had some primitive automation tools before, of course. But Auto-Woodpecker was the first system with a fundamentally new level:

  1. It freed up valuable experts from repetitive tasks, allowing them to focus on more advanced challenges.
  2. It massively scaled up operational efficiency.
  3. It helped highlight similar (or related) incidents for further analysis.

In simple terms, the system automatically received new files from agents (“crawlers”) that scanned websites, email traps, and network sensors. These files were then automatically unpacked and executed in a secure environment – an artificial setting designed to observe malware behaviour.

There, the samples were analyzed by automated scanners, classified, and then compiled into antivirus databases.

The key challenge when encountering a new malware sample was determining whether it was a never-before-seen threat, or simply a variation of a known one. This is where the file auto-classifier (marked as “FF” in the diagram above) came into play, utilizing AI/ML principles – now an essential feature in nearly every cybersecurity product (except for fraudulent ones).

It didn’t work perfectly at first, but it quickly improved. We systematically documented all our ideas, detailed how subsystems would interact, how data would be exchanged, and how false positives would be handled. Then we rolled up our sleeves and got to work.

A few months later, the first version of Auto-Woopecker went live.

The results were instant and dramatic. Previously, five of us manually analyzed around 300 malware samples per week – an impressive number at the time. But with Auto-Woodpecker our productivity skyrocketed. And as the technology improved, this skyrocketing just kept on… skyrocketing!

Before long, Auto-Woodpecker was processing the entire incoming stream – leaving only 2-5% of all suspicious files for manual expert review. Today, of course, our tools are far more advanced, and AI-driven technologies play an even bigger role in cybersecurity.

To give you a glimpse of how far we’ve come, here are just a few recent examples:

  • Kaspersky MLAD (Machine Learning for Anomaly Detection): A predictive analytics system that detects early signs of equipment failure, process disruptions, cyberattacks, and human errors in industrial telemetry signals – long before they cause real damage.
  • Kaspersky MDR (Managed Detection and Response) This service has been using an AI analyst for several years to filter out false positives, reducing the workload on SOC specialists and allowing them to focus on complex threat investigations.
  • Kaspersky Threat Lookup: Just last week we integrated a tool for finding contextual information on indicators of compromise using an AI-powered large language model.

The results speak for themselves, and we have even bigger plans ahead!…

Happy 20th Anniversary, Auto-Woodpecker!!

Cin cin!

Kaspersky official blog – ​Read More

What to do if your WhatsApp is hacked: a step-by-step guide | Kaspersky official blog

Your messaging-app account might be of interest to more than just jealous spouses or nosy coworkers. Stolen WhatsApp accounts fuel large-scale criminal activity — ranging from spam distribution to complex scam schemes. That’s why cybercriminals are constantly on the lookout for WhatsApp accounts — using various methods to hijack them. Here are eight signs your account may already be compromised.

  1. You get replies to messages you never sent.
  2. Friends complain about strange messages coming from your account.
  3. You notice deleted messages in chats, including from yourself — even though you never sent or deleted anything there.
  4. You receive a WhatsApp login verification code that you didn’t request or expect.
  5. Your account has a status or has posted stories you didn’t create.
  6. Your profile picture, name, or account description has changed unexpectedly.
  7. You’ve been added to chats or groups you never joined.
  8. When you try to log in, WhatsApp informs you that your account is in use on another device and prompts you to re-register (this is the most telling sign).

Pay special attention to the first three signs, and act immediately if you notice them — hackers often use compromised accounts to scam a victim’s friends and family. They might impersonate you to request urgent financial help, promise gifts, or invite people to participate in fake polls. In any of these cases, your friends could get scammed — with your unwitting help.

Two ways hackers can hijack your WhatsApp account

Cybercriminals can take control of your WhatsApp account in one of two ways. They either add another device to your account using the “Linked devices” feature, or re-register your account on their device as if you’d bought a new phone.

In the former case, you continue using WhatsApp as usual but the criminals also have access to it, including to your recent conversations.

In the second case, you lose access to your account, and when you try to log in, WhatsApp notifies you that your account is in use on another device. The attackers can control your account, but won’t have access to your past conversations.

What to do if your WhatsApp account has been hacked

  1. Make sure the SIM card linked to your WhatsApp account is inserted in your smartphone.
  2. Open WhatsApp on this smartphone.
  3. If it opens normally:
  • Go to the WhatsApp settings — Settings on iPhone, or the additional menu (three dots) on Android. Tap Linked devices.
  • Tap each device listed on this page.
  • Tap Log Out. This will disconnect all additional devices from your account and cut off the attackers.
  1. If the messenger tells you that you’re logged out and need to register:
  • Enter your phone number.
  • Request a one-time registration code.
  • Wait for an SMS or a voice call with the code.
  • Enter the received code.
  • If your account was protected with a two-step verification PIN, after entering the one-time registration code, enter your PIN as well.
  • WhatsApp may offer to restore your chats and settings from a backup in iCloud, Google Drive, or local storage. Accept!
  1. If you hadn’t previously set a two-step verification PIN, but WhatsApp requests it after you enter the one-time code, the attackers may have set a PIN to prevent you from regaining access to your account.
  • The PIN can be reset using the Forgot PIN
  • If an email address is linked to your WhatsApp account, you’ll receive a PIN reset link instantly. Go to your email, open the latest message from WhatsApp, tap the link inside, and then Confirm. After this, you can return to WhatsApp and set a new PIN.
  • If you hadn’t linked an email address, you can still request a PIN reset, but you’ll have to wait a week before the PIN is removed. During this time, your WhatsApp account will remain inaccessible. After a week, you can log back in to your account following the instructions above.

Once you’ve completed these steps, the attackers will be disconnected from your account. However, they may attempt to hijack it again, so be sure to follow the security tips below.

Warn your friends and family

Attackers may have sent tragic or provocative messages to your contacts, impersonating you. To ensure no one panics thinking you’re in hospital, got arrested, or had an accident — and to prevent them from sending money to “help” — inform as many people as possible that your account was hacked and that they should ignore any strange or unexpected messages sent earlier. For close friends, family, and coworkers, it’s best to call them personally. A less intrusive way to warn many people at once is to update your WhatsApp status. Go to Settings, tap your name, and in the About field, write something like, “My WhatsApp was hacked! Don’t trust messages from me, don’t send money, no help is needed”. It’s also a good idea to post the same warning on other social networks.

If your account has been restricted or banned for spam

If hackers used your account to send spam, WhatsApp may temporarily restrict it for a few hours or days. After following the steps above and regaining control of your account, you may find you’re unable to send messages.

In this case, appeal the restriction using the Request a review button, found under the notification about the imposed restrictions. After tapping this button, the restriction won’t be lifted immediately — depending on WhatsApp’s internal algorithms, it can take anywhere from a couple of hours to three days. Unfortunately, there’s no way to speed up this process.

How to protect your account from being hacked again

We’ve provided a detailed guide on WhatsApp security and privacy settings in a separate article, but here are the key points:

  • Enable two-step verification in WhatsApp and memorize your PIN — it’s not a one-time code. To do this, go to SettingsAccountTwo-step verification.
  • Never, ever share your PIN or one-time registration codes with anyone. Only scammers ask for these details.
  • WhatsApp recently introduced support for passkeys. If you enable this option (Settings → Account → Passkeys), logging in to your account will require biometric authentication, and instead of PIN codes, your smartphone will store a long cryptographic key. This is a very secure option, but it may not be convenient if you frequently change devices and switch between Android and iOS.
  • Set up a backup email address for account recovery: Settings → Account → Email address.
  • If you’ve already added an email address, log in to your email account and change your password to a strong, unique one. To store it securely, use a password manager, such as Kaspersky Password Manager.
  • Enable two-factor authentication for your email account.
  • Make sure you haven’t fallen victim to a SIM swap scam. Contact your mobile carrier — preferably in person — and verify that no duplicate SIM cards have recently been issued for your number. Also, make sure there’s no unauthorized call-forwarding set up on your number. Cancel any suspicious changes and ask the staff about additional security measures for your SIM card. These may include prohibiting SIM-related actions without your being present, an extra password required for authentication, or other protections. Available security measures vary significantly by country and mobile carrier.
  • Any security measures in WhatsApp will be of little use if your smartphone or computer is infected with malware. Therefore, be sure to install comprehensive protection on all your devices.

Kaspersky official blog – ​Read More