ANY.RUN, a leader in interactive malware analysis and threat intelligence, has released a technical analysis authored by RacWatchin8872 documenting new techniques used in multi-stage attacks involving AsyncRAT. The report details how attackers exploit open directories to distribute AsyncRAT, examines the infection mechanisms, and offers indicators of compromise (IOCs) for identifying and mitigating this persistent threat.
Overview
AsyncRAT is a type of Remote Access Trojan (RAT) malware designed to stealthily infiltrate systems and give attackers remote control over infected devices. It is commonly used for spying, data theft, and manipulation of compromised systems.
Recently, two open directories surfaced, each employing unique methods to distribute and infect victims with AsyncRAT. These techniques highlight the persistent threat posed by this malware and its diverse infection strategies.
Technique 1: Infiltration via Open Directory Structure
Open Directory
While investigating malicious open directories exposed to the internet, I discovered one with an unusual structure.
The directory contained the following files:
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A text file with an extensive string that turned out to be a VBS script
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A JPG file that was actually a disguised ZIP archive
Figure 1 – Open directory structure
Analysis of the Txt file
The text file’s extensive string conceals an obfuscated VBS script. It uses random variables to store parts of the text that will be used to download the JPG file.
Figure 2 – Obfuscated VBS code
To make it easier to read we just need to make a few changes:
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Replace the variables with the actual text,
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Use intuitive names for variables that are used to write or download files.
Figure 3 – Deobfuscated VBS code
Now we see that the VBS script creates an XML file OMjRRRRRRRRRRRRRRRRRRRRvbK.xml located at C:UsersPublic. The content of the XML file contains a PowerShell script that downloads the disguised JPG file, saves it, and extracts it to the same directory.
Once extracted, the process continues by executing another script, TesKKKeLAvaYdAfbBS.vbs. Then, it cleans up by deleting both the XML and ZIP files.
Figure 4 – TesKKKeLAvaYdAfbBS.vbs obfuscated
To make it simple to read, we just need to make a few changes:
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Replace the variables with the actual text,
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Use intuitive names for variables that are in use,
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Delete all the If Statements that execute the same code regardless of the result.
By making these changes, we can transform a 34-line VBS script into a simpler 6-line version that is easier to read.
Figure 5 – Clean TesKKKeLAvaYdAfbBS.vbs
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Analysis of the Bat file
The BAT script is also obfuscated, but it is possible to understand its purpose by reading the values stored inside the variables vertically.
Figure 6 – KKKKKKllLavIOOOOOtesAA.bat file
Its role is to execute PowerShell without a prompt window. It initiates the next stage by running KiLOvBeRNdautESaatnENn.ps1
Analysis of the PowerShell (PS1) file
The PS1 file is a simple script that creates a scheduled task named ‘tMicNet Work40,’ which runs UhLQoyDAMaCUTPaE.vbs every 2 minutes.
Figure 7 – Scheduled task created by PowerShell
Analysis of the Second VBS file
UhLQoyDAMaCUTPaE.vbs has the same structure as the previous VBS (TesKKKeLAvaYdAfbBS.vbs), so we can use the same technique to make the script easier to read and analyze.
Figure 8 – UhLQoyDAMaCUTPaE.vbs obfuscated
Using the same technique we will get this result:
Figure 9 – UhLQoyDAMaCUTPaE.vbs deobfuscated
Analysis of The Second BAT file
aaaNOOTKiiiLAViiiiOOs.bat has the same structure as the previous BAT (KKKKKKllLavIOOOOOtesAA.bat), so by reading it vertically, we can figure out what the file does.
Figure 10 – aaaNOOTKiiiLAViiiiOOs.bat
The BAT file executes the last stage, which is a Powershell file.
Analysis of the Last Stage
The final stage is obfuscated by changing the variable names to make the code harder to interpret. Instead of giving a straightforward name to the variable, they break the word into pieces, mix them up, and then call each position to reconstruct the variable name.
To simplify the analysis, we can deconstruct the code in a similar way, isolating each piece to make the script clearer and easier to understand.
Figure 11 – Analysis of the last stage
The first part of the code is a function that receives a string and converts it from hexadecimal to a 32-bit integer.
Figure 12 – First part of the final stage
The second part of the code contains two variables with large strings. Both strings use a replace function to retrieve the correct value, which are then sent to the ‘PARSer’ for further processing.
Figure 13 – Second part of the last stage
The last part of the final stage is simply loading the files into memory to execute them.
Figure 14 – Last part of the last stage
With the help of CyberChef, we can apply the same technique as shown in the second part of the final stage to retrieve the values inside the two variables and see what they really are:
The first variable is a DLL:
Figure 15 – AsyncRAT DLL
The second variable is an EXE:
Figure 16 – AsyncRAT EXE
By running both in ANY.RUN sandbox, it is possible to gather information about the C2, ports, certificates, mutex, and more.
Figure 17 – Text report generated by ANY.RUN sandbox
– Second Technique
Open Directory
The structure of the second open directory mirrors the first, containing two files: a TXT file and a JPG file.
The TXT file, with a shorter name, is a VBS script, while the JPG file hides a PowerShell script in disguise.
Figure 18 – Open directory
Analysis of the Txt file
In this case, the TXT file contains a VBS script that is easier to interpret due to its comments. It includes an array storing commands to download the disguised JPG file.
Figure 19- VBS script
To simplify the script further, we can delete the array and store all the array values in a single variable.
Figure 20 – Cleaning VBS script
Analysis of the Powershell file
The PowerShell file performs 2 main functions:
1.File creation and content writing – Creates three files essential to the infection process.
2.Scheduled task setup – Schedules a task to ensure repeated execution, thereby maintaining the AsyncRAT infection.
File Creation
The Powershell creates 3 files:
First file:
This obfuscated file stores and executes the values of EXE and DLL files related to AsyncRAT directly in memory.
Figure 21 – First file created by the Powershell file
After cleaning the file, it removes ‘%&%’ from both variables, converts them from hexadecimal, and then loads and executes them into memory.
Figure 22 – Loading file into memory
By carrying out the above-mentioned processes via CyberChef, we get the following results:
Figure 23 – AsyncRAT Exe
Figure 24 – AsyncRAT DLL
Second file:
The second file triggers PowerShell to execute the previous file (roox.ps1).
Figure 25 – Second file created by Powershell file
Third file:
The third and final file runs the previous file roox.bat while keeping the execution hidden from the victim. This ensures that the infection process remains invisible and minimizes any visible indicators, making it harder for the victim to detect the ongoing activity.
Figure 26- Third file created by Powershell file
Scheduled Task
The scheduled task, named thepiratMicrosoftEdgeUpdateTask, executes roox.vbs every two minutes, ensuring that the infection persists.
Figure 27 – Scheduled task named thepiratMicrosoftEdgeUpdateTask
Upon running the PowerShell script inside the ANY.RUN sandbox, we can see the files being created and executed. We can also gather more information about the command and control (C2) infrastructure.
Figure 28- Files created by the Powershell script
Figure 29 – C2 Ip and DNS
Conclusion
Our investigation uncovered two IPs actively spreading AsyncRAT through different methods. The first method follows a multi-stage process, employing several files and scripts to complete the infection.
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The second method uses only two stages, one of which involves generating files that are triggered by a scheduled task, as shown in the image below:
Figure 30 – Difference between two methods
The post AsyncRAT’s Infection Tactics via Open Directories: Technical Analysis appeared first on Cybersecurity Insiders.
November 10, 2024 at 09:55AM
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