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Uncovering RedStinger - Undetected APT cyber operations in Eastern Europe since 2020
Categories: Threat Intelligence We discovered a new interesting lure that targeted the Eastern Ukraine region and started tracking the threat actor behind it.
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The post Uncovering RedStinger - Undetected APT cyber operations in Eastern Europe since 2020 appeared first on Malwarebytes Labs.
This blog post was authored by Malwarebytes’ Roberto Santos and Fortinet’s Hossein Jazi
While the official conflict between Russia and Ukraine began in February 2022, there is a long history of physical conflict between the two nations, including the 2014 annexation of Crimea by Russia and when the regions of Donetsk and Luhansk declared themselves independent from Ukraine and came under Russia’s umbrella. Given this context, it would not be surprising that the cybersecurity landscape between these two countries has also been tense.
While looking for activities from the usual suspects, one of our former coworkers at Malwarebytes Threat Intelligence Team discovered a new interesting lure that targeted the Eastern Ukraine region and reported that finding to the public. Moreover, we started tracking the actor behind it, which we internally codenamed Red Stinger.
This investigation remained private for a while, but Kaspersky recently published information about the same actor (who it called Bad Magic). Now that the existence of this group is public, we will also share some of our information about the actor and its tactics.
Our investigation could be helpful to the community as we will provide new undisclosed data about the group. We have identified attacks from the group starting in 2020, meaning that they have remained under the radar for at least three years. Additionally, we will provide insights into the latest campaigns performed by Red Stinger, where we have found that the group has targeted entities in different places of Ukraine.
Military, transportation and critical infrastructure were some of the entities being targeted, as well as some involved in the September East Ukraine referendums. Depending on the campaign, attackers managed to exfiltrate snapshots, USB drives, keyboard strokes, and microphone recordings.
Finally, we will reveal unknown scripts and malware run by the group in this report.
Timeline
Our investigation started in September 2022, when one of our former coworkers Hossein Jazi discovered an interesting lure, that seemed to target some entities over the war context:
Tweet published by @hjazi in September 2022
In fact, this is the attack that Kaspersky analyzed in its blog. However, this was not the only activity carried out by the group. Malwarebytes has identified multiple operations, first dated in 2020. The next infographic shows some of the operations recognized by us:
Operations performed by Red Stinger
Since our investigation started in September 2022, information about the initial campaigns has been limited. However, the actor’s tactics, techniques, and procedures (TTPs) are very distinctive, which gives us a high level of confidence in our attribution.
Notes about activity before the war****OP#1 - Late 2020
The first operation we know of happened in December 2020. Although the infection chain is similar to what was already reported, the attackers were using a slightly different process back in 2020:
OP#1 Infection phase
An MSI file is downloaded from hxxp://91.234.33.185/f8f44e5de5b4d954a83961e8990af655/update.msi. This first MSI file, when executed, will show the following error to the user:
MSI file used in OP#1
In the background, this MSI file will execute a .vbs file that runs a dll file. The content is encoded using base64:
Contents of zip file and detail of shortcut.vbs
So finally, cachelib.dll will be executed. That file will drop two files named iesync.so and iesync.vbs.
iesync.so and iesync.vbs were dropped as part of OP#1 infection phase
After that, the iesync.vbs file will apply a XOR operation to iesync.so. After applying that conversion to the file, we can see that this file is what we called DBoxShell (also called PowerMagic by Kaspersky):
DboxShell variant used in OP#1
OP#2 - April 2021
We believe that the attack started with this zip file named ПОСТАНОВЛЕНИЕ № 583-НС.zip. How attackers sent this file to victims is still unknown. The lure in this case was themed about Luhansk:
Lure used in OP#2
A valid translation of this document would be:
RESOLUTION
dated March 25, 2021 No. 584-NS
Lugansk
On consideration in the second reading of the draft law
of the Luhansk People’s Republic dated March 19, 2021 No 417-PZ / 21-3
"On Amendments to the Law of the Luhansk People’s Republic
“On physical culture and sports”
ПОСТАНОВЛЕНИЕ № 583-НС.zip contains a lnk file as well as the previous pdf. This .lnk file will download an MSI file from the url hxxp://91.234.33.108/u3/ebe9c1f5e5011f667ef8990bf22a38f7/document.msi, and from there, the attack is pretty similar as the one performed in OP#1. Just a few differences to note, for example, in this case the dll used is named libsys.dll.
Dll used at infection phase in OP#2
Also, as the image shows, paths used the folder winappstorepackage or WinStoreApps instead of CacheWidgets, that was used in OP#1. Also, the powershell script is slightly different in this case:
Powershell snippet run in OP#2
Nevertheless, the infection phase finally used DBoxShell, as before.
OP#3 - September 2021
We have very little information about this operation, but based on the TTPs, we have identified overlapping techniques with both previous and subsequent attacks.
MSI files usage is a known signature from the group. Also, the MSI file was downloaded from hxxp://185.230.90.163/df07ac84fb9f6323c66036e86ad9a5f0d118734453342257f7a2d063bf69e39d/attachment.msi. Note the common pattern in urls.
185.230.90.163 belongs to ASN number 56485. All IPs used from 2020 till now belong to the same ASN.
VT telemetry showed common patterns with OP#2.
Activity at the onset of war
After the war began, we collected information about two distinct operations.
OP#4 - February 2022
OP#4 is perhaps one of the most interesting attacks performed by the group. As you can see in the following lines, this attack still has some characteristics that led us to attribute it to Red Stinger. Furthermore, the attack has some unique features that make it stand out as one of the most interesting ones.
In this case, the group used hxxp://176.114.9.192/11535685AB69DB9E1191E9375E165/attachment.msi to download the malicious MSI file. Note once more this common pattern in all URLs used by the group. This MSI file contained a PDF, a .vbs file, and a .dat file:
Lure used in OP#4
The group followed a similar infection chain as in previous operations. Finally, a .vbs file was responsible for XORing and executing a .dat file, which contained a small loader and a variant of DBoxShell:
DboxShell variant used in OP#4
DBoxShell is malware that utilizes cloud storage services as a command and control (C&C) mechanism. This stage serves as an entry point for the attackers, enabling them to assess whether the targets are interesting or not, meaning that in this phase they will use different tools.
A better look of how RedStinger operates can be seen in the next infographic:
Common pattern in Red Stinger operations
After the infection phase, we are aware that actors dropped at least the following artifacts:
SolarTools
In the reconnaissance phase, we noticed the execution of 2 MSI files named SolarTools.msi and Solar.msi. Both had inside tools named ngrok.exe and rsockstun.exe:
Ngrok.exe is a legitimate tool that allows web developers to deploy applications and expose services to the internet. Other groups also used ngrok for malicious purposes.
Rsockstun is a tool that allows attackers to route connections through external proxies.
More important, we have seen the same version of Solar.msi (02f84533a86fd2d689e92766b1ccf613) on OP#4 and OP#5, allowing us to connect the dots between these two attacks.
vs_secpack.msi
In addition to SolarTools, starting the exfiltration phase, we also found another file named vs_secpack.msi. This file contains two files: ntinit.exe and ntuser.dat, which will be located under c:/ProgramData/NativeApp. Ntinit.exe is a file that was developed as a Windows Service, named ntmscm.
Service created by ntinit.exe
Inside that service, eventually a thread will be executed. This thread contains all the functionality. Its main purpose is to execute one of the binaries hidden inside ntuser.dat, after some parsing. Also, it will execute C:/ProgramData/user.dat, if found.
vs_secpack.msi will drop ntuser.dat and ntinit.exe files
Ntuser.dat is an aggregation of PE files with a leading header and a final chunk. These executables are xored, each one with a different value. The next image shows the header:
Detail of Ntuser.dat header
This header can be seen as a C structure, defined like this:
struct head_FirstChunk{
DWORD signature;
DWORD osInstallDate;
int sizeMz1;
int sizeMz2;
int sizeMz3;
int sizeMz4;
int sizeConfig;
DWORD xorValsMZ1;
DWORD xorValsMZ2;
DWORD xorValsMZ3;
DWORD xorValsMZ4;
}
Following this header, four PE files are stored consecutively and XORed. As the previous structure shows, the size and XOR value used to decode these files can be recovered from the header.
ntuser.dat contents
We won’t analyze all MZs one by one, as we want to avoid overwhelming the reader with technical details that are out of scope. For a quick reference, the first MZ was a copy of ntinit.exe and the second was a dll capable of injecting files using the Process Doppelganging technique. Curiously, InjectorTransactedHollow.dll string was found inside the binary, so possibly that was how attackers named the file originally:
Process Hollowing technique was used to perform injections in OP#4
The third was also used for injection purposes. The fourth was the most interesting, because it communicates with a new Dropbox account. Some of these will be injected or used to inject MZs into legitimate process mobisync.exe
Finally, the last chunk of ntuser.dat was a configuration file. The configuration was encrypted, and looked like this:
Config file forms the end of ntuser.dat
That configuration was encrypted using AES. The IV is the first 16 bytes of the config. The key can be recovered from the fourth MZ. In fact, this executable will use this configuration to communicate with Dropbox.
Decrypted configuration is shown next:
Decrypted config file
This configuration is pretty representative of the group’s motivation. First of all, we see a new Dropbox account being used. This Dropbox account will be used to gather exfiltrated victims data. It can be seen like the exfiltration phase starts here. Note that attackers will use one account for reconnaissance and a different one for exfiltration.
The object field was also revealing. It contained a Russian name (redacted for privacy) followed by the DNR letters (probably Donetskaya Narodnaya Respublika, referring to one of the cities declared independent in 2014, and a known target to the group). Victimology will be discussed later.
OP#5
OP#5 was the last known activity we will cover. As Kaspersky already revealed some technical details about this operation, we won’t repeat that analysis again. A link to the analysis made by them can be found at the beginning of this report.
What we can do here is provide some extra insights regarding the attack. Let’s start at the Reconnaissance phase. Reconnaissance phase starts right after DBoxShell / GraphShell is executed. This is the GraphShell version used in OP#5:
OP#5 used GraphShell instead of DBoxShell
The way GrapShell works is pretty simple, and also can be almost guessed by viewing the image. A folder tree is created:
Root
\\\_\_\_ AmazonStore
\\\_\_\_ clients
\\\_\_\_ tasks
\\\_\_\_results
And as DBoxShell does, clients will hold heartbeats from clients, tasks will store tasks that will be executed at some point by victim systems, and results will be uploaded to results.
DETAIL - RECONNAISSANCE PHASE
As we were actively tracking the actors for a while, we managed to recover most of the actions performed by the attackers at this phase:
Support app used
Date (UTC)
Event
2022-09-23
Investigation starts
2022-09-24T02:53
Документи (Documents) folder is created in OneDrive
2022-09-24T02:53
Програми (Programs) folder is created in OneDrive
2022-09-24T02:53
JimmyMorrison43 folder is created under Documents, in OneDrive
2022-09-24T02:54
Робочий стіл (Desktop) folder is created in OneDrive
ListFiles
2022-09-24T10:25
Attackers sent a command to victim #1. Attackers were trying to list user files, as shown in the image
StartNgrok#1
2022-09-24T10:56
Attackers sent another command to victim #1.
This command is a powershell script with 32 lines, which executes SolarTools/ngrok.exe.
2022-09-25T16:09
An additional victim was found infected (Victim #4)
2022-09-27T10:01
An additional victim was found infected (Victim #5)
2022-09-28T05:07
An additional victim was found infected (Victim #6)
2022-09-28T05:17
An additional victim was found infected (Victim #7)
SysInfo
2022-09-28T06:14
A new command is sent to Victim #6. The command looks to be a basic reconnaisance
2022-09-28T06:14
ListFiles performed to Victim #6
SysInfo
2022-09-28T06:15
A new command is sent to Victim #7. The command looks to be a basic reconnaisance
2022-09-28T06:15
ListFiles performed to Victim #7
StartNgrok#2
2022-09-28T07:54
Attackers shown interest in Victim #6. They have installed an ngrok application to them, downloaded from
hxxp://185.166.217.184:2380/ApplicationSolarInstall_q3457y3487wy4t4bheors/Solar.msi
StartNgrok#1
2022-09-28T07:55
Attackers executed ngrok powershell in Victim #6 machine.
2022-09-28T08:22
An additional victim was found infected (Victim #8)
2022-09-28T11:37
An additional victim was found infected (Victim #9)
2022-09-28T13:21
An additional victim was found infected (Victim #10)
ListVars
2022-09-28T17:38:43
A new task is sent to Victim #8
ListVars
2022-09-28T17:48:12
New task to Victim
InstallNewPZZ
2022-09-29T06:58
InstallNewPZZ.ps1 was sent to Victim#6
InstallNewPZZ
20220929_06:59:21
InstallNewPZZ.ps1 was sent to Victim#1
InstallNewPZZ
20220929_06:59:49
InstallNewPZZ.ps1 was sent to Victim#4
InstallNewPZZ
20220929_07:00:28
InstallNewPZZ.ps1 was sent to Victim#7
InstallNewPZZ
20220929_07:06:22
InstallNewPZZ.ps1 was sent again to Victim#1
20220929_07:11:30
ps command was sent to Victim#6
20220929_07:11:45
ps command was sent to Victim#7
20220929_07:13:13
All.exe and ps was executed in Victim#6
20220929_07:13:30
All.exe and ps was executed in Victim#7
20220929_07:20:20
ps executed again in Victim#6
20220929_07:21:45
ls -r “C:\ProgramData\CommonCommand”
executed in Victim#6
MISSED FILE
[MISSED FILE] - probably schtasks /query
20220929_07:25:08
schtasks /run /tn "Synchronization
App" and ps executed in Victim#6
20220929_07:27:11
schtasks /run /tn "Synchronization
App" and ps executed in Victim#7
20220929_07:30:23
ls -r “C:\ProgramData\CommonCommand”
and schtasks /query sent to Victim#7
InstallNewPZZ
20220929_07:33:34
InstallNewPZZ.ps1 modification sent to Victim#7
20220929_07:35:41
ls -r “C:\ProgramData\CommonCommand” ,
schtasks /query and ps sent to Victim#7
InstallNewPZZ
20220929_08:01:30
InstallNewPZZ.ps1 modification sent to Victim#7
20220929_08:03:16
ls -r “C:\ProgramData\CommonCommand” ,
schtasks /query and ps sent to Victim#7
SysInfo
20220929_08:05:27
sysinfo.ps1 sent to Victim#1
InstallNewPZZ
20220929_08:16:38
InstallNewPZZ.ps1 sent to Victim#8
20220929_08:17:17
ls -r “C:\ProgramData\CommonCommand”
and ps sent to Victim#7
20220929_08:19:07
sysinfo.ps1 sent to Victim#1
20220929_08:27:07
ls "C:\Program Files (x86)\Internet
Explorer" sent to Victim#7
InstallNewPZZ
20220929_08:30:17
InstallNewPZZ.ps1 sent to Victim#7
20220929_08:34:27
ls -r “C:\ProgramData\CommonCommand”
sent to Victim#7
InstallNewPZZ
20220929_08:35:33
InstallNewPZZ.ps1 modification sent to Victim#7
20220929_08:38:13
ls C:\ProgramData sent to Victim#1
InstallNewPZZ
20220929_08:38:57
InstallNewPZZ.ps1 modification sent to Victim#7
InstallNewPZZ
20220929_08:41:12
InstallNewPZZ.ps1 modification sent to Victim#7
InstallNewPZZ
20220929_08:41:10
InstallNewPZZ.ps1 modification sent to Victim#1
InstallNewPZZ
20220929_09:53:07
InstallNewPZZ.ps1 modification sent to Victim#2
20220929_11:41:06
ls -r “C:\ProgramData\CommonCommand”
and schtasks /query sent to Victim#2
InstallNewPZZ
20220929_11:44:52
InstallNewPZZ.ps1 modification sent to Victim#2
20220929_11:46:09
ps sent to Victim#2
InstallNewPZZ
20220929_12:42:48
InstallNewPZZ.ps1 modification sent to Victim#2
20220929_12:43:02
ls -r “C:\ProgramData\CommonCommand”
sent to Victim#7
20220930_06:10:41
StartNgrok.ps1
InstallNewPZZ
20220930_06:17:40
InstallNewPZZ.ps1 modification sent to Victim#1
20220930_06:18:01
ls -r “C:\ProgramData\CommonCommand”
and schtasks /query sent to Victim#7
InstallNewPZZ
20220930_06:22:50
InstallNewPZZ.ps1 modification sent to Victim#7
InstallNewPZZ
20220930_06:24:10
InstallNewPZZ.ps1 modification sent to Victim#7
20221003_07:28:08
AppsJustForFunNoMatterWhatYouWant sent to Victim#1
Ld_dll_loader
20221003_07:28:24
ld_dll_loader.ps1 executed in Victim#1
20221003_07:28:41
ls “C:\ProgramData\” and ps executed
in Victim#1
Ld_dll_loader
20221003_07:28:57
ld_dll_loader.ps1 executed in Victim#2
Ld_dll_loader
20221003_07:42:51
ld_dll_loader.ps1 executed in Victim#2
20221003_07:43:07
ls “C:\ProgramData\” and ps executed
in Victim#2
StartRevSocks
20221005_14:25:50
StartRevSocks.ps1 was executed at Victim#3
20221007_07:32:24
New Client
20221007_14:46:49
New Client
Below are indicated some of the scripts used in this phase:
ListFiles
StartNgrok
Reconnaissance
InstallPZZ
Ld_dll_loader
StartRevSocks
After that, by using some of the tooling analyzed by Kaspersky, the exfiltration phase starts.
Victimology****OP#4
As this operation happened before our investigation started, we cannot determine how many victims were infected. However, at the time we began monitoring, we still had information about two victims. Surprisingly, these two victims were located in central Ukraine. This is interesting because all the information had previously pointed to East Ukraine, where the Donbass region is located.
Map of Ukraine, where known targets in OP#4 were highlighted
One of the victims was a military target, but the activity on this target was only carried out for a few hours. We have reason to believe that the user noticed something wrong, and executed an antimalware solution shortly after being infected, which likely detected and cleaned the system.
As far as we know, attackers managed to exfiltrate on this target several screenshots, microphone recordings and some office documents.
The other victim we found was located in Vinnitsya. Target was an officer working in critical infrastructure. Attackers made a great and long surveillance of this victim, which extended until Jan 2023. They have exfiltrated screenshots, microphone and office documents, but also keystrokes were uploaded.
OP#5
With the victimology shared in OP#4, we may think that this was a group targeting only UA-aligned entities. However, the analysis of OP#5 revealed an interesting fact: it mainly targeted RU-aligned entities.
REFERENDUM TARGETS
OP#5 started in September 2022. Back in those days, Russia made referendums at Luhansk, Donetsk, Zaporizhzhia and Kherson. While that was happening, Red Stinger targeted and made surveillance to officers and individuals involved in those elections.
Two victims attacked in OP#5 were workers at Yasinovataya Administration (Donetsk). Another victim was also part of DPR administration, in Port Mariupol. All of them were performing different activities regarding elections. We also have found one victim holding the advisor position from CEC (Central Election Commission). According to Wikipedia, “The Central Election Commission of the Russian Federation (Russian: Центральная избирательная комиссия Российской Федерации, abbr. ЦИК, also Центризбирком) is the superior power body responsible for conducting federal elections and overseeing local elections in the Russian Federation”.
Central Election Commission of the Russian Federation (CIK) stamp
Regarding CEC, we had seen another victim codenamed CIK_03D502E0. CIK is also another term that could refer to CEC. Attackers showed great interest in this one, as this victim was one of the only ones with its own name (some were just identified by using a drive ID). Also, USB drives from that victim were uploaded. Next image shows a small fraction of filenames exfiltrated by the attackers. To clarify, TИK probably stands for TEC (Territorial Election Commision).
Detail of exfiltrated USB from CIK_03D502E0
Reconnaissance phase also revealed some nice info. DNS records obtained from another victim showed mail.gorod-donetsk.org, pop.gorod-donetsk.org, which could suggest that the victim was part of DPR administration.
From that same victim, those DNS records revealed connections against xn–j1ab.xn–b1adbccegehv4ahbyd6o2c.xn–p1ai (лк[.]лидерывозрождения[.]рф) translate Revival Leaders. That website was created "in behalf of Putin", and is a contest to find potential leaders and fill out positions at Kherson, Zaporozhye, DPR and Lugansk. It is unclear which positions will be filled by that, but winners were promised to get 1.000.000 rubles for a personally chosen training program in the Russian Federation.
лк[.]лидерывозрождения[.]рф webpage photo
OTHER VICTIMS
In addition to the victims involved in the September referendums, we also identified two other victims that did not seem to be related to the elections. One of them appeared to be related to the transportation ministry or equivalent, codenamed by the attackers as ZhdDor, which could be translated as “railroad.” We also found additional data that suggested that the attackers could be interested in transportation.
Furthermore, we discovered that a library in Vinnitsya was infected in OP#5. Although this victim was UA-aligned, we do not understand why it was a target, especially since it was the only UA entity targeted in OP#5. However, it is worth noting that in OP#4, an entity located in Vinnitsya was also targeted.
EASTERN EGG
Finally, we have 2 victims named TstSCR and TstVM. It turns out that attackers, at some point, infected their own machines in order to carry out some testing, or by mistake.
Exfiltrated screenshot showing one of the attacker’s machine
This first image is a good example of that. First of all, we noticed that the keyboard language was set to ENG, which is unexpected. This may suggest that the group was composed of native English speakers. However, we find it strange because of the way they named the project folder (internet_WORK). We cannot be certain, but we believe that no native speaker would use that naming convention.
Exfiltrated screenshot showing one of the attacker’s machine while debugging Overall.exe
This second image is also nice to show. As you may notice, this is the source code of the file Overall.exe (reported by researchers), while being debugged. Also, some of the victim folders we named in this report are shown as part of the sources.
Exfiltrated screenshot showing one of the attacker’s machine. Some internal paths were shown in that screenshot.
For the account TstVM we choose this screenshot. In this case, attackers were developing a tool they use to tunnel victim communications. It can be seen (redacted) how source code reveals external IP addresses used by them, as some internal ones, naming for machines that we have not redacted and even passwords.
Analysis of these machines also revealed the usage of the application AdvOr, used for tunneling communications through TOR.
Attribution
In this case, attributing the attack to a specific country is not an easy task. Any of the involved countries or aligned groups could be responsible, as some victims were aligned with Russia, and others were aligned with Ukraine.
What is clear is that the principal motive of the attack was surveillance and data gathering. The attackers used different layers of protection, had an extensive toolset for their victims, and the attack was clearly targeted at specific entities. Perhaps in the future, further events or additional activity from the group can shed light on the matter.
Indicators of Compromise****OP#1
Type
SHA256
Host
91[.]234.33.185
LNK
41589c4e712690af11f6d12efc6cca2d584a53142782e5f2c677b4e980fae5bd
MSI
C68ce59f73c3d5546d500a296922d955ccc57c82b16ce4bd245ca93de3e32366
DLL
9e73dacedf847410dd4a0caa6aac83d31f848768336514335d4872d0fde28202
DLL
B6491d99d7193499a320bf6ad638146193af2ced6128afe8af3666a828f1b900
B2c2b232bc63c8feb22b689e44ce2fb5bf85f228fef665f2f1517e542e9906c6
A924dd46b6793ec82e1f32e3fb4215295e21c61eaafc7995cb08c20c5fbadc47
OP#2
Type
SHA256
Host
91[.]234.33.108
ZIP
301e819008e19b9803ad8b75ecede9ecfa5b11a3ecd8df0316914588b95371c8
LNK
D956f2bf75d2fe9bf0d7c319b22a834976f1786b09ff1bba0d2e26c771b19ca2
DLL
9a6d4ac64fa6645c58a19b8c8795a8cb586b82f6a77aaf8f06eb83ba1f1390e8
2643B38BDAD89168BAEA4226DD6496B91ED283330B2C5D8CA134BEFA796E0F34
1FA2B3315FB2A12E65FD5258D1395597101F225E7BC204F672BCF253C82AEA55
OP#3
Type
SHA256
Host
185[.]230.90.163
OP#4
Type
SHA256
Host
45[.]154.116.147
Host
176[.]114.9.192
MSI
2ac977e6883405e68671d523eab41fe4162b0a20fac259b201ac460a691d3f79
PowerShell
78634be886ccb3949c8e5b8f0893cff32c474a466e4d4ceba35ba05c3d373bff
F7437b4b011e57394c264ed42bb46ad6f2c6899f9ca62f507bebbff29f2a3d3f
Dfc1e73685d3f11a3c64a50bb023532963807193169d185584f287aa8ce22a8b
EXE
Ce9af73be2981c874b37b767873fa4d47219810e2672bf7e0b5af8c865448069
Fbe650223893284282e0be8f7719b554ff7a1d9fbbc72d3e17a47a9a1ceb6231
Dfa442780702863bf5c71af0c475743eef754743c3d0336ff8c5032a30f30dc0
12f16409b6191e3b2c5fd874cca5010711347d28900c108506dbc7f4d403c365
OP#5
Type
SHA256
Host
185[.]166.217.184
ZIP
961c52567232c1f98c04b1e605c34b0309ff280afe01e1a31384589e30eccf05
LNK
Fb48b9102388620bb02d1a47297ba101f755632f9a421d09e9ab419cbeb65db8
MSI
9c16cf1f962bf736e3d6fb9ec3a37bb6f92c5f6cb1886d4332694ccc94735de8
VBS
78634be886ccb3949c8e5b8f0893cff32c474a466e4d4ceba35ba05c3d373bff
MSI
4808815cb03b5f31841c74755897b65ed03e56dbddbe0d1fed06af3710f32d51
ZIP
22bb73e97b01be2e11d741f3f4852380b3dae91d9ac511f33de8877a9e7c0534
LNK
C75d905cd7826182505c15d39ebe952dca5b4c80fb62b8f7283fa09d7f51c815
F405a26904d2f6aaf4ff5f24dc345a24751d13b691a0bf17ba8c94f08ebb8b5b
Aa0e722832b1a039c96fd9ff169df8f48419f48e1dacf88633a5c561e6db0ba5
8aa19e3654f6c26b6c564a8103781174abc540384b20f645e87531c754814cf1
0e4b133fe7562fe5a65a8b7463f0c4f69d951f18d351cafe44e5cae393392057
EXE
Bc93ef8e20f2a9a8799934d629fe494d5d82ea49e06ed8fb00ea6cc2e96f407e
EXE
82e4b4fddf5ea7b7c846d44bcc24d75edcec5726dfa5b81b9f43387a1fc1922a
332f6e99403841998f950ce2543b4a54c78aace2a2e1901b08917f63c7faa2f4
EXE
052309916380ef609cacb7bafbd71dc54b57f72910dca9e5f0419204dba3841d
EXE
D6b5f48d4e94207a5a192c1784f9f121b59311bfd6a5e94be7c55b0108c4ed93
EXE
4a5f9f62ef8dfae47b164a4d46d242a19a11061284325e560df22b4da44bb97d
EXE
70801ef4f485ba4eb8a76da0d50fc53563d82fdf37951b421b3ae864a04ccd1c
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