Written by: Stav Shulman, Matan Mimran, Sarah Bock, Mark Lechtik
Executive Summary
UNC1860 is a persistent and opportunistic Iranian state-sponsored threat actor that is likely affiliated with Iran’s Ministry of Intelligence and Security (MOIS). A key feature of UNC1860 is its collection of specialized tooling and passive backdoors that Mandiant believes supports several objectives, including its role as a probable initial access provider and its ability to gain persistent access to high-priority networks, such as those in the government and telecommunications space throughout the Middle East.
UNC1860’s tradecraft and targeting parallels with Shrouded Snooper, Scarred Manticore, and Storm–0861, Iran-based threat actors publicly reported to have targeted the telecommunications and government sectors in the Middle East. These groups have also reportedly provided initial access for destructive and disruptive operations that targeted Israel in late October 2023 with BABYWIPER and Albania in 2022 using ROADSWEEP. Mandiant cannot independently corroborate that UNC1860 was involved in providing initial access for these operations. However, we identified specialized UNC1860 tooling including GUI-operated malware controllers, which are likely designed to facilitate hand-off operations, further supporting the initial access role played by UNC1860.
UNC1860 additionally maintains an arsenal of utilities and collection of “main-stage” passive backdoors designed to gain strong footholds into victim networks and establish persistent, long-term access. Among these main-stage backdoors includes a Windows kernel mode driver repurposed from a legitimate Iranian anti-virus software filter driver, reflecting the group’s reverse engineering capabilities of Windows kernel components and detection evasion capabilities. These capabilities demonstrate that UNC1860 is a formidable threat actor that likely supports various objectives ranging from espionage to network attack operations. As tensions continue to ebb and flow in the Middle East, we believe this actor’s adeptness in gaining initial access to target environments represents a valuable asset for the Iranian cyber ecosystem that can be exploited to answer evolving objectives as needs shift.
Teamwork Makes the Dream Work: UNC1860’s Role as an Initial Access Provider
Mandiant identified two custom, GUI-operated malware controllers tracked as TEMPLEPLAY and VIROGREEN that we assess were used to provide a team outside of UNC1860 remote access to victim networks. This tooling, coupled with public reporting and evidence suggesting that the group collaborates with MOIS-affiliated groups such as APT34, strengthens the assessment that UNC1860 acts as an initial access agent.
Using Sustained Access to Support Initial Access Operations
In 2020, Mandiant responded to an engagement in which UNC1860 used the victim’s network as a staging area to conduct additional scanning and exploitation operations against unrelated entities. The actor was observed scanning IP addresses predominantly located in Saudi Arabia in an attempt to identify exposed vulnerabilities. UNC1860 also used a command-line tool to validate credentials of accounts and email addresses across multiple domains belonging to Qatari and Saudi Arabian entities, and later targeted VPN servers of entities in the region.
UNC1860 Overlaps with APT34
Mandiant responded to several engagements in 2019 and 2020 in which organizations compromised by suspected APT34 actors were previously compromised by UNC1860. Similarly, organizations previously compromised by suspected APT34 actors were later compromised by UNC1860, suggesting the group may play a role in assisting with lateral movement. Mandiant additionally identified recent indications of operational pivoting to Iraq-based targets by both APT34-related clusters and UNC1860.
Web Shell and Droppers
UNC1860 web shells and droppers, such as STAYSHANTE and SASHEYAWAY, deployed and placed on compromised servers by the group after gaining initial access have the potential to be used in hand-off operations based on their functionality. In March 2024, the Israeli National Cyber Directorate was alerted to wiper activity targeting Israeli entities across various sectors in Israel, including managed service providers, local governments, and academia; technical indicators included the unique STAYSHANTE web shell and the SASHEYAWAY dropper we attribute to UNC1860.
STAYSHANTE is typically installed using names masquerading as Windows server file names or dependencies, and is controlled by the VIROGREEN custom framework described as follows.
SASHEYAWAY has a low detection rate that allows for the smooth execution of full passive backdoors, such as TEMPLEDOOR, FACEFACE, and SPARKLOAD, embedded within it.
Custom, GUI-Operated Malware Controllers
UNC1860 GUI-operated malware controllers TEMPLEPLAY and VIROGREEN could provide third-party actors who have no previous knowledge of the target environment the ability to remotely access infected networks via RDP and to control previously installed malware on victim networks with ease. These controllers additionally could provide third-party operators an interface that walks operators through how to deploy custom payloads and perform other operations such as conducting internal scanning and exploitation within the target network.
<div>
<img alt=”Illustration of collaborator actor’s C2 used to utilize existing UNC1860 implant infrastructure in compromised network” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig1.max-1000×1000.png” />
<p>Figure 1: Illustration of collaborator actor’s command and control (C2 or C&C) used to utilize existing UNC1860 implant infrastructure in compromised network</p>
</div>
</div>
TEMPLEPLAY Controller
TEMPLEPLAY (MD5: c517519097bff386dc1784d98ad93f9d) is a .NET-based controller for the TEMPLEDOOR passive backdoor. It is internally named Client Http and consists of several tabs, each one facilitating control of a separate backdoor command.
The Command Prompt Tab (Figure 2) sends a command line to execute on the target host. The default command is cmd /c 2 > &1 with parameter whoami.
<div>
<img alt=”TEMPLEPLAY GUI, Command Prompt Tab” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig2.max-1000×1000.png” />
<p>Figure 2: TEMPLEPLAY GUI, Command Prompt Tab</p>
</div>
</div>
The Upload File Tab (Figure 3) sends a file from a local path to a target path on the remote machine using a POST request. The default target path is C:Program FilesCommon FilesMicrosoft SharedWeb Server Extensions15TEMPLATELAYOUTS.
<div>
<img alt=”Upload File Tab” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig3.max-1000×1000.png” />
<p>Figure 3: Upload File Tab</p>
</div>
</div>
The Download File Tab (Figure 4) is used to obtain a file from a given path on the infected machine. The default path on the infected machine is C:Programdata1.txt.
<div>
<img alt=”Download File Tab” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig4.max-1000×1000.png” />
<p>Figure 4: Download File Tab</p>
</div>
</div>
The Http Proxy Tab (Figure 5) allows a remote machine infected with TEMPLEDOOR to be used as a middlebox that forwards data to a chosen target server. It appears that it is primarily intended to facilitate an RDP connection with the target server, most likely in cases where the latter is not accessible directly over the internet due to network boundaries (such as a NAT or a firewall), but may be accessible via the TEMPLEDOOR infected machine.
<div>
<img alt=”HTTP Proxy Tab” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig5.max-1000×1000.png” />
<p>Figure 5: HTTP Proxy Tab</p>
</div>
</div>
The URLs Tab (Figure 6) includes URL endpoints that are used when connecting to the infected machine. An endpoint string is chosen at random from the lists defined in this tab. These endpoints correspond to the ones that are defined in the TEMPLEDOOR sample (MD5:c57e59314aee7422e626520e495effe0).
<div>
<img alt=”URLs Tab” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig6.max-1000×1000.png” />
<p>Figure 6: URLs Tab</p>
</div>
</div>
The TEMPLEPLAY GUI also includes a Test Backdoor link, which creates a GET request with the string wOxhuoSBgpGcnLQZxipa as the relative URI and checks for the string UsEPTIkCRUwarKZfRnyjcG13DFA in the response. This corresponds to an echo ping mechanism that was seen in use in the TEMPLEDOOR samples (MD5:b219672bcd60ce9a81b900217b3b5864)and MD5:c57e59314aee7422e626520e495effe0).
Additional links include the Explore link that opens a new Explorer window in the host where the controller runs, and the Http Setting link points to a set of configuration parameters that pertain to the HTTP requests sent between the controller and the TEMPLEDOOR passive backdoor.
VIROGREEN Controller
VIROGREEN is a custom framework used to exploit vulnerable SharePoint servers with CVE-2019-0604 (Figure 7). The framework provides post-exploitation capabilities including scanning for and exploiting CVE-2019-0604; controlling post-exploitation payloads, backdoors (including the STAYSHANTE web shell and the BASEWALK backdoor) and tasking; controlling a compatible agent regardless of how the agent has been implanted; and executing commands and uploading/downloading files.
Additional details on TEMPLEPLAY and VIROGREEN can be found in the Technical Annex.
<div>
<img alt=”VIROGREEN GUI” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig7.max-1000×1000.png” />
<p>Figure 7: VIROGREEN GUI</p>
</div>
</div>
UNC1860 Malware: Gaining Persistent Access
UNC1860 gains initial access to victim environments in an opportunistic manner via the exploitation of vulnerable internet-facing servers leading to web shell deployment. After obtaining an initial foothold, the group typically deploys additional utilities and a selective suite of passive implants that are designed to be stealthier than common backdoors. These provide a higher degree of operational security by removing the dependency for classic C2 infrastructure, making detection more difficult for network defenders. Cisco and Check Point have provided extensive analysis on UNC1860’s passive implants that correspond to OATBOAT, a loader that loads and executes shellcode payloads; Fortinet additionally provided analysis regarding the Windows kernel driver, WINTAPIX, which has similar code to a malicious driver we track as TOFUDRV (Figure 8 and Figure 9).
A key feature of UNC1860 includes its maintenance of this diverse collection of passive/listener-based utilities that support the group’s initial access and lateral movement goals. We believe the group additionally maintains a smaller collection of “main-stage” backdoors that have greater capabilities than the usual web shells and small .NET utilities that may be deployed for select high-priority victims in the telecommunications sector. These implants demonstrate the group’s keen understanding of the Windows operating system (OS) and network detection solutions, reverse engineering capabilities of Windows kernel components, and detection evasion capabilities.
Passive implants do not initiate outbound traffic from the victim network to a C2 server. Further, the inbound traffic containing commands or payloads can arrive from any volatile source (e.g., VPN nodes within the target country, from another victim, or even internally from another part of the victim network). This makes network monitoring more difficult. Web shells and passive implants leverage HTTPS-encrypted traffic so commands/payloads cannot be extracted from captured network traffic.
Both passive implants TOFUDRV and TOFULOAD leverage undocumented Input/Output Control commands for communication, which requires knowledge of the OS and can lower the chances of this traffic being detected by endpoint detection and response (EDR) solutions.
Loading drivers is a “high risk / high reward” situation as loading them without creating a critical error screen requires extensive knowledge both of the OS internals and victim environments; however, using them promises lower detection rates and possibilities akin to filtering drivers, which act as middlemen allowing for the inspection, modification, or blocking of network traffic before it reaches the device or application, as well as assets like file system objects and registry entries.
The passive backdoor TEMPLEDROP repurposed an Iranian AV software Windows file system filter driver named Sheed AV (MD5: 0c93cac9854831da5f761ee98bb40c37) for the purpose of protecting some of the files it deploys as well as its own file from modification.
A .NET-based utility for defense evasion tracked as TEMPLELOCK was observed being implemented in both foothold utilities such as ROTPIPE and more complex passive implants such as TEMPLEDROP. TEMPLELOCK is capable of terminating threats associated with the Windows Event Log service and restarting the service’s operation on demand.
<div>
<img alt=”Driver file protection logic in WINTAPIX (MD5: 286bd9c2670215d3cb4790aac4552f22)” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig8.max-1000×1000.png” />
<p>Figure 8: Driver file protection logic in WINTAPIX (MD5: 286bd9c2670215d3cb4790aac4552f22)</p>
</div>
</div>
<div>
<img alt=”Driver file protection logic in TOFUDRV (MD5: b4b1e285b9f666ae7304a456da01545e)” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig9.max-1000×1000.png” />
<p>Figure 9: Driver file protection logic in TOFUDRV (MD5: b4b1e285b9f666ae7304a456da01545e)</p>
</div>
</div>
UNC1860 Unique Artifacts Suggest Consistent Development Support
In addition to the previous observations, we identified the following recurring artifacts related to the group’s independent implementation of Base64 encoding/decoding and XOR encryption/decryption in .NET code, despite these functions being available in build-in .NET code.
The intent of the independent implementation of these functions is not entirely clear. Nevertheless, it is highly likely that using such custom libraries bypasses common detections by EDRs and other security tools—detections designed to identify usage combinations of functions commonly seen in malware. Additionally, using these custom libraries may allow better compatibility if any of the built-in functions change in a specific version of a .NET control to ensure the group’s tooling is always compatible with its encryption and encoding schemes and/or to better help evade detection.
We observed the same encoding method using the Base64 algorithm to encode and decode data sent between controllers and proxy servers. In several cases, we identified the reuse of a seemingly misspelled Base64 DLL using the name “bsae64” in both foothold utilities deployed via SASHEYAWAY and passive implants including TEMPLEDOOR.
We observed the same rolling encryption module, XORO (MD5: 57cd8e220465aa8030755d4009d0117c),dropped by the TANKSHELL utility; TUNNELBOI network tunneller capable of establishing a connection with a remote host, managing web shells on the network, and creating RDP connections; and the TEMPLEPLAY controller.
Foothold Utilities and Backdoors and Malware Use for Longer Term Persistence
Mandiant is tracking multiple foothold utilities and backdoors used in UNC1860 initial access operations. These generally use custom obfuscation methods that can lower detection rates and make analysis more difficult by renaming strings and function names. Additionally, we are tracking numerous code families that we consider to be UNC1860 “main-stage” implants that further increase the group’s persistence in victim environments.
Please see the Technical Annex for more information.
Additional Protection Information for Google Cloud Customers
For Google SecOps Enterprise+ customers, SecOps rules have been released to the Emerging Threats rule pack, and IOCs listed in this blog post are available for prioritization with Applied Threat Intelligence.
Indicators of Compromise (IOCs)
A Google Threat Intelligence Collection featuring IOCs related to the activity described in this post is now available for registered users.
MD5 Hashes
1176381da7dea356f3377a59a6f0e799
41f4732ed369f2224a422752860b0bc5
4029bc4a06638bb9ac4b8528523b72f6
126bc1c30fba27f8bf67dce4892b1e8c
0c9ff0db00f04fd4c6a9160bffd85a1d
a7693e399602eb79db537c5022dd1e01
d9719f6738dbfaa21be7f184512fe074
17b27e6aa0ab6501f11bb4d2e0f829ff
4dd6250eb2d368f500949952eb013964
69fd67c115349abb4a313230a1692642
7f5f5f290910d256e6b012f898c88bf3
c90ec587e3333dabb647ebc182673460
efe8043e1b4214640c5f7b5ddf737653
a90236e4962620949b720f647a91f101
b26d54b7da7b2bf600104f69da4ea00f
d87ca3f830b8b53fde358bb64900f6af
c50ae2c4b76f0d5724ec240568c78c4f
57cd8e220465aa8030755d4009d0117c
4b2c78bb2c439998cff0cc097a14b942
4abcf21b63781a53bbc1aa17bd8d2cbc
a3ea0d13848a104c28d035a9d518acc2
bd6464f12bb6f7f02b6ffebb363d8e5f
f89be788e4adf665acf1a8ef8fcaa133
f292e61774c267c3787fdfcace50ea7b
c11a4e4a2d484513f79bd127a0387b0c
14e54ff4805840e656efb8cd38de4751
3d5d05f230ae702c04098de512d93d48
a038975255d3dda636d86ccd307f7838
31f2369d2e38c78f5b3f2035dba07c08
c21eefc65cda49f17ddd1d243a7bffb5
c8fa0ce3ae6a13af640607ea606c55f9
2cece71e107d12ffd74b2fb24bf339a6
fa1c6f7a5e02374b9d33de2578cb3399
1e896f026246872b2feb4f8e3e093815
57c916da83cc634af22bde0ad44d0db3
07db3058e32fe5f36823dc7092cd7d5b
3dd829fb27353622eff34be1eabb8f18
1e6679cd25d1bb127a0bec665adcf21e
2e803d28809be2a0216f25126efde37b
2398a83f10329a107801d3d23d06f7cb
73fb0fe5cd96a14a4f85639223aec6a8
85427a8a47c4162b48d8dfb37440665d
a500561c0b374816972094c2aa90da2a
a65ee1a82975ee4c8d4e70219e1bfff5
ce537dd649a391e52c27a3f88a0a8912
e67687b4443f58d2b0a465e3af3caffe
b34883fb1630db43e06a38cebfa0bce2
46804472541ed61cc904cd14be18fe1d
4de802f7e61cb8c820a02e042b58b215
929b12bc9f9e5f8e854de1d46ebf40d9
f0dfb7bf01c0412891da8fa2702f4c7b
b219672bcd60ce9a81b900217b3b5864
fc90907e70f18c7f6a6b9d9599b6f97c
d1e45afbfd3424612b4a4218cc7357ef
da0085a97c38ead734885e5cced1847f
490590bfdeeedf44b3ae306409bb0d03
e86e885e6c96ac72482741d8696c17fb
ca3f0d25f7da0e8cde8e1f367451c77a
7b2fa099d51fa3885766f6d60d768748
6626dbe74acd15d06ff6900071ef240c
YARA Rules
meta:
author = Mandiant
description = “wintapix malware family”
created = “06/26/2023”
modified = “06/26/2023”
version = “1.0”
test_hash = “8578bff36e3b02cc71495b647db88c67c3
c5ca710b5a2bd539148550595d0330″
filetypes = “exe,dll”
dighash_cov_0 = “[[“bf59653dbad735041063″, 1]]”
target_set = “filemd5 +code(“wintapix”) ;; +filemime=
“application/x-dosexec” -pe:framework=dotnet +limit(2000)”
target_set_size = 1
validation_set = “filemd5 +code(“wintapix”) ;;
+filemime=”application/x-dosexec” -pe:framework=dotnet +limit(2000)”
validation_set_approx_size = 1
strings:
$p00_0 = {84ec5ff5f84863f6e9[4]66458b65??4981c5[4]4d0faccf}
$p00_1 = {0f16c00f11014c03c14883c1??
4883e1??4c2bc14d8bc849c1e9??74}
condition:
uint16(0) == 0x5A4D and uint32(uint32(0x3C)) == 0x00004550 and
(
($p00_0 in (660000..690000) and $p00_1 in (9700..20000))
)
}
rule M_WINTAPIX_StringDecodingMethod_1 {
meta:
author = Mandiant
hash1 = “286bd9c2670215d3cb4790aac4552f22”
hash2 = “4dd6250eb2d368f500949952eb013964”
desc = “Detects the byte pattern of a string decoding
method found in the WINTAPIX driver image”
strings:
$a1 = { 48 89 54 24 10 48 89 4C 24 08 48 83 EC 18 C7
04 24 00 00 00 00 48 63 04 24 48 8B 4C 24 ?? 0F BE 04 01
48 8B 4C 24 ?? 0F B6 49 ?? 33 C1 48 63 0C 24 48 8B 54 24
?? 88 04 0A 8B 04 24 FF C0 89 04 24 8B 04 24 FF C8 48 98
48 8B 4C 24 ?? 0F B6 04 01 85 C0 75 }
condition:
uint16(0) == 0x5A4D and
filesize < 1MB and
pe.subsystem == pe.SUBSYSTEM_NATIVE and
all of them
}
rule M_WINTAPIX_PaddedStrings_1 {
meta:
author = Mandiant
hash1 = “286bd9c2670215d3cb4790aac4552f22”
hash2 = “4dd6250eb2d368f500949952eb013964”
desc = “Detects unique strings found in the WINTAPIX
driver image”
strings:
$a1 = { CC CC CC CC CC CC CC 4E 74 44 65 6C 61 79
45 78 65 63 75 74 69 6F 6E 00 }
$a2 = { CC CC CC CC CC 5C 00 }
$a3 = “InitSafeBootMode” ascii fullword
condition:
uint16(0) == 0x5A4D and
pe.subsystem == pe.SUBSYSTEM_NATIVE and
filesize < 1MB and
(
(
all of them and
#a2 == 2
) or
pe.imphash() == “8d070a93a45ed8ba6dba6bfbe0d084e7”
)
}
rule M_UNC1860_TEMPLEDOOR_Strings_1 {
meta:
author = Mandiant
date = “28/02/2024”
hash1 = “caffdb648a0a68cd36694f0f0c7699d7”
desc = “Detects the TEMPLEDOOR family based on
unique strings”
comment = “Triggers on TUNNELBOI sample
c517519097bff386dc1784d98ad93f9d”
strings:
$url = “{0}://+:{1}/{2}/” wide fullword
$a1 = “+CjxoZWFkPgo8bWV0YSBodHRwLWVxdWl2
PSJDb250ZW50LVR5cGUiIGNvbnRlbnQ9InRleHQvaHRtb
DsgY2hhcnNldD1pc28tODg1OS0xIi8″ wide
$b1 = “Jet” wide fullword
$b2 = ” Ver” wide fullword
$b3 = “CmD” wide fullword
$c1 = “Command” wide fullword
$c2 = “Upload” wide fullword
$c3 = “Download” wide fullword
$c4 = “Load” wide fullword
$c5 = “Rundll” wide fullword
$c6 = “ERROR” wide fullword
condition:
int16(0) == 0x5a4d and
uint32(uint32(0x3C)) == 0x00004550 and
dotnet.is_dotnet and
$url and
(
$a1 or
2 of ($b*) or
5 of ($c*)
)
}
rule M_UNC1860_TEMPLEDOOR_BytePatterns_1 {
meta:
author = Mandiant
date = “28/02/2024”
hash1 = “caffdb648a0a68cd36694f0f0c7699d7”
desc = “Detects the TEMPLEDOOR family based
on unique byte patterns”
comment = “Triggers on TUNNELBOI sample
c517519097bff386dc1784d98ad93f9d and on WINPAY
sample b219672bcd60ce9a81b900217b3b5864″
strings:
$encode_msil = { 7E ?? ?? 00 04 1F 41 1F 61 6F ??
?? 00 0A D2 0A 02 2C 07 02 8E 16 FE 03 2B 01 16 2C 69
16 0B 2B 0F 02 07 02 07 91 06 61 19 58 D2 9C 07 17 58
0B 07 02 8E 69 FE 04 2D E9 02 28 ?? ?? 00 0A } // Packet
encoding method MSIL
$encryption_key = { 54 62 2d 0c 03 45 49 15 2b 43
59 4a 4e 0c 40 }
condition:
int16(0) == 0x5a4d and
uint32(uint32(0x3C)) == 0x00004550 and
dotnet.is_dotnet and
any of them
}
meta:
desc = “Detects the UNC1860 OBFUSLAY malware by its
string decryption method”
rs1 = “b66919a18322aa4ce2ad47d149b7fe38063cd3cfa2
e4062cd1a01ad6b3e47651″
strings:
$a1 = {
FE 09 00 00
6F ?? 00 00 0A
FE 0E 00 00
FE 0C 00 00
20 02 00 00 00
5B
8D ?? 00 00 01
FE 0E 01 00
20 00 00 00 00
FE 0E 04 00
38 39 00 00 00
FE 0C 01 00
FE 0C 04 00
20 02 00 00 00
5B
FE 09 00 00
FE 0C 04 00
20 02 00 00 00
6F ?? 00 00 0A
20 10 00 00 00
28 ?? 00 00 0A
9C
FE 0C 04 00
20 02 00 00 00
58
FE 0E 04 00
FE 0C 04 00
FE 0C 00 00
3F BA FF FF FF
FE 0C 01 00
}
condition:
uint16(0) == 0x5A4D and
all of them
}
meta:
desc = “Detects the UNC1860 CRYPTOSLAY malware by its
string decryption method”
rs1 = “3F2FD2DFD27BF3CAFCBF0946E308832E11A1D9C1
D98FB04AC848E023E6720F53″
rs2 = “5c1a42e9baaec115df337d2f4a9dcce8d73f29375921
827e367fcba8499cdfa2″
strings:
$a1 = {
FE 09 00 00
6F ?? 00 00 0A
FE 0E 00 00
FE 0C 00 00
20 02 00 00 00
5B
8D ?? 00 00 01
FE 0E 01 00
20 00 00 00 00
FE 0E 04 00
38 39 00 00 00
FE 0C 01 00
FE 0C 04 00
20 02 00 00 00
5B
FE 09 00 00
FE 0C 04 00
20 02 00 00 00
6F ?? 00 00 0A
20 10 00 00 00
28 ?? 00 00 0A
9C
FE 0C 04 00
20 02 00 00 00
58
FE 0E 04 00
FE 0C 04 00
FE 0C 00 00
3F BA FF FF FF
28 ?? 00 00 0A
}
$a2 = {
FE 09 00 00
6F ?? 00 00 0A
FE 0E 00 00
FE 0C 00 00
20 02 00 00 00
5B
8D ?? 00 00 01
FE 0E 01 00
20 00 00 00 00
FE 0E 06 00
38 39 00 00 00
FE 0C 01 00
FE 0C 06 00
20 02 00 00 00
5B
FE 09 00 00
FE 0C 06 00
20 02 00 00 00
6F ?? 00 00 0A
20 10 00 00 00
28 ?? 00 00 0A
9C
FE 0C 06 00
20 02 00 00 00
58
FE 0E 06 00
FE 0C 06 00
FE 0C 00 00
FE 04
FE 0E 07 00
FE 0C 07 00
3A B0 FF FF FF
}
condition:
uint16(0) == 0x5A4D and
any of them
}
meta:
author = “autopatt”
description = “oatboat malware family”
created = “02/09/2024”
modified = “02/09/2024”
version = “1.0”
test_hash = “6f0a38c9eb9171cd323b0f599b74ee571
620bc3f34aa07435e7c5822663de605″
filetypes = “exe,dll”
dighash_cov_0 = “[[“10a0654cddaedc8bfee4”, 3],
[“aa6b664471b41b27e9a8″, 3]]”
target_set = “filemd5 +code(“oatboat”)
;; +filemime=”application/x-dosexec” -pe:framework=dotnet +limit(2000)”
target_set_size = 7
validation_set = “filemd5 +code(“oatboat”); filemd5
+sig(“mal.oatboat”) ;; +filemime=”application/x-dosexec”
-pe:framework=dotnet +limit(2000)”
validation_set_approx_size = 9
strings:
$p00_0 = {48897c24??55488bec4883ec??488bf9c745[5]33d
bc745[5]488d4d}
$p00_1 = {443ac975??48ffc64883c3??493bf372??498b42??4885c075}
condition:
uint16(0) == 0x5A4D and uint32(uint32(0x3C)) == 0x00004550 and
(
($p00_0 in (250..6500) and $p00_1 in (0..6000))
)
}
meta:
desc = “Strings observed in the webshell loader”
rs1 = “2538767f13218503bccf31fccb74e753199
4b69a36a3780b53ba5020d938af20″
strings:
$ = “FromBase64String”
$ = “Page Language=”C#””
$ = “private static System.Reflection.Assembly”
$ = “Page_Load”
$ = “System.Reflection.MethodInfo”
$ = “Activator.CreateInstance”
$ = “Invoke”
condition:
all of them
}
meta:
author = Mandiant
date_created = “2023-08-15”
date_modified = “2023-08-15”
description = “This is a hunting rule to look for TOFULOAD
backdoor used by UNC1860″
md5 = “d1ce3117060e85247145c82005dda985”
strings:
$s1 = {66 77 88 99 48 8D [2] C7 [2] 52 74 6C 52}
// 0x99887766; LEA ??, ??; MOV ??, ‘RltR’;
$s2 = {B8 E1 83 0F 3E F7 [1] C1 [1] 03 0F [2] 6B [1] 21}
// MOV ??, 0x3E0F83E1; MUL ??, ??; SHR ??, 03; MOVZX ??, ??;
IMUL ??, ??, 21;
$s3 = {FF [1] 40 [2] 43 32 [2] 41 88 [3] 44 8B [1] 4D [2] 7C} //
INC ??; MOV ??, ??; XOR ??, ??; MOV ??, ??; MOV ??, ??; CMP ??, ??; JL
condition:
filesize < 50KB and
any of them
}
rule M_UNC1860_TEMPLEDROP_Strings_2 {
meta:
author = Mandiant
date = “28/02/2024”
hash1 = “6d3041b89484c273376e5189e190d235”
desc = “Detects the TEMPELDROP family based on unique strings”
comment = “Triggers on TEMPLEDOOR controller sample c517519
097bff386dc1784d98ad93f9d”
strings:
$a1 = “Nothing changed :D” wide fullword
$a2 = “Access: KO” wide fullword
$a3 = “Eventlog stoped.” wide fullword
$b1 = “The Microsoft Exchange Self Protection Driver.” wide fullword
$b2 = “The Microsoft Exchange Filter Driver.” wide fullword
$c1 = “Create RegKey: ” wide
$c2 = “Create Service: ” wide
$c3 = “Test Event lock: ” wide
$c4 = “Test http listner: ” wide
$c5 = “Test IO Changes: ” wide
$c6 = “Test ‘Event lock’: ” wide
$d1 = “no active http port to listen.” wide
$d2 = “Prefixes.Add Error , ” wide
$d3 = “‘ driver service created and started.” wide
$d4 = “‘ service started.” wide
$d5 = “Unhandled exception on create reg key ” wide
$d6 = “Failed to change file ‘CreationTime’.” wide
condition:
int16(0) == 0x5a4d and
uint32(uint32(0x3C)) == 0x00004550 and
dotnet.is_dotnet and
(
1 of ($a*) or
1 of ($b*) or
2 of ($c*) or
2 of ($d*)
)
}
meta:
author = Mandiant
description = “tofudrv malware family”
created = “11/29/2023”
modified = “11/29/2023”
version = “1.0”
test_hash = “03d2e623d7f4430952cf27afe8e137ef1dcb
320f1a9781048798582b55e48f9b”
filetypes = “exe,dll”
dighash_cov_0 = “[[“5499758ed59a9ea0cacd”, 1]]”
target_set = “filemd5 +code(“tofudrv”) ;;
+filemime=”application/x-dosexec” -pe:framework=dotnet +limit(2000)”
target_set_size = 1
validation_set = “filemd5 +code(“tofudrv”) ;;
+filemime=”application/x-dosexec” -pe:framework=dotnet +limit(2000)”
validation_set_approx_size = 1
strings:
$p00_0 = {eb??33c083f8??0f85[4]488b4c24??e8[4]eb??c74424[5]eb}
$p00_1 =
{f3aa41b8[4]33d2488d4c24??e8[4]488b8424[4]48898424[4]48638424[4]48898424}
condition:
uint16(0) == 0x5A4D and uint32(uint32(0x3C)) == 0x00004550 and
(
($p00_0 in (34000..45000) and $p00_1 in (28000..39000))
)
}
rule M_TOFUDRV_Strings_1 {
meta:
author = Mandiant
hash = “b4b1e285b9f666ae7304a456da01545e”
desc = “Detects cleartext strings that appear in the TOFUDRV image”
strings:
$a1 = “\systemroot\system32\drivers” ascii fullword
$a2 = “\SafeBoot\Minimal\” ascii fullword
$a3 = “\REGISTRY\MACHINE\SYSTEM\CurrentControlSet\Control”
ascii fullword
$a4 = “\SafeBoot\Network\” ascii fullword
$a5 =
“ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/”
ascii fullword
$a6 = “Found” ascii fullword
condition:
uint16(0) == 0x5A4D and
filesize < 500KB and
pe.subsystem == pe.SUBSYSTEM_NATIVE and
(
3 of them or
pe.imphash() == “ff6f16b00c9f36b32cd60fecd4dfc8e9”
)
}
rule M_TOFUDRV_RtlSubtreeStackStrings_1 {
meta:
author = Mandiant
hash = “b4b1e285b9f666ae7304a456da01545e”
desc = “Detects a stack string byte pattern in a function intended
to resolve the memory image base of ntoskrnl.exe in TOFUDRV”
strings:
// “RtlSubtreePredecessor”
$a1 = { C6 44 24 ?? 52 C6 44 24 ?? 74 C6 44 24 ?? 6C C6 44 24 ??
53 C6 44 24 ?? 75 C6 44 24 ?? 62 C6 44 24 ?? 74 C6 44 24 ?? 72 C6 44
24 ?? 65 C6 44 24 ?? 65 C6 44 24 ?? 50 C6 44 24 ?? 72 C6 44 24 ?? 65
C6 44 24 ?? 64 C6 44 24 ?? 65 }
// “RtlSubtreeSuccessor”
$a2 = { C6 84 24 ?? 00 00 00 6C C6 84 24 ?? 00 00 00 53 C6 84 24
?? 00 00 00 75 C6 84 24 ?? 00 00 00 62 C6 84 24 ?? 00 00 00 74 C6 84
24 ?? 00 00 00 72 C6 84 24 ?? 00 00 00 65 C6 84 24 ?? 00 00 00 65 C6
84 24 ?? 00 00 00 53 C6 84 24 ?? 00 00 00 75 }
$KeGetPcr = { 65 48 8B 04 25 18 00 00 00 48 89 44 24 }
condition:
uint16(0) == 0x5A4D and
filesize < 500KB and
pe.subsystem == pe.SUBSYSTEM_NATIVE and
$KeGetPcr and
any of ($a*)
}
meta:
author = Mandiant
date_created = “2020-05-22”
date_modified = “2020-05-22”
md5 = “6d3041b89484c273376e5189e190d235”
rev = 2
strings:
$ss1 = “–install” fullword wide
$ss2 = “‘ directory created.” fullword wide
$ss3 = “‘ file created.” fullword wide
$ss4 = “‘ service created.” fullword wide
$ss5 = “Nothing changed :D” fullword wide
$ss6 = “x00ProtectDriverx00”
$ss7 = “x00WriteAllBytesx00”
$ss8 = “x00CopyTimex00”
$ss9 = “Tx00Vx00qx00Qx00”
condition:
(
uint16(0) == 0x5A4D and
uint32(uint32(0x3C)) == 0x00004550
) and
all of them
}
meta:
author = Mandiant
date_created = “2020-05-22”
date_modified = “2020-05-22”
md5 = “a991bdbf1e36d7818d7a340a35a4ea26”
rev = 2
strings:
$sb1 = { 02 7B [2] 00 04 [0-8] FE 03 [0-8] 39 [4-8] 02 7B [2] 00 04
[5] 0? 02 7B [2] 00 04 [5-12] 0C }
$sb2 = { 7B [2] 00 04 [0-16] 13 ?? 11 [1-8] 17 59 45 04 00 00 00 02
[4-64] 2B ?? 02 [1-2] 7B [2] 00 04 73 [2] 00 06 28 [2] 00 06 0A 2B ?? 02
[1-2] 7B [2] 00 04 73 [2] 00 06 28 [2] 00 06 [0-4] 0A 2B }
$ss1 = “x00set_UseShellExecutex00”
$ss2 = “x00HttpListenerRequestx00”
$ss3 = “x00HttpListenerResponsex00”
$ss4 = “x00HttpListenerx00”
condition:
(
uint16(0) == 0x5A4D and
uint32(uint32(0x3C)) == 0x00004550
) and
all of them
}
meta:
author = Mandiant
date_created = “2020-05-22”
date_modified = “2020-05-22”
md5 = “952482949f495fb66e493e441229ae4b”
rev = 2
strings:
$sb1 = { 06 17 7D [4] 06 20 36 01 00 C0 7D [4] DE 00 07
15 3B [4] 07 28 [4-12] 0D [8-64] 11 06 [4-12] 13 07 11 07 39 [4-32]
20 FF FF 1F 00 12 09 [0-12] 11 09 12 0A [4-12] 12 0A 11 07 }
$ss1 = “x00GetProcessByIdx00”
$ss2 = “x00NtOpenThreadx00”
$ss3 = “x00NtQueryInformationThreadx00”
$ss4 = “x00ReadProcessMemoryx00”
$ss5 = “x00NtTerminateProcessx00”
$ss6 = “x00set_UseShellExecutex00”
$ss7 = “x00DESCryptoServiceProviderx00”
$ss8 = “x00GetExecutingAssemblyx00”
condition:
(
uint16(0) == 0x5A4D and
uint32(uint32(0x3C)) == 0x00004550
) and
all of them
}
Article Link: https://cloud.google.com/blog/topics/threat-intelligence/unc1860-iran-middle-eastern-networks/
1 post – 1 participant
Written by: Stav Shulman, Matan Mimran, Sarah Bock, Mark Lechtik
Executive Summary
UNC1860 is a persistent and opportunistic Iranian state-sponsored threat actor that is likely affiliated with Iran’s Ministry of Intelligence and Security (MOIS). A key feature of UNC1860 is its collection of specialized tooling and passive backdoors that Mandiant believes supports several objectives, including its role as a probable initial access provider and its ability to gain persistent access to high-priority networks, such as those in the government and telecommunications space throughout the Middle East.
UNC1860’s tradecraft and targeting parallels with Shrouded Snooper, Scarred Manticore, and Storm-0861, Iran-based threat actors publicly reported to have targeted the telecommunications and government sectors in the Middle East. These groups have also reportedly provided initial access for destructive and disruptive operations that targeted Israel in late October 2023 with BABYWIPER and Albania in 2022 using ROADSWEEP. Mandiant cannot independently corroborate that UNC1860 was involved in providing initial access for these operations. However, we identified specialized UNC1860 tooling including GUI-operated malware controllers, which are likely designed to facilitate hand-off operations, further supporting the initial access role played by UNC1860.
UNC1860 additionally maintains an arsenal of utilities and collection of “main-stage” passive backdoors designed to gain strong footholds into victim networks and establish persistent, long-term access. Among these main-stage backdoors includes a Windows kernel mode driver repurposed from a legitimate Iranian anti-virus software filter driver, reflecting the group’s reverse engineering capabilities of Windows kernel components and detection evasion capabilities. These capabilities demonstrate that UNC1860 is a formidable threat actor that likely supports various objectives ranging from espionage to network attack operations. As tensions continue to ebb and flow in the Middle East, we believe this actor’s adeptness in gaining initial access to target environments represents a valuable asset for the Iranian cyber ecosystem that can be exploited to answer evolving objectives as needs shift.
Teamwork Makes the Dream Work: UNC1860’s Role as an Initial Access Provider
Mandiant identified two custom, GUI-operated malware controllers tracked as TEMPLEPLAY and VIROGREEN that we assess were used to provide a team outside of UNC1860 remote access to victim networks. This tooling, coupled with public reporting and evidence suggesting that the group collaborates with MOIS-affiliated groups such as APT34, strengthens the assessment that UNC1860 acts as an initial access agent.
Using Sustained Access to Support Initial Access Operations
In 2020, Mandiant responded to an engagement in which UNC1860 used the victim’s network as a staging area to conduct additional scanning and exploitation operations against unrelated entities. The actor was observed scanning IP addresses predominantly located in Saudi Arabia in an attempt to identify exposed vulnerabilities. UNC1860 also used a command-line tool to validate credentials of accounts and email addresses across multiple domains belonging to Qatari and Saudi Arabian entities, and later targeted VPN servers of entities in the region.
UNC1860 Overlaps with APT34
Mandiant responded to several engagements in 2019 and 2020 in which organizations compromised by suspected APT34 actors were previously compromised by UNC1860. Similarly, organizations previously compromised by suspected APT34 actors were later compromised by UNC1860, suggesting the group may play a role in assisting with lateral movement. Mandiant additionally identified recent indications of operational pivoting to Iraq-based targets by both APT34-related clusters and UNC1860.
Web Shell and Droppers
UNC1860 web shells and droppers, such as STAYSHANTE and SASHEYAWAY, deployed and placed on compromised servers by the group after gaining initial access have the potential to be used in hand-off operations based on their functionality. In March 2024, the Israeli National Cyber Directorate was alerted to wiper activity targeting Israeli entities across various sectors in Israel, including managed service providers, local governments, and academia; technical indicators included the unique STAYSHANTE web shell and the SASHEYAWAY dropper we attribute to UNC1860.
STAYSHANTE is typically installed using names masquerading as Windows server file names or dependencies, and is controlled by the VIROGREEN custom framework described as follows.
SASHEYAWAY has a low detection rate that allows for the smooth execution of full passive backdoors, such as TEMPLEDOOR, FACEFACE, and SPARKLOAD, embedded within it.
Custom, GUI-Operated Malware Controllers
UNC1860 GUI-operated malware controllers TEMPLEPLAY and VIROGREEN could provide third-party actors who have no previous knowledge of the target environment the ability to remotely access infected networks via RDP and to control previously installed malware on victim networks with ease. These controllers additionally could provide third-party operators an interface that walks operators through how to deploy custom payloads and perform other operations such as conducting internal scanning and exploitation within the target network.
<div>
<div>
<img alt=”Illustration of collaborator actor’s C2 used to utilize existing UNC1860 implant infrastructure in compromised network” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig1.max-1000×1000.png” />
<p>Figure 1: Illustration of collaborator actor’s command and control (C2 or C&C) used to utilize existing UNC1860 implant infrastructure in compromised network</p>
</div>
</div>
TEMPLEPLAY Controller
TEMPLEPLAY (MD5: c517519097bff386dc1784d98ad93f9d) is a .NET-based controller for the TEMPLEDOOR passive backdoor. It is internally named Client Http and consists of several tabs, each one facilitating control of a separate backdoor command.
The Command Prompt Tab (Figure 2) sends a command line to execute on the target host. The default command is cmd /c 2 > &1 with parameter whoami.
<div>
<div>
<img alt=”TEMPLEPLAY GUI, Command Prompt Tab” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig2.max-1000×1000.png” />
<p>Figure 2: TEMPLEPLAY GUI, Command Prompt Tab</p>
</div>
</div>
The Upload File Tab (Figure 3) sends a file from a local path to a target path on the remote machine using a POST request. The default target path is C:Program FilesCommon FilesMicrosoft SharedWeb Server Extensions15TEMPLATELAYOUTS.
<div>
<div>
<img alt=”Upload File Tab” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig3.max-1000×1000.png” />
<p>Figure 3: Upload File Tab</p>
</div>
</div>
The Download File Tab (Figure 4) is used to obtain a file from a given path on the infected machine. The default path on the infected machine is C:Programdata1.txt.
<div>
<div>
<img alt=”Download File Tab” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig4.max-1000×1000.png” />
<p>Figure 4: Download File Tab</p>
</div>
</div>
The Http Proxy Tab (Figure 5) allows a remote machine infected with TEMPLEDOOR to be used as a middlebox that forwards data to a chosen target server. It appears that it is primarily intended to facilitate an RDP connection with the target server, most likely in cases where the latter is not accessible directly over the internet due to network boundaries (such as a NAT or a firewall), but may be accessible via the TEMPLEDOOR infected machine.
<div>
<div>
<img alt=”HTTP Proxy Tab” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig5.max-1000×1000.png” />
<p>Figure 5: HTTP Proxy Tab</p>
</div>
</div>
The URLs Tab (Figure 6) includes URL endpoints that are used when connecting to the infected machine. An endpoint string is chosen at random from the lists defined in this tab. These endpoints correspond to the ones that are defined in the TEMPLEDOOR sample (MD5:c57e59314aee7422e626520e495effe0).
<div>
<div>
<img alt=”URLs Tab” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig6.max-1000×1000.png” />
<p>Figure 6: URLs Tab</p>
</div>
</div>
The TEMPLEPLAY GUI also includes a Test Backdoor link, which creates a GET request with the string wOxhuoSBgpGcnLQZxipa as the relative URI and checks for the string UsEPTIkCRUwarKZfRnyjcG13DFA in the response. This corresponds to an echo ping mechanism that was seen in use in the TEMPLEDOOR samples (MD5:b219672bcd60ce9a81b900217b3b5864)and MD5:c57e59314aee7422e626520e495effe0).
Additional links include the Explore link that opens a new Explorer window in the host where the controller runs, and the Http Setting link points to a set of configuration parameters that pertain to the HTTP requests sent between the controller and the TEMPLEDOOR passive backdoor.
VIROGREEN Controller
VIROGREEN is a custom framework used to exploit vulnerable SharePoint servers with CVE-2019-0604 (Figure 7). The framework provides post-exploitation capabilities including scanning for and exploiting CVE-2019-0604; controlling post-exploitation payloads, backdoors (including the STAYSHANTE web shell and the BASEWALK backdoor) and tasking; controlling a compatible agent regardless of how the agent has been implanted; and executing commands and uploading/downloading files.
Additional details on TEMPLEPLAY and VIROGREEN can be found in the Technical Annex.
<div>
<div>
<img alt=”VIROGREEN GUI” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig7.max-1000×1000.png” />
<p>Figure 7: VIROGREEN GUI</p>
</div>
</div>
UNC1860 Malware: Gaining Persistent Access
UNC1860 gains initial access to victim environments in an opportunistic manner via the exploitation of vulnerable internet-facing servers leading to web shell deployment. After obtaining an initial foothold, the group typically deploys additional utilities and a selective suite of passive implants that are designed to be stealthier than common backdoors. These provide a higher degree of operational security by removing the dependency for classic C2 infrastructure, making detection more difficult for network defenders. Cisco and Check Point have provided extensive analysis on UNC1860’s passive implants that correspond to OATBOAT, a loader that loads and executes shellcode payloads; Fortinet additionally provided analysis regarding the Windows kernel driver, WINTAPIX, which has similar code to a malicious driver we track as TOFUDRV (Figure 8 and Figure 9).
A key feature of UNC1860 includes its maintenance of this diverse collection of passive/listener-based utilities that support the group’s initial access and lateral movement goals. We believe the group additionally maintains a smaller collection of “main-stage” backdoors that have greater capabilities than the usual web shells and small .NET utilities that may be deployed for select high-priority victims in the telecommunications sector. These implants demonstrate the group’s keen understanding of the Windows operating system (OS) and network detection solutions, reverse engineering capabilities of Windows kernel components, and detection evasion capabilities.
Passive implants do not initiate outbound traffic from the victim network to a C2 server. Further, the inbound traffic containing commands or payloads can arrive from any volatile source (e.g., VPN nodes within the target country, from another victim, or even internally from another part of the victim network). This makes network monitoring more difficult. Web shells and passive implants leverage HTTPS-encrypted traffic so commands/payloads cannot be extracted from captured network traffic.
Both passive implants TOFUDRV and TOFULOAD leverage undocumented Input/Output Control commands for communication, which requires knowledge of the OS and can lower the chances of this traffic being detected by endpoint detection and response (EDR) solutions.
Loading drivers is a “high risk / high reward” situation as loading them without creating a critical error screen requires extensive knowledge both of the OS internals and victim environments; however, using them promises lower detection rates and possibilities akin to filtering drivers, which act as middlemen allowing for the inspection, modification, or blocking of network traffic before it reaches the device or application, as well as assets like file system objects and registry entries.
The passive backdoor TEMPLEDROP repurposed an Iranian AV software Windows file system filter driver named Sheed AV (MD5: 0c93cac9854831da5f761ee98bb40c37) for the purpose of protecting some of the files it deploys as well as its own file from modification.
A .NET-based utility for defense evasion tracked as TEMPLELOCK was observed being implemented in both foothold utilities such as ROTPIPE and more complex passive implants such as TEMPLEDROP. TEMPLELOCK is capable of terminating threats associated with the Windows Event Log service and restarting the service’s operation on demand.
<div>
<div>
<img alt=”Driver file protection logic in WINTAPIX (MD5: 286bd9c2670215d3cb4790aac4552f22)” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig8.max-1000×1000.png” />
<p>Figure 8: Driver file protection logic in WINTAPIX (MD5: 286bd9c2670215d3cb4790aac4552f22)</p>
</div>
</div>
<div>
<div>
<img alt=”Driver file protection logic in TOFUDRV (MD5: b4b1e285b9f666ae7304a456da01545e)” src=”https://storage.googleapis.com/gweb-cloudblog-publish/images/unc1860-temple-of-oats-fig9.max-1000×1000.png” />
<p>Figure 9: Driver file protection logic in TOFUDRV (MD5: b4b1e285b9f666ae7304a456da01545e)</p>
</div>
</div>
UNC1860 Unique Artifacts Suggest Consistent Development Support
In addition to the previous observations, we identified the following recurring artifacts related to the group’s independent implementation of Base64 encoding/decoding and XOR encryption/decryption in .NET code, despite these functions being available in build-in .NET code.
The intent of the independent implementation of these functions is not entirely clear. Nevertheless, it is highly likely that using such custom libraries bypasses common detections by EDRs and other security tools—detections designed to identify usage combinations of functions commonly seen in malware. Additionally, using these custom libraries may allow better compatibility if any of the built-in functions change in a specific version of a .NET control to ensure the group’s tooling is always compatible with its encryption and encoding schemes and/or to better help evade detection.
We observed the same encoding method using the Base64 algorithm to encode and decode data sent between controllers and proxy servers. In several cases, we identified the reuse of a seemingly misspelled Base64 DLL using the name “bsae64” in both foothold utilities deployed via SASHEYAWAY and passive implants including TEMPLEDOOR.
We observed the same rolling encryption module, XORO (MD5: 57cd8e220465aa8030755d4009d0117c),dropped by the TANKSHELL utility; TUNNELBOI network tunneller capable of establishing a connection with a remote host, managing web shells on the network, and creating RDP connections; and the TEMPLEPLAY controller.
Foothold Utilities and Backdoors and Malware Use for Longer Term Persistence
Mandiant is tracking multiple foothold utilities and backdoors used in UNC1860 initial access operations. These generally use custom obfuscation methods that can lower detection rates and make analysis more difficult by renaming strings and function names. Additionally, we are tracking numerous code families that we consider to be UNC1860 “main-stage” implants that further increase the group’s persistence in victim environments.
Please see the Technical Annex for more information.
Additional Protection Information for Google Cloud Customers
For Google SecOps Enterprise+ customers, SecOps rules have been released to the Emerging Threats rule pack, and IOCs listed in this blog post are available for prioritization with Applied Threat Intelligence.
Indicators of Compromise (IOCs)
A Google Threat Intelligence Collection featuring IOCs related to the activity described in this post is now available for registered users.
MD5 Hashes
1176381da7dea356f3377a59a6f0e799
41f4732ed369f2224a422752860b0bc5
4029bc4a06638bb9ac4b8528523b72f6
126bc1c30fba27f8bf67dce4892b1e8c
0c9ff0db00f04fd4c6a9160bffd85a1d
a7693e399602eb79db537c5022dd1e01
d9719f6738dbfaa21be7f184512fe074
17b27e6aa0ab6501f11bb4d2e0f829ff
4dd6250eb2d368f500949952eb013964
69fd67c115349abb4a313230a1692642
7f5f5f290910d256e6b012f898c88bf3
c90ec587e3333dabb647ebc182673460
efe8043e1b4214640c5f7b5ddf737653
a90236e4962620949b720f647a91f101
b26d54b7da7b2bf600104f69da4ea00f
d87ca3f830b8b53fde358bb64900f6af
c50ae2c4b76f0d5724ec240568c78c4f
57cd8e220465aa8030755d4009d0117c
4b2c78bb2c439998cff0cc097a14b942
4abcf21b63781a53bbc1aa17bd8d2cbc
a3ea0d13848a104c28d035a9d518acc2
bd6464f12bb6f7f02b6ffebb363d8e5f
f89be788e4adf665acf1a8ef8fcaa133
f292e61774c267c3787fdfcace50ea7b
c11a4e4a2d484513f79bd127a0387b0c
14e54ff4805840e656efb8cd38de4751
3d5d05f230ae702c04098de512d93d48
a038975255d3dda636d86ccd307f7838
31f2369d2e38c78f5b3f2035dba07c08
c21eefc65cda49f17ddd1d243a7bffb5
c8fa0ce3ae6a13af640607ea606c55f9
2cece71e107d12ffd74b2fb24bf339a6
fa1c6f7a5e02374b9d33de2578cb3399
1e896f026246872b2feb4f8e3e093815
57c916da83cc634af22bde0ad44d0db3
07db3058e32fe5f36823dc7092cd7d5b
3dd829fb27353622eff34be1eabb8f18
1e6679cd25d1bb127a0bec665adcf21e
2e803d28809be2a0216f25126efde37b
2398a83f10329a107801d3d23d06f7cb
73fb0fe5cd96a14a4f85639223aec6a8
85427a8a47c4162b48d8dfb37440665d
a500561c0b374816972094c2aa90da2a
a65ee1a82975ee4c8d4e70219e1bfff5
ce537dd649a391e52c27a3f88a0a8912
e67687b4443f58d2b0a465e3af3caffe
b34883fb1630db43e06a38cebfa0bce2
46804472541ed61cc904cd14be18fe1d
4de802f7e61cb8c820a02e042b58b215
929b12bc9f9e5f8e854de1d46ebf40d9
f0dfb7bf01c0412891da8fa2702f4c7b
b219672bcd60ce9a81b900217b3b5864
fc90907e70f18c7f6a6b9d9599b6f97c
d1e45afbfd3424612b4a4218cc7357ef
da0085a97c38ead734885e5cced1847f
490590bfdeeedf44b3ae306409bb0d03
e86e885e6c96ac72482741d8696c17fb
ca3f0d25f7da0e8cde8e1f367451c77a
7b2fa099d51fa3885766f6d60d768748
6626dbe74acd15d06ff6900071ef240c
YARA Rules
rule M_Autopatt_DropperMemonly_WINTAPIX_1 {
meta:
author = Mandiant
description = “wintapix malware family”
created = “06/26/2023”
modified = “06/26/2023”
version = “1.0”
test_hash = “8578bff36e3b02cc71495b647db88c67c3
c5ca710b5a2bd539148550595d0330″
filetypes = “exe,dll”
dighash_cov_0 = “[[“bf59653dbad735041063″, 1]]”
target_set = “filemd5 +code(“wintapix”) ;; +filemime=
“application/x-dosexec” -pe:framework=dotnet +limit(2000)”
target_set_size = 1
validation_set = “filemd5 +code(“wintapix”) ;;
+filemime=”application/x-dosexec” -pe:framework=dotnet +limit(2000)”
validation_set_approx_size = 1
strings:
$p00_0 = {84ec5ff5f84863f6e9[4]66458b65??4981c5[4]4d0faccf}
$p00_1 = {0f16c00f11014c03c14883c1??
4883e1??4c2bc14d8bc849c1e9??74}
condition:
uint16(0) == 0x5A4D and uint32(uint32(0x3C)) == 0x00004550 and
(
($p00_0 in (660000..690000) and $p00_1 in (9700..20000))
)
}
import “pe”
rule M_WINTAPIX_StringDecodingMethod_1 {
meta:
author = Mandiant
hash1 = “286bd9c2670215d3cb4790aac4552f22”
hash2 = “4dd6250eb2d368f500949952eb013964”
desc = “Detects the byte pattern of a string decoding
method found in the WINTAPIX driver image”
strings:
$a1 = { 48 89 54 24 10 48 89 4C 24 08 48 83 EC 18 C7
04 24 00 00 00 00 48 63 04 24 48 8B 4C 24 ?? 0F BE 04 01
48 8B 4C 24 ?? 0F B6 49 ?? 33 C1 48 63 0C 24 48 8B 54 24
?? 88 04 0A 8B 04 24 FF C0 89 04 24 8B 04 24 FF C8 48 98
48 8B 4C 24 ?? 0F B6 04 01 85 C0 75 }
condition:
uint16(0) == 0x5A4D and
filesize < 1MB and
pe.subsystem == pe.SUBSYSTEM_NATIVE and
all of them
}
import “pe”
rule M_WINTAPIX_PaddedStrings_1 {
meta:
author = Mandiant
hash1 = “286bd9c2670215d3cb4790aac4552f22”
hash2 = “4dd6250eb2d368f500949952eb013964”
desc = “Detects unique strings found in the WINTAPIX
driver image”
strings:
$a1 = { CC CC CC CC CC CC CC 4E 74 44 65 6C 61 79
45 78 65 63 75 74 69 6F 6E 00 }
$a2 = { CC CC CC CC CC 5C 00 }
$a3 = “InitSafeBootMode” ascii fullword
condition:
uint16(0) == 0x5A4D and
pe.subsystem == pe.SUBSYSTEM_NATIVE and
filesize < 1MB and
(
(
all of them and
#a2 == 2
) or
pe.imphash() == “8d070a93a45ed8ba6dba6bfbe0d084e7”
)
}
import “dotnet”
rule M_UNC1860_TEMPLEDOOR_Strings_1 {
meta:
author = Mandiant
date = “28/02/2024”
hash1 = “caffdb648a0a68cd36694f0f0c7699d7”
desc = “Detects the TEMPLEDOOR family based on
unique strings”
comment = “Triggers on TUNNELBOI sample
c517519097bff386dc1784d98ad93f9d”
strings:
$url = “{0}://+:{1}/{2}/” wide fullword
$a1 = “+CjxoZWFkPgo8bWV0YSBodHRwLWVxdWl2
PSJDb250ZW50LVR5cGUiIGNvbnRlbnQ9InRleHQvaHRtb
DsgY2hhcnNldD1pc28tODg1OS0xIi8″ wide
$b1 = “Jet” wide fullword
$b2 = ” Ver” wide fullword
$b3 = “CmD” wide fullword
$c1 = “Command” wide fullword
$c2 = “Upload” wide fullword
$c3 = “Download” wide fullword
$c4 = “Load” wide fullword
$c5 = “Rundll” wide fullword
$c6 = “ERROR” wide fullword
condition:
int16(0) == 0x5a4d and
uint32(uint32(0x3C)) == 0x00004550 and
dotnet.is_dotnet and
$url and
(
$a1 or
2 of ($b*) or
5 of ($c*)
)
}
import “dotnet”
rule M_UNC1860_TEMPLEDOOR_BytePatterns_1 {
meta:
author = Mandiant
date = “28/02/2024”
hash1 = “caffdb648a0a68cd36694f0f0c7699d7”
desc = “Detects the TEMPLEDOOR family based
on unique byte patterns”
comment = “Triggers on TUNNELBOI sample
c517519097bff386dc1784d98ad93f9d and on WINPAY
sample b219672bcd60ce9a81b900217b3b5864″
strings:
$encode_msil = { 7E ?? ?? 00 04 1F 41 1F 61 6F ??
?? 00 0A D2 0A 02 2C 07 02 8E 16 FE 03 2B 01 16 2C 69
16 0B 2B 0F 02 07 02 07 91 06 61 19 58 D2 9C 07 17 58
0B 07 02 8E 69 FE 04 2D E9 02 28 ?? ?? 00 0A } // Packet
encoding method MSIL
$encryption_key = { 54 62 2d 0c 03 45 49 15 2b 43
59 4a 4e 0c 40 }
condition:
int16(0) == 0x5a4d and
uint32(uint32(0x3C)) == 0x00004550 and
dotnet.is_dotnet and
any of them
}
rule M_OBFUSLAY_UNC1860_1 {
meta:
desc = “Detects the UNC1860 OBFUSLAY malware by its
string decryption method”
rs1 = “b66919a18322aa4ce2ad47d149b7fe38063cd3cfa2
e4062cd1a01ad6b3e47651″
strings:
$a1 = {
FE 09 00 00
6F ?? 00 00 0A
FE 0E 00 00
FE 0C 00 00
20 02 00 00 00
5B
8D ?? 00 00 01
FE 0E 01 00
20 00 00 00 00
FE 0E 04 00
38 39 00 00 00
FE 0C 01 00
FE 0C 04 00
20 02 00 00 00
5B
FE 09 00 00
FE 0C 04 00
20 02 00 00 00
6F ?? 00 00 0A
20 10 00 00 00
28 ?? 00 00 0A
9C
FE 0C 04 00
20 02 00 00 00
58
FE 0E 04 00
FE 0C 04 00
FE 0C 00 00
3F BA FF FF FF
FE 0C 01 00
}
condition:
uint16(0) == 0x5A4D and
all of them
}
rule M_APT_CRYPTOSLAY_UNC1860_1 {
meta:
desc = “Detects the UNC1860 CRYPTOSLAY malware by its
string decryption method”
rs1 = “3F2FD2DFD27BF3CAFCBF0946E308832E11A1D9C1
D98FB04AC848E023E6720F53″
rs2 = “5c1a42e9baaec115df337d2f4a9dcce8d73f29375921
827e367fcba8499cdfa2″
strings:
$a1 = {
FE 09 00 00
6F ?? 00 00 0A
FE 0E 00 00
FE 0C 00 00
20 02 00 00 00
5B
8D ?? 00 00 01
FE 0E 01 00
20 00 00 00 00
FE 0E 04 00
38 39 00 00 00
FE 0C 01 00
FE 0C 04 00
20 02 00 00 00
5B
FE 09 00 00
FE 0C 04 00
20 02 00 00 00
6F ?? 00 00 0A
20 10 00 00 00
28 ?? 00 00 0A
9C
FE 0C 04 00
20 02 00 00 00
58
FE 0E 04 00
FE 0C 04 00
FE 0C 00 00
3F BA FF FF FF
28 ?? 00 00 0A
}
$a2 = {
FE 09 00 00
6F ?? 00 00 0A
FE 0E 00 00
FE 0C 00 00
20 02 00 00 00
5B
8D ?? 00 00 01
FE 0E 01 00
20 00 00 00 00
FE 0E 06 00
38 39 00 00 00
FE 0C 01 00
FE 0C 06 00
20 02 00 00 00
5B
FE 09 00 00
FE 0C 06 00
20 02 00 00 00
6F ?? 00 00 0A
20 10 00 00 00
28 ?? 00 00 0A
9C
FE 0C 06 00
20 02 00 00 00
58
FE 0E 06 00
FE 0C 06 00
FE 0C 00 00
FE 04
FE 0E 07 00
FE 0C 07 00
3A B0 FF FF FF
}
condition:
uint16(0) == 0x5A4D and
any of them
}
rule M_Autopatt_DropperMemonly_OATBOAT_1 {
meta:
author = “autopatt”
description = “oatboat malware family”
created = “02/09/2024”
modified = “02/09/2024”
version = “1.0”
test_hash = “6f0a38c9eb9171cd323b0f599b74ee571
620bc3f34aa07435e7c5822663de605″
filetypes = “exe,dll”
dighash_cov_0 = “[[“10a0654cddaedc8bfee4”, 3],
[“aa6b664471b41b27e9a8″, 3]]”
target_set = “filemd5 +code(“oatboat”)
;; +filemime=”application/x-dosexec” -pe:framework=dotnet +limit(2000)”
target_set_size = 7
validation_set = “filemd5 +code(“oatboat”); filemd5
+sig(“mal.oatboat”) ;; +filemime=”application/x-dosexec”
-pe:framework=dotnet +limit(2000)”
validation_set_approx_size = 9
strings:
$p00_0 = {48897c24??55488bec4883ec??488bf9c745[5]33d
bc745[5]488d4d}
$p00_1 = {443ac975??48ffc64883c3??493bf372??498b42??4885c075}
condition:
uint16(0) == 0x5A4D and uint32(uint32(0x3C)) == 0x00004550 and
(
($p00_0 in (250..6500) and $p00_1 in (0..6000))
)
}
rule SASHEYAWAY_Strings_1 {
meta:
desc = “Strings observed in the webshell loader”
rs1 = “2538767f13218503bccf31fccb74e753199
4b69a36a3780b53ba5020d938af20″
strings:
$ = “FromBase64String”
$ = “Page Language=”C#””
$ = “private static System.Reflection.Assembly”
$ = “Page_Load”
$ = “System.Reflection.MethodInfo”
$ = “Activator.CreateInstance”
$ = “Invoke”
condition:
all of them
}
rule M_Hunting_Backdoor_TOFULOAD_1 {
meta:
author = Mandiant
date_created = “2023-08-15”
date_modified = “2023-08-15”
description = “This is a hunting rule to look for TOFULOAD
backdoor used by UNC1860″
md5 = “d1ce3117060e85247145c82005dda985”
strings:
$s1 = {66 77 88 99 48 8D [2] C7 [2] 52 74 6C 52}
// 0x99887766; LEA ??, ??; MOV ??, ‘RltR’;
$s2 = {B8 E1 83 0F 3E F7 [1] C1 [1] 03 0F [2] 6B [1] 21}
// MOV ??, 0x3E0F83E1; MUL ??, ??; SHR ??, 03; MOVZX ??, ??;
IMUL ??, ??, 21;
$s3 = {FF [1] 40 [2] 43 32 [2] 41 88 [3] 44 8B [1] 4D [2] 7C} //
INC ??; MOV ??, ??; XOR ??, ??; MOV ??, ??; MOV ??, ??; CMP ??, ??; JL
condition:
filesize < 50KB and
any of them
}
import “dotnet”
rule M_UNC1860_TEMPLEDROP_Strings_2 {
meta:
author = Mandiant
date = “28/02/2024”
hash1 = “6d3041b89484c273376e5189e190d235”
desc = “Detects the TEMPELDROP family based on unique strings”
comment = “Triggers on TEMPLEDOOR controller sample c517519
097bff386dc1784d98ad93f9d”
strings:
$a1 = “Nothing changed :D” wide fullword
$a2 = “Access: KO” wide fullword
$a3 = “Eventlog stoped.” wide fullword
$b1 = “The Microsoft Exchange Self Protection Driver.” wide fullword
$b2 = “The Microsoft Exchange Filter Driver.” wide fullword
$c1 = “Create RegKey: ” wide
$c2 = “Create Service: ” wide
$c3 = “Test Event lock: ” wide
$c4 = “Test http listner: ” wide
$c5 = “Test IO Changes: ” wide
$c6 = “Test ‘Event lock’: ” wide
$d1 = “no active http port to listen.” wide
$d2 = “Prefixes.Add Error , ” wide
$d3 = “‘ driver service created and started.” wide
$d4 = “‘ service started.” wide
$d5 = “Unhandled exception on create reg key ” wide
$d6 = “Failed to change file ‘CreationTime’.” wide
condition:
int16(0) == 0x5a4d and
uint32(uint32(0x3C)) == 0x00004550 and
dotnet.is_dotnet and
(
1 of ($a*) or
1 of ($b*) or
2 of ($c*) or
2 of ($d*)
)
}
rule M_Autopatt_Backdoor_TOFUDRV_1 {
meta:
author = Mandiant
description = “tofudrv malware family”
created = “11/29/2023”
modified = “11/29/2023”
version = “1.0”
test_hash = “03d2e623d7f4430952cf27afe8e137ef1dcb
320f1a9781048798582b55e48f9b”
filetypes = “exe,dll”
dighash_cov_0 = “[[“5499758ed59a9ea0cacd”, 1]]”
target_set = “filemd5 +code(“tofudrv”) ;;
+filemime=”application/x-dosexec” -pe:framework=dotnet +limit(2000)”
target_set_size = 1
validation_set = “filemd5 +code(“tofudrv”) ;;
+filemime=”application/x-dosexec” -pe:framework=dotnet +limit(2000)”
validation_set_approx_size = 1
strings:
$p00_0 = {eb??33c083f8??0f85[4]488b4c24??e8[4]eb??c74424[5]eb}
$p00_1 =
{f3aa41b8[4]33d2488d4c24??e8[4]488b8424[4]48898424[4]48638424[4]48898424}
condition:
uint16(0) == 0x5A4D and uint32(uint32(0x3C)) == 0x00004550 and
(
($p00_0 in (34000..45000) and $p00_1 in (28000..39000))
)
}
import “pe”
rule M_TOFUDRV_Strings_1 {
meta:
author = Mandiant
hash = “b4b1e285b9f666ae7304a456da01545e”
desc = “Detects cleartext strings that appear in the TOFUDRV image”
strings:
$a1 = “\systemroot\system32\drivers” ascii fullword
$a2 = “\SafeBoot\Minimal\” ascii fullword
$a3 = “\REGISTRY\MACHINE\SYSTEM\CurrentControlSet\Control”
ascii fullword
$a4 = “\SafeBoot\Network\” ascii fullword
$a5 =
“ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/”
ascii fullword
$a6 = “Found” ascii fullword
condition:
uint16(0) == 0x5A4D and
filesize < 500KB and
pe.subsystem == pe.SUBSYSTEM_NATIVE and
(
3 of them or
pe.imphash() == “ff6f16b00c9f36b32cd60fecd4dfc8e9”
)
}
import “pe”
rule M_TOFUDRV_RtlSubtreeStackStrings_1 {
meta:
author = Mandiant
hash = “b4b1e285b9f666ae7304a456da01545e”
desc = “Detects a stack string byte pattern in a function intended
to resolve the memory image base of ntoskrnl.exe in TOFUDRV”
strings:
// “RtlSubtreePredecessor”
$a1 = { C6 44 24 ?? 52 C6 44 24 ?? 74 C6 44 24 ?? 6C C6 44 24 ??
53 C6 44 24 ?? 75 C6 44 24 ?? 62 C6 44 24 ?? 74 C6 44 24 ?? 72 C6 44
24 ?? 65 C6 44 24 ?? 65 C6 44 24 ?? 50 C6 44 24 ?? 72 C6 44 24 ?? 65
C6 44 24 ?? 64 C6 44 24 ?? 65 }
// “RtlSubtreeSuccessor”
$a2 = { C6 84 24 ?? 00 00 00 6C C6 84 24 ?? 00 00 00 53 C6 84 24
?? 00 00 00 75 C6 84 24 ?? 00 00 00 62 C6 84 24 ?? 00 00 00 74 C6 84
24 ?? 00 00 00 72 C6 84 24 ?? 00 00 00 65 C6 84 24 ?? 00 00 00 65 C6
84 24 ?? 00 00 00 53 C6 84 24 ?? 00 00 00 75 }
$KeGetPcr = { 65 48 8B 04 25 18 00 00 00 48 89 44 24 }
condition:
uint16(0) == 0x5A4D and
filesize < 500KB and
pe.subsystem == pe.SUBSYSTEM_NATIVE and
$KeGetPcr and
any of ($a*)
}
rule M_Dropper_MSIL_TEMPLESHOT_1 {
meta:
author = Mandiant
date_created = “2020-05-22”
date_modified = “2020-05-22”
md5 = “6d3041b89484c273376e5189e190d235”
rev = 2
strings:
$ss1 = “–install” fullword wide
$ss2 = “‘ directory created.” fullword wide
$ss3 = “‘ file created.” fullword wide
$ss4 = “‘ service created.” fullword wide
$ss5 = “Nothing changed :D” fullword wide
$ss6 = “x00ProtectDriverx00”
$ss7 = “x00WriteAllBytesx00”
$ss8 = “x00CopyTimex00”
$ss9 = “Tx00Vx00qx00Qx00”
condition:
(
uint16(0) == 0x5A4D and
uint32(uint32(0x3C)) == 0x00004550
) and
all of them
}
rule M_Backdoor_MSIL_TEMPLESHOT_2 {
meta:
author = Mandiant
date_created = “2020-05-22”
date_modified = “2020-05-22”
md5 = “a991bdbf1e36d7818d7a340a35a4ea26”
rev = 2
strings:
$sb1 = { 02 7B [2] 00 04 [0-8] FE 03 [0-8] 39 [4-8] 02 7B [2] 00 04
[5] 0? 02 7B [2] 00 04 [5-12] 0C }
$sb2 = { 7B [2] 00 04 [0-16] 13 ?? 11 [1-8] 17 59 45 04 00 00 00 02
[4-64] 2B ?? 02 [1-2] 7B [2] 00 04 73 [2] 00 06 28 [2] 00 06 0A 2B ?? 02
[1-2] 7B [2] 00 04 73 [2] 00 06 28 [2] 00 06 [0-4] 0A 2B }
$ss1 = “x00set_UseShellExecutex00”
$ss2 = “x00HttpListenerRequestx00”
$ss3 = “x00HttpListenerResponsex00”
$ss4 = “x00HttpListenerx00”
condition:
(
uint16(0) == 0x5A4D and
uint32(uint32(0x3C)) == 0x00004550
) and
all of them
}
rule M_Backdoor_MSIL_TEMPLESHOT_1 {
meta:
author = Mandiant
date_created = “2020-05-22”
date_modified = “2020-05-22”
md5 = “952482949f495fb66e493e441229ae4b”
rev = 2
strings:
$sb1 = { 06 17 7D [4] 06 20 36 01 00 C0 7D [4] DE 00 07
15 3B [4] 07 28 [4-12] 0D [8-64] 11 06 [4-12] 13 07 11 07 39 [4-32]
20 FF FF 1F 00 12 09 [0-12] 11 09 12 0A [4-12] 12 0A 11 07 }
$ss1 = “x00GetProcessByIdx00”
$ss2 = “x00NtOpenThreadx00”
$ss3 = “x00NtQueryInformationThreadx00”
$ss4 = “x00ReadProcessMemoryx00”
$ss5 = “x00NtTerminateProcessx00”
$ss6 = “x00set_UseShellExecutex00”
$ss7 = “x00DESCryptoServiceProviderx00”
$ss8 = “x00GetExecutingAssemblyx00”
condition:
(
uint16(0) == 0x5A4D and
uint32(uint32(0x3C)) == 0x00004550
) and
all of them
}
Article Link: https://cloud.google.com/blog/topics/threat-intelligence/unc1860-iran-middle-eastern-networks/
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