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The code appears to have been forked by a second author and has additions that target the Danske Bank MobilePay application and the popular Danish Nem ID two factor authentication 2FA system. This article shows the process of walking through Static and Dynamic analysis to unlock the packed source code for the malware. As part of my journey into Cyber Security I thought it would be interesting to see how modern mobile malware operates. I chose the following sample at random based on an article here. A quick google search for these hashes will lead you to the file used if you would also like to explore this sample. The article above demonstrates that the analyst has gone from sample to source code, but it is not clear how this is achieved. There are references to suggest that the code has been packed, but again no information on how it was unpacked for analysis. This post will break down the process I used to analyse this sample, hopefully with enough detail to provide some tips and guidance for others wishing to attempt similar. The process I followed can be logically broken into the following stages:. However, we also note that all classify it heuristically as a generic strain of malware — either a Trojan, Dropper, Fake Installer etc. Nothing to suggest it is in fact GM Bot Android, or any specific type of malware. The original Security Intelligence article references IBM X-Force research, so this is the next stop — but again nothing immediately obvious with regards to this sample could be located. A wider search of the internet reveals some history of GM bot, originally built and sold by Ganga Man on dark web forums. Following a dispute the source code for both client APK and C2 server were released publicly. A copy is hosted here on Github and will provide useful for cross referencing with this sample later in the analysis. This will unzip the contents, as well as providing a disassembly of the DEX code into Smali:. The results of this can be seen below and the tool has also provided a human readable version of the AndroidManifest. First stop is to take a look at the Android Manifest file, that should provide an overview of the components of the application and permissions requested. Initial analysis shows a broad range of permissions that indicate malicious behavior including permissions to:. A summarized view of referenced class files for the main application, activities 15 and services 2 can be seen below:. In addition, we see 4 further classes mapped as Broadcast Receivers which will process event messages Android system Intents as shown below:. Before proceeding with any reverse engineering of the code, the next step is to explore the other files in the APK for clues. A binary file with no immediately obvious format. The strings clearly indicate that this malware is targeting capturing victims credit card information. It is interesting to note that:. It is likely that the attackers would seek to obtain additional VBV credentials via the malware in order to allow online purchases with the card details or avoid these countries. Next we attempt to reverse engineer the DEX file back to original Java source code. The resulting java classes that we see in JD-GUI show that there are only 4 java classes contained in the application. This is in direct contrast to the 16 different classes we saw declared in the application manifest. This confirms that there must be additional code that is loaded dynamically at run time — it is most likely that these four classes are in fact an unpacker. Examining the code we see that it is heavily obfuscated and has been crafted in a way to prevent clean decompiling of the code. This aside, we can start to get an understanding of the function of these four classes by examining the system classes that are imported and therefore used when the application is first executed. After exporting the java source from JD-GUI and unzipping to a new folder, we can extract the imported classes from these files:. Essentially we have a very small set of libraries that are being imported and used. These consist of functionality for:. As the Java code cannot be readily decompiled due to protections injected by the malware author we will instead debug the executable against the Smali assembly code. We next set the breakpoints as required across the three classes that we are interested in a,b,c:. We will initially debug the calls to interesting reflection methods identified, which are as below:. To enable the debugger to connect to the application, we perform the following prior to starting the application:. In Android Studio, attach the debugger using the icon. Choose the malicious application process. The debugger then stops at our first breakpoint as shown below:. Note you should now set some variables to watch — as per above I have set v0 through v10 and p1 through p3. Our first breakpoint is hit and we see we are about to execute a method by reflection. Noting that we have not yet called newInstance we can assume this is calling existing loaded classes — either one of the four loaded by the application, or some other Android framework classes. An initial call to get the current context object -presumably to start retrieving local resources from the APK. We now allow the debugger to continue, and repeat this exercise several times to build up a flow of the reflected method calls:. Pausing here, we can see the code is attempting to load the file that we had previously flagged as of interest in the static analysis section. Continuing we see the file is read, presumably decrypted and then written out again as a jar file:. Looking at the API for the DexClassLoader we can see that it takes two arguments — the location of the file to load, and a writeable area that it will use to re-write an optimised version of the code for the specific machine architecture — eg the Android Run Time ART. Further information on this can be seen in the Android API documentation:. We can see the exact location of the jar file in the debugger below, and the next step is to recover this file via ADB command line. After execution of the classloader, connecting via ADB shell we see the two files, the original and the DEX optimised code:. Repeating the steps to convert this to a jar file using dex2jar and decompiling with JD-GUI, we confirm we now have the full un-obfuscated source code for this malware sample. Upon initial analysis we can see the codebase bear remarkable similarities with the leaked source identified in the static analysis. However there are significant differences, and the code has been customised to specifically target the Danske Bank MobilePay application. Upon first installation and execution the application will perform two primary functions. Secondly the malware will then nag the user to accept the software as a device administrator. If the user declines the request is re-triggered, making it very difficult for most users to escape this screen without accepting. With this permission in place, the malware achieves two objectives:. The malware maintains a regular heartbeat to the C2 server, which provides a mechanism for the attacker to issue specific commands to the device. Each hearbeat contains the installation ID and the current screen status. It is hypothesised that the attacker would ideally choose to execute malicious activities when the screen was off, and the user was not watching the phone. This simulates an Android software update screen, and effectively hides any other activity that is occurring behind the screen overlay such as sending, receiving or deleting SMS messages. Additionally this could be used to disable the user, and prevent them from using the phone whilst their accounts or cards are being compromised in real time. Next we see another function that is intended to intercept and forward SMS messages to the C2 server, and specifically trying to remove evidence that they ever existed by deleting them. This is used to steal 2FA credentials. Finally, we see the ability to send an arbitrary SMS message to a mobile defined by the attacker and a function to launch a customised push notification to another application on the device. It was not clear what this could be used for. By listening for incoming SMS messages the malware could also trigger a fake Android update screen that would then harvest, forward and attempt to delete messages as they arrived on the phone. As per the original article and many of the indicators from the static analysis, the primary purpose of the application is to steal data by performing overlays on top of legitimate applications. The malware targets three specific classes of applications:. Upon launching the MobilePay application the overlay attempts to steal the users CPR number unique social security type id , mobile number and Nem pass code. It then asks the user to take a photo of their Nem ID passbook, containing one time use codes which can be used by the attacker to then log into MobilePay and other Danish systems and issue payments. Upon launching one of the targeted applications, a credit card overlay is displayed with a configurable icon depending on the application launched. After basic card details are collected, the application then attempts to recover the Verified by Visa password for the user. These details are then forwarded to the C2 server. The sample appears to be a specifically customised variant that is being used in a campaign to target the Danske Bank MobilePay application. This is a good example of how once released, complex code can be quickly and easily forked by less skilled authors and a pattern we also see today with the release of the Mirai botnet code. Quickly we see a spread of variants of the codebase that become harder to trace and detect and importantly attribute to any individual or group. As ever, the best advice to prevent becoming a victim of such malware is to ensure that your phone is not configured to install 3rd party applications, and always review requests for permissions carefully — eg, are they aligned with the expected purpose of the application? Due to time constraints there are a few further areas I would have liked to explore. I may pick these up in a subsequent post, but for the record they are:. I welcome and encourage all feedback! Analyzing a variant of the GM Bot Android malware. Background As part of my journey into Cyber Security I thought it would be interesting to see how modern mobile malware operates. The process I followed can be logically broken into the following stages: Analysis Process Public Analysis — What can we find out using existing public sources of information? What analysis has already been performed automated or manual? Static Analysis — What can we determine from the sample without actually running it in an emulated environment? DEX Extraction and De-compilation — Once we have mapped out the function of the unpacker, how do we then recover the main code for the malware and reverse it? VirusTotal Results However, we also note that all classify it heuristically as a generic strain of malware — either a Trojan, Dropper, Fake Installer etc. This will unzip the contents, as well as providing a disassembly of the DEX code into Smali: Extracted APK files First stop is to take a look at the Android Manifest file, that should provide an overview of the components of the application and permissions requested. Manifest Analysis — AndroidManifest. Classes Declared in Manifest -Application, Activities and Services In addition, we see 4 further classes mapped as Broadcast Receivers which will process event messages Android system Intents as shown below: Executing code when the phone is powered on starting the application automatically Receive notification when Device Admin is granted, requested or a request to disable admin is received and hence interfere, or nag the user to enable it Receive notification of a new inbound SMS — with high priority flag to ensure the code can intercept it first and potentially stop any further alerts can be used to steal 2FA tokens Before proceeding with any reverse engineering of the code, the next step is to explore the other files in the APK for clues. Files of interest The following files were noted as of interest: It is interesting to note that: The resource keys here are all in English, suggesting the original developer may be English speaking There are specific strings that are in Danish, despite this resource file being intended for English language In addition to English language strings we also see several other targeted countries: Other Resource Files File: Unpacker Classes Examining the code we see that it is heavily obfuscated and has been crafted in a way to prevent clean decompiling of the code. After exporting the java source from JD-GUI and unzipping to a new folder, we can extract the imported classes from these files: Class Imported Class com. These consist of functionality for: Stage 3 — Unpacker Debugging As the Java code cannot be readily decompiled due to protections injected by the malware author we will instead debug the executable against the Smali assembly code. We next set the breakpoints as required across the three classes that we are interested in a,b,c: Setting Breakpoints in Android Studio We will initially debug the calls to interesting reflection methods identified, which are as below: To enable the debugger to connect to the application, we perform the following prior to starting the application: Attaching Debugger In Android Studio, attach the debugger using the icon. The debugger then stops at our first breakpoint as shown below: First Breakpoint Reached Note you should now set some variables to watch — as per above I have set v0 through v10 and p1 through p3. Stepping into Reflected Method Call An initial call to get the current context object -presumably to start retrieving local resources from the APK. We now allow the debugger to continue, and repeat this exercise several times to build up a flow of the reflected method calls: IllegalArgumentException String s void Java. Continuing we see the file is read, presumably decrypted and then written out again as a jar file: Further information on this can be seen in the Android API documentation: Examining the files Extracting the jar file we find the classes. Decompiled Source Code Stage 5 — Dynamic and Functional Analysis First Installation Upon initial analysis we can see the codebase bear remarkable similarities with the leaked source identified in the static analysis. First Installation Process Overview Upon first installation and execution the application will perform two primary functions. With this permission in place, the malware achieves two objectives: The application cannot be un-installed by the user easily, without de-activating the device administrator. Attempting to do this will trigger the launching of overlays that prevent removing the device admin At some point in the future, once further data has been stolen from the phone, the C2 server can issue a command to wipe the device, removing evidence of the infection and restoring the device to a factory state Ongoing Operations — including after each reboot Command and Control Process Flows The malware maintains a regular heartbeat to the C2 server, which provides a mechanism for the attacker to issue specific commands to the device. Automating Data Theft Decompiled Code Showing Targeted Applications As per the original article and many of the indicators from the static analysis, the primary purpose of the application is to steal data by performing overlays on top of legitimate applications. The malware targets three specific classes of applications: Stealing Credit Card Details Credit Card Overlay Process Upon launching one of the targeted applications, a credit card overlay is displayed with a configurable icon depending on the application launched. Summary The sample appears to be a specifically customised variant that is being used in a campaign to target the Danske Bank MobilePay application. Open Questions Due to time constraints there are a few further areas I would have liked to explore. I may pick these up in a subsequent post, but for the record they are: The debugger failed to return from the call to unpack the payload code. It is not clear if any further reflected actions were performed beyond this. Android GM Bot Android malware mobile. The passion for writing and a strong belief that security is founded on sharing and awareness led Pierluigi to find the security blog 'Security Affairs' recently named a Top National Security Resource for US. You might also like. A second sample of the Shamoon V3 wiper analyzed by the experts. Operation Sharpshooter targets critical infrastructure and global defense. This site uses cookies, including for analytics, personalization, and advertising purposes. For more information or to change your cookie settings, click here. If you continue to browse this site without changing your cookie settings, you agree to this use.

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