SysWhispers2 - AV/EDR Evasion Via Direct System Calls
SysWhispers helps with evasion by generating header/ASM files implants can use to make direct system calls.
All core syscalls are supported and example generated files available in the example-output/
folder.
The usage is almost identical to SysWhispers1 but you don't have to specify which versions of Windows to support. Most of the changes are under the hood. It no longer relies on @j00ru's syscall tables, and instead uses the "sorting by system call address" technique popularized by @modexpblog. This significantly reduces the size of the syscall stubs.
The specific implementation in SysWhispers2 is a variation of @modexpblog's code. One difference is that the function name hashes are randomized on each generation. @ElephantSe4l, who had published this technique earlier, has another implementation based in C++17 which is also worth checking out.
The original SysWhispers repository is still up but may be deprecated in the future.
Introduction
Various security products place hooks in user-mode API functions which allow them to redirect execution flow to their engines and detect for suspicious behaviour. The functions in ntdll.dll
that make the syscalls consist of just a few assembly instructions, so re-implementing them in your own implant can bypass the triggering of those security product hooks. This technique was popularized by @Cn33liz and his blog post has more technical details worth reading.
SysWhispers provides red teamers the ability to generate header/ASM pairs for any system call in the core kernel image (ntoskrnl.exe
). The headers will also include the necessary type definitions.
Installation
> git clone https://github.com/jthuraisamy/SysWhispers2.git
> cd SysWhispers2
> py .\syswhispers.py --help
Usage and Examples
Command Lines
# Export all functions with compatibility for all supported Windows versions (see example-output/).
py .\syswhispers.py --preset all -o syscalls_all
# Export just the common functions (see below for list).
py .\syswhispers.py --preset common -o syscalls_common
# Export NtProtectVirtualMemory and NtWriteVirtualMemory with compatibility for all versions.
py .\syswhispers.py --functions NtProtectVirtualMemory,NtWriteVirtualMemory -o syscalls_mem
Script Output
PS C:\Projects\SysWhispers2> py .\syswhispers.py --preset common --out-file syscalls_common
. ,--.
,-. . . ,-. . , , |-. o ,-. ,-. ,-. ,-. ,-. /
`-. | | `-. |/|/ | | | `-. | | |-' | `-. ,-'
`-' `-| `-' ' ' ' ' ' `-' |-' `-' ' `-' `---
/| | @Jackson_T
`-' ' @modexpblog, 2021
SysWhispers2: Why call the kernel when you can whisper?
Common functions selected.
Complete! Files written to:
syscalls_common.h
syscalls_common.c
syscalls_common_stubs.asm
Before-and-After Example of Classic
CreateRemoteThread
DLL Injectionpy .\syswhispers.py -f NtAllocateVirtualMemory,NtWriteVirtualMemory,NtCreateThreadEx -o syscalls
#include <Windows.h>
void InjectDll(const HANDLE hProcess, const char* dllPath)
{
LPVOID lpBaseAddress = VirtualAllocEx(hProcess, NULL, strlen(dllPath), MEM_COMMIT | MEM_RESERVE, PAGE_READWRITE);
LPVOID lpStartAddress = GetProcAddress(GetModuleHandle(L"kernel32.dll"), "LoadLibraryA");
WriteProcessMemory(hProcess, lpBaseAddress, dllPath, strlen(dllPath), nullptr);
CreateRemoteThread(hProcess, nullptr, 0, (LPTHREAD_START_ROUTINE)lpStartAddress, lpBaseAddress, 0, nullptr);
}
#include <Windows.h>
#include "syscalls.h" // Import the generated header.
void InjectDll(const HANDLE hProcess, const char* dllPath)
{
HANDLE hThread = NULL;
LPVOID lpAllocationStart = nullptr;
SIZE_T szAllocationSize = strlen(dllPath);
LPVOID lpStartAddress = GetProcAddress(GetModuleHandle(L"kernel32.dll"), "LoadLibraryA");
NtAllocateVirtualMemory(hProcess, &lpAllocationStart, 0, (PULONG)&szAllocationSize, MEM_COMMIT | MEM_RESERVE, PAGE_READWRITE);
NtWriteVirtualMemory(hProcess, lpAllocationStart, (PVOID)dllPath, strlen(dllPath), nullptr);
NtCreateThreadEx(&hThread, GENERIC_EXECUTE, NULL, hProcess, lpStartAddress, lpAllocationStart, FALSE, 0, 0, 0, nullptr);
}
Common Functions
Using the --preset common
switch will create a header/ASM pair with the following functions:
- NtCreateProcess (CreateProcess)
- NtCreateThreadEx (CreateRemoteThread)
- NtOpenProcess (OpenProcess)
- NtOpenThread (OpenThread)
- NtSuspendProcess
- NtSuspendThread (SuspendThread)
- NtResumeProcess
- NtResumeThread (ResumeThread)
- NtGetContextThread (GetThreadContext)
- NtSetContextThread (SetThreadContext)
- NtClose (CloseHandle)
- NtReadVirtualMemory (ReadProcessMemory)
- NtWriteVirtualMemory (WriteProcessMemory)
- NtAllocateVirtualMemory (VirtualAllocEx)
- NtProtectVirtualMemory (VirtualProtectEx)
- NtFreeVirtualMemory (VirtualFreeEx)
- NtQuerySystemInformation (GetSystemInfo)
- NtQueryDirectoryFile
- NtQueryInformationFile
- NtQueryInformationProcess
- NtQueryInformationThread
- NtCreateSection (CreateFileMapping)
- NtOpenSection
- NtMapViewOfSection
- NtUnmapViewOfSection
- NtAdjustPrivilegesToken (AdjustTokenPrivileges)
- NtDeviceIoControlFile (DeviceIoControl)
- NtQueueApcThread (QueueUserAPC)
- NtWaitForMultipleObjects (WaitForMultipleObjectsEx)
Importing into Visual Studio
- Copy the generated H/C/ASM files into the project folder.
- In Visual Studio, go to Project → Build Customizations... and enable MASM.
- In the Solution Explorer, add the .h and .c/.asm files to the project as header and source files, respectively.
- Go to the properties of the ASM file, and set the Item Type to Microsoft Macro Assembler.
- Ensure that the project platform is set to x64. 32-bit projects are not supported at this time.
Caveats and Limitations
- Only 64-bit Windows is supported at this time.
- System calls from the graphical subsystem (
win32k.sys
) are not supported. - Tested on Visual Studio 2019 (v142) with Windows 10 SDK.
Troubleshooting
- Type redefinitions errors: a project may not compile if typedefs in
syscalls.h
have already been defined.- Ensure that only required functions are included (i.e.
--preset all
is rarely necessary). - If a typedef is already defined in another used header, then it could be removed from
syscalls.h
.
- Ensure that only required functions are included (i.e.
Credits
Developed by @Jackson_T and @modexpblog, but builds upon the work of many others:
- @FoxHex0ne for cataloguing many function prototypes and typedefs in a machine-readable format.
- @PetrBenes, NTInternals.net team, and MSDN for additional prototypes and typedefs.
- @Cn33liz for the initial Dumpert POC implementation.
Related Articles and Projects
- @modexpblog: Bypassing User-Mode Hooks and Direct Invocation of System Calls for Red Teams
- @hodg87: Malware Mitigation when Direct System Calls are Used
- @Cn33liz: Combining Direct System Calls and sRDI to bypass AV/EDR (Code)
- @0x00dtm: Userland API Monitoring and Code Injection Detection
- @0x00dtm: Defeating Userland Hooks (ft. Bitdefender) (Code)
- @mrgretzky: Defeating Antivirus Real-time Protection From The Inside
- @SpecialHoang: Bypass EDR’s memory protection, introduction to hooking (Code)
- @xpn and @domchell: Silencing Cylance: A Case Study in Modern EDRs
- @mrjefftang: Universal Unhooking: Blinding Security Software (Code)
- @spotheplanet: Full DLL Unhooking with C++
- @hasherezade: Floki Bot and the stealthy dropper
- @hodg87: Latest Trickbot Variant has New Tricks Up Its Sleeve
References to SysWhispers
- @JFaust_: Process Injection Part 1, Part 2, and Alaris loader project (Code)
- @0xPat: Malware Development Part 2
- @brsn76945860: Implementing Syscalls In The CobaltStrike Artifact Kit
- @Cn33liz and @_DaWouw: Direct Syscalls in Beacon Object Files (Code)