Recently I've been using lot of assembly language in *NIX operating systems. I was wondering about the Windows domain.

Calling convention in Linux:

mov $SYS_Call_NUM, %eax
mov $param1 , %ebx
mov $param2 , %ecx
int $0x80

Thats it. That is how we should make a system call in Linux.

Reference of all system calls in Linux:

Regarding which $SYS_Call_NUM & which parameters we can use this reference : http://docs.cs.up.ac.za/programming/asm/derick_tut/syscalls.html

OFFICIAL Reference : http://kernel.org/doc/man-pages/online/dir_section_2.html

Calling convention in Windows:


Reference of all system calls in Windows:


Unofficial : http://www.metasploit.com/users/opcode/syscalls.html , but how do I use these in assembly unless I know the calling convention.


  • If you say, they didn't documented it. Then how is one going to write libc for windows without knowing system calls? How is one gonna do Windows Assembly programming? Atleast in the driver programming one needs to know these. right?

Now, whats up with the so called Native API? Is Native API & System calls for windows both are different terms referring to same thing? In order to confirm I compared these from two UNOFFICIAL Sources

System Calls: http://www.metasploit.com/users/opcode/syscalls.html

Native API: http://undocumented.ntinternals.net/aindex.html

My observations:

  1. All system calls are beginning with letters Nt where as Native API is consisting of lot of functions which are not beginning with letters Nt.
  2. System Call of windows are subset of Native API. System calls are just part of Native API.

Can any one confirm this and explain.


There was another answer. It was a 2nd answer. I really liked it but I don't know why answerer has deleted it. I request him to repost his answer.

  • Also read this: stackoverflow.com/questions/919051/…
    – claws
    Mar 22, 2010 at 18:12
  • 4
    Your metasploit links are broken...
    – Calmarius
    Aug 23, 2013 at 13:03
  • 1
    "how is one going to write libc for windows" - By using the documented API. Linux doesn't have an API, and syscalls are the closest thing, so that's what you need to use on Linux. Not because that's a terribly great way of interacting with the OS, but because it's the only way there is. Nov 19, 2021 at 16:17
  • 1
    how is one going to write libc for windows - by calling the WinAPI functions. How do you implement those yourself? By working at Microsoft and consulting their internal documentation and code with call-numbers. For anyone else, reverse-engineering MS's existing libraries if you really want to make code that will break on future Windows versions when they change the private interface between their DLLs and their kernel. Aug 5, 2022 at 11:59

5 Answers 5


If you're doing assembly programming under Windows you don't do manual syscalls. You use NTDLL and the Native API to do that for you.

The Native API is simply a wrapper around the kernelmode side of things. All it does is perform a syscall for the correct API.

You should NEVER need to manually syscall so your entire question is redundant.

Linux syscall codes do not change, Windows's do, that's why you need to work through an extra abstraction layer (aka NTDLL).


Also, even if you're working at the assembly level, you still have full access to the Win32 API, there's no reason to be using the NT API to begin with! Imports, exports, etc all work just fine in assembly programs.


If you REALLY want to do manual syscalls, you're going to need to reverse NTDLL for each relevant Windows version, add version detection (via the PEB), and perform a syscall lookup for each call.

However, that would be silly. NTDLL is there for a reason.

People have already done the reverse-engineering part: see https://j00ru.vexillium.org/syscalls/nt/64/ for a table of system-call numbers for each Windows kernel. (Note that the later rows do change even between versions of Windows 10.) Again, this is a bad idea outside of personal-use-only experiments on your own machine to learn more about asm and/or Windows internals. Don't inline system calls into code that you distribute to anyone else.

  • 7
    A short & concise article that is a great supplement to this answer: codeproject.com/KB/system/Win32.aspx
    – claws
    Mar 22, 2010 at 18:14
  • 5
    That article is not what you're looking for. It shows how to perform manual syscalls, which you should not be doing because the numbers change across Windows versions and service packs. As I've already stated, you should be using the Windows API to perform the dispatching for you. NTDLL is mapped into all processes automatically. So even if for some reason you can't use imports (I can't think of any reasonable times where this would be the case) you can still get a handle to NTDLL and enumerate the EAT manually to get the necessary function pointers (though you should never have to). Mar 22, 2010 at 21:25
  • 2
    @claws The article is a very interesting read, thanks a lot Sep 24, 2012 at 22:43
  • 15
    This isn't really directed at the author of this answer specifically, but I don't understand why these "don't do this" answers are so prevalent on SO, isn't this supposed to be a site "for professional and enthusiast programmers"? Why on one hand does this site encourage extreme research effort but then when you get to these low level curiosity questions I see a constant stream of "you don't need to know that!!!". Who is the real target audience for this site again? People who need their hands held or people who really are willing to dig deep?
    – jrh
    Mar 15, 2017 at 12:25
  • 2
    Here is the new location of the arcticle that was originally linked by claws on Mar 22'10 at 5:09: codeproject.com/Articles/33870/…
    – riQQ
    Aug 21, 2020 at 13:46

The other thing you need to know about the windows syscall convention is that as I understand it the syscall tables are generated as part of the build process. This means that they can simply change - no one tracks them. If someone adds a new one at the top of the list, it doesn't matter. NTDLL still works, so everyone else who calls NTDLL still works.

Even the mechanism used to perform syscalls (which int, or sysenter) is not fixed in stone and has changed in the past, and I think that once upon a time the same version of windows used different DLLs which used different entry mechanisms depending on the CPU in the machine.

  • 1
    +1 because I found this very interesting. Do you have any resources (internet or books) where one can learn more about that kind of Win32 API / syscall internals? Apr 30, 2010 at 19:34
  • 3
    It is a bit out of date, but Inside Windows 2000 covers this I think. nynaeve.net/?p=48 has a nice discussion and also demonstrates that there are at last three syscall conventions in use on windows on x86 and x64. IA64 probably does something totally different again, and then of course there was Alpha, PowerPC, MIPS and probably others. Of course, usual caveat applies - all undocumented and likely to change.
    – Stewart
    Apr 30, 2010 at 21:44

I was interested in doing a windows API call in assembly with no imports (as an educational exercise), so I wrote the following FASM assembly to do what NtDll!NtCreateFile does. It's a rough demonstration on my 64-bit version of Windows (Win10 1803 Version 10.0.17134), and it crashes out after the call, but the return value of the syscall is zero so it is successful. Everything is set up per the Windows x64 calling convention, then the system call number is loaded into RAX, and then it's the syscall assembly instruction to run the call. My example creates the file c:\HelloWorldFile_FASM, so it has to be run "as administrator".

format PE64 GUI 4.0

entry start

section '.text' code readable executable

 ;puting the first four parameters into the right registers

                            mov rcx, _Handle
                            mov rdx, [_access_mask]
                            mov r8, objectAttributes
                            mov r9, ioStatusBlock

 ;I think we need 1 stack word of padding:

                            push 0x0DF0AD8B

 ;pushing the other params in reverse order:

                            push [_eaLength]
                            push [_eaBuffer]
                            push [_createOptions]
                            push [_createDisposition]
                            push [_shareAcceses]
                            push [_fileAttributes]
                            push [_pLargeInterger]

 ;adding the shadow space (4x8)

 ;                               push 0x0
 ;                               push 0x0
 ;                               push 0x0
 ;                               push 0x0

 ;pushing the 4 register params into the shadow space for ease of debugging

                            push r9
                            push r8
                            push rdx
                            push rcx

 ;now pushing the return address to the stack:

                            push endOfProgram

                            mov r10, rcx ;copied from ntdll!NtCreateFile, not sure of the reason for this
                            mov eax, 0x55


 section '.data' data readable writeable


 _Handle                         dq      0x0
 _access_mask                    dq      0x00000000c0100080
 _pObjectAttributes              dq      objectAttributes        ; at 00402058
 _pIoStatusBlock                 dq           ioStatusBlock
 _pLargeInterger                 dq      0x0
 _fileAttributes                 dq      0x0000000000000080
 _shareAcceses                   dq      0x0000000000000002
 _createDisposition              dq      0x0000000000000005
 _createOptions                  dq      0x0000000000000060
 _eaBuffer                       dq      0x0000000000000000       ; "optional" param
 _eaLength                       dq      0x0000000000000000


                            align   16
 _oalength                       dq      0x30
 _rootDirectory                  dq      0x0
 _objectName                     dq           unicodeString
 _attributes                     dq      0x40
 _pSecurityDescriptor            dq      0x0
 _pSecurityQualityOfService      dq      securityQualityOfService

 _unicodeStringLength            dw      0x34
 _unicodeStringMaxumiumLength    dw      0x34, 0x0, 0x0
 _pUnicodeStringBuffer           dq      _unicodeStringBuffer

 _unicodeStringBuffer            du      '\??\c:\HelloWorldFile_FASM'       ; may need to "run as adinistrator" for the file create to work.

 _status_pointer                 dq      0x0
 _information                    dq      0x0

 _sqlength                       dd      0xC
 _impersonationLevel             dd      0x2
 _contextTrackingMode            db      0x1
 _effectiveOnly                  db      0x1, 0x0, 0x0

I used the documentation for Ntdll!NtCreateFile, and I also used the kernel debugger to look at and copy a lot of the params.

__kernel_entry NTSTATUS NtCreateFile(
  OUT PHANDLE                      FileHandle,
  IN ACCESS_MASK                   DesiredAccess,
  IN POBJECT_ATTRIBUTES            ObjectAttributes,
  OUT PIO_STATUS_BLOCK             IoStatusBlock,
  IN ULONG                         FileAttributes,
  IN ULONG                         ShareAccess,
  IN ULONG                         CreateDisposition,
  IN ULONG                         CreateOptions,
  IN PVOID EaBuffer                OPTIONAL,
  IN ULONG                         EaLength
  • 1
    Thanks for the info about the mov r10, rcx line; I hadn't looked into that yet. My version of windows is 10.0.17134 Build 17134 .
    – Elliot
    Jul 23, 2018 at 16:41
  • 2
    @PeterCordes I'm not saying I recommend using syscall numbers directly (as they do change), but the syscall numbers are unofficially documented. Windows Version 10.0.17134 is Windows(1803) and the syscall for NtCreateFile is 0x55. All 5 released builds of Win 10 use 0x55 thus far. (Pre Win10 have used system call numbers other than 0x55) Jul 24, 2018 at 14:42
  • 1
    The mov r10,rcx is because the syscall interface passes the first parameter via r10 instead of RCX. A regular 64-bit function call uses RCX, RDX, R8, and R9. Syscall uses R10, RDX, R8, and R9. The reason for this is that the syscall instruction instruction overwrites RCX (it also overwrites R11).Microsoft chose to use R10 for the first parameter of the system call instead thus why you will see mov r10, rcx Jul 24, 2018 at 15:45
  • 1
    The reason for the extra padding (ie push 0x0DF0AD8B) is to maintain stack alignment for performance reasons. You should add 8 bytes (a quadword) of padding IF there are an equivalent of an even number of pushes done before the syscall (otherwise you don't need the padding). This is because the stack is misaligned by 8 at the point start is executed because the return address was on the stack. Jul 24, 2018 at 15:48
  • 1
    As to why your code is failing, it is because you didn't clean up the stack after the syscall. You pushed the equivalent of 13 quadwords to set up the syscall you need to adjust the stack after the syscall to restore the stack pointer to its previous state before you do the ret. 13*8=104 bytes put on the stack prior to syscall. After the syscall you can simply do add rsp, 104 to clean up the stack. Jul 24, 2018 at 15:54

Windows system calls are performed by calling into system DLLs such as kernel32.dll or gdi32.dll, which is done with ordinary subroutine calls. The mechanisms for trapping into the OS privileged layer is undocumented, but that is okay because DLLs like kernel32.dll do this for you.

And by system calls, I'm referring to documented Windows API entry points like CreateProcess() or GetWindowText(). Device drivers will generally use a different API from the Windows DDK.

  • 1. How am I gonna use these in Assembly language programming? 2. Windows API and system calls are not the same thing. WINDOWS API use system calls. The similar analogy on linux domain would be POSIX API (WINDOWS API) use system calls provided by linux kernel (windows kernel). So, my concern is about the true system calls.
    – claws
    Mar 22, 2010 at 3:44
  • 2
    I understand that there's a difference between API calls and traps into the OS privileged layer (what you call "true" system calls). These "true" system calls are an implementation detail of Windows system DLLs. You might be able to figure out how they work by disassembling the DLLs and looking at the assembly. Or you could just write your assembly code to call into the DLLs as appropriate... it's possible.
    – Will
    Mar 22, 2010 at 3:56

OFFICIAL Calling convention in Windows: http://msdn.microsoft.com/en-us/library/7kcdt6fy.aspx

(hope this link survives in the future; if it doesn't, just search for "x64 Software Conventions" on MSDN).

The function calling convention differs in Linux & Windows x86_64. In both ABIs, parameters are preferably passed via registers, but the registers used differ. More on the Linux ABI can be found at http://www.x86-64.org/documentation/abi.pdf

  • 5
    This doesn't answer the question, which was about the convention for calling into kernel mode. This is for the user mode function calling convention, which is quite different. And fully documented.
    – Stewart
    May 11, 2013 at 17:42

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.