For curiosity, I'm looking to write minimal replacements for some of the functions in the standard C library. So far, I have finished printf(), strlen(), strcpy(), memcpy(), memset(), etc... but when I try to use the printf function, I don't know how to implement stdarg.h! What is a way that I could do that?

Does it use macros or actual functions?

I am using gcc OR clang on 32-bit x86, if it helps to make this any easier to answer.

  • 3
    Why not just look into the header provided by your prefered compiler? Note that this is implementation-specific. Any comprehensive answer would be too broad. Please be more specific. Commented Aug 29, 2015 at 23:49
  • @Olaf I've been looking in the source code of both gcc, clang and glibc for 2 hours, and I couldn't find one that even remotely looks like an implementation. Commented Aug 29, 2015 at 23:51
  • 1
    I think reimplementing functions expected only from a hosted environment, as you’ve been doing so far, is a good exercise; however, implementing functionality from headers that are supposed to be available even in a freestanding environment, namely float.h, iso646.h, limits.h, stdarg.h, stdbool.h, stddef.h, and stdint.h, is not such a great exercise, as implementations of those are more likely to rely on compiler- or architecture-specific behavior and may not be portable.
    – icktoofay
    Commented Aug 29, 2015 at 23:55
  • 1
    In particular, stdarg.h is probably one of the harder things to decide to reimplement, rivaled only by setjmp.h. Both of these need to know low-level things about both the compiler, the architecture, and the rest of the implementation, and depending on the architecture and other factors, may need to be implemented at least partially in assembly rather than pure C.
    – icktoofay
    Commented Aug 29, 2015 at 23:58
  • 1
    I like he is learning in this manner. Next step could be to improve those standard functions as many old c-standard functions are rather badly designed - compared to todays standards and best practices. If you really want to use the results of your works, I would even recommend to start with this improvement step right away and skip the re-implementing.
    – BitTickler
    Commented Aug 30, 2015 at 0:00

4 Answers 4


On 32-bit x86 with the cdecl calling convention, parameters are passed on the stack:

^ higher addresses (lower on the stack)
| caller local variables
| ...
| argument 3
| argument 2
| argument 1
| return address
| saved EBP (usually)
| callee local variables
v lower addresses (higher on the stack)

You can implement va_list as a pointer. va_start can take the address of the argument passed to it and add the size of that argument to move to the next argument. va_arg can access the pointer and bump it to the next argument. va_copy can just copy the pointer value. va_end doesn’t need to do anything.

If, on the other hand, you’re not using cdecl (maybe you’re using fastcall), you’re not 32-bit, you’re not x86, this won’t work; you might need to muck with registers rather than just pointer values. And even still it’s not guaranteed to work, since you’re relying on undefined behavior; as as example of only one potential problem, inlining could ruin everything. And that’s why the header file just typedefs it to a compiler built-in—implementing this in C is hopeless, you need compiler support. And don’t even get me started on implementing setjmp and longjmp

  • Because this is practically impossible to implement "properly" without writing a compiler (and I don't know how), is the best solution just to link with libgcc? Commented Aug 30, 2015 at 0:18
  • @AnonymousShadow: First try linking without including libgcc; since va_* are macros that refer to built-ins, it might not add any external function references, and hence you might not need to link anything extra in at all. That said, if you get undefined symbol errors for symbols that libgcc defines, yeah, I guess you’d need to link that in.
    – icktoofay
    Commented Aug 30, 2015 at 0:21
  • 2
    This answer is wrong; it assumes ancient compiler technology where the address of argument objects will actually be the address they were (or would have been) passed on the stack. There's no reason this need be the case. Even on archs like i386 where the arguments to external functions are passed on the stack, the compiler is completely free to move them to separate local storage and have & yield a pointer to that new storage. It's also free to perform inlining/LTO in which case the arguments might never live on the stack at all. Commented Aug 30, 2015 at 1:16
  • 1
    @R..: I understand, which is why I point out that it is entirely unreliable, even if all the preconditions are met, in the last paragraph.
    – icktoofay
    Commented Aug 30, 2015 at 1:27
  • Fair enough. FYI, despite calling it "wrong", I'm not the one who downvoted your answer. Commented Aug 30, 2015 at 4:51

There is no way to implement stdarg.h macros in C; you need compiler builtins like __builtin_va_arg, etc. which GCC and compatible compilers provide, or the equivalent for your compiler.

Even if you know the argument passing convention for the particular target you're working with (like i386 in icktoofay's answer), there is no way in C to get access to this memory. Simply performing pointer arithmetic on the address passed to va_start is not valid; it results in undefined behavior. But even if C did allow that arithmetic, there's no guarantee that the address of the last named argument actually corresponds to the place it was passed on the stack as part of the calling convention; the compiler could have chosen to move it to a different location in its stack frame (perhaps for the sake of obtaining additional alignment or data locality).

  • That depends on the PCS/ABI of the architecture. The macros can very well care about alignment, as they know the types. Early implementations actually did use macros for this. I had these on the 68000, for example (IIRC, this was gcc 1.something, but not sure). And reordering would mess up calls between different compilation units, at least. Commented Aug 30, 2015 at 12:28
  • @Olaf: It's independent of ABI. Even if you know that args are passed the the stack, you do not know that &argN is the address of the stack slot it was passed on. Within the function body, argN is just a normal automatic-storage object. The compiler is free to position it wherever it wants (as long as it copies the original value from wherever the calling convention put it) and this is purely an internal consideration of how the function was compiled, not ABI. Commented Aug 30, 2015 at 19:32
  • Of course it's true that some historical compilers were so primitive that &argN was always the stack slot it was passed on, or that they intentionally chose to forgo optimizations to facilitate legacy stdarg.h implementations. But in that case, it worked only because of assumptions about the non-ABI-relevant behavior of the compiler, not just by knowing the ABI. Commented Aug 30, 2015 at 19:40
  • Huh? The standard implementations increment the pointer just by the size of the current argument, align it and have the address of the next entry. This is normally part of the PCS and ABI. See the current ARM-standard (AAPCS, this includes the basic C/C++ ABI). And, no, the compiler is not free, unless it can proof the functions is not called from elsewhere. This can only work for static. Commented Aug 30, 2015 at 19:43
  • As stdarg.h is part of the implementation, i.e. the compiler, so it certainly has to know what the compiler does (it has to conform to the ABI ...). Note that this clearly assumes the compiler does not inline such functions, but this can also be specified in the ABI. Commented Aug 30, 2015 at 19:47

There's an implementation in the CALC source code posted to comp.sources.unix in 1992.

This is from a shar archive, so ignore the Xs.

X * Copyright (c) 1992 David I. Bell
X * Permission is granted to use, distribute, or modify this source,
X * provided that this copyright notice remains intact.

X *
X * WARNING: This type of stdarg makes assumptions about the stack
X *             that may not be true on your system.  You may want to
X *            define STDARG (if using ANSI C) or VARARGS.
X */
Xtypedef char *va_list;
X#define va_start(ap,parmn) (void)((ap) = (char*)(&(parmn) + 1))
X#define va_end(ap) (void)((ap) = 0)
X#define va_arg(ap, type) \
X    (((type*)((ap) = ((ap) + sizeof(type))))[-1])

You can see examples of how to implement the va macros here. This header is used in VC++ and there are different implementations for each processor architecture. The macros don't seem to be specific to the Microsoft compiler. In both GCC and Clang the va macros refer to compiler built-in functions.

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