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I found this:

Because the stack is cleaned by the called function, the __stdcall calling convention creates smaller executables than __cdecl, in which the code for stack cleanup must be generated for each function call.

Suppose I got 2 functions:

void __cdecl func1(int x)
    //do some stuff using x

void __stdcall func2(int x, int y)
    //do some stuff using x, y

and here in the main():

int main()
    func2(5, 6);

IMO, it is main()'s responsibility to clean up the stack of the call to func1(5), and func2 will clean up the stack of the call to func2(5,6), right?

Four questions:

1.For the call to func1 in main(), it's main's responsibility to clean up the stack, so will compiler insert some code (code to clean up the stack) before and after the call to func? Like this:

int main()
    before_call_to_cdecl_func(); //compiler generated code for stack-clean-up of cdecl-func-call
    after_call_to_cdecl_func(); //compiler generated code for stack-clean-up of cdecl-func-call

    func2(5, 6);

2.For the call to func2 in main(), it's func2's own job to clean up the stack, so I presume, no code will be inserted in main() before or after the call to func2, right?

3.Because func2 is __stdcall, so I presume, compiler will automatically insert code (to clean up the stack) like this:

void __stdcall func1(int x, int y)
    before_call_to_stdcall_func(); //compiler generated code for stack-clean-up of stdcall-func-call
    //do some stuff using x, y
    after_call_to_cdecl_func(); //compiler generated code for stack-clean-up of stdcall-func-call

I presume right?

4.Finally, back to the quoted words, why __stdcall results in smaller executable than __cdecl? And there is no such a thing as __stdcall in linux, right? Does it means linux elf will be always larger than exe in win?

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stdcall cannot be used for variadic functions which is why you don't tend to see it on Linux. It's only present on Windows for win32 API calls. Native Windows compilers typically use some form of fastcall, or cdecl. –  David Heffernan Feb 7 '12 at 8:29
So, linux supports cdecl only? –  Alcott Feb 7 '12 at 8:34
@David: actually they tend to use __stdcall or __cdecl, as the entirety of the WINAPI is __stdcall or __cdecl, I never once encountered a compiler that defaults to __fastcall nor and API that makes extensive use of it –  Necrolis Feb 7 '12 at 8:37
@Necrolis My day to day compiler, Delphi, uses fastcall by default. MSVC defaults to fastcall for C++ member functions. –  David Heffernan Feb 7 '12 at 9:03
@Alcott It's not even that simple. Consider x64. On both Windows and Linux (don't know about Mac), there only is one x64 calling convention. –  David Heffernan Feb 7 '12 at 9:04

4 Answers 4

  1. It'll only insert code after the call, which is to reset the stack pointer, so long as there where call arguments.*
  2. __stdcall generates no cleanup code at the call site, however, it should be noted that compilers can accrue stack cleanup from multiple __cdecl calls into one cleanup, or it can delay the cleanup to prevent pipeline stalls.
  3. Ignoring the inverted order in this example, no, it'll only insert code to cleanup the __cdecl function, setting up of function arguments is something different (different compilers generate/prefer different methods).
  4. __stdcall was more a windows thing, see this. the size of the binary depends on the number of calls to the __cdecl funcs, more calls means more clean up code, where as __stdcall has only 1 singular instance of cleanup code. however, you shouldn't see that much size increase, as at most you have a few bytes per call.

*Its important to distinguish between cleanup and setting up call parameters.

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Sorry about the typo –  Alcott Feb 7 '12 at 8:50
If no code is inserted to clean up the __stdcall function, then how will the stack get cleaned up? Do you mean, the frame stack of the __stdcall function will just vanishes when the function finishes, which means the stack gets cleaned up? –  Alcott Feb 7 '12 at 8:55
@Alcott: no worries, I have many typo's through my SO answers :( –  Necrolis Feb 7 '12 at 8:55
@Alcott: I change the wording a little, __stdcall functions embed their cleanup code in the function itself (with stack cleanup done by the return, see the RETN imm8/imm16 assembly instruction), __cdecl functions require the compiler to emit the cleanup at ever call site that has arguments (this allows var arg functions). –  Necrolis Feb 7 '12 at 8:58
Got it. So, setting up call parameters in __cdecl and __stdcall differs? –  Alcott Feb 7 '12 at 9:00

Historically, the first C++ compilers used the equivalent of __stdcall. From a quality of implementation point of view, I'd expect the C compiler to use the __cdecl convensions, and the C++ compiler the __stdcall (which were known as the Pascal convensions back then). This is one thing that the early Zortech compiles got right.

Of course, vararg functions must still use __cdecl conventions. The callee can't clean up the stack if it doesn't know how much to clean up.

(Note that the C standard was carefully designed to allow the __stdcall conventions in C as well. I only know of one compiler which took advantage of this, however; the amount of existing code at the time which called vararg functions without a prototype in view was enormous, and while the standard declared it broken, compiler implementors didn't want to break their clients' code.)

In a lot of milieu, there seems to be a very strong tendency to insist that the C and the C++ conventions be the same, that one can take the address of an extern "C++" function, and pass it to a function written in C which calls it. IIRC, for example, g++ doesn't treat

extern "C" void f();


void f();

as having two different types (although the standard requires it), and allows passing the address of a static member function to pthread_create, for example. The result is that such compilers use the exact same conventions everywhere, and on Intel, they are the equivalent of __cdecl.

Many compilers have extensions to support other convensions. (Why they don't use the standard extern "xxx", I don't know.) The syntax for these extensions is very varied, however. Microsoft puts the attribute directly before the function name:

void __stdcall func( int, int );

, g++ puts it in a special attribute clause after the function declaration:

void func( int, int ) __attribute__((stdcall));

The C++11 has added a standard way of specifying attributes:

void [[stdcall]] func( int, int );

It doesn't specify stdcall as an attribute, but it does specify that additional attributes (other than those defined in the standard) may be specified, and are implementation dependent. I expect that both g++ and VC++ accept this syntax in their most recent versions, at least if C++11 is activated. The exact name of the attribute (__stdcall, stdcall, etc.) may vary, however, so you probably want to wrap this in a macro.

Finally: in a modern compiler with optimization turned on, the difference in the calling conventions is probably negligible. Attributes like const (not to be confused with the C++ keyword const), regparm or noreturn will probably have a larger impact, both in terms of executable size and performance.

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If I simply define a function like this: void foo();, then is it __cdecl? –  Alcott Feb 7 '12 at 9:04
C++ could not use __cdecl, because __cdecl does not have knowledge of the object pointer <this>. They had to use a different calling convention. AFAIK, Microsoft calls it __thiscall... –  Malkocoglu Feb 7 '12 at 9:13
@Malkocoglu: C++ can easily use __cdecl, the this would just be passed on the stack, just like its done for stdcall based COM interfaces –  Necrolis Feb 7 '12 at 9:21
@Necrolis: Yes, for class-member vararg functions, they use the scheme you described. Yet, a C program can not call this special kind of __cdecl, because it does not know about <this> object pointer ! From a binary point of view, they are different... –  Malkocoglu Feb 7 '12 at 9:26
@Malkocoglu: you'd just define a dummy param to place hold the this pointer (again see COM interfaces, especially Direct X). but C couldn't call class member functions with invoking UB or the use of special interfaces like COM anyways... –  Necrolis Feb 7 '12 at 9:30

This calling convention crowd is history by the new 64-bit ABI.


There is also the ABI side of things for different architectures. (like ARM) Not everything executes the same for all architectures. So do not bother thinking about this calling convention thing !


EXE size improvement is insignificant (maybe nonexistent), do not bother...

__cdecl is much more flexible than __stdcall. Variable number of arguments flexibility, the insignificance of cleanup code (instruction), __cdecl function can be called with wrong number of arguments and this does not necessarily cause a serious problem ! But the same situation with __stdcall always goes wrong !

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The 64-bit API is only used when compiling in 64 bit mode (if at all---it wouldn't surprise me if there were still additional options). And if you've written correct C++ (and the compiler will complain if you don't), or even correct C (but the compiler can't know in the case of C, and a lot of legacy code is not "correct" according to the C standard), using __stdcall is no problem (since the conventions in __stdcall for calling a vararg function are the same as in __cdecl). –  James Kanze Feb 7 '12 at 9:51
@james Kanze: The two 64 bit API's (Microsoft and EveryoneElse) do not have options or variants similar to __stdcall or cdecl. –  MSalters Feb 7 '12 at 11:00
@MSalters Such options or variants aren't generally part of the official API. A compiler could still offer them. (For that matter, a compiler could use some sort of global code generation, and use different calling conventions for each function, depending what the function did with the arguments.) –  James Kanze Feb 7 '12 at 11:46
@JamesKanze: That's of course quite possible when a compiler sees both caller and callee. But in that case, optimization can do truly weird things with calling conventions anyway (often as a side-effect, e.g. when reordering instructions that came from prologs or epilogs). In the "Everyone Else" case, there might be interoperability issues if the caller and callee are compiled with different compilers and non-standard options - a linker in general cannot patch that up. –  MSalters Feb 7 '12 at 12:14
@MSalters Yes. Once the compiler can see both caller and callee, anything goes, and we can't really talk about an ABI. Extending the compiler to support additional calling conventions is an intermediate solution: you're guaranteeing that the callee and all of the callers will be compiled with a compiler which supports the additional calling conventions. (I can imagine calling conventions which would be optimal for certain types of functions only. You write that type of function, add the attribute declaration, and get faster code.) –  James Kanze Feb 7 '12 at 12:22

Others have answered the other parts of your question, so I'll just add my answer about the size:

4.Finally, back to the quoted words, why __stdcall results in smaller executable than __cdecl?

That appears to not be true. I tested it by compiling libudis with and without the stdcall calling convention. First without:

$ clang -target i386-pc-win32 -DHAVE_CONFIG_H -Os -I.. -I/usr/include -fPIC -c *.c && strip *.o
$ du -cb *.o
6524    decode.o
95932   itab.o
1434    syn-att.o
1706    syn-intel.o
2288    syn.o
1245    udis86.o
109129  totalt

And with. It is the -mrtd switch that enables stdcall:

$ clang -target i386-pc-win32 -DHAVE_CONFIG_H -Os -I.. -I/usr/include -fPIC -mrtd -c *.c && strip *.o
7084    decode.o
95932   itab.o
1502    syn-att.o
1778    syn-intel.o
2296    syn.o
1305    udis86.o
109897  totalt

As you can see, cdecl beats stdcall with a few hundred bytes. It could be my testing methodology that is flawed, or clang's stdcall code generator is weak. But I think that with modern compilers the extra flexibility afforded by caller cleanup means that they will always generate better code with cdecl rather than stdcall.

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