Passing non-PODs to variable argument functions such as printf is undefined behaviour (1, 2), but I don't understand why the C++ standard was set this way. Is there anything inherent in variable arg functions that prevents them from accepting classes as arguments?

The variable-arg callee indeed knows nothing about their type - but nor does it know anything about built-in types or plain PODs it accepts.

Also, these are necessarily cdecl functions, so the caller can be responsible e.g. for copying them upon passing and destroying them on return.

Any insight would be appreciated.

EDIT: I still see no reason why the suggested variadic semantics won't work, but zneak's answer demonstrates well what it would take to adjust compilers to it - so I accepted it. Ultimately, it might be some historical glitch.

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    Now, we have variadic template, so why bother with old ellipsis C-argument ? – Jarod42 Aug 24 '16 at 19:18
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    @cpplearner: True. The standard has no concept of cdecl functions - but in practise for a varargs function, the caller has to be responsible for cleanup, because the callee doesn't know how many args were passed: printf("%s", "a", "b"); is entirely legal. – Martin Bonner Aug 24 '16 at 19:18
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    My guess: In the old old days of C, the compiler understood only three types for function arguments - int, double, and pointer. It was able to convert any arguments used in a function call to one of the above types. It couldn't do that, you were SOL. Hence, structs were completely out of the reckoning as a type that could be used in variable argument function calls. – R Sahu Aug 24 '16 at 19:28
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    This is only UB in C++03 and earlier. It's conditionally-supported in C++11. – T.C. Aug 24 '16 at 19:32
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    @TobySpeight here's a meatier discussion about this exactly: stackoverflow.com/questions/2512746/… – Ofek Shilon Aug 24 '16 at 19:37

The calling convention does specify who does the low-level stack dance, but it doesn't say who's responsible for "high-level" C++ bookkeeping. At least on Windows, a function that accepts an object by value is responsible for calling its destructor, even though it is not responsible for the storage space. For instance, if you build this:

#include <stdio.h>

struct Foo {
    Foo() { puts("created"); }
    Foo(const Foo&) { puts("copied"); }
    ~Foo() { puts("destroyed"); }

void __cdecl x(Foo f) { }

int main() {
    Foo f;
    return 0;

you get:

    mov     qword ptr [rsp+8],rcx
    sub     rsp,28h
    mov     rcx,qword ptr [rsp+30h]
    call    module!Foo::~Foo (00000001`400027e0)
    add     rsp,28h

    sub     rsp,48h
    mov     qword ptr [rsp+38h],0FFFFFFFFFFFFFFFEh
    lea     rcx,[rsp+20h]
    call    module!Foo::Foo (00000001`400027b0) # default ctor
    lea     rax,[rsp+21h]
    mov     qword ptr [rsp+28h],rax
    lea     rdx,[rsp+20h]
    mov     rcx,qword ptr [rsp+28h]
    call    module!Foo::Foo (00000001`40002780) # copy ctor
    mov     qword ptr [rsp+30h],rax
    mov     rcx,qword ptr [rsp+30h]
    call    module!x (00000001`40002810)
    mov     dword ptr [rsp+24h],0
    lea     rcx,[rsp+20h]
    call    module!Foo::~Foo (00000001`400027e0)
    mov     eax,dword ptr [rsp+24h]
    add     rsp,48h

Notice how main constructs two Foo objects but destroys only one; x takes care of the other one. That obviously wouldn't work if the object was passed as a vararg.

EDIT: Another problem with passing objects to functions with variadic parameters is that in its current form, regardless of the calling convention, the "right thing" requires two copies, whereas normal parameter passing requires just one. Unless C++ extended C variadic functions by making it possible to pass and/or accept references to objects (which is extremely unlikely to ever happen, given that C++ solves the same problem in a type-safe way using variadic templates), the caller needs to make one copy of the object, and va_arg only allows the callee to get a copy of that copy.

Microsoft's CL tries to get away with one bitwise copy and one full copy construction of that bitwise copy at the va_arg site, but it can have nasty consequences. Consider this example:

struct foo {
    char* ptr;

    foo(const char* ptr) { this->ptr = _strdup(ptr); }
    foo(const foo& that) { ptr = _strdup(that.ptr); }
    ~foo() { free(ptr); }

    void setPtr(const char* ptr) {
        this->ptr = _strdup(ptr);

void variadic(foo& a, ...)

    va_list list;
    va_start(list, a);
    foo b = va_arg(list, foo);

    printf("%s %s\n", a.ptr, b.ptr);

int main() {
    foo f = "foo";
    variadic(f, f);

On my machine, this prints "bar bar", even though it would print "foo bar" if I had a non-variadic function whose second parameter accepted another foo by copy. This is because a bitwise copy of f happens in main at the call site of variadic, but the copy constructor is only invoked when va_arg is called. Between the two, a.setPtr invalidates the original f.ptr value, which is however still present in the bitwise copy, and by pure coincidence _strdup returns that same pointer (albeit with a new string inside). Another outcome of the same code could be a crash in _strdup.

Note that this design works great for POD types; it only falls apart when constructors and destructors need side effects.

The original point that calling conventions and parameter passing mechanisms don't necessarily support non-trivial construction and destruction of objects still stands: this is exactly what happens here.

EDIT: answer originally said that the construction and destruction behavior was specific to cdecl; it is not. (Thanks Cody!)

  • Thanks for your answer. If this is the case, how come std::string str("Hello");printf("%s", str) doesn't leak memory? I just tested and it doesn't - there isn't even a std::string copy ctor called. – Ofek Shilon Aug 25 '16 at 10:12
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    The terminology in this answer is somewhat misleading. Although there is a __cdecl calling convention on the Windows platform, it exists only for 32-bit code. Your object code example is obviously 64-bit code, since it uses the 64-bit registers. There is no __cdecl for 64-bit platforms on Windows. In fact, there are only two calling conventions for AMD64: (a) the standard Microsoft 64-bit calling convention, which doesn't have a name, and (b) __vectorcall. – Cody Gray Aug 25 '16 at 10:13
  • It just so happens that if you pass an object with a destructor, the 32-bit __cdecl, like the 32-bit __stdcall and __fastcall, all transfer a copy of that entire object on the stack. This changes the object's ownership, making the recipient responsible for managing its lifetime. The Microsoft 64-bit calling convention, like __vectorcall, is the same in spirit, but different in implementation because it passes a copy of the destructor-containing object in a register, only falling back to the stack if all registers are used. – Cody Gray Aug 25 '16 at 10:18
  • @OfekShilon most STLs implement small string optimizations. In MSVC's case (at least for 64 bits), strings under 16 characters don't need a dynamic allocation. I only have a Windows machine at work so I can't check the constructor/destructor situation. – zneak Aug 25 '16 at 14:28
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    @OfekShilon, this is the only right thing to do for PODs, not an optimization. The extension of this mechanism for non-POD types requires two full copies of each object passed as a variadic argument. You might not be able to fix the double copy issue without changing how va_lists work in C. Ultimately, there might be no better answer than "it broke a bunch of assumptions and nobody cares enough". – zneak Aug 26 '16 at 16:14

I'm recording this, because it's too big to be a comment, and it was reasonably time consuming to hunt this down, so no one else wastes time looking down this route.

The text was first changed to something similar to the current wording in the draft standard in N2134 released 2006-11-03.

With some effort, I was able to trace back the wording to DR506.

Paper J16/04-0167=WG21 N1727 suggests that passing a non-POD object to ellipsis be ill-formed. In discussions at the Lillehammer meeting, however, the CWG felt that the newly-approved category of conditionally-supported behavior would be more appropriate.

The paper referenced (N1727), says very little on the subject:

The existing wording (5.2.2¶7) makes it undefined behavior to pass a non-POD object to an ellipsis in a function call:


Once again, the CWG saw no reason not to require implementations to issue a diagnostic in such cases.

However, this doesn't tell me very much about why it was the way it was to begin with, which is what you want to know. Turning the clock back further to when that language was first written is not possible for me, because the oldest freely available draft standard is from 2005 and already has the wording you're wondering about, all standards prior to this either require authentication or are simply contentless.

  • In C++98 and C++03 there is "If the argument has a non-POD class type (clause 9), the behavior is undefined.". I guess this would have been for C compatibility: C code that passed structs via varargs should continue to work. – M.M Aug 25 '16 at 21:17

I guess the problem is/was the breach of type safety. Generally, passing a derived class object where a base class object is expected should be safe. If the base class object is taken by value, then the derived class object will be simply sliced. If it is taken by pointer/reference - the pointer/reference to the derived class object is adjusted properly during compilation. This doesn't work with variable-argument functions, where interpretation of the input types is performed by the code rather than by the compiler.


struct A { char c; };
struct B { int i; };
struct D : A, B { double d; };

// This is similar to printf, but also handles the
// format specifier %b assuming an object of type B
void non_pod_printf(const char* fmt, ...);

D d1, d2;

// I bet that the code inside non_pod_printf will fail to correctly
// handle the d1 and d2 arguments even though the language rules
// ensure that D is a B
non_pod_printf("%d %b %b", 123, d1, d2);


As a now deleted comment pointed out, A, B and D in the example above are actually POD types. However, the problem that I am bringing to your attention has to do with inheritance, which, although allows POD types, but in the majority of cases involves non-POD types.

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