Yes, the answer is compiler-dependent.
A quick experiment with my compiler (
g++ 4.4.3) reveals that its runtime library first tries to
malloc memory for the exception and, failing that, attempts to allocate space within a process-wide "emergency buffer" that lives on the data segment. If that doesn't work out, it calls
It would appear that the main purpose of the emergency buffer is to be able to throw
std::bad_alloc after the process has run out of heap space (in which case the
malloc call would fail).
The relevant function is
extern "C" void *
__cxxabiv1::__cxa_allocate_exception(std::size_t thrown_size) throw()
thrown_size += sizeof (__cxa_refcounted_exception);
ret = malloc (thrown_size);
if (! ret)
bitmask_type used = emergency_used;
unsigned int which = 0;
if (thrown_size > EMERGENCY_OBJ_SIZE)
while (used & 1)
used >>= 1;
if (++which >= EMERGENCY_OBJ_COUNT)
emergency_used |= (bitmask_type)1 << which;
ret = &emergency_buffer[which];
// We have an uncaught exception as soon as we allocate memory. This
// yields uncaught_exception() true during the copy-constructor that
// initializes the exception object. See Issue 475.
__cxa_eh_globals *globals = __cxa_get_globals ();
globals->uncaughtExceptions += 1;
memset (ret, 0, sizeof (__cxa_refcounted_exception));
return (void *)((char *)ret + sizeof (__cxa_refcounted_exception));
I don't know how typical this scheme is.