Array placement-new requires unspecified overhead in the buffer?
Don't use operator new[](std::size_t, void* p) unless you know a-priori the answer to this question. The answer is an implementation detail and can change with compiler/platform. Though it is typically stable for any given platform. E.g. this is something specified by the Itanium ABI.
If you don't know the answer to this question, write your own placement array new that can check this at run time:
inline
void*
operator new[](std::size_t n, void* p, std::size_t limit)
{
if (n <= limit)
std::cout << "life is good\n";
else
throw std::bad_alloc();
return p;
}
int main()
{
alignas(std::string) char buffer[100];
std::string* p = new(buffer, sizeof(buffer)) std::string[3];
}
By varying the array size and inspecting n in the example above, you can infer y for your platform. For my platform y is 1 word. The sizeof(word) varies depending on whether I'm compiling for a 32 bit or 64 bit architecture.
Update: After some discussion, I understand that my answer no longer applies to the question. I'll leave it here, but a real answer is definitely still called for.
I'll be happy to support this question with some bounty if a good answer isn't found soon.
I'll restate the question here as far as I understand it, hoping that a shorter version might help others understand what's being asked. The question is:
Is the following construction always correct? Is arr == addr at the end?
void * addr = std::malloc(N * sizeof(T));
T * arr = ::new (addr) T[N]; // #1
We know from the standard that #1 causes the call ::operator new[](???, addr), where ??? is an unspecified number no smaller than N * sizeof(T), and we also know that that call only returns addr and has no other effects. We also know that arr is offset from addr correspondingly. What we do not know is whether the memory pointed to by addr is sufficiently large, or how we would know how much memory to allocate.
You seem to confuse a few things:
Your example calls
operator new[](), notoperator new()The allocation functions do not construct anything. They allocate.
What happens is that the expression T * p = new T[10]; causes:
a call to
operator new[]()with size argument10 * sizeof(T) + x,ten calls to the default constructor of
T, effectively::new (p + i) T().
The only peculiarity is that the array-new expression asks for more memory than what is used by the array data itself. You don't see any of this and cannot make use of this information in any way other than by silent acceptance.
If you are curious how much memory was actually allocated, you can simply replace the array allocation functions operator new[] and operator delete[] and make it print out the actual size.
Update: As a random piece of information, you should note that the global placement-new functions are required to be no-ops. That is, when you construct an object or array in-place like so:
T * p = ::new (buf1) T;
T * arr = ::new (buf10) T[10];
Then the corresponding calls to ::operator new(std::size_t, void*) and ::operator new[](std::size_t, void*) do nothing but return their second argument. However, you do not know what buf10 is supposed to point to: It needs to point to 10 * sizeof(T) + y bytes of memory, but you cannot know y.
As mentioned by Kerrek SB in comments, this defect was first reported in 2004, and it was resolved in 2012 as:
The CWG agreed that EWG is the appropriate venue for dealing with this issue.
Then the defect was reported to EWG in 2013, but closed as NAD (presumably means "Not A Defect") with the comment:
The problem is in trying to use array new to put an array into pre-existing storage. We don't need to use array new for that; just construct them.
which presumably means that the suggested workaround is to use a loop with a call to non-array placement new once for each object being constructed.
A corollary not mentioned elsewhere on the thread is that this code causes undefined behaviour for all T:
T *ptr = new T[N];
::operator delete[](ptr);
Even if we comply with the lifetime rules (i.e. T either has trivial destruction, or the program does not depend on the destructor's side-effects), the problem is that ptr has been adjusted for this unspecified cookie, so it is the wrong value to pass to operator delete[].