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A different question inspired the following thought:

Does std::vector<T> have to move all the elements when it increases its capacity?

As far as I understand, the standard behaviour is for the underlying allocator to request an entire chunk of the new size, then move all the old elements over, then destroy the old elements and then deallocate the old memory.

This behaviour appears to be the only possible correct solution given the standard allocator interface. But I was wondering, would it make sense to amend the allocator to offer a reallocate(std::size_t) function which would return a pair<pointer, bool> and could map to the underlying realloc()? The advantage of this would be that in the event that the OS can actually just extend the allocated memory, then no moving would have to happen at all. The boolean would indicate whether the memory has moved.

(std::realloc() is maybe not the best choice, because we don't need do copy data if we cannot extend. So in fact we'd rather want something like extend_or_malloc_new(). Edit: Perhaps a is_pod-trait-based specialization would allow us to use the actual realloc, including its bitwise copy. Just not in general.)

It seems like a missed opportunity. Worst case, you could always implement reallocate(size_t n) as return make_pair(allocate(n), true);, so there wouldn't be any penalty.

Is there any problem that makes this feature inappropriate or undesirable for C++?

Perhaps the only container that could take advantage of this is std::vector, but then again that's a fairly useful container.

Update: A little example to clarify. Current resize():

pointer p = alloc.allocate(new_size);

for (size_t i = 0; i != old_size; ++i)
  alloc.construct(p + i, T(std::move(buf[i])))
for (size_t i = old_size; i < new_size; ++i)
  alloc.construct(p + i, T());

buf = p;

New implementation:

pair<pointer, bool> pp = alloc.reallocate(buf, new_size);

if (pp.second) { /* as before */ }
else           { /* only construct new elements */ }
share|improve this question
I don't think it needs a pair, you can simply compare to the pointer that was passed in. As long as reallocate understands proper move semantics I can't think of a problem. –  Mooing Duck Nov 3 '11 at 23:35
@MooingDuck: On your first comment: The only possiblity is if the grow function of the allocator were to fail in the event of not being able to grow, and leave the memory as it was before (no bitwise copy). By the time you get to compare the pointers of realloc, the damage is done. –  David Rodríguez - dribeas Nov 3 '11 at 23:45
@David: grow is arguably a much better name for the feature! –  Kerrek SB Nov 3 '11 at 23:46
@Praetorian: There are different issues with the bitwise copies... consider for example, that there might be internal pointers, for example I have used an implementation of the NullObject pattern where the object held a null-object and a pointer to the current object that could either refer to a dynamically allocated real-object or to the null-object member. In the cases where the object is null, the pointer references another member of the same object. In that case, a bitwise copy will leave dangling pointers. –  David Rodríguez - dribeas Nov 3 '11 at 23:49
std::deque is one of the most unfortunate containers. It is really good at what it does. And you almost never need what it does. A geometrically growing circular buffer would have been a much better candidate for a std::container than std::deque. The circular buffer has much better performance and far less complexity. But it doesn't guarantee the stability of references like std::deque and std::list do. But in my experience, the circular buffer solves most push-pop queue problems better than std::deque and when it doesn't, std::list is the correct alternative. –  Howard Hinnant Nov 4 '11 at 2:57

3 Answers 3

up vote 26 down vote accepted

When std::vector<T> runs out of capacity it has to allocate a new block. You have correctly covered the reasons.

IMO it would make sense to augment the allocator interface. Two of us tried to for C++11 and we were unable to gain support for it: [1] [2]

I became convinced that in order to make this work, an additional C-level API would be needed. I failed in gaining support for that as well: [3]

share|improve this answer
Sweet, thanks! I'm sorry to hear you failed to garner further support -- it seems to be to be totally trivial to add a C interface function: Just take realloc() and remove the part that copies the memory. It wouldn't even have to become part of the C standard; it could just be something that the C++ library implements... –  Kerrek SB Nov 3 '11 at 23:55
Custom C++ allocators would benefit from a C realloc-but-don't-move function. That was the principle motivation for going to the C committee with this. –  Howard Hinnant Nov 3 '11 at 23:59
Well, there's always the possibility that other, user-defined classes could use an allocator that has such a "may grow" interface. Shame that it got rejected. Is it OK to write an allocator that does more than the prescribed allocator interface, though? –  Kerrek SB Nov 4 '11 at 0:03
Yes. But std::containers won't be smart enough to use your extended interface. But maybe boost::intrusive containers would. The author of that library is the same person that wrote N2045. –  Howard Hinnant Nov 4 '11 at 0:05
I'm facing the same problem at the moment. Is there a known workaround or do I have to implement my own container? –  Olumide Dec 30 '14 at 16:51

In most cases, realloc will not extend the memory, but rather allocate a separate block and move the contents. That was considered when defining C++ in the first place, and it was decided that the current interface is simpler and not less efficient in the common case.

In real life, there are actually few cases where reallocis able to grow. In any implementation where malloc has different pool sizes, chances are that the new size (remember that vector sizes must grow geometrically) will fall in a different pool. Even in the case of large chunks that are not allocated from any memory pool, it will only be able to grow if the virtual addresses of the larger size are free.

Note that while realloc can sometimes grow the memory without moving, but by the time realloc completes it might have already moved (bitwise move) the memory, and that binary move will cause undefined behavior for all non-POD types. I don't know of any allocator implementation (POSIX, *NIX, Windows) where you can ask the system whether it will be able to grow, but that would fail if it requires moving.

share|improve this answer
I think he meant a new reallocation function, not compatible with malloc.h realloc, that doesn't move contents, nor free the old block, when resizing in place isn't possible. –  Ben Voigt Nov 3 '11 at 23:42
+1 even though I have absolutely no idea what you just said. –  FailedDev Nov 3 '11 at 23:42
Also, VirtualAlloc and mmap allow you to request the address immediately following your block, so you'll either extend the block or fail. But I too don't know of any heap-based allocators that support the "grow if possible" operation. –  Ben Voigt Nov 3 '11 at 23:44
@Ben: Yes, indeed. I'd need 1) an interface addition for the standard library allocator, and 2) an underlying implementation that grows if possible but does a naked malloc if not, without moving. –  Kerrek SB Nov 3 '11 at 23:44
Linux provides mremap, which you can use to extend an existing anonymous memory map (or fail while trying). –  Nemo May 6 '14 at 22:16

Yep, you're right that the standard allocator interface doesn't provide optimizations for memcpy'able types.

It's been possible to determine whether a type can be memcpy'd using boost type traits library (not sure if they provide it out of the box or one would have to build a composite type discriminator based on the boost ones).

Anyway, to take advantage of realloc() one would probably create a new container type that can explicitly take advantage of this optimization. With current standard allocator interface it doesn't seem to be possible.

share|improve this answer
No, no, I don't care about memcpyability. I'm fully prepared to invoke my allocator's construction and destruction sequence. I just want to give the allocator the chance to be lazy! –  Kerrek SB Nov 3 '11 at 23:43

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