Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

The C++ standard provides the guarantee that the content of a std::vector is stored contiguously. But does it states that the total occupied memory is:

S = C+N*sizeof(T)


  • S is the total size on the stack AND on the heap
  • C is the total size on the stack: C = sizeof(std::vector)
  • N is the capacity of the vector
  • T is the type stored

In other words, do I have the guarantee that there is no overhead per element ? And if I have no such guarantee is there any reason ?

EDIT: to be clear, if I take the example of a std::list, it generally stores 2 extra pointers per element. So my question is: would a such implementation of a std::vector be standard-compliant ?

share|improve this question
@Mehrdad: Can you elaborate? – Peter A. Schneider Apr 22 '14 at 0:35
While reallocating the memory, it normally double its size from the current. So in that case(worst case) scenario vector could hold almost the double size than on current number of elements.(2N*sizeof(T)) – Mantosh Kumar Apr 22 '14 at 0:36
Typical allocation systems have hidden overhead, but usually it scales with the number of allocated blocks, not the size of allocated blocks. Not sure what Mehrdad is getting at. – aschepler Apr 22 '14 at 0:36
Note that N is not std::vector::size but std::vector::capacity. Do your remarks hold Mehrdad ? – Vincent Apr 22 '14 at 0:40
@Vincent: Sure, but that's a bad implementation, wasting your memory for no reason. – Deduplicator Apr 22 '14 at 0:48
up vote 11 down vote accepted

For there to be any such guarantee, the standard would have to pass the requirement on to the interface of the allocator. It doesn't, so there isn't.

In practice though, as a quality of implementation issue, you expect that memory allocators probably have a constant overhead per allocation but no overhead proportional to the size of the allocation. A counter-example to this would be a memory allocator that always uses a power-of-two-sized block regardless of the size requested. This would be pretty wasteful for large allocations, but not forbidden either as a user-defined allocator or even as the system allocator used by ::operator new[]. It would create an overhead proportional to N on average, assuming that the vector capacities don't happen to fit nicely.

Leaving aside the allocator, I don't believe there's anything in the standard to say that the vector can't allocate (for example) an extra byte per element and use it to store some flags for who-knows-what purpose. As others have remarked, the contiguousness requirement means that those extra bytes cannot lie between the vector elements. They would have to be in a separate allocation or all together at one end of the allocation.

There's at least one good reason that the standard doesn't forbid implementations from "wasting" space by using it to store data used for operations not required by the standard -- doing so would rule out many debugging techniques!

share|improve this answer
It depends on how "total memory occupied" is defined. If it's defined by the total size given to allocate then this is an independent requirement. – Mehrdad Apr 22 '14 at 0:43
For efficiency reasons, constant is unlikely: More memory is used to avoid fragmentation. Fibonacci and other low-fragmentation schemes. – Deduplicator Apr 22 '14 at 0:44
@Mehrdad: well, it's not defined as exactly that since it's defined to include some memory on the stack. But sure, if it's defined something like that then there's still no explicit guarantee but it becomes harder to think of a plausible place for the overhead to go. – Steve Jessop Apr 22 '14 at 0:51
I don't think "it's defined to include some memory on the stack" is true. Consider new vector<T>. – Lightness Races in Orbit Apr 22 '14 at 0:55
@LightnessRacesinOrbit: it is defined exactly that way. Perhaps mistakenly so or perhaps the questioner realises that he is talking only about automatic variables. "C is the total size on the stack: C = sizeof(std::vector)". But even allowing for new vector<T>, the space in question still isn't part of "the total size given to allocate", so with suitable adjustment my point to Mehrdad stands I think. I guess you could go std::allocator<std::vector<T>>::allocate followed by emplace just to get it all under one allocator. – Steve Jessop Apr 22 '14 at 0:56

Do I have the guarantee that there is no overhead per element?

Does the standard prohibit it? No.
But would you ever expect to see this in practice? No.

The rule of contiguous data storage and the complexity requirements of vector growth mean that the only possible way for a non-constant-sized data block to be part of the vector would be if it were emplaced directly before the dynamically-allocated element data, or somewhere else entirely. There is no guarantee that this doesn't happen, but, quite simply, no implementation does it because it would be entirely ridiculous and serve no purpose whatsoever.

Does it states that the total occupied memory is:

S = C+N*sizeof(T)

There may be other data members of the vector itself (what you've inaccurately deemed to be "on the stack"), increasing the object's size in constant terms.

share|improve this answer
Just for information, in what part of memory are stored the elements which make the result of sizeof(T) (for example often 3 pointers for a std::vector): static, stack or heap ? – Vincent Apr 22 '14 at 0:50
@Deduplicator: That passage refers to direct members of the vector, whose combined size must be constant, as is the case with any type. Adding random+42 bytes would require dynamic allocation, which is covered by the rest of the answer. – Lightness Races in Orbit Apr 22 '14 at 0:53

The standard gives no guarantee, afaics. But the requirement that the elements be stored contiguously makes it likely that there is no per element overhead. The whole data must be in a memory area which was allocated in one piece. @aschepler remarked correctly though that typical free store implementations have a (constant) overhead per allocation unit, typically a size variable or an end pointer.

Additionally there may be some padding overhead, e.g. an allocation unit will probably span multiples of the natural word size on a machine. And then the OS call will likely reserve a whole memory page to the program, even if you allocate only 1 byte. Whether you consider that as overhead or not is a matter of taste (from the outside yes, from the inside of the program no; and of course subsequent vectors or resize()s dine from the same page).

So at least it's CM + CV + N*sizeof(T), CM and CV being the overhead in the vector (not necessarily on the stack, as Lighness said) and CM the overhead of the memory management.

share|improve this answer
Why doesn't he always allocate a second block of size C? It's insane, but there's no guarantee he won't do so. – Deduplicator Apr 22 '14 at 0:54
-1 re "But the requirement that the elements be stored contiguously implies that there is no per element overhead." is wrong. there is no requirement that a std::vector stores all its state in the user-visible part of the main items buffer. – Cheers and hth. - Alf Apr 22 '14 at 0:54
@Alf: Strictly spoken true. I changed to "likely" ;-). It excludes pathological implementations through list etc. – Peter A. Schneider Apr 22 '14 at 0:59
@Deduplicator because it's not guaranteed to be contiguous. In fact, with typical implementations it's guaranteed to be not contiguous (because of the intervening alloc block size information). – Peter A. Schneider Apr 22 '14 at 1:02
0 - removed downvote, text fixed. – Cheers and hth. - Alf Apr 22 '14 at 1:06

No, the implementation characteristics you suggest would not be standard compliant. The STL specifies that a std::vector support appending individual elements in amortized constant time.

In order for the amortized cost of inserting an element to be O(1), the size of the array must increase in at least a geometric progression when it is reallocated (see here). A geometric progression means that if the size of the array was N, the new size after reallocation must be K * N, for some K > 1. The choice of K is implementation dependent.

To find out how much space a std::vector has allocated, call std::vector::capacity(). With regard to overhead per element, in the best case the capacity() == size(). In the worst case capacity() == K * (size() - 1).

If you must ensure that your vector is absolutely no larger than it has to be, you can call std::vector::reserve() if you know exactly how large your std::vector will be. You may also call std::vector::resize() (or std::vector::shrink_to_fit() in C++11) after you are done adding elements to reduce the amount of memory reserved.

share|improve this answer
In the question, N already is the capacity of the vector and not the size. – Steve Jessop Apr 22 '14 at 1:28
@SteveJessop: Yes, it seems I misinterpreted the OP's question. – Mark Apr 22 '14 at 17:22
@SteveJessop: Although the OP also claims that his specification has no overhead per element, which seemed natural to me to interpret to mean data elements (rather than the entire allocated capacity). – Mark Apr 22 '14 at 17:28

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.