49

In C++11 std::array is defined to have contiguous storage and performance that is no worse than an array, but I can't decide if the various requirements of the standard imply that std::array has the same size and memory layout as a normal array. That is can you count on sizeof(std::array<int,N>) == sizeof(int)*N or is that implementation specific?

In particular, is this guaranteed to work the way you would expect it to:

std::vector< std::array<int, N> > x(M);
typedef (*ArrayPointer)[N];
ArrayPointer y = (ArrayPointer) &x[0][0];
// use y like normal multidimensional array

It works in the two compilers I tried (GNU & Intel). Furthermore, all the 3rd party documentation I could find (like this), states that std::array is just as memory efficient as a plain array, which combined with the contiguous requirement would imply that it must have identical memory layout. However I can't find this requirement in the standard.

3
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    There is no such guarantee in 23.3.2 Class template array, and indeed, searching the standard for sizeof seems to only turn up the following guarantees for me: char and its variants are 1, and nullptr has the same sizeof as void*.
    – us2012
    Commented Sep 30, 2013 at 20:37
  • As @us2012 states, there is no explicit guarantee. While it may work on your platform of choice, it may fail on other platforms with different alignment constraints. Commented Sep 30, 2013 at 20:43
  • I suppose you can simply have a static_assert(sizeof(std::array<T,N>) == sizeof(T)*N) for all types in your code as a tripwire for an unusual library implementation (or some alignment option which causes std::array to align differently). If the sizes are equal the layout must be the same. Commented Dec 28, 2020 at 21:59

2 Answers 2

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It's nearly required. Specifically, §23.3.2.1/2 says:

An array is an aggregate (8.5.1) that can be initialized with the syntax

array<T, N> a = { initializer-list };

where initializer-list is a comma-separated list of up to N elements whose types are convertible to T.

Since it's an aggregate, it can't use any sort of constructor to convert the data in the initializer-list to the correct format. That really only leaves one possibility: about the only thing it can store are the values themselves.

I suppose it would be possible for an std::array to store some sort of auxiliary data following the specified data, such as extra memory set to some predefined value, so if you write past the end of the array, you'd probably change that data. The compiler/run-time would then check those values at shut-down, and if you'd changed the values, report your code's undefined behavior.

It's also possible that a compiler could do padding/alignment differently for an std::array than for a built-in array. One obvious example for which this could even be desirable would be to support super-alignment requirements, such as data for use with Intel's SSE instructions. A built-in array can't support super-alignment, but I think the specification of std::array might be barely loose enough to allow it.

Bottom line: without getting into questions of how many possibilities might exist, it's pretty clear that std::array doesn't necessarily have to follow the rule you're asking about.

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    I think it can also have padding, even at the beginning, as it isn't required to be a standard-layout class (and can't be, for its members may be of non-standard-layout type).
    – dyp
    Commented Sep 30, 2013 at 20:52
  • 1
    Live example (Yes, this doesn't prove anything. I carefully searched the Standard and didn't find any layout requirements for aggregates or literal types, just for standard-layout types; formerly PODs had these requirements in C++03.)
    – dyp
    Commented Sep 30, 2013 at 21:01
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    C forbids structures to have unnamed padding at their beginning in 6.7.2.1/15 "There may be unnamed padding within a structure object, but not at its beginning." (i.e. you could still have it at the end)
    – dyp
    Commented Sep 30, 2013 at 21:07
  • 1
    You might be interested in this as well, especially given that 0 is a special case for std::array. Commented Sep 30, 2013 at 21:27
  • 1
    "I suppose it would be possible for an std::array to store some sort of auxiliary data following the specified data, such as extra memory set to some predefined value, so if you write past the end of the array, you'd probably change that data." the wording of en.cppreference.com/w/cpp/container/array appears to suggest that this is not possible: "This container is an aggregate type with the same semantics as a struct holding a C-style array T[N] as its only non-static data member." Not sure which is correct. Commented Apr 23, 2020 at 10:54
0

I am not sure what the standard guarantee is exactly but by using simple logic I think that it is a pretty safe assumption that sizeof(std::array<T,N>) == sizeof(T[N]).

First of all the design goal of std::array is to work around the problem of array type decay when passed or returned to/from functions.

A secondary goal of std::array is to provide a minimalist STL container interface by implementing some regular methods like size(), begin(), end(), and so on.

The first goal is achieved by creating a new class/type with which the array dimension is encoded in the type, therefore array decay is not possible.

That is the only purpose of std::array. Now, if you think about how this is implemented. It should look something like this:

template <class T, size_t N>
array
{
private:
  T a_[N];
};

I have a very hard time thinking why an implementation would generate a class that is of a different size!

Even if sizeof(T) is not a perfect multiple of the enforced alignment. The equality should still hold because the padding is only added between variables in a structure. As far as I know, padding is not added at the end of class to round its size.

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