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std::array is vastly superior to the C arrays. And even if I want to interoperate with legacy code, I can just use std::array::data(). Is there any reason I would ever want an old-school array?

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up vote 41 down vote accepted

Unless I've missed something (I've not followed the most recent changes in the standard too closely), most of the uses of C style arrays still remain. std::array does allow static initialization, but it still won't count the initializers for you. And since the only real use of C style arrays before std::array was for statically initialized tables along the lines of:

MyStruct const table[] =
    { something1, otherthing1 },
    //  ...

using the usual begin and end template functions (adopted in C++11) to iterate over them. Without ever mentionning the size, which the compiler determines from the number of initializers.

EDIT: Another thing I forgot: string literals are still C style arrays; i.e. with type char[]. I don't think that anyone would exclude using string literals just because we have std::array.

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You can write a variadic function template which constructs arrays without you having to specify the length. – rightfold Apr 22 '15 at 12:37

No. To, uh, put it bluntly. And in 30 characters.

Of course, you need C arrays to implement std::array, but that's not really a reason that a user would ever want C arrays. In addition, no, std::array is not less performant than a C array, and has an option for a bounds-checked access. And finally, it is completely reasonable for any C++ program to depend on the Standard library- that's kind of the point of it being Standard- and if you don't have access to a Standard library, then your compiler is non-conformant and the question is tagged "C++", not "C++ and those not-C++ things that miss out half the specification because they felt it inappropriate.".

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Hm. What if you're writing C++ code that gets called from another language and needs something to be passed as a parameter? – asveikau May 24 '11 at 16:00
Freestanding implementations are allowed to leave out almost all of the standard library and still be compliant. I would have serious doubts about a compiler that couldn't implement std::array in a freestanding C++11 implementation, though. – Dennis Zickefoose May 24 '11 at 16:54
C++0x Final Draft (Document N3092) § 1.4.7 "Two kinds of implementations are defined: hosted and freestanding. For a hosted implementation, this International Standard defines the set of available libraries. A freestanding implementation is one in which execution may take place without the benefit of an operating system, and has an implementation-defined set of libraries that includes certain language-support libraries" .. The STL is not included as a "language-support" library in a freestanding compiler – Earlz May 24 '11 at 18:03

Seems like using multi-dimensional arrays is easier with C arrays than std::array. For instance,

char c_arr[5][6][7];

as opposed to

std::array<std::array<std::array<char, 7>, 6>, 5> cpp_arr;

Also due to the automatic decay property of C arrays, c_arr[i] in the above example will decay to a pointer and you just need to pass the remaining dimensions as two more parameters. My point is it c_arr is not expensive to copy. However, cpp_arr[i] will be very costly to copy.

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However, you could pass a multidimensional array to a function without loosing dimensions. And if you pass it to a function template, then that function could deduce both the dimension and the size of each dimension, or just one of them two. This might be interesting for scientific template libraries that principally work on arbitrary dimensions. – Sebastian Mach Sep 1 '11 at 9:55
a simple template <typename T, int M, int N> using array2d = std::array<std::array<T, N>, M>; should solve any of those issues. – Miles Rout Mar 16 '13 at 23:54
also if have atomic in the mix :) – NoSenseEtAl May 21 '13 at 20:30
Your example c_arr is very expensive to copy! You have to provide the code to do so yourself. The pointer it will decay to is a closer equivalent to a reference than a copy and you can use std::array to pass a reference if that is what you want. – ChetS May 21 '14 at 18:10

As Sumant said, multi-dimensional arrays are a lot easier to use with built in C-arrays than with std::array.

When nested, std::array can become very hard to read and unnecessarily verbose.

For example:

std::array<std::array<int, 3>, 3> arr1; 

compared to

char c_arr[3][3]; 

Also, note that begin(), end() and size() all return meaningless values when you nest std::array.

For these reasons I've created my own fixed size multidimensional array containers, array_2d and array_3d. They are analogous to std::array but for multidimensional arrays of 2 and 3 dimensions. They are safer and have no worse performance than built-in multidimensional arrays. I didn't include a container for multidimensional arrays with dimensions greater than 3 as they are uncommon. In C++0x a variadic template version could be made which supports an arbitrary number of dimensions.

An example of the two-dimensional variant:

//Create an array 3 x 5 (Notice the extra pair of braces) 

fsma::array_2d <double, 3, 5> my2darr = {{
    { 32.19, 47.29, 31.99, 19.11, 11.19},
    { 11.29, 22.49, 33.47, 17.29, 5.01 },
    { 41.97, 22.09, 9.76, 22.55, 6.22 }

Full documentation is available here:

You can download the library here:

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Fixed-size C-style arrays are easy, but if you want to vary the dimensions things get complicated. For example, given arr[x][y], you can't tell whether arr is an array of arrays, an array of pointers, a pointer to an array, or a pointer to a pointer; all for implementations are legitimate, depending on your needs. And probably most real-world use cases for multidimensional arrays require the size to be determined at run time. – Keith Thompson Aug 11 '11 at 20:13
I would love to see that variadic-template-implementation of n-dimensional arrays! Meta-programming at its best! – steffen Oct 22 '14 at 11:25
@steffen I did make an attempt a few years ago. You can view it here:…. Test case here:…. I'm sure it can be done a lot better though. – Ricky65 Nov 2 '14 at 15:14

The C-style arrays that are available in C++ are actually much less versatile than the real C-arrays. The difference is, that in C, array types can have runtime sizes. The following is valid C code, but it can neither be expressed with C++ C-style arrays nor with the C++ array<> types:

void foo(int bar) {
    double tempArray[bar];
    //Do something with the bar elements in tempArray.

In C++, you would have to allocate the temporary array on the heap:

void foo(int bar) {
    double* tempArray = new double[bar];
    //Do something with the bar elements behind tempArray.
    delete[] tempArray;

This cannot be achieved with std::array<>, because bar is not known at compile time, it requires the use of either C-style arrays in C++ or of std::vector<>.

While the first example could relatively easily be expressed in C++ (albeit requiring new[] and delete[]), the following cannot be achieved in C++ without std::vector<>:

void smoothImage(int width, int height, int (*pixels)[width]) {
    int (*copy)[width] = malloc(height*sizeof(*copy));
    memcpy(copy, pixels, height*sizeof(*copy));
    for(y = height; y--; ) {
        for(x = width; x--; ) {
            pixels[y][x] = //compute smoothed value based on data around copy[y][x]

The point is, that the pointers to the line arrays int (*)[width] cannot use a runtime width in C++, which makes any image manipulation code much more complicated in C++ than it is in C. A typical C++ implementation of the image manipulation example would look like this:

void smoothImage(int width, int height, int* pixels) {
    int* copy = new int[height*width];
    memcpy(copy, pixels, height*width*sizeof(*copy));
    for(y = height; y--; ) {
        for(x = width; x--; ) {
            pixels[y*width + x] = //compute smoothed value based on data around copy[y*width + x]
    delete[] copy;

This code does precisely the same calculations as the C code above, but it needs to perform the index computation by hand wherever the indices are used. For the 2D case, this is still feasible (even though it comes with a lot of opportunities to get the index calculation wrong). It gets really nasty in the 3D case, though.

I like writing code in C++. But whenever I need to manipulate multidimensional data, I really ask myself whether I should move that part of the code to C.

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It should be noted that at least Clang and GCC support VLA's in C++. – Janus Troelsen Jun 6 '14 at 13:38
@JanusTroelsen and also that they are horribly limited in which element types they support. – rightfold Apr 22 '15 at 12:39
Doesn’t C11 make VLA optional? If so then I think your answer is misleading. It would be correct when C99 was the standard but not C11. – Z boson Jan 28 at 9:05
@Zboson C99 is a C standard, and there are compilers that implement its VLA features (gcc for instance). C11 has made quite a bit of interesting stuff optional, and I don't think that's because they want to outlaw the feature. I tend to see it as a sign that they wanted to lower the level for writing a fully standard compliant compiler: VLA's are quite a difficult beast to implement, and much code can do without, so it makes sense for a new compiler on some new platform to not have to implement VLA's right away. – cmaster Jan 29 at 17:24

May be the std::array is not slow. But I did some benchmarking using simple store and read from the std::array; See the below benchmark results (on W8.1, VS2013 Update 4):

ARR_SIZE: 100 * 1000
Avrg = Tick / ARR_SIZE;

==>VMem: 5.15Mb
==>PMem: 8.94Mb
==>Tick: 3132
==>Avrg: 0.03132
==>VMem: 5.16Mb
==>PMem: 8.98Mb
==>Tick: 925
==>Avrg: 0.00925
==>VMem: 5.16Mb
==>PMem: 8.97Mb
==>Tick: 769
==>Avrg: 0.00769
==>VMem: 5.16Mb
==>PMem: 8.94Mb
==>Tick: 358
==>Avrg: 0.00358
==>VMem: 5.16Mb
==>PMem: 8.94Mb
==>Tick: 305
==>Avrg: 0.00305

According to the negative marks, the code I used is in the pastebin (link)

The benchmark class code is here;

I don't know a lot about benchmarkings... My code may be flawed

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Benchmark results without benchmark code, or compilation flags? Come on, you can do better. – R. Martinho Fernandes Apr 22 '15 at 12:10
FWIW, just that small bit of code already shows the benchmark is severely flawed. A smart enough compiler will just turn the whole thing into long test_arr_without_init() { return ARR_SIZE; } – R. Martinho Fernandes Apr 22 '15 at 12:13
That was just an example. I thought it was not big deal. I changed the code to return void, used release build in VS 2013, with /O2 /Ot /Gl. – K'Prime Apr 22 '15 at 13:59
Removing the return value means the compiler can turn the whole thing into void test_arr_without_init() {} now. You really need to jump through hoops to make sure the code you are measuring is the code you want to measure. – R. Martinho Fernandes Apr 22 '15 at 14:17
  1. to implement something like std::array
  2. if you don't want to use the STL or can't
  3. For performance
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Tell me how std::array will be less performant than a C array. – Xeo May 24 '11 at 14:01
From wikipedia: "The array implementation is not required to do bound check. However the implementation in boost does that for operator[], but not for iterators." -- so operator[] is slower. I haven't looked at implementations, but any code in the implementation could get in the way of the optimizer. – Lou Franco May 24 '11 at 14:07
@Aaron McDaid: That's only in at(), it's not in operator[], just like std::vector. There's no performance decrease or code bloat to std::array, the compiler is designed to optimize this kind of thing. And, of course, the addition of the checked function is an excellent debug tool and a large advantage. @Lou Franco: All C++ code may depend on the Standard library- that's kind of what it's for. @Earlz: If you don't have STL available, then it's not C++, and that's the end of that. – Puppy May 24 '11 at 14:20
@Earlz: The C++ Standard contains the Standard library. If you can't use the library, it's not conformant. And secondly, you must have one hell of a shitty compiler for the use of std::array to be larger than equivalent C array usage. – Puppy May 24 '11 at 14:47
@Earlz: There's a big difference between "not quite conforming" and "missing features which are hundreds of pages in specification". – Puppy May 24 '11 at 17:11

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