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Is the following a valid C++ code, and why not?

std::array<std::string, 42> a1;
std::array<int, a1.size()> a2;

It doesn't compile in GCC 4.8 (in C++11 mode). There is a simple but inelegant workaround:

std::array<std::string, 42> a1;
std::array<int, sizeof(a1)/sizeof(a1[0])> a2;

So clearly the compiler can figure out the number of elements in std::array. Why std::array::size() is not a constexpr static function?

EDIT: I have found another workaround:

std::array<std::string, 42> a1;
std::array<int, std::tuple_size<decltype(a1)>::value> a2;
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Are you using the -std=c++0x flag? –  user529758 May 31 '13 at 21:13
By the way, it is clearly constexpr(). –  user529758 May 31 '13 at 21:13
Rather than give a1 a size and then give a2 the same size, why not just create a variable like size_t x=42 and then create both a1 and a2 with a size of x? –  Lorkenpeist May 31 '13 at 22:35
@Lorkenpeist: Because maybe you have auto a1 = some_function<some_template_argument>(); –  Ben Voigt Jun 1 '13 at 0:35

4 Answers 4

up vote 4 down vote accepted

array<T>::size() is constexpr, but you can't use it in this way because a1 isn't a constexpr value. Additionally, it can't be constexpr because string isn't a literal type.

However, you can work around this if you want, by deducing the size_t template parameter. Example:

#include <string>
#include <array>
#include <iostream>
using namespace std;

struct array_size;
template<typename T, size_t N>
struct array_size<array<T,N> > {
    static size_t const size = N;

array<string, 42> a1;
array<string, array_size<decltype(a1)>::size> a2;

int main() {
    cout << a2.size() << endl;
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And that's why size() should be a static function, as suggested in the question. –  Ben Voigt May 31 '13 at 21:19
@BenVoigt If size was a static constexpr function, there would be no problem? –  robson3.14 May 31 '13 at 22:23
@robson: Right, because then it would be constexpr depending only on whether all arguments are constexpr (trivially met since there are zero arguments) and not depending on whether the object instance *this is constexpr. –  Ben Voigt Jun 1 '13 at 0:34

std::array::size is actually required to be constexpr per § of the C++11 standard: array::size [array.size]  
template <class T, size_t N> constexpr size_type array<T,N>::size() noexcept;  
Returns: N

I'm guessing this just slipped past whoever implemented it in GCC.

After testing, this works:

std::array<int, 42> a1;
std::array<int, a1.size()> a2;

This may actually have something to do with std::string not being a valid constexpr type to make compile-time instances of, whereas int is.

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You can use the same template-inference method as has always been used for C++98 array bound detection.

template<size_t N, typename T>
constant_integer<N> array_size( const std::array<T, N>& );

Make a nice macro wrapper and enjoy!

Many variations are also possible, such as:

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return what? that is not a valid c++ –  BЈовић May 31 '13 at 21:20
Seems like a pretty solid workaround. –  chris May 31 '13 at 21:21
@BЈовић: It is when constant_integer<N> has a default constructor. Click through to the full source code. –  Ben Voigt May 31 '13 at 21:22
Should return constant_integer<N>();. not just return; –  BЈовић May 31 '13 at 21:23
@BЈовић: Actually, the function body isn't even needed. –  Ben Voigt May 31 '13 at 21:24

It is not static but it is a constexpr
EDIT: this may not be a bug, take a look at this Error using a constexpr as a template parameter within the same class

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