How do I initialize std::array<T, n> if T is not default constructible?

I know it's possible to initialize it like that:

T t{args};
std::array<T, 5> a{t, t, t, t, t};

But n for me is template parameter:

template<typename T, int N>
void f(T value)
    std::array<T, N> items = ??? 

And even if it wasn't template, it's quite ugly to repeat value by hand if n is too large.

  • Yes, you can write a function or two to generate them.
    – chris
    Aug 28 '13 at 20:03
  • Will the 'fill()` help?
    – Arun
    Aug 28 '13 at 20:04
  • @Arun, no. It may be called only on already constructed array.
    – RiaD
    Aug 28 '13 at 20:04
  • 1
    std::array is an aggregate, there is not that much you can do about it Aug 28 '13 at 20:09
  • 1
    @Nawaz: Very creative. It seems that there is not that much you can do, although you can to this :) +1 Aug 28 '13 at 20:57

Given N, you could generate a sequence-type calledseq<0,1,2,3,...N-1> using a generator called genseq_t<>, then do this:

template<typename T, int N>
void f(T value)
     //genseq_t<N> is seq<0,1,...N-1>
     std::array<T, N> items = repeat(value, genseq_t<N>{});

where repeat is defined as:

template<typename T, int...N>
auto repeat(T value, seq<N...>) -> std::array<T, sizeof...(N)> 
   //unpack N, repeating `value` sizeof...(N) times
   //note that (X, value) evaluates to value
   return {(N, value)...}; 

And the rest is defined as:

template<int ... N>
struct seq
   using type = seq<N...>;

   static const std::size_t size = sizeof ... (N);

   template<int I>
   struct push_back : seq<N..., I> {};

template<int N>
struct genseq : genseq<N-1>::type::template push_back<N-1> {};

struct genseq<0> : seq<> {};

template<int N>
using genseq_t = typename genseq<N>::type;

Online demo

Hope that helps.

  • 1
    Thanks for posting this. I knew I've seen something like this before and I didn't quite finish my attempted solution.
    – chris
    Aug 28 '13 at 20:30
  • Why is valuelist an integral_constant as an aside? Aug 29 '13 at 2:24
  • @Yakk: So that you can know the size of the list. valuelist<0,1,2,3>::value is 4. In this example, this is not needed, but it is good to have this feature.
    – Nawaz
    Aug 29 '13 at 2:36
  • 1
    You don't need you own seq and all other boilerplate, standard already has std::integer_sequence. See ideone.com/yEWZVq (a little different task, but approach is the same).
    – Mikhail
    Jun 18 '16 at 11:26

Sadly the existing answers here don't work for non-copyable types. So I took @Nawaz answer and modified it:

#include <utility>
#include <array>

template<typename T, size_t...Ix, typename... Args>
std::array<T, sizeof...(Ix)> repeat(std::index_sequence<Ix...>, Args &&... args) {
   return {{((void)Ix, T(args...))...}};

template<typename T, size_t N>
class initialized_array: public std::array<T, N> {
    template<typename... Args>
    initialized_array(Args &&... args)
        : std::array<T, N>(repeat<T>(std::make_index_sequence<N>(), std::forward<Args>(args)...)) {}

Note that this is an std::array subclass so that one can easily write

class A { 
    A(int, char) {}


class C {
    initialized_array<A, 5> data;


    C(): data(1, 'a') {}

Without repeating the type and size. Of course, this way can also be implemented as a function initialize_array.

  • Don't use perfect forwarding here - ultimately you have to copy them. Just use const Args&... args.
    – L. F.
    Feb 19 '20 at 4:49

Following will solve your issue:

#if 1 // Not in C++11, but in C++1y (with a non linear better version)

template <std::size_t ...> struct index_sequence {};

template <std::size_t I, std::size_t ...Is>
struct make_index_sequence : make_index_sequence<I - 1, I - 1, Is...> {};

template <std::size_t ... Is>
struct make_index_sequence<0, Is...> : index_sequence<Is...> {};


namespace detail
    template <typename T, std::size_t ... Is>
    constexpr std::array<T, sizeof...(Is)>
    create_array(T value, index_sequence<Is...>)
        // cast Is to void to remove the warning: unused value
        return {{(static_cast<void>(Is), value)...}};

template <std::size_t N, typename T>
constexpr std::array<T, N> create_array(const T& value)
    return detail::create_array(value, make_index_sequence<N>());

So test it:

struct NoDefaultConstructible {
    constexpr NoDefaultConstructible(int i) : m_i(i) { }
    int m_i;

int main()
    constexpr auto ar1 = create_array<10>(NoDefaultConstructible(42));
    constexpr std::array<NoDefaultConstructible, 10> ar2 = create_array<10>(NoDefaultConstructible(42));

    return 0;

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