I just saw that C++23 plans to deprecate both std::aligned_storage and std::aligned_storage_t as well as std::aligned_union and std::aligned_union_t.

Placement new'd objects in aligned storage are not particularly constexpr friendly as far as I understand, but that doesn't appear to be a good reason to throw out the type completely. This leads me to assume that there is some other fundamental problem with using std::aligned_storage and friends that I am not aware of. What would that be?

And is there a proposed alternative to these types?


1 Answer 1


Here are three excerpts from P1413R3:


aligned_* are harmful to codebases and should not be used. At a high level:

  • Using aligned_* invokes undefined behavior (The types cannot provide storage.)
  • The guarantees are incorrect (The standard only requires that the type be at least as large as requested but does not put an upper bound on the size.)
  • The API is wrong for a plethora of reasons (See "On the API".)
  • Because the API is wrong, almost all usage involves the same repeated pre-work (See "Existing usage".)

On the API

std::aligned_* suffer from many poor API design decisions. Some of these are shared, and some are specific to each. As for what is shared, there are three main problems [only one is included here for brevity]:

  • Using reinterpret_cast is required to access the value

There is no .data() or even .data on std::aligned_* instances. Instead, the API requires you to take the address of the object, call reinterpret_cast<T*>(...) with it, and then finally indirect the resulting pointer giving you a T&. Not only does this mean that it cannot be used in constexpr, but at runtime it's much easier to accidentally invoke undefined behavior. reinterpret_cast being a requirement for use of an API is unacceptable.

Suggested replacement

The easiest replacement for aligned_* is actually not a library feature. Instead, users should use a properly-aligned array of std::byte, potentially with a call to std::max(std::initializer_list<T>) . These can be found in the <cstddef> and <algorithm> headers, respectively (with examples at the end of this section). Unfortunately, this replacement is not ideal. To access the value of aligned_*, users must call reinterpret_cast on the address to read the bytes as T instances. Using a byte array as a replacement does not avoid this problem. That said, it's important to recognize that continuing to use reinterpret_cast where it already exists is not nearly as bad as newly introducing it where it was previously not present. ...

The above section from the accepted proposal to retire aligned_* is then followed with a number of examples, like these two replacement suggestions:

// To replace std::aligned_storage
template <typename T>
class MyContainer {
    //std::aligned_storage_t<sizeof(T), alignof(T)> t_buff;
    alignas(T) std::byte t_buff[sizeof(T)];
// To replace std::aligned_union
template <typename... Ts>
class MyContainer {
    //std::aligned_union_t<0, Ts...> t_buff;
    alignas(Ts...) std::byte t_buff[std::max({sizeof(Ts)...})];
  • 5
    Also, the argument that reinterpret_cast is a necessary part of ever using this idiom/type is false, because placement-new will return a proper T*. So a use-case that never requires reinterpreting any points is conceivable and plausible. Anyhow, it's gone now and people will have to roll their own.
    – bitmask
    Apr 11, 2022 at 14:34
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    What we really need is a new way of declaring a properly typed array without constructing its elements yet, eg: [[uninitialized_storage]] T t_arr[len]; where the compiler would allocate the array of sufficient size and alignment, just not call any constructors on it. allowing the developer to use placement-new to initialize each T element as needed. I know, wishful thinking... Apr 11, 2022 at 22:40
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    @TedLyngmo If I understand the footnote on this answer by Barry, C++23 should be able to do this -- but I haven't been following c++23 that closely. The alternative that would definitely work would be to throw an empty trivial struct in the union to be active member when T is not (e.g. union { struct empty_type {} empty; T entry; } t_arr[len]. Then std::construct_at changes the active member legally, and entry can still be accessed in constexpr contexts without reinterpret_cast being needed. Apr 20, 2022 at 18:51
  • 4
    God I hate the C++ standard. They make everything so complicated and forget about the basics.
    – Bas
    Jan 28, 2023 at 23:47
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    @digito_evo I think I followed the rules and I used alignas(T) std::byte buf[sizeof(T)]; as suggested P1413R3 for one element and only made it N times bigger. It'd require a language-lawyer to say for sure :-)
    – Ted Lyngmo
    Jul 11, 2023 at 3:09

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