Revised 2025-11-06 at 18:16:32 UTC

Tentative Issues

3908(i). enumerate_view::iterator constructor is explicit

Section: 25.7.24.3 [range.enumerate.iterator] Status: Tentatively NAD Submitter: Jonathan Wakely Opened: 2023-03-23 Last modified: 2024-06-24

Priority: Not Prioritized

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Discussion:

enumerate_view::iterator has this constructor: 

    constexpr explicit
      iterator(iterator_t<Base> current, difference_type pos);  // exposition only

In P2164R9 the detailed description of the function showed a default argument for the second parameter, which would justify it being explicit. However, that default argument was not present in the class synopsis and was removed from the detailed description when applying the paper to the draft.

[2023-06-01; Reflector poll]

Set status to Tentatively NAD after four votes in favour during reflector poll. The constructor is exposition-only, it doesn't make any difference to anything whether it's explicit or not.

Proposed resolution:

This wording is relative to N4944.

  1. Modify the class synopsis in 25.7.24.3 [range.enumerate.iterator] as shown: 

    
    constexpr explicit
      iterator(iterator_t<Base> current, difference_type pos);  // exposition only

  2. Modify the detailed description in 25.7.24.3 [range.enumerate.iterator] as shown: 

      constexpr explicit iterator(iterator_t<Base> current, difference_type pos);

    -2- Effects: Initializes current_ with std::move(current) and pos_ with pos.

3909(i). Issues about viewable_range

Section: 99 [ranges.refinements], 25.7.2 [range.adaptor.object] Status: Tentatively NAD Submitter: Jiang An Opened: 2023-03-27 Last modified: 2023-06-01

Priority: Not Prioritized

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Discussion:

After LWG 3724(i), views::all is well-constrained for view types, and the constraints are stronger than viewable_range. The difference is that given an expression such that decltype gives R, when decay_t<R> is a view type and the implicit conversion of R to decay_t<R> is forbidden, views::all rejects the expression, but viewable_range may accept R. So I think we should remove the additional constraints on views::all_t.

While viewable_range is probably not introducing any additional constraint within the standard library, I think it is still useful to express the constraints on views::all, so it should be slightly adjusted to match views::all.

Furthermore, viewable_range is currently used in 25.7.2 [range.adaptor.object], but given P2378R3 relaxed the requirements for range adaptor closure objects, I think we should also apply similar relaxation for range adaptor objects. This should have no impact on standard range adaptor objects.

[2023-06-01; Reflector poll]

Set status to Tentatively NAD after three votes in favour during reflector poll.

"First change is pointless. Second change is a duplicate of 3896(i). Range adaptors return a view over their first argument, so they need to require it's a viewable_range."

Proposed resolution:

This wording is relative to N4944.

  1. Change the definition of views::all_t in 25.2 [ranges.syn] as indicated: 

    
   template<viewable_rangeclass R>
      using all_t = decltype(all(declval<R>()));          // freestanding

  2. Change the definition of viewable_range in 25.4.6 [range.refinements] as indicated:

    -6- The viewable_range concept specifies the requirements of a range type that can be converted to a view safely. 

    
template<class T>
  concept viewable_range =
    range<T> &&
    ((view<remove_cvref_t<T>> && constructible_from<remove_cvref_t<T>, T> convertible_to<T, remove_cvref_t<T>>) ||
     (!view<remove_cvref_t<T>> &&
      (is_lvalue_reference_v<T> || (movable<remove_reference_t<T>> && !is-initializer-list<T>))));

  3. Change 25.7.2 [range.adaptor.object] as indicated:

    -6- A range adaptor object is a customization point object (16.3.3.3.5 [customization.point.object]) that accepts a viewable_rangerange as its first argument and returns a view.

    […]

    -8- If a range adaptor object adaptor accepts more than one argument, then let range be an expression such that decltype((range)) models viewable_rangerange, let args... be arguments such that adaptor(range, args...) is a well-formed expression as specified in the rest of subclause 25.7 [range.adaptors], and let BoundArgs be a pack that denotes decay_t<decltype((args))>.... The expression adaptor(args...) produces a range adaptor closure object f that is a perfect forwarding call wrapper (22.10.4 [func.require]) with the following properties: [...]

3958(i). ranges::to should prioritize the "reserve" branch

Section: 25.5.7.2 [range.utility.conv.to] Status: Tentatively NAD Submitter: Hewill Kang Opened: 2023-07-17 Last modified: 2024-01-29

Priority: Not Prioritized

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Discussion:

When the constructed range object has no range version constructor, ranges::to falls into a branch designed specifically for C++17-compliant containers, which calls the legacy constructor that accepts an iterator pair with C(ranges::begin(r), ranges::end(r), std::forward<Args>(args)...).

However, this kind of initialization may bring some performance issues, because we split the original range into pairs of iterators, which may lose information contained in the original range, for example: 

#include <boost/container/vector.hpp>
#include <sstream>
#include <ranges>

int main() {
  std::istringstream ints("1 2 3 4 5");
  std::ranges::subrange s(std::istream_iterator<int>(ints),
                          std::istream_iterator<int>(),
                          5);
  auto r = std::ranges::to<boost::container::vector>(s); // discard size info
}

Above, subrange saves the size information of the stream, but ranges::to only extracts its iterator pair to create the object, so that the original size information is discarded, resulting in unnecessary allocations.

I believe we should prefer to use the "reserve" branch here because it is really designed for this situation.

[2023-10-30; Reflector poll]

Set status to Tentatively NAD after reflector poll. "This optimizes exotic cases at the expense of realistic cases."

Proposed resolution:

This wording is relative to N4950.

  1. Modify 25.5.7.2 [range.utility.conv.to] as indicated:

    template<class C, input_range R, class... Args> requires (!view<C>)
  constexpr C to(R&& r, Args&&... args);

    -1- Mandates: C is a cv-unqualified class type.

    -2- Returns: An object of type C constructed from the elements of r in the following manner:

    1. (2.1) — If C does not satisfy input_range or convertible_to<range_reference_t<R>, range_value_t<C>> is true:

      1. (2.1.1) — If constructible_from<C, R, Args...> is true:

        C(std::forward<R>(r), std::forward<Args>(args)...)

      2. (2.1.2) — Otherwise, if constructible_from<C, from_range_t, R, Args...> is true:

        C(from_range, std::forward<R>(r), std::forward<Args>(args)...)

      3. (2.1.3) — Otherwise, if

        1. (2.1.3.1) — common_range<R> is true,

        2. (2.1.3.2) — the qualified-id iterator_traits<iterator_t<R>>::iterator_category is valid and denotes a type that models derived_from<input_iterator_tag>, and

        3. (2.1.3.3) — constructible_from<C, iterator_t<R>, sentinel_t<R>, Args...> is true:

          C(ranges::begin(r), ranges::end(r), std::forward<Args>(args)...)

      4. (2.1.4) — Otherwise, if

        1. (2.1.4.1) — constructible_from<C, Args...> is true, and

        2. (2.1.4.2) — container-insertable<C, range_reference_t<R>> is true:

          C c(std::forward<Args>(args)...);
if constexpr (sized_range<R> && reservable-container<C>)
  c.reserve(static_cast<range_size_t<C>>(ranges::size(r)));
ranges::copy(r, container-inserter<range_reference_t<R>>(c));

      5. (?.?.?) — Otherwise, if

        1. (?.?.?.?) — common_range<R> is true,

        2. (?.?.?.?) — the qualified-id iterator_traits<iterator_t<R>>::iterator_category is valid and denotes a type that models derived_from<input_iterator_tag>, and

        3. (?.?.?.?) — constructible_from<C, iterator_t<R>, sentinel_t<R>, Args...> is true:

          C(ranges::begin(r), ranges::end(r), std::forward<Args>(args)...)

    2. (2.2) — Otherwise, if input_range<range_reference_t<R>> is true:

      to<C>(r | views::transform([](auto&& elem) {
  return to<range_value_t<C>>(std::forward<decltype(elem)>(elem));
}), std::forward<Args>(args)...);

    3. (2.3) — Otherwise, the program is ill-formed.

3980(i). The read exclusive ownership of an atomic read-modify-write operation and whether its read and write are two operations are unclear

Section: 32.5.4 [atomics.order] Status: Tentatively NAD Submitter: jim x Opened: 2023-08-22 Last modified: 2023-11-03

Priority: Not Prioritized

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Discussion:

Such two questions are sourced from StackOverflow:

  1. Can the read operations in compare_exchange_strong in different two thread read the same value?

  2. For purposes of ordering, is atomic read-modify-write one operation or two?

Given this example: 

#include <iostream>
#include <atomic>
#include <thread>

struct SpinLock{
  std::atomic<bool> atomic_;
  void lock(){
    bool expected = false;
    while (!atomic_.compare_exchange_strong(expected,true,std::memory_order_release,std::memory_order_relaxed)) {
    }
  }
  void unlock(){
    atomic_.store(false, std::memory_order_release);
  }
};

int main(){
  SpinLock spin{false};
  auto t1 = std::thread([&](){
    spin.lock();
    spin.unlock();
  });
  auto t2 = std::thread([&](){
    spin.lock();
    spin.unlock();
  });
  t1.join();
  t2.join();
}

In the current draft, the relevant phrasing that can interpret that only one read-modify-write operation reads the initial value false is 32.5.4 [atomics.order] p10:

Atomic read-modify-write operations shall always read the last value (in the modification order) written before the write associated with the read-modify-write operation.

However, the wording can have two meanings, each kind of read can result in different explanations for the example

  1. The check of the violation is done before the side effect of the RMW is in the modification order, i.e. the rule is just checked at the read point.

  2. The check of the violation is done after the side effect of the RMW is in the modification order, i.e. the rule is checked when RMW tries to add the side effect that is based on the read-value to the modification order, and that side effect wouldn't be added to the modification order if the rule was violated.

With the first interpretation, the two RMW operations can read the same initial value because that value is indeed the last value in the modification order before such two RMW operations produce the side effect to the modification order.

With the second interpretation, there is only one RMW operation that can read the initial value because the latter one in the modification order would violate the rule if it read the initial value.

Such two interpretations arise from that the wording doesn't clearly specify when that check is performed.

So, my proposed wording is:

Atomic read-modify-write operations shall always read the value from a side effect X, where X immediately precedes the side effect of the read-modify-write operation in the modification order.

This wording keeps a similar utterance to 6.10.2.2 [intro.races], and it can clearly convey the meaning that we say the value read by RWM is associated with the side effect of RMW in the modification order.

Relevant discussion can be seen CWG/issues/423 here.

[2023-11-03; Reflector poll]

NAD. The first reading isn't plausible.

Proposed resolution:

This wording is relative to N4958.

  1. Modify 32.5.4 [atomics.order] as indicated:

    -10- Atomic read-modify-write operations shall always read the last value from a side effect X, where X immediately precedes the side effect of the read-modify-write operation (in the modification order) written before the write associated with the read-modify-write operation.

    -11- Implementations should make atomic stores visible to atomic loads within a reasonable amount of time.

3981(i). Range adaptor closure object is underspecified for its return type

Section: 25.7.2 [range.adaptor.object] Status: Tentatively NAD Submitter: Hewill Kang Opened: 2023-08-22 Last modified: 2024-06-24

Priority: Not Prioritized

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Discussion:

In order to provide pipe support for user-defined range adaptors, P2387R3 removed the specification that the adaptor closure object returns a view, which conforms to the wording of ranges::to.

However, the current wording seems to be too low-spec so that the range adaptor closure object can return any type or even void. This makes it possible to break the previous specification when returning types that don't make sense, for example: 

#include <ranges>

struct Closure : std::ranges::range_adaptor_closure<Closure> {
  struct NonCopyable {
    NonCopyable(const NonCopyable&) = delete;
  };

  const NonCopyable& operator()(std::ranges::range auto&&);
};

auto r = std::views::iota(0) | Closure{}; // hard error in libstdc++ and MSVC-STL

Above, since the return type of the pipeline operator is declared as auto, this causes the deleted copy constructor to be invoked in the function body and produces a hard error.

The proposed resolution adds a specification for the range adaptor closure object to return a cv-unqualified class type.

[2023-10-30; Reflector poll]

Set status to Tentatively NAD. "The wording says R | C is equivalent to C(R), not auto(C(R))."

Proposed resolution:

This wording is relative to N4958.

  1. Modify 25.7.2 [range.adaptor.object] as indicated:

    -1- A range adaptor closure object is a unary function object that accepts a range argument. For a range adaptor closure object C and an expression R such that decltype((R)) models range, the following expressions are equivalent:

    […]

    -2- Given an object t of type T, where

    1. (2.1) — t is a unary function object that accepts a range argument and returns a cv-unqualified class object,

    2. […]

    then the implementation ensures that t is a range adaptor closure object.

3982(i). is-derived-from-view-interface should require that T is derived from view_interface<T>

Section: 25.4.5 [range.view] Status: Tentatively NAD Submitter: Hewill Kang Opened: 2023-08-22 Last modified: 2023-10-30

Priority: Not Prioritized

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Discussion:

Currently, the wording of is-derived-from-view-interface only detects whether type T is unambiguously derived from one base class view_interface<U> where U is not required to be T, which is not the intention of CRTP.

[2023-10-30; Reflector poll]

Set status to Tentatively NAD. The wording correctly handles the case where T derives from Base which derives from view_interface<Base>. We don't want it to only be satisfied for direct inheritance from view_interface<T>, but from any specialization of view_interface. Previously the concept only checked for inheritance from view_base but it was changed when view_interface stopped inheriting from view_base.

Proposed resolution:

This wording is relative to N4958.

  1. Modify 25.4.5 [range.view] as indicated:

    template<class T>
  constexpr bool is-derived-from-view-interface = see below;            // exposition only
template<class T>
  constexpr bool enable_view =
    derived_from<T, view_base> || is-derived-from-view-interface<T>;

    -6- For a type T, is-derived-from-view-interface<T> is true if and only if T has exactly one public base class view_interface<TU> for some type U and T has no base classes of type view_interface<UV> for any other type UV.

3992(i). basic_stringbuf::str()&& should enforce 𝒪(1)

Section: 31.8.2.4 [stringbuf.members] Status: Tentatively NAD Submitter: Peter Sommerlad Opened: 2023-10-05 Last modified: 2025-10-24

Priority: 4

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Discussion:

Recent discussions on llvm-64644 came to the conclusion that basic_stringbuf() && introduced by P0408 might just copy the underlying buffer into a string object and not actually move the allocated space. While the wording tried to encourage that, especially with the postcondition that the buffer must be empty afterwards, it failed to specify that the move is never a copy.

I suggest to amend the specification to enforce implementors to do the 𝒪(1) thing. There might be ABI issues for those who still copy.

Some investigation into 23.2.2.2 [container.reqmts] p.16 and 27.4.3.1 [basic.string.general] shows that a basic_string as a standard container should move with 𝒪(1).

Unfortunately, we cannot say

str().data() == buf.data() before calling str()

as a postcondition due to SSO. Maybe a note could be added to eliminate the confusion.

[2025-10-23; Reflector poll; Status changed: New → Tentatively NAD.]

The requirements are already implied, and proposed wording has no effect.

Proposed resolution:

This wording is relative to N4958.

  1. Modify 31.8.2.4 [stringbuf.members] as indicated:

    basic_string<charT, traits, Allocator> str() &&;

    -9- Postconditions: The underlying character sequence buf is empty and pbase(), pptr(), epptr(), eback(), gptr(), and egptr() are initialized as if by calling init_buf_ptrs() with an empty buf.

    -10- Returns: A basic_string<charT, traits, Allocator> object move constructed from the basic_stringbuf's underlying character sequence in buf. This can be achieved by first adjusting buf to have the same content as view().

    [Note: — 23.2.2.2 [container.reqmts] require the move construction of the return value to be 𝒪(1) end note]

4003(i). view_interface::back is overconstrained

Section: 25.5.3 [view.interface] Status: Tentatively NAD Submitter: Hewill Kang Opened: 2023-10-28 Last modified: 2024-06-24

Priority: Not Prioritized

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Discussion:

Currently, view_interface only provides the back member when the derived class satisfies both bidirectional_range and common_range, which ensures that ranges::prev can act its sentinel.

However, requiring common_range seems to be too strict because when the derived class satisfies both random_access_range and sized_range, its end iterator can still be calculated in constant time, which is what some range adaptors currently do to greedily become common ranges.

I think we should follow similar rules to eliminate this inconsistency (demo): 

#include <ranges>

constexpr auto r = std::ranges::subrange(std::views::iota(0), 5);
constexpr auto z = std::views::zip(r);
static_assert(r.back() == 4); // ill-formed
static_assert(std::get<0>(z.back()) == 4); // ok

[2023-11-07; Reflector poll]

NAD. "During the concat discussion LEWG decided not to support the corner case of random-access sized but not-common ranges." "If we did want to address such ranges, would be better to enforce commonness for random-access sized ranges by having ranges::end return ranges::begin(r) + ranges::size(r)."

Proposed resolution:

This wording is relative to N4964.

  1. Modify 25.5.3 [view.interface], class template view_interface synopsis, as indicated:

    namespace std::ranges {
  template<class D>
    requires is_class_v<D> && same_as<D, remove_cv_t<D>>
  class view_interface {
    […]
  public:
    […]
    constexpr decltype(auto) back() requires (bidirectional_range<D> && common_range<D>) ||
                                             (random_access_range<D> && sized_range<D>);
    constexpr decltype(auto) back() const
      requires (bidirectional_range<const D> && common_range<const D>) ||
               (random_access_range<const D> && sized_range<const D>);
    […]
  };
}

  2. Modify 25.5.3.2 [view.interface.members] as indicated:

    constexpr decltype(auto) back() requires (bidirectional_range<D> && common_range<D>) ||
                                         (random_access_range<D> && sized_range<D>);
constexpr decltype(auto) back() const
  requires (bidirectional_range<const D> && common_range<const D>) ||
           (random_access_range<const D> && sized_range<const D>);

    -3- Preconditions: !empty() is true.

    -4- Effects: Equivalent to: 

    auto common-arg-end = []<class R>(R& r) {
  if constexpr (common_range<R>) {
    return ranges::end(r);
  } else {
    return ranges::begin(r) + ranges::distance(r);
  }
};
return *ranges::prev(common-arg-endranges::end(derived()));

4006(i). chunk_view::outer-iterator::value_type should provide empty

Section: 25.7.29.4 [range.chunk.outer.value] Status: Tentatively NAD Submitter: Hewill Kang Opened: 2023-11-05 Last modified: 2024-03-11

Priority: Not Prioritized

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Discussion:

chunk_view::outer-iterator::value_type can determine whether it is empty by simply checking whether the chunk_view's remainder_ is 0, which makes it valuable to explicitly provide a noexcept empty member.

Otherwise, the view_interface::empty is synthesized only through the size member when the original sentinel and iterator type model sized_sentinel_for, which seems overkill: 

#include <cassert>
#include <iostream>
#include <sstream>
#include <ranges>

int main() {
  auto ints = std::istringstream{"1 2 3 4 5 6 7 8 9 10"};
  for (auto chunk : std::views::istream<int>(ints) | std::views::chunk(3)) {
    for (auto elem : chunk) {
      assert(!chunk.empty()); // no matching function for call to 'empty()'
      std::cout << elem << " ";
    }
    assert(chunk.empty()); // ditto
    std::cout << "\n";
  }
}

[2024-03-11; Reflector poll]

Set status to Tentatively NAD after reflector poll in November 2023.

"The example shows you could use it if it existed, but not why that would be useful."

"This is a bad idea - the fact that the chunk 'shrinks' as it is iterated over is an implementation detail and not supposed to be observable."

Proposed resolution:

This wording is relative to N4964.

  1. Modify 25.7.29.4 [range.chunk.outer.value] as indicated:

      namespace std::ranges {
    template<view V>
      requires input_range<V>
    struct chunk_view<V>::outer-iterator::value_type : view_interface<value_type> {
    private:
      chunk_view* parent_;                                        // exposition only

      constexpr explicit value_type(chunk_view& parent);          // exposition only

    public:
      constexpr inner-iterator begin() const noexcept;
      constexpr default_sentinel_t end() const noexcept;

      constexpr bool empty() const noexcept;
      constexpr auto size() const
        requires sized_sentinel_for<sentinel_t<V>, iterator_t<V>>;
    };
  }
    […] 
    constexpr default_sentinel_t end() const noexcept;

    -3- Returns: default_sentinel. 

    constexpr bool empty() const noexcept;

    -?- Effects: Equivalent to: return parent_->remainder_ == 0;

4009(i). drop_view::begin const may have 𝒪(n) complexity

Section: 25.7.12.2 [range.drop.view] Status: Tentatively NAD Submitter: Hewill Kang Opened: 2023-11-08 Last modified: 2025-10-22

Priority: 3

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Discussion:

drop_view::begin const is specified to return ranges::next(ranges::begin(base_), count_, ranges::end(base_)), which has 𝒪(n) complexity when base_ is a random-access-sized but non-common range (demo): 

#include <ranges>

int main() {
  const auto s = std::ranges::subrange(std::views::iota(0uz), size_t(-1));
  const auto r = std::ranges::drop_view(s, s.size() - 1);
  const auto b = r.begin(); // time out
}

[2025-10-22; Reflector poll. Status changed: New → Tentatively NAD]

Set priority to 3 after reflector poll, status to Tentatively NAD.

"NAD, it's Returns: not 'Effects: Equivalent to ...', implementations need to implement it to return that while meeting the amortized 𝒪(1) guarantee."

Proposed resolution:

This wording is relative to N4964.

  1. Modify 25.7.12.2 [range.drop.view] as indicated:

    constexpr auto begin()
  requires (!(simple-view<V> &&
              random_access_range<const V> && sized_range<const V>));
constexpr auto begin() const
  requires random_access_range<const V> && sized_range<const V>;

    -3- Returns:

    1. (?.?) — If V models random_access_range and sized_range,

      ranges::begin(base_) + (ranges::distance(base_) - range_difference_t<V>(size()))

    2. (?.?) — Otherwise, ranges::next(ranges::begin(base_), count_, ranges::end(base_)).

    -4- Remarks: In order to provide the amortized constant-time complexity required by the range concept when Vdrop_view does not models random_access_range and sized_rangeforward_range, this functionthe first overload caches the result within the drop_view for use on subsequent calls.

    [Note 1: Without this, applying a reverse_view over a drop_view would have quadratic iteration complexity. — end note] 

    
constexpr auto begin() const
  requires random_access_range<const V> && sized_range<const V>;

    -?- Returns: ranges::begin(base_) + (ranges::distance(base_) - range_difference_t<const V>(size())).

4050(i). Should views::iota(0) | views::take(5) be views::iota(0, 5)?

Section: 25.7.10.1 [range.take.overview], 25.7.10.1 [range.take.overview] Status: Tentatively NAD Submitter: Hewill Kang Opened: 2024-01-28 Last modified: 2025-10-20

Priority: Not Prioritized

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Discussion:

Given that C++20 ranges does not introduce the infinite range notification present in range/v3, this means that views::iota(0) | views::take(5) will currently return a take_view object that does not model sized_range.

However, with the introduction of C++23 repeat_view, its interaction with views::take/drop does have special handling depending on whether it is an infinite range, which causes views::repeat(0) | views::take(5) to return a repeat_view objects that satisfy sized_range.

This inconsistency leads to very different behavior of these two range factories in the case of infinite ranges (demo): 

#include <ranges>

auto take_and_drop = std::views::drop(5)
                   | std::views::take(4)
                   | std::views::drop(3)
                   | std::views::take(2)
                   | std::views::drop(1);

// The type of iota is drop_view<take_view<drop_view<take_view<drop_view<iota_view<int, unreachable_sentinel_t>>>>>>, which is indeed a template bloat.
auto iota = std::views::iota(0) | take_and_drop;
static_assert(std::ranges::sized_range<decltype(iota)>); // failed

// The type of repeat is simply std::ranges::repeat_view<int, long>
std::ranges::sized_range auto repeat = std::views::repeat(0) | take_and_drop; // ok

If we do account for the infinity of repeat_view, then I see no reason not to do it for iota_view, as this is obviously intuitive and can indeed be considered an enhancement.

[2025-10-20; Reflector poll; Status changed: New → Tentatively NAD.]

"This changes meaning of existing C++20 for unclear benefit. This would need a paper."

"Why does iota(0, 10) | take(5) give you iota(0, 5) but iota(0) | take(5) doesn't?"

"IIRC there was opposition to P1739 introducing any kind of special cases in the adaptor objects. What got consensus was only the 'specialisations' that preserve the exact type of the underlying range. Thus iota(0, 10)iota(0, 5) was fine, but iota(0)iota(0, 5) would not have been. I still think that all changes that simplify the return types are helpful, but it would certainly be a breaking change now."

Proposed resolution:

This wording is relative to N4971.

  1. Modify 25.7.10.1 [range.take.overview] as indicated:

    -2- The name views::take denotes a range adaptor object (25.7.2 [range.adaptor.object]). Let E and F be expressions, let T be remove_cvref_t<decltype((E))>, and let D be range_difference_t<decltype((E))>. If decltype((F)) does not model convertible_to<D>, views::take(E, F) is ill-formed. Otherwise, the expression views::take(E, F) is expression-equivalent to:

    1. (2.1) — if T is a specialization of empty_view (25.6.2.2 [range.empty.view]), then ((void)F, decay-copy(E)), except that the evaluations of E and F are indeterminately sequenced.

    2. (2.2) — Otherwise, if T models random_access_range and sized_range and is a specialization of span (23.7.2.2 [views.span]), basic_string_view (27.3 [string.view]), or ranges::subrange (25.5.4 [range.subrange]), then U(ranges::begin(E), ranges::begin(E) + std::min<D>(ranges::distance(E), F)), except that E is evaluated only once, where U is a type determined as follows:

      1. (2.2.1) — if T is a specialization of span, then U is span<typename T::element_type>;

      2. (2.2.2) — otherwise, if T is a specialization of basic_string_view, then U is T;

      3. (2.2.3) — otherwise, T is a specialization of subrange, and U is subrange<iterator_t<T>>;

    3. (2.3) — otherwise, if T is a specialization of iota_view (25.6.4.2 [range.iota.view]) that models random_access_range and sized_range, then iota_view(*ranges::begin(E), *(ranges::begin(E) + std::min<D>(ranges::distance(E), F))), except that E is evaluated only once.

    4. (2.?) — Otherwise, if T is a specialization of iota_view that models random_access_range and same_as<sentinel_t<T>, unreachable_sentinel_t> is true, then views::iota(*ranges::begin(E), *(ranges::begin(E) + static_cast<D>(F))), except that E is evaluated only once.

    5. (2.4) — Otherwise, if T is a specialization of repeat_view (25.6.5.2 [range.repeat.view]):

      1. (2.4.1) — if T models sized_range, then 

          views::repeat(*E.value_, std::min<D>(ranges::distance(E), F))
        except that E is evaluated only once;

      2. (2.4.2) — otherwise, views::repeat(*E.value_, static_cast<D>(F)).

    6. (2.5) — Otherwise, take_view(E, F).

  2. Modify 25.7.12.1 [range.drop.overview] as indicated:

    -2- The name views::drop denotes a range adaptor object (25.7.2 [range.adaptor.object]). Let E and F be expressions, let T be remove_cvref_t<decltype((E))>, and let D be range_difference_t<decltype((E))>. If decltype((F)) does not model convertible_to<D>, views::drop(E, F) is ill-formed. Otherwise, the expression views::drop(E, F) is expression-equivalent to:

    1. (2.1) — if T is a specialization of empty_view (25.6.2.2 [range.empty.view]), then ((void)F, decay-copy(E)), except that the evaluations of E and F are indeterminately sequenced.

    2. (2.2) — Otherwise, if T models random_access_range and sized_range and is

      1. (2.2.1) — a specialization of span (23.7.2.2 [views.span]),

      2. (2.2.2) — a specialization of basic_string_view (27.3 [string.view]),

      3. (2.2.3) — a specialization of iota_view (25.6.4.2 [range.iota.view]), or

      4. (2.2.4) — a specialization of subrange (25.5.4 [range.subrange]) where T::StoreSize is false,

      then U(ranges::begin(E) + std::min<D>(ranges::distance(E), F), ranges::end(E)), except that E is evaluated only once, where U is span<typename T::element_type> if T is a specialization of span and T otherwise.

    3. (2.?) — Otherwise, if T is a specialization of iota_view that models random_access_range and same_as<sentinel_t<T>, unreachable_sentinel_t> is true, then views::iota(*(ranges::begin(E) + static_cast<D>(F))).

    4. (2.3) — Otherwise, if T is a specialization of subrange (25.5.4 [range.subrange]) that models random_access_range and sized_range, then T(ranges::begin(E) + std::min<D>(ranges::distance(E), F), ranges::end(E), to-unsigned-like(ranges::distance(E) - std::min<D>(ranges::distance(E), F))), except that E and F are each evaluated only once.

    5. (2.4) — Otherwise, if T is a specialization of repeat_view (25.6.5.2 [range.repeat.view]):

      1. (2.4.1) — if T models sized_range, then 

          views::repeat(*E.value_, ranges::distance(E) - std::min<D>(ranges::distance(E), F))
        except that E is evaluated only once;

      2. (2.4.2) — otherwise, ((void)F, decay-copy(E)), except that the evaluations of E and F are indeterminately sequenced.

    6. (2.5) — Otherwise, drop_view(E, F).

4095(i). ranges::fold_meow should explicitly spell out the return type

Section: 26.4 [algorithm.syn], 26.6.18 [alg.fold] Status: Tentatively NAD Submitter: Hewill Kang Opened: 2024-05-03 Last modified: 2024-06-24

Priority: Not Prioritized

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Discussion:

Unlike other algorithms, the return types of ranges::fold_meow are specified in terms of auto and see below, and its implementation details depend on the return types of other overloads through decltype(fold_meow(...)).

This makes determining the return type of a certain overload (such as fold_right_last) extremely difficult even for experts, requiring several trips back and forth to different overloads to finally understand what the actual return type is. The situation is even worse for newbies because such a form of specifying the return type makes it impossible for the IDE to deduce the real return type, which is extremely user-unfriendly.

I think that explicitly specifying the return type for these overloads not only greatly improves readability but also offloads the compiler from deducing the return type, which can definitely be considered an improvement.

The proposed resolution does not touch the Effects clause and only changes the function signature to seek minimal changes.

[2024-06-24; Reflector poll: NAD]

Implementations are free to spell this out if desired.

Proposed resolution:

This wording is relative to N4981.

  1. Modify 26.4 [algorithm.syn], header <algorithm> synopsis, as indicated:

    #include <initializer_list>     // see 17.11.2 [initializer.list.syn]

namespace std {
  […]
  namespace ranges {
    […]
    template<input_iterator I, sentinel_for<I> S, class T = iter_value_t<I>,
             indirectly-binary-left-foldable<T, I> F>
      constexpr auto fold_left(I first, S last, T init, F f) ->
        decay_t<invoke_result_t<F&, T, iter_reference_t<I>>>;

    template<input_range R, class T = range_value_t<R>,
             indirectly-binary-left-foldable<T, iterator_t<R>> F>
      constexpr auto fold_left(R&& r, T init, F f) ->
        decay_t<invoke_result_t<F&, T, range_reference_t<R>>>;

    template<input_iterator I, sentinel_for<I> S,
             indirectly-binary-left-foldable<iter_value_t<I>, I> F>
      requires constructible_from<iter_value_t<I>, iter_reference_t<I>>
      constexpr auto fold_left_first(I first, S last, F f) ->
        optional<decay_t<invoke_result_t<F&, iter_value_t<I>, iter_reference_t<I>>>>;

    template<input_range R, indirectly-binary-left-foldable<range_value_t<R>, iterator_t<R>> F>
      requires constructible_from<range_value_t<R>, range_reference_t<R>>
      constexpr auto fold_left_first(R&& r, F f) ->
        optional<decay_t<invoke_result_t<F&, range_value_t<R>, range_reference_t<R>>>>;

    template<bidirectional_iterator I, sentinel_for<I> S, class T = iter_value_t<I>,
             indirectly-binary-right-foldable<T, I> F>
      constexpr auto fold_right(I first, S last, T init, F f) ->
        decay_t<invoke_result_t<F&, iter_reference_t<I>, T>>;

    template<bidirectional_range R, class T = range_value_t<R>,
             indirectly-binary-right-foldable<T, iterator_t<R>> F>
      constexpr auto fold_right(R&& r, T init, F f) ->
        decay_t<invoke_result_t<F&, range_reference_t<R>, T>>;

    template<bidirectional_iterator I, sentinel_for<I> S,
             indirectly-binary-right-foldable<iter_value_t<I>, I> F>
      requires constructible_from<iter_value_t<I>, iter_reference_t<I>>
    constexpr auto fold_right_last(I first, S last, F f) ->
      optional<decay_t<invoke_result_t<F&, iter_reference_t<I>, iter_value_t<I>>>>;

    template<bidirectional_range R,
             indirectly-binary-right-foldable<range_value_t<R>, iterator_t<R>> F>
      requires constructible_from<range_value_t<R>, range_reference_t<R>>
    constexpr auto fold_right_last(R&& r, F f) ->
      optional<decay_t<invoke_result_t<F&, range_reference_t<R>, range_value_t<R>>>>;

    template<class I, class T>
      using fold_left_with_iter_result = in_value_result<I, T>;
    template<class I, class T>
      using fold_left_first_with_iter_result = in_value_result<I, T>;

    template<input_iterator I, sentinel_for<I> S, class T = iter_value_t<I>,
             indirectly-binary-left-foldable<T, I> F>
      constexpr see belowauto fold_left_with_iter(I first, S last, T init, F f) ->
        fold_left_with_iter_result<I, decay_t<invoke_result_t<F&, T, iter_reference_t<I>>>>;

    template<input_range R, class T = range_value_t<R>,
             indirectly-binary-left-foldable<T, iterator_t<R>> F>
      constexpr see belowauto fold_left_with_iter(R&& r, T init, F f) ->
        fold_left_with_iter_result<borrowed_iterator_t<R>,
                                   decay_t<invoke_result_t<F&, T, range_reference_t<R>>>>;

    template<input_iterator I, sentinel_for<I> S,
             indirectly-binary-left-foldable<iter_value_t<I>, I> F>
      requires constructible_from<iter_value_t<I>, iter_reference_t<I>>
      constexpr see belowauto fold_left_first_with_iter(I first, S last, F f) ->
        fold_left_first_with_iter_result<
          I, optional<decay_t<invoke_result_t<F&, iter_value_t<I>, iter_reference_t<I>>>>>;

    template<input_range R,
             indirectly-binary-left-foldable<range_value_t<R>, iterator_t<R>> F>
      requires constructible_from<range_value_t<R>, range_reference_t<R>>
      constexpr see belowauto fold_left_first_with_iter(R&& r, F f) ->
        fold_left_first_with_iter_result<
          borrowed_iterator_t<R>,
          optional<decay_t<invoke_result_t<F&, range_value_t<R>, range_reference_t<R>>>>>;
  }
  […]
}

  2. Modify 26.6.18 [alg.fold] as indicated:

    template<input_iterator I, sentinel_for<I> S, class T = iter_value_t<I>,
         indirectly-binary-left-foldable<T, I> F>
constexpr auto ranges::fold_left(I first, S last, T init, F f) ->
  decay_t<invoke_result_t<F&, T, iter_reference_t<I>>>;

template<input_range R, class T = range_value_t<R>,
         indirectly-binary-left-foldable<T, iterator_t<R>> F>
constexpr auto ranges::fold_left(R&& r, T init, F f) ->
  decay_t<invoke_result_t<F&, T, range_reference_t<R>>>;

    -1- Returns: 

    ranges::fold_left_with_iter(std::move(first), last, std::move(init), f).value

    template<input_iterator I, sentinel_for<I> S,
         indirectly-binary-left-foldable<iter_value_t<I>, I> F>
  requires constructible_from<iter_value_t<I>, iter_reference_t<I>>
  constexpr auto ranges::fold_left_first(I first, S last, F f) ->
    optional<decay_t<invoke_result_t<F&, iter_value_t<I>, iter_reference_t<I>>>>;

template<input_range R, indirectly-binary-left-foldable<range_value_t<R>, iterator_t<R>> F>
  requires constructible_from<range_value_t<R>, range_reference_t<R>>
  constexpr auto ranges::fold_left_first(R&& r, F f) ->
    optional<decay_t<invoke_result_t<F&, range_value_t<R>, range_reference_t<R>>>>;

    -2- Returns: 

    ranges::fold_left_first_with_iter(std::move(first), last, f).value

    template<bidirectional_iterator I, sentinel_for<I> S, class T = iter_value_t<I>,
         indirectly-binary-right-foldable<T, I> F>
  constexpr auto ranges::fold_right(I first, S last, T init, F f) ->
    decay_t<invoke_result_t<F&, iter_reference_t<I>, T>>;

template<bidirectional_range R, class T = range_value_t<R>,
        indirectly-binary-right-foldable<T, iterator_t<R>> F>
  constexpr auto ranges::fold_right(R&& r, T init, F f) ->
    decay_t<invoke_result_t<F&, range_reference_t<R>, T>>;

    -3- Effects: Equivalent to: 

    using U = decay_t<invoke_result_t<F&, iter_reference_t<I>, T>>;
if (first == last)
  return U(std::move(init));
I tail = ranges::next(first, last);
U accum = invoke(f, *--tail, std::move(init));
while (first != tail)
  accum = invoke(f, *--tail, std::move(accum));
return accum;

    template<bidirectional_iterator I, sentinel_for<I> S,
        indirectly-binary-right-foldable<iter_value_t<I>, I> F>
  requires constructible_from<iter_value_t<I>, iter_reference_t<I>>
constexpr auto ranges::fold_right_last(I first, S last, F f) ->
  optional<decay_t<invoke_result_t<F&, iter_reference_t<I>, iter_value_t<I>>>>;

template<bidirectional_range R,
         indirectly-binary-right-foldable<range_value_t<R>, iterator_t<R>> F>
 requires constructible_from<range_value_t<R>, range_reference_t<R>>
constexpr auto ranges::fold_right_last(R&& r, F f) ->
  optional<decay_t<invoke_result_t<F&, range_reference_t<R>, range_value_t<R>>>>;

    -4- Let U be decltype(ranges::fold_right(first, last, iter_value_t<I>(*first), f)).

    -5- Effects: Equivalent to: 

    if (first == last)
  return optional<U>();
I tail = ranges::prev(ranges::next(first, std::move(last)));
return optional<U>(in_place,
  ranges::fold_right(std::move(first), tail, iter_value_t<I>(*tail), std::move(f)));

    template<input_iterator I, sentinel_for<I> S, class T = iter_value_t<I>,
         indirectly-binary-left-foldable<T, I> F>
  constexpr see belowauto ranges::fold_left_with_iter(I first, S last, T init, F f) ->
    fold_left_with_iter_result<I, decay_t<invoke_result_t<F&, T, iter_reference_t<I>>>>;

template<input_range R, class T = range_value_t<R>,
         indirectly-binary-left-foldable<T, iterator_t<R>> F>
  constexpr see belowauto ranges::fold_left_with_iter(R&& r, T init, F f) ->
    fold_left_with_iter_result<borrowed_iterator_t<R>,
                               decay_t<invoke_result_t<F&, T, range_reference_t<R>>>>;

    -6- Let U be decay_t<invoke_result_t<F&, T, iter_reference_t<I>>>.

    -7- Effects: Equivalent to: 

    if (first == last)
  return {std::move(first), U(std::move(init))};
U accum = invoke(f, std::move(init), *first);
for (++first; first != last; ++first)
  accum = invoke(f, std::move(accum), *first);
return {std::move(first), std::move(accum)};

    -8- Remarks: The return type is fold_left_with_iter_result<I, U> for the first overload and fold_left_with_iter_result<borrowed_iterator_t<R>, U> for the second overload. 

    template<input_iterator I, sentinel_for<I> S,
         indirectly-binary-left-foldable<iter_value_t<I>, I> F>
  requires constructible_from<iter_value_t<I>, iter_reference_t<I>>
  constexpr see belowauto ranges::fold_left_first_with_iter(I first, S last, F f) ->
    fold_left_first_with_iter_result<
      I, optional<decay_t<invoke_result_t<F&, iter_value_t<I>, iter_reference_t<I>>>>>;

template<input_range R,
         indirectly-binary-left-foldable<range_value_t<R>, iterator_t<R>> F>
  requires constructible_from<range_value_t<R>, range_reference_t<R>>
  constexpr see belowauto ranges::fold_left_first_with_iter(R&& r, F f) ->
    fold_left_first_with_iter_result<
      borrowed_iterator_t<R>,
      optional<decay_t<invoke_result_t<F&, range_value_t<R>, range_reference_t<R>>>>>;

    -9- Let U be 

    decltype(ranges::fold_left(std::move(first), last, iter_value_t<I>(*first), f))

    -10- Effects: Equivalent to: 

    if (first == last)
  return {std::move(first), optional<U>()};
optional<U> init(in_place, *first);
for (++first; first != last; ++first)
  *init = invoke(f, std::move(*init), *first);
return {std::move(first), std::move(init)};

    -11- Remarks: The return type is fold_left_first_with_iter_result<I, optional<U>> for the first overload and fold_left_first_with_iter_result<borrowed_iterator_t<R>, optional<U>> for the second overload.

4163(i). Can the overload of std::num_get::do_get for bool call the overload for long?

Section: 28.3.4.3.2.3 [facet.num.get.virtuals] Status: Tentatively NAD Submitter: Jiang An Opened: 2024-09-29 Last modified: 2025-02-07

Priority: Not Prioritized

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Discussion:

28.3.4.3.2.3 [facet.num.get.virtuals]/6 currently says:

Effects: If (str.flags()&ios_base::boolalpha) == 0 then input proceeds as it would for a long except that if a value is being stored into val, […]

It is unclear whether an implementation is allowed to call the overload for long in this case. Currently, libc++'s version calls that overload, while libstdc++ and MSVC STL's don't (example).

As the divergence implementation strategies is observable, perhaps we should clarify on this.

[2025-02-07; Reflector poll: NAD]

I think this is just a libc++ bug. The wording says it "proceeds as it would for long", which is not the same as actually making a virtual call to do_get for long. It can either duplicate the code from do_get for long, or make a non-virtual (i.e. qualified) call to num_get::do_get.

Proposed resolution:

4171(i). P2609R3 breaks code that uses views::zip and get<T>

Section: 24.3.6.3 [indirectcallable.indirectinvocable] Status: Tentatively NAD Submitter: S. B. Tam Opened: 2024-11-01 Last modified: 2025-10-23

Priority: Not Prioritized

View all issues with Tentatively NAD status.

Discussion:

The following use of std::ranges::for_each is valid before P2609R3 and invalid after that. 

#include <algorithm>
#include <ranges>
#include <tuple>
using namespace std::ranges;

void f() {
  int a[1];
  auto fun = [](auto t) {
    [[maybe_unused]] auto x = std::get<int&>(t);
  };
  for_each(views::zip(a), fun);
}

The reason is that, P2609R3 requires fun to be invocable with iter_value_t<I>&, which is tuple<int>& when I is zip_view's iterator, and tuple<int>& doesn't support std::get<int&>(t) because there isn't a int& member.

P2609R3 argues that "The actual consequence on user code seems small", but I believe that this code pattern is common enough, and it hurts if we cannot use get<int&>(t) in the lambda body.

Note that for_each doesn't actually call fun with iter_value_t<I>, as can be seen by adding an explicit return type to fun.

Did LWG foresee this impact of P2609R3? Could P2609R3 be reverted to unbreak this code pattern?

[2025-10-23; Reflector poll; Status changed: New → Tentatively NAD.]

The range concepts are over-constrained by design, and indirect_unary_invocable always required invocability with iter_value_t. The P2609 changes enforced this requirement properly for iterators returning proxy references, including zip_iterator.

Proposed resolution:

4184(i). Domain of ranges::cmeow doesn't match ranges::meow

Section: 25.3 [range.access] Status: Tentatively NAD Submitter: Hewill Kang Opened: 2024-12-17 Last modified: 2025-02-07

Priority: Not Prioritized

View all issues with Tentatively NAD status.

Discussion:

ranges::begin/rbegin/data can be used on non-ranges as long as the object has a begin/rbegin/data member, this is also true for their const versions before C++23.

However, in C++23 the const version always applied possibly-const-range to the object, which no longer worked for non-ranges due to this function requiring input_range, which seems to be a breaking change (demo): 

#include <ranges>

struct NotRange {
        int* begin();
  const int* begin() const;
        int* rbegin();
  const int* rbegin() const;
        int* data();
  const int* data() const;
};

int main() {
  NotRange r;

  (void) std::ranges::begin(r);
  (void) std::ranges::rbegin(r);
  (void) std::ranges::data(r);

  // The following works in C++20, fails in C++23
  (void) std::ranges::cbegin(r);
  (void) std::ranges::crbegin(r);
  (void) std::ranges::cdata(r);
}

[2025-02-07; Reflector poll: NAD]

"We don't need to support ranges::cbegin on non-ranges."

"Seems to be very similar to LWG 3913(i) which LWG closed as NAD."

Proposed resolution:

4194(i). atomic<void*> should use generic class template

Section: 32.5.8.5 [atomics.types.pointer] Status: Tentatively NAD Submitter: Gonzalo Brito Opened: 2025-01-16 Last modified: 2025-02-07

Priority: Not Prioritized

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Discussion:

32.5.8.5 [atomics.types.pointer] p1 states (emphasis mine):

There is a partial specialization of the atomic class template for pointers.

which requires atomic<void*> to use the atomic class template for pointers. However, the fetch_add/_sub member functions add a difference_type to a T* which requires a pointer-to-object type (these member functions are constexpr, so trying to support this seems unimplementable).

For atomic_ref, the 32.5.7.5 [atomics.ref.pointer] p1 states (emphasis mine):

There are specializations of the atomic_ref` class template for all pointer-to-object types.

which avoids this issue and applying the same form to 32.5.8.5 [atomics.types.pointer] would make atomic<void*> and atomic_ref<void*> consistent.

Technically this would be a breaking change, but all C++ standard library implementations surveyed are broken, and the proposed fix would make them compliant: see libstdc++, libc++ and MSVC STL errors here. These standard libraries require a pointer-to-object type, atomic<void*> uses the general template. Therefore, no user code seems to be impacted.

[2025-02-07; Reflector poll: NAD]

The fetch_OP members have "Mandates: T is a complete object type." and a note explaining that this means arithmetic on void* is ill-formed. So implementations are expected to use the partial specialization for void* but to reject attempts at arithmetic. They all do this correctly today.

Proposed resolution:

This wording is relative to N5001.

  1. Modify 32.5.8.5 [atomics.types.pointer] as indicated:

    -1- There is a partial specialization of the atomic class template for pointerspointer-to-object types. Specializations of this partial specialization are standard-layout structs. They each have a trivial destructor.

4219(i). std::vector::erase[_if] should be based on ranges remove

Section: 23.3.13.6 [vector.erasure] Status: Tentatively NAD Submitter: Peter Kasting Opened: 2025-03-05 Last modified: 2025-10-21

Priority: Not Prioritized

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Discussion:

C++20 added std::vector::erase[_if]. Per 23.3.13.6 [vector.erasure], these are equivalent to a call to std::remove[_if] followed by an appropriate erase.

This is unfortunate, because std::remove_if is specified (by 26.7.8 [alg.remove]) as invoking its predicate as pred(*i), while std::ranges::remove_if uses the more flexible invoke(pred, invoke(proj, *i)). Disregarding the projection, the latter allows the use of member function pointers as predicates, while the former does not.

I assume the committee intentionally did not change the non-ranges version to use invoke because it caused a backwards-compatibility risk. (If I am mistaken and this was an oversight, perhaps this and other non-ranges algorithms that take predicates should be updated to use invoke() to invoke them.)

If that's true, though, it's perplexing why a new-to-c++20 function like std::vector::erase_if should suffer the same drawback.

[2025-10-21; Reflector poll. Status changed: New → Tentatively NAD.]

"This is a design change and needs a paper."

[2025-10-21; .]

"Paper should discuss whether std::erase_if(c, &T::mf) works on paper, currently works on STL implementations in the field, and whether it should work."

Proposed resolution:

This wording is relative to N5001.

  1. Modify 23.3.13.6 [vector.erasure] as indicated:

    template<class T, class Allocator, class U = T>
  constexpr typename vector<T, Allocator>::size_type
    erase(vector<T, Allocator>& c, const U& value);

    -1- Effects: Equivalent to: 

    auto rit = ranges::remove(c.begin(), c.end(), value);
auto r = distance(it, c.end());
c.erase(r.begin()it, rc.end());
return r.size();

    template<class T, class Allocator, class Predicate>
  constexpr typename vector<T, Allocator>::size_type
    erase_if(vector<T, Allocator>& c, Predicate pred);

    -2- Effects: Equivalent to: 

    auto rit = ranges::remove_if(c.begin(), c.end(), pred);
auto r = distance(it, c.end());
c.erase(r.begin()it, rc.end());
return r.size();

4228(i). Does vector<bool, Allocator> mandate that Allocator::value_type is bool?

Section: 23.3.14.1 [vector.bool.pspc] Status: Tentatively NAD Submitter: Stephan T. Lavavej Opened: 2025-03-18 Last modified: 2025-06-13

Priority: Not Prioritized

View all other issues in [vector.bool.pspc].

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Discussion:

N5008 23.3.14.1 [vector.bool.pspc]/2 says:

Unless described below, all operations have the same requirements and semantics as the primary vector template, except that operations dealing with the bool value type map to bit values in the container storage and allocator_traits::construct (20.2.9.3 [allocator.traits.members]) is not used to construct these values.

23.2.2.5 [container.alloc.reqmts]/5 says:

Mandates: allocator_type::value_type is the same as X::value_type.

Is vector<bool, allocator<int>> forbidden? There's implementation divergence: MSVC's STL enforces the mandate, while libc++ and libstdc++ accept this code, discovered while running libc++'s tests with MSVC's STL.

Preferred resolution: I would be satisfied with resolving this as NAD, with a record that LWG believes that "all operations have the same requirements" means that the Mandate applies. I suppose that an editorial note could also be added to this effect, although I don't believe it's necessary.

Alternate resolution: If LWG believes that the Mandate does not apply, and that vector<bool> should be unique among containers in accepting allocator<Anything>, then I believe that a normative sentence should be added to 23.3.14.1 [vector.bool.pspc]/2, specifically creating an exemption to 23.2.2.5 [container.alloc.reqmts]/5.

[2025-06-13; Reflector poll]

Set status to Tentatively NAD. This is just a bug in some implementations (now fixed in libstdc++).

Proposed resolution:

4229(i). std::ranges::to with union return type

Section: 25.5.7.2 [range.utility.conv.to], 25.5.7.3 [range.utility.conv.adaptors] Status: Tentatively NAD Submitter: Jiang An Opened: 2025-03-20 Last modified: 2025-10-20

Priority: Not Prioritized

View other active issues in [range.utility.conv.to].

View all other issues in [range.utility.conv.to].

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Discussion:

LWG 3847(i) made std::ranges::to require the return type (or the target type for the overload returning range adaptor closure object) to be a cv-unqualified class type. Although the term "class type" in core language specification also covers union types, implementations (libstdc++ and MSVC STL) tend to implement this part of the Mandates only with std::is_class_v, which rejects union types.

E.g. the following program is rejected by libstdc++ and MSVC STL (https://godbolt.org/z/MnsY4Tzen): 

#include <memory>
#include <ranges>
#include <type_traits>
#include <utility>
#include <vector>

template<class T, class A = std::allocator<T>>
union weird_vector {
  std::vector<T, A> vec_;

  constexpr weird_vector() : vec_() {}
  constexpr weird_vector(const weird_vector& other) : vec_(other.vec_) {}
  constexpr weird_vector(weird_vector&& other) noexcept : vec_(std::move(other.vec_)) {}

  template<class U>
    requires (!std::same_as<std::remove_cvref_t<U>, weird_vector>) &&
      (!std::same_as<std::remove_cvref_t<U>, std::vector<T, A>>) &&
      requires(U&& u) { std::vector<T, A>(std::forward<U>(u)); }
  constexpr explicit weird_vector(U&& u) : vec_(std::forward<U>(u)) {}

  template<class T1, class T2, class... Ts>
    requires requires(T1&& t1, T2&& t2, Ts&&... ts) {
      std::vector<T, A>(std::forward<T1>(t1), std::forward<T2>(t2), std::forward<Ts>(ts)...);
    }
  constexpr weird_vector(T1&& t1, T2&& t2, Ts&&... ts)
    : vec_(std::forward<T1>(t1), std::forward<T2>(t2), std::forward<Ts>(ts)...) {}

  constexpr weird_vector& operator=(const weird_vector& other) {
    vec_ = other.vec_;
    return *this;
  }
  constexpr weird_vector& operator=(weird_vector&& other)
    noexcept(std::is_nothrow_move_assignable_v<std::vector<T, A>>) {
    vec_ = std::move(other.vec_);
    return *this;
  }

  constexpr ~weird_vector() {
    vec_.~vector();
  }
};

int main() {
  int arr[]{42, 1729};
  auto v [[maybe_unused]] = std::ranges::to<weird_vector<int>>(arr);
}

Although libc++ currently accepts this example, the acceptance seems to be a bug, because libc++ hasn't implemented the "class" part in the Mandates at all (llvm/llvm-project#132133).

It's unclear whether union types were intended to be accepted. Perhaps we should follow implementations' choices and reject them.

[2025-10-20; Reflector poll; Status changed: New → Tentatively NAD.]

"Those implementations have bugs and should be fixed."

There's no intrinsic reason why unions (with suitable constructors) should be rejected here."

Proposed resolution:

This wording is relative to N5008.

  1. Modify 25.5.7.2 [range.utility.conv.to] as indicated:

    template<class C, input_range R, class... Args> requires (!view<C>)
  constexpr C to(R&& r, Args&&... args);

    -1- Mandates: C is a cv-unqualified non-union class type.

    […]

  2. Modify 25.5.7.3 [range.utility.conv.adaptors] as indicated:

    template<class C, class... Args> requires (!view<C>)
  constexpr auto to(Args&&... args);
template<template<class...> class C, class... Args>
  constexpr auto to(Args&&... args);

    -1- Mandates: For the first overload, C is a cv-unqualified non-union class type.

    […]

4244(i). Whether the spuriously failed comparison applies to compare_exchange_strong is unclear

Section: 32.5.7.2 [atomics.ref.ops], 32.5.8.2 [atomics.types.operations] Status: Tentatively NAD Submitter: jim x Opened: 2025-04-17 Last modified: 2025-10-20

Priority: Not Prioritized

View other active issues in [atomics.ref.ops].

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Discussion:

Both compare_exchange_strong and compare_exchange_weak share the same specified rule

If and only if the comparison is false then, after the atomic operation, the value in expected is replaced by the value read from the value referenced by *ptr during the atomic comparison.

However, there is a remark for the weak version

A weak compare-and-exchange operation may fail spuriously.

That is, even when the contents of memory referred to by expected and ptr are equal, it may return false and store back to expected the same memory contents that were originally there.

However, we don't explicitly say whether the strong version can have the spuriously failed comparison. The status quo is that we can only infer the point from the name, namely, the strong version should have a stronger guarantee than the weak version.

Suggested resolution:

Explicitly specify whether compare_exchange_strong can have the spurious failed comparison.

[2025-10-20; Reflector poll. Status changed: New → Tentatively NAD.]

"The Effects: explain the behaviour, and don't allow for spurious failures."

"The Remarks: are normative and are explicitly adding permission to fail spuriously. Absent such permission, the specification for strong operations is clear and has no spurious failures."

Proposed resolution:

4246(i). Redundant constraint in range_formatter::format

Section: 28.5.7.2 [format.range.formatter] Status: Tentatively NAD Submitter: Hewill Kang Opened: 2025-04-18 Last modified: 2025-06-12

Priority: Not Prioritized

View all other issues in [format.range.formatter].

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Discussion:

Currently, the signature of range_formatter::format is as follows: 

template<ranges::input_range R, class FormatContext>
  requires formattable<ranges::range_reference_t<R>, charT> &&
           same_as<remove_cvref_t<ranges::range_reference_t<R>>, T>
typename FormatContext::iterator
  format(R&& r, FormatContext& ctx) const;

which requires that the reference type of the range parameter must be formattable, and such type must be exactly T after removing the cvref-qualifiers.

However, satisfying the latter always implies satisfying the former, as the range_formatter class already requires that T must be formattable.

There is no need to perform a redundant check here.

[2025-06-12; Reflector poll]

Set status to Tentatively NAD. This is not redundant, it might check that const T is formattable, which is not the same as checking that T is formattable.

Proposed resolution:

This wording is relative to N5008.

  1. Modify 28.5.7.2 [format.range.formatter] as indicated:

    namespace std {
  template<class T, class charT = char>
    requires same_as<remove_cvref_t<T>, T> && formattable<T, charT>
  class range_formatter {
    […]
    template<ranges::input_range R, class FormatContext>
        requires formattable<ranges::range_reference_t<R>, charT> &&
                 same_as<remove_cvref_t<ranges::range_reference_t<R>>, T>
      typename FormatContext::iterator
        format(R&& r, FormatContext& ctx) const;
  };
}
    […] 
    template<ranges::input_range R, class FormatContext>
  requires formattable<ranges::range_reference_t<R>, charT> &&
           same_as<remove_cvref_t<ranges::range_reference_t<R>>, T>
typename FormatContext::iterator
  format(R&& r, FormatContext& ctx) const;

    -11- Effects: Writes the following into ctx.out(), adjusted according to the range-format-spec:

4271(i). Caching range views claim amortized amortized 𝒪(1) runtime complexity for algorithms that are in fact 𝒪(n)

Section: 24.3.1 [iterator.requirements.general], 25.4.3 [range.approximately.sized], 25.4.1 [range.req.general], 25.4.2 [range.range], 25.4.4 [range.sized], 25.7.8.2 [range.filter.view], 25.7.12.2 [range.drop.view], 25.7.13.2 [range.drop.while.view], 25.7.17.2 [range.split.view], 25.7.21.2 [range.reverse.view], 25.7.30.2 [range.slide.view], 25.7.31.2 [range.chunk.by.view] Status: Tentatively NAD Submitter: Andreas Weis Opened: 2025-06-02 Last modified: 2025-10-23

Priority: Not Prioritized

View all other issues in [iterator.requirements.general].

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Discussion:

Currently range views that cache the result of their operation claim an amortized 𝒪(1) worst-case runtime complexity. This is inconsistent with the established practice in algorithm analysis, where the given complexity bound must hold for all possible sequences of operations. Caching is not sufficient to lower the complexity bound here, as the sequence that contains only a single call to the operation will cause a runtime cost linear in the size of the underlying range. Thus all of the caching range operations are in fact 𝒪(n).

Apart from the caching view operations, this also has secondary impacts in other places that rely on the complexity of iterator functions, such as the iterator requirements and functions for computing the size of a range.

It is unclear how desirable it is under these circumstances to continue disallowing other kinds of 𝒪(n) behavior for iterator functions. While caching offers clear benefits in the context of lazy evaluation, it cannot prevent losing the 𝒪(1) complexity guarantee. The proposed changes below therefore do not address the issue that other types of views (such as hypothetical non-caching variants of the affected views) that were previously considered invalid will become valid with these changes.

[2025-10-23; Reflector poll; Status changed: New → Tentatively NAD.]

Relaxing complexity of ranges::begin/ranges::end is design change, and not direction we want to pursue.

The "amortized constant" are not quite right words to describe intended requirements. A rework preserving the intent of current wording would be welcomed.

Proposed resolution:

This wording is relative to N5008.

  1. Modify 24.3.1 [iterator.requirements.general] as indicated:

    -14- All the categories of iterators require only those functions that are realizable for a given category in constant time (amortized)linear time. Therefore, requirement tables and concept definitions for the iterators do not specify complexity.

  2. Modify 25.4.3 [range.approximately.sized] as indicated:

    -1- The approximately_sized_range concept refines range with the requirement that an approximation of the number of elements in the range can be determined in amortized constantlinear time using ranges::reserve_hint.

  3. Modify 25.4.1 [range.req.general] as indicated:

    -2- The range concept requires that ranges::begin and ranges::end return an iterator and a sentinel, respectively. The sized_range concept refines range with the requirement that ranges::size be amortized 𝒪(1n). The view concept specifies requirements on a range type to provide operations with predictable complexity.

  4. Modify 25.4.2 [range.range] as indicated:

    -2- Given an expression t such that decltype((t)) is T&, T models range only if

    1. (2.1) — […]

    2. (2.2) — both ranges::begin(t) and ranges::end(t) are amortized constantlinear time and non-modifying, and

    3. (2.3) — […]

  5. Modify 25.4.4 [range.sized] as indicated:

    -1- The sized_range concept refines approximately_sized_range with the requirement that the number of elements in the range can be determined in amortized constantlinear time using ranges::size. 

    template<class T>
  concept sized_range =
    approximately_sized_range<T> && requires(T& t) { ranges::size(t); };

    -2- Given an lvalue t of type remove_reference_t<T>, T models sized_range only if

    1. (2.1) — ranges::size(t) is amortized 𝒪(1n), does not modify t, and is equal to ranges::distance(ranges::begin(t), ranges::end(t)), and

    2. (2.2) — […]

  6. Modify 25.7.8.2 [range.filter.view] as indicated:

    constexpr iterator begin();

    -3- Preconditions: […]

    -4- Returns: […]

    -5- Remarks: In order to provide the amortized constant time complexity required by the range concept when filter_view models forward_range, thisThis function caches the result within the filter_view for use on subsequent calls.

  7. Modify 25.7.12.2 [range.drop.view] as indicated:

    constexpr auto begin()
  requires (!(simple-view<V> &&
              random_access_range<const V> && sized_range<const V>));
constexpr auto begin() const
  requires random_access_range<const V> && sized_range<const V>;

    -3- Returns: […]

    -4- Remarks: In order to provide the amortized constant-time complexity required by the range concept when drop_view models forward_range, theThe first overload caches the result within the drop_view for use on subsequent calls.

  8. Modify 25.7.13.2 [range.drop.while.view] as indicated:

    constexpr auto begin();

    -3- Preconditions: […]

    -4- Returns: […]

    -5- Remarks: In order to provide the amortized constant-time complexity required by the range concept when drop_while_view models forward_range, theThe first call caches the result within the drop_while_view for use on subsequent calls.

  9. Modify 25.7.17.2 [range.split.view] as indicated:

    constexpr iterator begin();

    -3- Returns: […]

    -4- Remarks: In order to provide the amortized constant time complexity required by the range concept, thisThis function caches the result within the split_view for use on subsequent calls.

  10. Modify 25.7.21.2 [range.reverse.view] as indicated:

    constexpr reverse_iterator<iterator_t<V>> begin();

    -2- Returns: […]

    -3- Remarks: In order to provide the amortized constant time complexity required by the range concept, thisThis function caches the result within the reverse_view for use on subsequent calls.

  11. Modify 25.7.30.2 [range.slide.view] as indicated:

    constexpr auto begin()
  requires (!(simple-view<V> && slide-caches-nothing<const V>));

    -3- Returns: […]

    -4- Remarks: In order to provide the amortized constant-time complexity required by the range concept, thisThis function caches the result within the slide_view for use on subsequent calls when V models slide-caches-first.

    […] 
    constexpr auto end()
  requires (!(simple-view<V> && slide-caches-nothing<const V>));

    -6- Returns: […]

    -7- Remarks: In order to provide the amortized constant-time complexity required by the range concept, thisThis function caches the result within the slide_view for use on subsequent calls when V models slide-caches-first.

  12. Modify 25.7.31.2 [range.chunk.by.view] as indicated:

    constexpr iterator begin();

    -3- Preconditions: […]

    -4- Returns: […]

    -5- Remarks: In order to provide the amortized constant-time complexity required by the range concept, thisThis function caches the result within the chunk_by_view for use on subsequent calls.

4309(i). How are two seq_cst operations ordered in the single total order if these two operations are unsequenced?

Section: 32.5.4 [atomics.order] Status: Tentatively NAD Submitter: jim x Opened: 2025-08-06 Last modified: 2025-10-23

Priority: Not Prioritized

View other active issues in [atomics.order].

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Discussion:

Consider this snippet code: 

std::atomic<int> flag = {0};
std::atomic<int> turn = {0};

if(flag + turn){}

The loads of flag and turn as the operands of + are unsequenced according to [intro.execution] p10.

Except where noted, evaluations of operands of individual operators and of subexpressions of individual expressions are unsequenced.

However, 32.5.4 [atomics.order] p4 says:

There is a single total order S on all memory_order::seq_cst operations, including fences, that satisfies the following constraints.

Then, it says that:

First, if A and B are memory_order::seq_cst operations and A strongly happens before B, then A precedes B in S.

According to the first sentence, the load of flag and the load of turn do have an order in the single total order S since they are both memory_order::seq_cst operations. However, since they are unsequenced, the second sentence does not apply to them. So, what's the order of them in S? Is the order of them in S unspecified?

Suggested Resolution:

We may want to say the order of such operations is indeterminate in the single total order. That is, either A precedes B or B precedes A, but it is unspecified which.

[2025-10-23; Reflector poll; Status changed: New → Tentatively NAD.]

The loads are both done within functions calls, so are at worst indeterminately sequenced. So we already say what the suggested resolution wants.

Proposed resolution:

4321(i). How are evaluations occurring within a store and a load operation ordered where the store synchronized with the load

Section: 32.5.8.2 [atomics.types.operations] Status: Tentatively NAD Submitter: jim x Opened: 2025-08-20 Last modified: 2025-10-23

Priority: Not Prioritized

View other active issues in [atomics.types.operations].

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Discussion:

Consider this example: 

std::atomic<int> v = 0;
// thread 1:
v.store(1, memory_order::release); // #1
// thread 2:
v.load(memory_order::acquire); // #2

Say, #2 reads the value written by #1, #1 synchronizes with #2. According to 6.10.2.2 [intro.races] p7:

An evaluation A happens before an evaluation B (or, equivalently, B happens after A) if either

  1. (7.1) — […]

  2. (7.2) — A synchronizes with B, or

  3. (7.3) — […]

So, #1 happens before B. However, 6.10.1 [intro.execution] p12 says:

For each

  1. (12.1) — function invocation,

  2. (12.2) — […]

  3. (12.3) — […]

F, each evaluation that does not occur within F but is evaluated on the same thread and as part of the same signal handler (if any) is either sequenced before all evaluations that occur within F or sequenced after all evaluations that occur within F;

Because both v.store(...) and v.load(...) are function invocations, and we can think that the member functions comprise some evaluations to form the operation, therefore, how are these evaluations that occur within the store ordered with those within the load?

The rule only says the store synchronizes with the load, hence, the evaluation of the function call expression v.store(...) happens before the evaluation of the function call expression v.load(...), but how about these evaluations occurring within these functions?

A possible resolution might be: The order between all evaluations occurring within a function invocation and another evaluation B is determined by how the evaluation of the function call expression is ordered in relation to the expression B.

For example, if v.store() happens-before E, then all evaluations occurring within the store happen-before E. As well, v.store(...) synchronizes with v.load(...), then all evaluations occurring within v.store(...) synchronize with all evaluations occurring within v.load(...).

[2025-10-23; Reflector poll; Status changed: New → Tentatively NAD.]

The load/store functions invocations participate in happens-before as atomic (indivisible) units.

Proposed resolution:

4337(i). co_await change_coroutine_scheduler(s) requires assignable

Section: 33.13.6.5 [task.promise] Status: Tentatively NAD Submitter: Dietmar Kühl Opened: 2025-08-31 Last modified: 2025-10-27

Priority: Not Prioritized

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Discussion:

Addresses US 256-383

The specification of change_coroutine_scheduler(sched) uses std::exchange to put the scheduler into place (in 33.13.6.5 [task.promise] paragraph 11). The problem is that std::exchange(x, v) expects x to be assignable from v but there is no requirement for scheduler to be assignable.

[2025-10-23; Reflector poll. Status → Tentatively NAD .]

"scheduler requires copyable which requires assignment."

Proposed resolution:

Change the wording in 33.13.6.5 [task.promise] paragraph 11 to avoid the use of std::exchange and transfer the using construction: 

template<class Sch>
  auto await_transform(change_coroutine_scheduler<Sch> sch) noexcept;

-11- Effects: Equivalent to: 

return await_transform(just(exchange(SCHED(*this), scheduler_type(sch.scheduler))), *this);
auto* s{address_of(SCHED(*this))};
auto rc{std::move(*s)};
s->~scheduler_type();
new(s) scheduler_type(std::move(sch));
return std::move(rc);

4362(i). Inconsistent usage of constexpr for inplace_stop_token and inplace_stop_source

Section: 32.3.8 [stoptoken.inplace] Status: Tentatively NAD Submitter: Lewis Baker Opened: 2025-08-28 Last modified: 2025-10-17

Priority: Not Prioritized

View all issues with Tentatively NAD status.

Discussion:

The inplace_stop_source::get_token() member function is declared constexpr, but there are no constexpr member-functions declared on inplace_stop_token, making the utility of being able to call this member function during constant evaluation limited.

Should the member functions of inplace_stop_token also be declared constexpr? i.e. operator==, swap(), stop_possible() and stop_requested().

The operator== and stop_possible() and swap() member functions should be able to be made constexpr trivially as they are just required to compare/modify pointers to the associated stop source.

The stop_requested() member function is specified to be equivalent to calling stop_requested() on the associated inplace_stop_source (if any), which is not currently declared constexpr primarily because its implementation requires synchronisation/atomic operations.

Now that std::atomic operations are now constexpr, it may be possible/appropriate for stop_requested() on both inplace_stop_source and inplace_stop_token to also be declared constexpr.

[2025-10-17; Reflector poll. Status changed: New → Tentatively NAD.]

This allows constant-initializing a token, it's basically a constructor. Other member functions don't need to be constexpr, similar to how std::mutex::lock() doesn't need to be constexpr for constant-init of std::mutex to be useful.

Proposed resolution:

This wording is relative to N5014.

[Drafting note:: This is the minimum proposed wording change. Additionally, consider adding constexpr to the declaration of inplace_stop_token::stop_requested() (in 32.3.8.1 [stoptoken.inplace.general] and 32.3.8.2 [stoptoken.inplace.mem]) and to inplace_stop_source::stop_requested() (in 32.3.9.1 [stopsource.inplace.general] and 32.3.9.3 [stopsource.inplace.mem])]

  1. Modify 32.3.8.1 [stoptoken.inplace.general], class inplace_stop_token synopsis, as indicated:

    namespace std {
  class inplace_stop_token {
  public:
    template<class CallbackFn>
      using callback_type = inplace_stop_callback<CallbackFn>;
    
    constexpr inplace_stop_token() = default;
    constexpr bool operator==(const inplace_stop_token&) const = default;
    
    // 32.3.8.2 [stoptoken.inplace.mem], member functions
    bool stop_requested() const noexcept;
    constexpr bool stop_possible() const noexcept;
    constexpr void swap(inplace_stop_token&) noexcept;
    
  private:
    const inplace_stop_source* stop-source = nullptr; // exposition only
  };
}

  2. Modify 32.3.8.2 [stoptoken.inplace.mem] as indicated:

    [Drafting note:: As a drive-by fix this adds the missing return type bool to the stop_possible() prototype] 

    constexpr void swap(inplace_stop_token& rhs) noexcept;

    -1- Effects: Exchanges the values of stop-source and rhs.stop-source.

    […] 
    constexpr bool stop_possible() const noexcept;

    -4- Returns: stop-source != nullptr.

4363(i). transform_sender comparing types ignoring cv-qualifiers doesn't take into account differences in value category

Section: 33.9.6 [exec.snd.transform] Status: Tentatively NAD Submitter: Lewis Baker Opened: 2025-08-28 Last modified: 2025-10-23

Priority: Not Prioritized

View all issues with Tentatively NAD status.

Discussion:

In 33.9.6 [exec.snd.transform] p1, the specification for transform_sender() states:

Let transformed-sndr be the expression 

dom.transform_sender(std::forward<Sndr>(sndr), env...)

if that expression is well-formed; otherwise, 

default_domain().transform_sender(std::forward<Sndr>(sndr), env...)

Let final-sndr be the expression transformed-sndr if transformed-sndr and sndr have the same type ignoring cv-qualifiers; otherwise, it is the expression transform_sender(dom, transformed-sndr, env...).

However, the use of the phrase "have the same type ignoring cv-qualifiers" asks to compare the types without const or volatile qualifiers, but doesn't take into account differences in value category of the types of these expressions.

For example sndr might have type T&& and transformed-sndr might return a new prvalue of type T.

My interpretation of the current wording is that I should apply the test same_as<remove_cv_t<decltype(sndr)>, remove_cv_t<decltype(transformed-sndr)>>.

However, remove_cv_t does not remove reference-qualifiers from a type Sndr&& (which in the above example, is the type of sndr), and thus would compare as different to a transform-sndr type of Sndr.

I believe the intention is that this should instead use same_as<remove_cvref_t<decltype(sndr)>, remove_cvref_t<decltype(transformed-sndr)>>. For example, the implementation in NVIDIA's stdexec repository uses same_as<decay_t<T>, decay_t<U>> for this check.

The wording should be modified to use a phrase that removes both reference and cv-qualifiers when comparing types.

[2025-10-23; Reflector poll. Status → Tentatively NAD .]

"NAD, expressions never have reference type."

Proposed resolution:

This wording is relative to N5014.

  1. Modify 33.9.6 [exec.snd.transform] as indicated:

    namespace std::execution {
  template<class Domain, sender Sndr, queryable... Env>
    requires (sizeof...(Env) <= 1)
  constexpr sender decltype(auto) transform_sender(Domain dom, Sndr&& sndr, const Env&... env)
    noexcept(see below);
}

    -1- Let transformed-sndr be the expression 

    dom.transform_sender(std::forward<Sndr>(sndr), env...)

    if that expression is well-formed; otherwise, 

    default_domain().transform_sender(std::forward<Sndr>(sndr), env...)

    Let final-sndr be the expression transformed-sndr if transformed-sndr and sndr have the same decayed type ignoring cv-qualifiers; otherwise, it is the expression transform_sender(dom, transformed-sndr, env...).

4371(i). Container adaptor's empty/size should be noexcept

Section: 23.6.3.1 [queue.defn], 23.6.4.1 [priqueue.overview], 23.6.6.2 [stack.defn] Status: Tentatively NAD Submitter: Hewill Kang Opened: 2025-09-09 Last modified: 2025-10-22

Priority: Not Prioritized

View all other issues in [queue.defn].

View all issues with Tentatively NAD status.

Discussion:

C++23 container adaptors flat_meow all have noexcept size/empty members.

However, the size/empty members of other container adaptors are not mark noexcept, even though they behave the same as flat_meow that returning the size/empty of the underlying container.

It makes sense to make them noexcept as well for consistency. Although the standard doesn't explicitly say those two members of the container must not throw, the fact that all standard containers and common third-party containers mark them as unconditionally noexcept implies that it's perfectly reasonable to assume that they never will.

[2025-10-22 Reflector poll. Status changed: New → Tentatively NAD.]

General disagrement with the proposed change. Implicitly changing container requirements. We should fix flat_ adaptors instead.

Proposed resolution:

This wording is relative to N5014.

  1. Modify 23.6.3.1 [queue.defn] as indicated:

    namespace std {
  template<class T, class Container = deque<T>>
  class queue {
  public:
    […]
    constexpr bool              empty() const noexcept { return c.empty(); }
    constexpr size_type         size()  const noexcept { return c.size(); }
    […]
  };
  […]
}

  2. Modify 23.6.4.1 [priqueue.overview] as indicated:

    namespace std {
  template<class T, class Container = vector<T>,
           class Compare = less<typename Container::value_type>>
  class priority_queue {
  public:
    […]
    constexpr bool            empty() const noexcept { return c.empty(); }
    constexpr size_type       size()  const noexcept { return c.size(); }
    […]
  };
  […]
}

  3. Modify 23.6.6.2 [stack.defn] as indicated:

    namespace std {
  template<class T, class Container = deque<T>>
  class stack {
  public:
    […]
    constexpr bool              empty() const noexcept { return c.empty(); }
    constexpr size_type         size()  const noexcept { return c.size(); }
    […]
  };
  […]
}

4391(i). Ambiguities of simd::basic_vec constructor

Section: 29.10.7.2 [simd.ctor] Status: Tentatively NAD Submitter: Hewill Kang Opened: 2025-09-29 Last modified: 2025-10-17

Priority: Not Prioritized

View other active issues in [simd.ctor].

View all other issues in [simd.ctor].

View all issues with Tentatively NAD status.

Discussion:

The broadcasting, generator-based, and range constructors of simd::basic_vec all take a single argument, and their constraints are not mutually exclusive.

This means that when a type satisfies both characteristics, such as a range that can be converted to a value_type, this will lead to ambiguity: 

#include <simd>

struct S {
  operator double() const;       // basic_vec(U&& value)
  
  double operator()(int) const;  // basic_vec(G&& gen)

  double* begin() const;         // basic_vec(R&& r, flags<Flags...> = {});
  double* end() const;
  constexpr static int size() { return 2; }
};

int main() {
  std::simd::vec<double> simd(S{}); // error: call of overloaded 'basic_simd(S)' is ambiguous
}

Do we need more constraints, similar to the one in string_view(R&& r) that requires R not to be convertible to const char*, to make the above work, i.e., only invoke the broadcasting constructor?

[2025-10-17; Reflector poll. Status changed: New → Tentatively NAD.]

Users of such types should do disambiguation explicitly, basic_vec should not guess what they mean.

Proposed resolution:

This wording is relative to N5014.

  1. Modify 29.10.7.2 [simd.ctor] as indicated:

    template<class G> constexpr explicit basic_vec(G&& gen);

    -8- Let Fromi denote the type decltype(gen(integral_constant<simd-size-type, i>())).

    -9- Constraints:

    1. (9.?) — constructible_from<value_type, G> is false.

    2. (9.?) — Fromi satisfies convertible_to<value_type> for all i in the range of [0, size()). In addition, for all i in the range of [0, size()), if Fromi is an arithmetic type, conversion from Fromi to value_type is value-preserving.

    […] 
    template<class R, class... Flags>
  constexpr basic_vec(R&& r, flags<Flags...> = {});
template<class R, class... Flags>
  constexpr basic_vec(R&& r, const mask_type& mask, flags<Flags...> = {});

    -12- Let mask be mask_type(true) for the overload with no mask parameter.

    -13- Constraints:

    1. (13.1) — R models ranges::contiguous_range and ranges::sized_range,

    2. (13.2) — ranges::size(r) is a constant expression, and

    3. (13.3) — ranges::size(r) is equal to size().,

    4. (13.?) — constructible_from<value_type, R> is false, and

    5. (13.?) — r(integral_constant<simd-size-type, 0>()) is not a valid expression.

4404(i). Should span(R&&) CTAD apply P2280?

Section: 23.7.2.2.3 [span.deduct] Status: Tentatively NAD Submitter: Hewill Kang Opened: 2025-10-04 Last modified: 2025-10-20

Priority: Not Prioritized

View all issues with Tentatively NAD status.

Discussion:

Thanks to P2280R4, simd::basic_vec's CTAD can specify template parameters directly through ranges::size: 

basic_vec(R&& r, ...) -> vec<ranges::range_value_t<R>, ranges::size(r)>

However, span with similar CTAD forms do not have this automatic static size optimization applied: 

span(R&&) -> span<remove_reference_t<ranges::range_reference_t<R>>>;

Do we need to do it for span?

Note that the span constructor actually requires R to be a contiguous_range and a sized_range. If it is further required that ranges::size be a constant expression, only raw array, array, span, ranges::empty_view, and ranges::single_view satisfy this requirement. Given that span already has CTAD for raw arrays and arrays, this improvement is not significant, but it still seems worthwhile as a compile-time optimization for certain user-defined types or in some specialized cases (demo): 

#include <array>
#include <ranges>

constexpr std::size_t N = 42;

auto to_span(auto& r) { 
  static_assert(std::ranges::size(r) == N); // ok after P2280
  return std::span(r);
}

std::array<int, N> a;
auto s1 = to_span(a);
static_assert(std::same_as<decltype(s1), std::span<int, N>>);

auto r = std::array<int, N>{} | std::views::as_const; // as_const_view<owning_view<array<int, N>>>
auto s2 = to_span(r);
static_assert(std::same_as<decltype(s2), std::span<const int, N>>); // fire, ok after this PR

[2025-10-20 Reflector poll. Status changed: NAD → Tentatively NAD.]

This is breaking change, and we need a paper with analysis.

Proposed resolution:

This wording is relative to N5014.

  1. Modify 23.7.2.2.1 [span.overview] as indicated:

    namespace std {
  template<class ElementType, size_t Extent = dynamic_extent>
  class span {
    […]
  };
  […]
  template<class R>
    span(R&& r) -> see belowspan<remove_reference_t<ranges::range_reference_t<R>>>;
}

  2. Modify 23.7.2.2.3 [span.deduct] as indicated:

    template<class R>
  span(R&& r) -> see belowspan<remove_reference_t<ranges::range_reference_t<R>>>;

    -2- Constraints: R satisfies ranges::contiguous_range.

    -?- Remarks: Let T denote the type remove_reference_t<ranges::range_reference_t<R>>. The deduced type is equivalent to

    1. (?.1) — span<T, static_cast<size_t>(ranges::size(r))> if R satisfies ranges::sized_range and ranges::size(r) is a constant expression.

    2. (?.2) — span<T> otherwise.