11

From libstdc++ <concepts> header:

  namespace ranges
  {
    namespace __cust_swap
    {
      template<typename _Tp> void swap(_Tp&, _Tp&) = delete;

From MS-STL <concepts> header:

namespace ranges {
    namespace _Swap {
        template <class _Ty>
        void swap(_Ty&, _Ty&) = delete;

I've never encountered = delete; outside the context where you want to prohibit the call to copy/move assignment/ctor.

I was curious if this was necessary, so I've commented out the = delete; part from the library like this:

// template<typename _Tp> void swap(_Tp&, _Tp&) = delete;

to see if the following test case compiles.

#include <concepts>
#include <iostream>

struct dummy {
    friend void swap(dummy& a, dummy& b) {
        std::cout << "ADL" << std::endl;
    }
};

int main()
{
    int a{};
    int b{};
    dummy c{};
    dummy d{};
    std::ranges::swap(a, b);
    std::ranges::swap(c, d); // Ok. Prints "ADL" on console.
}

Not only it compiles, it seems to behave well by calling user defined swap for struct dummy. So I'm wondering,

  1. What does template<typename _Tp> void swap(_Tp&, _Tp&) = delete; exactly do in this context?
  2. On what occasion does this break without template<typename _Tp> void swap(_Tp&, _Tp&) = delete;?
2
  • 5
    What does template<typename _Tp> void swap(_Tp&, _Tp&) = delete; exactly do in this context? I've found this :/ – Language Lawyer Aug 23 '20 at 1:07
  • 1
    Note that the =delete idiom can also be used to hide a non-virtual inherited function. (That's not what is happening here, but it's another use beyond deleting any implicitly-defined constructor or assignment operator.) – cdhowie Aug 23 '20 at 1:10
8

TL;DR: It's there to keep from calling std::swap.

This is actually an explicit requirement of the ranges::swap customization point:

S is (void)swap(E1, E2) if E1 or E2 has class or enumeration type ([basic.compound]) and that expression is valid, with overload resolution performed in a context that includes this definition:

 template<class T>
  void swap(T&, T&) = delete;

So what does this do? To understand the point of this, we have to remember that the ranges namespace is actually the std::ranges namespace. That's important because a lot of stuff lives in the std namespace. Including this, declared in <utility>:

template< class T >
void swap( T& a, T& b );

There's probably a constexpr and noexcept on there somewhere, but that's not relevant for our needs.

std::ranges::swap, as a customization point, has a specific way it wants you to customize it. It wants you to provide a swap function that can be found via argument-dependent lookup. Which means that ranges::swap is going to find your swap function by doing this: swap(E1, E2).

That's fine, except for one problem: std::swap exists. In the pre-C++20 days, one valid way of making a type swappable was to provide a specialization for the std::swap template. So if you called std::swap directly to swap something, your specializations would be picked up and used.

ranges::swap does not want to use those. It has one customization mechanism, and it wants you to very definitely use that mechanism, not template specialization of std::swap.

However, because std::ranges::swap lives in the std namespace, unqualified calls to swap(E1, E2) can find std::swap. To avoid finding and using this overload, it poisons the overload by making visible a version that is = deleted. So if you don't provide an ADL-visible swap for your type, you get a hard error. A proper customization is also required to be more specialized (or more constrained) than the std::swap version, so that it can be considered a better overload match.

Note that ranges::begin/end and similar functions have similar wording to shut down similar problems with similarly named std:: functions.

3
  • 2
    Lookup inside the CPO is never affected by using-declarations at the point of use. – T.C. Aug 23 '20 at 4:28
  • @T.C.: I made a test program to investigate this, but I didn't actually see what happened if I took out the using declaration. So you're right; the reason it's there is still similar to what I said, but different. It's to keep from calling std::swap directly because std::swap is in the same namespace as std::ranges::swap and is therefore visible to it. I've edited the answer to correct it. – Nicol Bolas Aug 23 '20 at 13:48
  • The implementation could perform the lookup from somewhere (ugly) outside of std; it’s more ::swap that’s being avoided. – Davis Herring Aug 23 '20 at 14:56
7

There were two motivations for the poison pill overloads, most of which don't actually exist anymore but we still have them anyway.

swap / iter_swap

As described in P0370:

The Ranges TS has another customization point problem that N4381 does not cover: an implementation of the Ranges TS needs to co-exist alongside an implementation of the standard library. There’s little benefit to providing customization points with strong semantic constraints if ADL can result in calls to the customization points of the same name in namespace std. For example, consider the definition of the single-type Swappable concept:

namespace std { namespace experimental { namespace ranges { inline namespace v1 {
  template <class T>
  concept bool Swappable() {
    return requires(T&& t, T&& u) {
      (void)swap(std::forward<T>(t), std::forward<T>(u));
    };
  }
}}}}

unqualified name lookup for the name swap could find the unconstrained swap in namespace std either directly - it’s only a couple of hops up the namespace hierarchy - or via ADL if std is an associated namespace of T or U. If std::swap is unconstrained, the concept is “satisfied” for all types, and effectively useless. The Ranges TS deals with this problem by requiring changes to std::swap, a practice which has historically been forbidden for TSs. Applying similar constraints to all of the customization points defined in the TS by modifying the definitions in namespace std is an unsatisfactory solution, if not an altogether untenable.

The Range TS was built on C++14, where std::swap was unconstrained (std::swap didn't become constrained until P0185 was adopted for C++17), so it was important to make sure that Swappable didn't just trivially resolve to true for any type that had std as an associated namespace.

But now std::swap is constrained, so there's no need for the swap poison pill.

However, std::iter_swap is still unconstrained, so there is a need for that poison pill. However, that one could easily become constrained and then we would again have no need for a poison pill.

begin / end

As described in P0970:

For the sake of compatibility with std::begin and ease of migration, std::experimental::ranges::begin accepted rvalues and treated them the same as const lvalues. This behavior was deprecated because it is fundamentally unsound: any iterator returned by such an overload is highly likely to dangle after the full expression that contained the invocation ofbegin

Another problem, and one that until recently seemed unrelated to the design of begin, was that algorithms that return iterators will wrap those iterators in std::experimental::ranges::dangling<>if the range passed to them is an rvalue. This ignores the fact that for some range types — P0789’s subrange<>, in particular — the iterator’s validity does not depend on the range’s lifetime at all. In the case where a prvalue subrange<> is passed to an algorithm, returning a wrapped iterator is totally unnecessary.

[...]

We recognized that by removing the deprecated default support for rvalues from the range access customization points, we made design space for range authors to opt-in to this behavior for their range types, thereby communicating to the algorithms that an iterator can safely outlive its range type. This eliminates the need for dangling when passing an rvalue subrange, an important usage scenario.

The paper went on to propose a design for safe invocation of begin on rvalues as a non-member function that takes, specifically, an rvalue. The existence of the:

template <class T>
void begin(T&&) = delete;

overload:

gives std2::begin the property that, for some rvalue expression E of type T, the expression std2::begin(E) will not compile unless there is a free function begin findable by ADL that specifically accepts rvalues of type T, and that overload is prefered by partial ordering over the general void begin(T&&) “poison pill” overload.

For example, this would allow us to properly reject invoking ranges::begin on an rvalue of type std::vector<int>, even though the non-member std::begin(const C&) would be found by ADL.

But this paper also says:

The author believed that to fix the problem with subrange and dangling would require the addition of a new trait to give the authors of range types a way to say whether its iterators can safely outlive the range. That felt like a hack, and that feeling was reinforced by the author’s inability to pick a name for such a trait that was sufficiently succint and clear.

Since then, this functionality has become checked by a trait - which was first called enable_safe_range (P1858) and is now called enable_borrowed_range (LWG3379). So again, the poison pill here is no longer necessary.

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