Discussion about this was started under this answer for quite simple question.


This simple code has unexpected overload resolution of constructor for std::basic_string:

#include <string>

int main() {
    std::string s{"some string to test", 2, 3};
    return 0;

Now someone was expecting that this will invoke this constructor:

std::basic_string<CharT,Traits,Allocator>::basic_string - cppreference.com

template< class T > basic_string( const T& t, size_type pos, size_type n, const Allocator& alloc = Allocator() ); (since C++17) (11)
template< class T > constexpr basic_string( const T& t, size_type pos, size_type const Allocator& alloc = Allocator() ); (since C++20) (11)

Rationale is based on section of this c++ standard:


template<class T> constexpr basic_string(const T& t, size_type pos, size_type n, const Allocator& a = Allocator());

5 Constraints: is_­convertible_­v<const T&, basic_­string_­view<charT, traits>> is true.

6 Effects: Creates a variable, sv, as if by basic_­string_­view<charT, traits> sv = t; and then behaves the same as: basic_string(sv.substr(pos, n), a);

Now when this code is processed by cppinsights result is different then expected:

#include <string>

int main()
  std::string s = std::basic_string<char>{std::basic_string<char>("some string to test", std::allocator<char>()), 2, 3};
  return 0;

After collapsing this code to respective type definitions of std::string it becomes this:

#include <string>

int main()
  std::string s = std::string{std::string("some string to test"), 2, 3};
  return 0;

So conversion of string literal to std::string was performed and then constructor in form (3) was used. So undesired extra allocation is performed.

I'm sure this is not fault of tool I did other experiments to confirm that. Here is a godbolt example. Assembly clearly follows this pattern.


To find explanation of this problem I've introduced an error to this code, so error report prints possible overload resolutions. Here is most interesting part of error report:

/opt/compiler-explorer/gcc-trunk-20220104/include/c++/12.0.0/bits/basic_string.h:771:9: note: candidate: 'template<class _Tp, class> std::__cxx11::basic_string<_CharT, _Traits, _Alloc>::basic_string(const _Tp&, size_type, size_type, const _Alloc&) [with <template-parameter-2-2> = _Tp; _CharT = char; _Traits = std::char_traits<char>; _Alloc = std::allocator<char>]'
  771 |         basic_string(const _Tp& __t, size_type __pos, size_type __n,
      |         ^~~~~~~~~~~~
/opt/compiler-explorer/gcc-trunk-20220104/include/c++/12.0.0/bits/basic_string.h:771:9: note:   template argument deduction/substitution failed:
In file included from /opt/compiler-explorer/gcc-trunk-20220104/include/c++/12.0.0/bits/char_traits.h:42,
                 from /opt/compiler-explorer/gcc-trunk-20220104/include/c++/12.0.0/string:40,
                 from <source>:1:
/opt/compiler-explorer/gcc-trunk-20220104/include/c++/12.0.0/type_traits: In substitution of 'template<bool _Cond, class _Tp> using enable_if_t = typename std::enable_if::type [with bool _Cond = false; _Tp = void]':
/opt/compiler-explorer/gcc-trunk-20220104/include/c++/12.0.0/bits/basic_string.h:156:8:   required by substitution of 'template<class _CharT, class _Traits, class _Alloc> template<class _Tp, class _Res> using _If_sv = std::enable_if_t<std::__and_<std::is_convertible<const _Tp&, std::basic_string_view<_CharT, _Traits> >, std::__not_<std::is_convertible<const _Tp*, const std::__cxx11::basic_string<_CharT, _Traits, _Alloc>*> >, std::__not_<std::is_convertible<const _Tp&, const _CharT*> > >::value, _Res> [with _Tp = char [20]; _Res = void; _CharT = char; _Traits = std::char_traits<char>; _Alloc = std::allocator<char>]'
/opt/compiler-explorer/gcc-trunk-20220104/include/c++/12.0.0/bits/basic_string.h:769:30:   required from here
/opt/compiler-explorer/gcc-trunk-20220104/include/c++/12.0.0/type_traits:2614:11: error: no type named 'type' in 'struct std::enable_if<false, void>'
 2614 |     using enable_if_t = typename enable_if<_Cond, _Tp>::type;
      |           ^~~~~~~~~~~

So overload (11) has been rejected by SFINAE.

Related standard library code looks like this: Overload (11) of std::basic_string constructor:

    template<typename _Tp, typename = _If_sv<_Tp, void>>
    basic_string(const _Tp& __t, size_type __pos, size_type __n,
             const _Alloc& __a = _Alloc())
    : basic_string(_S_to_string_view(__t).substr(__pos, __n), __a) { }

And here is implementation of _If_sv:

    template<typename _Tp, typename _Res>
    using _If_sv = enable_if_t<
      __and_<is_convertible<const _Tp&, __sv_type>,
         __not_<is_convertible<const _Tp*, const basic_string*>>,
         __not_<is_convertible<const _Tp&, const _CharT*>>>::value,

So last part of this condition: __not_<is_convertible<const _Tp&, const _CharT*>>>::value is a problem since clearly char array (string literal) is convertible to pointer to characters.


Why does the implementation of _If_sv look like this? What is the rationale of having this extra condition which is not mentioned in the standard?

If I understand overload resolution correctly, this extra condition is obsolete, since when first argument is std::string overloads (3) has priority over overload (11) as exact match of non template function. On the other hand if an argument is something other than std::string and it is convertible to std::string_view then template overload (11) should win and extra allocation is avoided.

Is this a bug in the implementation of the standard library or did I miss something?

Why are these extra SFINAE conditions needed?

Bonus question

Is there a nice way to write a test which detects this issue? Some ways to verify that a proper overload has been selected without modifying tested code (in this case std::basic_string)?

  • 1
    Interestingly, both libstdc++ and libc++ do this... Jan 5, 2022 at 10:47
  • Must you use a braced-init-list?
    – jxh
    Jan 5, 2022 at 11:33
  • @jxh Braces or parenthesis will not change anything here.
    – Marek R
    Jan 5, 2022 at 11:56
  • 3
    The SFINAE rules were introduced in library issue2946
    – BoP
    Jan 5, 2022 at 12:20
  • 8
    This is a libstdc++ bug. Reported #103919, already fixed on trunk.
    – Barry
    Jan 5, 2022 at 16:29

2 Answers 2


In C++14 your code always created a new std::string temporary, there was no constructor taking const char* or std::string_view that could be used.

In C++17 your code should create a string_view and avoid the temporary. GCC's implementation is overconstrained and so still behaves like C++14, creating the extra temporary.

Why implementation of _If_sv looks like this? What is rationale to have this extra conditions not mentioned in standard?

It has three conditions, and two of them are in the standard. And the third has a reason too.

The _If_sv helper implements the constraints needed by every basic_string function that takes a basic_string_view except the one constructor you're asking about. That one has a slightly weaker constraint, allowing const CharT* pointers to be passed to it and converted to a string view. Because libstdc++ uses the same _If_sv helper for that constructor, it doesn't work as the standard requires. I've fixed that now (PR 103919).

Of the three conditions in _If_sv:

  • The "convertible to string_view one is required by the standard.
  • The "not convertible to const CharT*" one is required by the standard for all functions except the constructor you're asking about.
  • The final condition, the "not convertible to basic_string" one, was added to fix a regression I discovered, caused by the constraints specified by the standard. That problem is described below, for people who don't like clicking on links to leave SO.

If I understood overload resolution correctly this extra conditions are obsolete,


since when first argument is std::string overloads (3) has priority over overload (11) as exact match of non template function.

Yes, if it's a std::string then the other constructor would be chosen anyway. The "not convertible to std::string" constraint is redundant here, because another constructor would be chosen anyway. It's harmless, but redundant. But what if the argument is not std::string, but is something derived from std::string? Consider:

class tstring : public std::string
  tstring() : std::string() {}
  tstring(tstring&& s) : std::string(std::move(s)) {}

In C++14 this uses the basic_string(basic_string&&) move constructor, as intended. In C++17 it uses basic_string(const T&, const Alloc& = Alloc()) because the tstring&& argument is convertible to string_view. That means we make a copy of s instead of moving it as intended.

The additional constraint that T is not convertible to std::string removes the new string_view overload from consideration here, so the move constructor is used again. So that extra constraint is harmless for cases where the constructor wouldn't be chosen anyway, but useful for cases where the new basic_string(const T&, const Alloc&) constructor would be chosen but shouldn't be.


Maybe I'm wrong, but it seems that last part:

__not_<is_convertible<const _Tp&, const _CharT*>>>::value

is added to _If_sv for preventing ambiguity between these 2 constructors:

constexpr basic_string( const CharT* s,
                        const Allocator& alloc = Allocator() ); //(5)

template< class T >
explicit basic_string( const T& t,
                       const Allocator& alloc = Allocator() ); //(10)

(10) should be selected if T is convertible to string_view. But (10) is explicit so this problem should be selected without {}. I don't think this check is needed in _If_sv. They probably have used same _If_sv for both overloads (10) and (11) that you mentioned, so both are working incorrectly now.

  • as I point out in overload resolution none template functions with exact type match have priority over template versions. If you have some experiment or document proving that I'm wrong in this point then it would be nice to see it.
    – Marek R
    Jan 5, 2022 at 12:11
  • @MarekR from this answer, I meant that you are probably right. That additional check in _Is_sv is wrong and it is probably a bug.
    – Afshin
    Jan 5, 2022 at 12:16
  • 1
    To be clear, the standard mandates the 'additional' check for (10) so it's necessary and correct there.
    – ildjarn
    Jan 5, 2022 at 12:54

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