OpenGrok

    1.1  mrg // <experimental/internet> -*- C++ -*-
    1.1  mrg
1.1.1.6  mrg // Copyright (C) 2015-2024 Free Software Foundation, Inc.
    1.1  mrg //
    1.1  mrg // This file is part of the GNU ISO C++ Library.  This library is free
    1.1  mrg // software; you can redistribute it and/or modify it under the
    1.1  mrg // terms of the GNU General Public License as published by the
    1.1  mrg // Free Software Foundation; either version 3, or (at your option)
    1.1  mrg // any later version.
    1.1  mrg
    1.1  mrg // This library is distributed in the hope that it will be useful,
    1.1  mrg // but WITHOUT ANY WARRANTY; without even the implied warranty of
    1.1  mrg // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    1.1  mrg // GNU General Public License for more details.
    1.1  mrg
    1.1  mrg // Under Section 7 of GPL version 3, you are granted additional
    1.1  mrg // permissions described in the GCC Runtime Library Exception, version
    1.1  mrg // 3.1, as published by the Free Software Foundation.
    1.1  mrg
    1.1  mrg // You should have received a copy of the GNU General Public License and
    1.1  mrg // a copy of the GCC Runtime Library Exception along with this program;
    1.1  mrg // see the files COPYING3 and COPYING.RUNTIME respectively.  If not, see
    1.1  mrg // <http://www.gnu.org/licenses/>.
    1.1  mrg
    1.1  mrg /** @file experimental/internet
    1.1  mrg  *  This is a TS C++ Library header.
1.1.1.2  mrg  *  @ingroup networking-ts
    1.1  mrg  */
    1.1  mrg
    1.1  mrg #ifndef _GLIBCXX_EXPERIMENTAL_INTERNET
    1.1  mrg #define _GLIBCXX_EXPERIMENTAL_INTERNET
    1.1  mrg
    1.1  mrg #pragma GCC system_header
    1.1  mrg
1.1.1.6  mrg #include <bits/requires_hosted.h> // experimental is currently omitted
1.1.1.6  mrg
    1.1  mrg #if __cplusplus >= 201402L
    1.1  mrg
    1.1  mrg #include <experimental/netfwd>
    1.1  mrg #include <experimental/io_context>
    1.1  mrg #include <experimental/bits/net.h>
    1.1  mrg #include <array>
    1.1  mrg #include <forward_list>
    1.1  mrg #include <sstream>
    1.1  mrg #include <cstdint>
    1.1  mrg #include <experimental/string_view>
1.1.1.6  mrg #include <bits/charconv.h>
    1.1  mrg #ifdef _GLIBCXX_HAVE_UNISTD_H
    1.1  mrg # include <unistd.h>
    1.1  mrg #endif
    1.1  mrg #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H
    1.1  mrg # include <sys/socket.h>	// AF_INET, AF_INET6, SOCK_DGRAM, SOCK_STREAM
    1.1  mrg #endif
    1.1  mrg #ifdef _GLIBCXX_HAVE_ARPA_INET_H
    1.1  mrg # include <arpa/inet.h>		// inet_ntop
    1.1  mrg #endif
    1.1  mrg #ifdef _GLIBCXX_HAVE_NETINET_IN_H
1.1.1.4  mrg # include <netinet/in.h>	// IPPROTO_IP, IPPROTO_IPV6, in_addr, in6_addr
    1.1  mrg #endif
    1.1  mrg #ifdef _GLIBCXX_HAVE_NETINET_TCP_H
    1.1  mrg # include <netinet/tcp.h>	// TCP_NODELAY
    1.1  mrg #endif
    1.1  mrg #ifdef _GLIBCXX_HAVE_NETDB_H
    1.1  mrg # include <netdb.h>		// getaddrinfo etc.
    1.1  mrg #endif
    1.1  mrg
1.1.1.4  mrg #if defined _WIN32 && __has_include(<ws2tcpip.h>)
1.1.1.4  mrg # include <ws2tcpip.h>
1.1.1.4  mrg #endif
1.1.1.4  mrg
    1.1  mrg namespace std _GLIBCXX_VISIBILITY(default)
    1.1  mrg {
    1.1  mrg _GLIBCXX_BEGIN_NAMESPACE_VERSION
    1.1  mrg namespace experimental
    1.1  mrg {
    1.1  mrg namespace net
    1.1  mrg {
    1.1  mrg inline namespace v1
    1.1  mrg {
    1.1  mrg namespace ip
    1.1  mrg {
1.1.1.2  mrg   /** @addtogroup networking-ts
1.1.1.2  mrg    *  @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   /** Error codes for resolver errors.
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   enum class resolver_errc : int {
1.1.1.4  mrg #ifdef _GLIBCXX_HAVE_NETDB_H
    1.1  mrg     host_not_found = EAI_NONAME,
    1.1  mrg     host_not_found_try_again = EAI_AGAIN,
    1.1  mrg     service_not_found = EAI_SERVICE
1.1.1.4  mrg     // N.B. POSIX defines additional errors that have no enumerator here:
1.1.1.4  mrg     // EAI_BADFLAGS, EAI_FAIL, EAI_FAMILY, EAI_MEMORY, EAI_SOCKTYPE, EAI_SYSTEM
1.1.1.4  mrg     // Some C libraries define additional errors:
1.1.1.4  mrg     // EAI_BADHINTS, EAI_OVERFLOW, EAI_PROTOCOL
1.1.1.4  mrg     // Some C libraries define additional (obsolete?) errors:
1.1.1.4  mrg     // EAI_ADDRFAMILY, EAI_NODATA
1.1.1.4  mrg #endif
    1.1  mrg   };
    1.1  mrg
    1.1  mrg   /// Error category for resolver errors.
    1.1  mrg   inline const error_category& resolver_category() noexcept // TODO non-inline
    1.1  mrg   {
    1.1  mrg     struct __cat : error_category
    1.1  mrg     {
    1.1  mrg       const char* name() const noexcept { return "resolver"; }
1.1.1.4  mrg       std::string message(int __e) const {
1.1.1.4  mrg #ifdef _GLIBCXX_HAVE_NETDB_H
1.1.1.4  mrg 	  return ::gai_strerror(__e);
1.1.1.4  mrg #else
1.1.1.4  mrg 	  return "name resolution requires <netdb.h>";
1.1.1.4  mrg #endif
1.1.1.4  mrg       }
    1.1  mrg       virtual void __message(int) { } // TODO dual ABI XXX
    1.1  mrg     };
    1.1  mrg     static __cat __c;
    1.1  mrg     return __c;
    1.1  mrg   }
    1.1  mrg
1.1.1.3  mrg   inline error_code make_error_code(resolver_errc __e) noexcept
    1.1  mrg   { return error_code(static_cast<int>(__e), resolver_category()); }
    1.1  mrg
1.1.1.3  mrg   inline error_condition make_error_condition(resolver_errc __e) noexcept
    1.1  mrg   { return error_condition(static_cast<int>(__e), resolver_category()); }
    1.1  mrg
1.1.1.4  mrg   /// @cond undocumented
1.1.1.4  mrg   inline error_code
1.1.1.4  mrg   __make_resolver_error_code(int __ai_err,
1.1.1.4  mrg 			     [[__maybe_unused__]] int __sys_err) noexcept
1.1.1.4  mrg   {
1.1.1.4  mrg #ifdef EAI_SYSTEM
1.1.1.4  mrg     if (__builtin_expect(__ai_err == EAI_SYSTEM, 0))
1.1.1.4  mrg       return error_code(__sys_err, std::generic_category());
    1.1  mrg #endif
1.1.1.4  mrg     return error_code(__ai_err, resolver_category());
1.1.1.4  mrg   }
1.1.1.4  mrg   /// @endcond
1.1.1.4  mrg
1.1.1.4  mrg   /// @}
    1.1  mrg
1.1.1.4  mrg   using port_type = uint_least16_t;	///< Type used for port numbers.
1.1.1.4  mrg   using scope_id_type = uint_least32_t;	///< Type used for IPv6 scope IDs.
    1.1  mrg
    1.1  mrg   /// Convenience alias for constraining allocators for strings.
    1.1  mrg   template<typename _Alloc>
    1.1  mrg     using __string_with
    1.1  mrg       = enable_if_t<std::is_same<typename _Alloc::value_type, char>::value,
    1.1  mrg 		    std::basic_string<char, std::char_traits<char>, _Alloc>>;
    1.1  mrg
1.1.1.4  mrg   constexpr errc
1.1.1.4  mrg   __unsupported_err() noexcept
1.1.1.4  mrg   {
1.1.1.4  mrg #if defined EAFNOSUPPORT
1.1.1.4  mrg     return std::errc::address_family_not_supported;
1.1.1.4  mrg #else
1.1.1.4  mrg     return std::errc::operation_not_supported;
1.1.1.4  mrg #endif
1.1.1.4  mrg   }
1.1.1.4  mrg
    1.1  mrg   /** Tag indicating conversion between IPv4 and IPv4-mapped IPv6 addresses.
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   struct v4_mapped_t {};
    1.1  mrg   constexpr v4_mapped_t v4_mapped;
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /// An IPv4 address.
    1.1  mrg   class address_v4
    1.1  mrg   {
    1.1  mrg   public:
    1.1  mrg     // types:
1.1.1.4  mrg     using uint_type = uint_least32_t;
    1.1  mrg
    1.1  mrg     struct bytes_type : array<unsigned char, 4>
    1.1  mrg     {
    1.1  mrg       template<typename... _Tp>
    1.1  mrg 	explicit constexpr
    1.1  mrg 	bytes_type(_Tp... __tp)
    1.1  mrg 	: array<unsigned char, 4>{{static_cast<unsigned char>(__tp)...}}
    1.1  mrg 	{
    1.1  mrg #if UCHAR_MAX > 0xFF
    1.1  mrg 	  for (auto __b : *this)
    1.1  mrg 	    if (__b > 0xFF)
    1.1  mrg 	      __throw_out_of_range("invalid address_v4::bytes_type value");
    1.1  mrg #endif
    1.1  mrg 	}
    1.1  mrg     };
    1.1  mrg
    1.1  mrg     // constructors:
    1.1  mrg     constexpr address_v4() noexcept : _M_addr(0) { }
    1.1  mrg
    1.1  mrg     constexpr address_v4(const address_v4& a) noexcept = default;
    1.1  mrg
    1.1  mrg     constexpr
    1.1  mrg     address_v4(const bytes_type& __b)
1.1.1.6  mrg #if __has_builtin(__builtin_bit_cast)
1.1.1.6  mrg     : _M_addr(__builtin_bit_cast(uint_type, __b))
1.1.1.6  mrg #else
1.1.1.6  mrg     : _M_addr(_S_hton_32((__b[0] << 24) | (__b[1] << 16)
1.1.1.6  mrg 			   | (__b[2] << 8) | __b[3]))
1.1.1.6  mrg #endif
    1.1  mrg     { }
    1.1  mrg
    1.1  mrg     explicit constexpr
    1.1  mrg     address_v4(uint_type __val) : _M_addr(_S_hton_32(__val))
    1.1  mrg     {
    1.1  mrg #if UINT_LEAST32_MAX > 0xFFFFFFFF
    1.1  mrg       if (__val > 0xFFFFFFFF)
    1.1  mrg 	__throw_out_of_range("invalid address_v4::uint_type value");
    1.1  mrg #endif
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     // assignment:
    1.1  mrg     address_v4& operator=(const address_v4& a) noexcept = default;
    1.1  mrg
    1.1  mrg     // members:
    1.1  mrg     constexpr bool is_unspecified() const noexcept { return to_uint() == 0; }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_loopback() const noexcept
    1.1  mrg     { return (to_uint() & 0xFF000000) == 0x7F000000; }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_multicast() const noexcept
    1.1  mrg     { return (to_uint() & 0xF0000000) == 0xE0000000; }
    1.1  mrg
    1.1  mrg     constexpr bytes_type
    1.1  mrg     to_bytes() const noexcept
    1.1  mrg     {
1.1.1.6  mrg #if __has_builtin(__builtin_bit_cast)
1.1.1.6  mrg       return __builtin_bit_cast(bytes_type, _M_addr);
1.1.1.6  mrg #else
1.1.1.6  mrg       auto __host = to_uint();
    1.1  mrg       return bytes_type{
1.1.1.6  mrg 	(__host >> 24) & 0xFF,
1.1.1.6  mrg 	(__host >> 16) & 0xFF,
1.1.1.6  mrg 	(__host >> 8) & 0xFF,
1.1.1.6  mrg 	__host & 0xFF
    1.1  mrg       };
1.1.1.6  mrg #endif
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     constexpr uint_type
    1.1  mrg     to_uint() const noexcept { return _S_ntoh_32(_M_addr); }
    1.1  mrg
    1.1  mrg     template<typename _Allocator = allocator<char>>
    1.1  mrg       __string_with<_Allocator>
    1.1  mrg       to_string(const _Allocator& __a = _Allocator()) const
    1.1  mrg       {
1.1.1.6  mrg 	auto __write = [__addr = to_uint()](char* __p, size_t) {
1.1.1.6  mrg 	  auto __to_chars = [](char* __p, uint8_t __v) {
1.1.1.6  mrg 	    unsigned __n = __v >= 100u ? 3 : __v >= 10u ? 2 : 1;
1.1.1.6  mrg 	    std::__detail::__to_chars_10_impl(__p, __n, __v);
1.1.1.6  mrg 	    return __p + __n;
1.1.1.6  mrg 	  };
1.1.1.6  mrg 	  const auto __begin = __p;
1.1.1.6  mrg 	  __p = __to_chars(__p, uint8_t(__addr >> 24));
1.1.1.6  mrg 	  for (int __i = 2; __i >= 0; __i--) {
1.1.1.6  mrg 	    *__p++ = '.';
1.1.1.6  mrg 	    __p = __to_chars(__p, uint8_t(__addr >> (__i * 8)));
1.1.1.6  mrg 	  }
1.1.1.6  mrg 	  return __p - __begin;
1.1.1.6  mrg 	};
    1.1  mrg 	__string_with<_Allocator> __str(__a);
1.1.1.6  mrg #if __cpp_lib_string_resize_and_overwrite
1.1.1.6  mrg 	__str.resize_and_overwrite(15, __write);
1.1.1.4  mrg #else
1.1.1.6  mrg 	__str.resize(15);
1.1.1.6  mrg 	__str.resize(__write(&__str.front(), 15));
    1.1  mrg #endif
1.1.1.6  mrg 	return __str;
1.1.1.4  mrg       }
    1.1  mrg
    1.1  mrg     // static members:
    1.1  mrg     static constexpr address_v4 any() noexcept { return address_v4{}; }
    1.1  mrg
    1.1  mrg     static constexpr
    1.1  mrg     address_v4 loopback() noexcept { return address_v4{0x7F000001}; }
    1.1  mrg
    1.1  mrg     static constexpr
    1.1  mrg     address_v4 broadcast() noexcept { return address_v4{0xFFFFFFFF}; }
    1.1  mrg
    1.1  mrg   private:
    1.1  mrg     template<typename _InternetProtocol>
    1.1  mrg       friend class basic_endpoint;
    1.1  mrg
    1.1  mrg     friend address_v4 make_address_v4(const char*, error_code&) noexcept;
    1.1  mrg
    1.1  mrg #if __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__
    1.1  mrg     static constexpr uint16_t _S_hton_16(uint16_t __h) { return __h; }
    1.1  mrg     static constexpr uint16_t _S_ntoh_16(uint16_t __n) { return __n; }
    1.1  mrg     static constexpr uint32_t _S_hton_32(uint32_t __h) { return __h; }
    1.1  mrg     static constexpr uint32_t _S_ntoh_32(uint32_t __n) { return __n; }
    1.1  mrg #else
    1.1  mrg     static constexpr uint16_t
    1.1  mrg     _S_hton_16(uint16_t __h) { return __builtin_bswap16(__h); }
    1.1  mrg
    1.1  mrg     static constexpr uint16_t
    1.1  mrg     _S_ntoh_16(uint16_t __n) { return __builtin_bswap16(__n); }
    1.1  mrg
    1.1  mrg     static constexpr uint32_t
    1.1  mrg     _S_hton_32(uint32_t __h) { return __builtin_bswap32(__h); }
    1.1  mrg
    1.1  mrg     static constexpr uint32_t
    1.1  mrg     _S_ntoh_32(uint32_t __n) { return __builtin_bswap32(__n); }
    1.1  mrg #endif
    1.1  mrg
1.1.1.4  mrg #ifdef _GLIBCXX_HAVE_ARPA_INET_H
    1.1  mrg     in_addr_t _M_addr; // network byte order
1.1.1.4  mrg #else
1.1.1.4  mrg     uint32_t _M_addr;
1.1.1.4  mrg #endif
    1.1  mrg   };
    1.1  mrg
    1.1  mrg   /// An IPv6 address.
    1.1  mrg   class address_v6
    1.1  mrg   {
    1.1  mrg   public:
    1.1  mrg     // types:
    1.1  mrg     struct bytes_type : array<unsigned char, 16>
    1.1  mrg     {
1.1.1.4  mrg       template<typename... _Tp>
1.1.1.4  mrg 	explicit constexpr
1.1.1.4  mrg 	bytes_type(_Tp... __t)
1.1.1.4  mrg 	: array<unsigned char, 16>{{static_cast<unsigned char>(__t)...}}
1.1.1.4  mrg 	{ }
    1.1  mrg     };
    1.1  mrg
    1.1  mrg     // constructors:
    1.1  mrg     constexpr address_v6() noexcept : _M_bytes(), _M_scope_id() { }
    1.1  mrg
    1.1  mrg     constexpr address_v6(const address_v6& __a) noexcept = default;
    1.1  mrg
    1.1  mrg     constexpr
    1.1  mrg     address_v6(const bytes_type& __bytes, scope_id_type __scope = 0)
    1.1  mrg     : _M_bytes(__bytes), _M_scope_id(__scope)
    1.1  mrg     { }
    1.1  mrg
    1.1  mrg     // assignment:
    1.1  mrg     address_v6& operator=(const address_v6& __a) noexcept = default;
    1.1  mrg
    1.1  mrg     // members:
    1.1  mrg     void scope_id(scope_id_type __id) noexcept { _M_scope_id = __id; }
    1.1  mrg
    1.1  mrg     constexpr scope_id_type scope_id() const noexcept { return _M_scope_id; }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_unspecified() const noexcept
    1.1  mrg     {
    1.1  mrg       for (int __i = 0; __i < 16; ++__i)
    1.1  mrg 	if (_M_bytes[__i] != 0x00)
    1.1  mrg 	  return false;
    1.1  mrg       return _M_scope_id == 0;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_loopback() const noexcept
    1.1  mrg     {
    1.1  mrg       for (int __i = 0; __i < 15; ++__i)
    1.1  mrg 	if (_M_bytes[__i] != 0x00)
    1.1  mrg 	  return false;
    1.1  mrg       return _M_bytes[15] == 0x01 && _M_scope_id == 0;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_multicast() const noexcept { return _M_bytes[0] == 0xFF; }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_link_local() const noexcept
    1.1  mrg     { return _M_bytes[0] == 0xFE && (_M_bytes[1] & 0xC0) == 0x80; }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_site_local() const noexcept
    1.1  mrg     { return _M_bytes[0] == 0xFE && (_M_bytes[1] & 0xC0) == 0xC0; }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_v4_mapped() const noexcept
    1.1  mrg     {
    1.1  mrg       const bytes_type& __b = _M_bytes;
    1.1  mrg       return __b[0] == 0 && __b[1] == 0 && __b[ 2] == 0    && __b[ 3] == 0
    1.1  mrg 	  && __b[4] == 0 && __b[5] == 0 && __b[ 6] == 0    && __b[ 7] == 0
    1.1  mrg 	  && __b[8] == 0 && __b[9] == 0 && __b[10] == 0xFF && __b[11] == 0xFF;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_multicast_node_local() const noexcept
    1.1  mrg     { return is_multicast() && (_M_bytes[1] & 0x0F) == 0x01; }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_multicast_link_local() const noexcept
    1.1  mrg     { return is_multicast() && (_M_bytes[1] & 0x0F) == 0x02; }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_multicast_site_local() const noexcept
    1.1  mrg     { return is_multicast() && (_M_bytes[1] & 0x0F) == 0x05; }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_multicast_org_local() const noexcept
    1.1  mrg     { return is_multicast() && (_M_bytes[1] & 0x0F) == 0x08; }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_multicast_global() const noexcept
    1.1  mrg     { return is_multicast() && (_M_bytes[1] & 0x0F) == 0x0b; }
    1.1  mrg
    1.1  mrg     constexpr bytes_type to_bytes() const noexcept { return _M_bytes; }
    1.1  mrg
    1.1  mrg     template<typename _Allocator = allocator<char>>
    1.1  mrg       __string_with<_Allocator>
    1.1  mrg       to_string(const _Allocator& __a = _Allocator()) const
    1.1  mrg       {
1.1.1.4  mrg #ifdef _GLIBCXX_HAVE_ARPA_INET_H
    1.1  mrg 	__string_with<_Allocator> __str(__a);
1.1.1.2  mrg 	__str.resize(INET6_ADDRSTRLEN + (_M_scope_id ? 11 : 0));
1.1.1.2  mrg 	char* const __p = &__str.front();
1.1.1.2  mrg 	if (inet_ntop(AF_INET6, &_M_bytes, __p, __str.size()))
1.1.1.2  mrg 	  {
1.1.1.2  mrg 	    auto __end = __str.find('\0');
1.1.1.2  mrg 	    if (unsigned long __scope = _M_scope_id)
1.1.1.2  mrg 	      {
1.1.1.2  mrg 		__end +=
1.1.1.2  mrg #if _GLIBCXX_USE_C99_STDIO
1.1.1.2  mrg 		  __builtin_snprintf(__p + __end, __str.size() - __end,
1.1.1.2  mrg 				     "%%%lu", __scope);
1.1.1.2  mrg #else
1.1.1.2  mrg 		  __builtin_sprintf(__p + __end, "%%%lu", __scope);
1.1.1.2  mrg #endif
1.1.1.2  mrg 	      }
1.1.1.2  mrg 	    __str.erase(__end);
1.1.1.2  mrg 	  }
    1.1  mrg 	else
    1.1  mrg 	  __str.resize(0);
    1.1  mrg 	return __str;
1.1.1.4  mrg #else
1.1.1.4  mrg 	std::__throw_system_error((int)__unsupported_err());
    1.1  mrg #endif
1.1.1.4  mrg       }
    1.1  mrg
    1.1  mrg     // static members:
1.1.1.2  mrg
    1.1  mrg     static constexpr address_v6
    1.1  mrg     any() noexcept
    1.1  mrg     {
1.1.1.2  mrg       return {};
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     static constexpr address_v6
    1.1  mrg     loopback() noexcept
    1.1  mrg     {
1.1.1.2  mrg       return {bytes_type{0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,1}};
    1.1  mrg     }
    1.1  mrg
    1.1  mrg   private:
    1.1  mrg     template<typename _InternetProtocol>
    1.1  mrg       friend class basic_endpoint;
    1.1  mrg
    1.1  mrg     friend constexpr bool
    1.1  mrg     operator==(const address_v6&, const address_v6&) noexcept;
    1.1  mrg
    1.1  mrg     friend constexpr bool
    1.1  mrg     operator< (const address_v6&, const address_v6&) noexcept;
    1.1  mrg
    1.1  mrg     bytes_type _M_bytes;
    1.1  mrg     scope_id_type _M_scope_id;
    1.1  mrg   };
    1.1  mrg
    1.1  mrg   /// Exception type thrown on misuse of IPv4 addresses as IPv6 or vice versa.
    1.1  mrg   class bad_address_cast : public bad_cast
    1.1  mrg   {
    1.1  mrg   public:
    1.1  mrg     bad_address_cast() { }
    1.1  mrg
    1.1  mrg     const char* what() const noexcept { return "bad address cast"; }
    1.1  mrg   };
    1.1  mrg
    1.1  mrg   /// An IPv4 or IPv6 address.
    1.1  mrg   class address
    1.1  mrg   {
    1.1  mrg   public:
    1.1  mrg     // constructors:
    1.1  mrg     constexpr address() noexcept : _M_v4(), _M_is_v4(true) { }
    1.1  mrg
1.1.1.4  mrg #if __cpp_constexpr_dynamic_alloc
    1.1  mrg     constexpr
1.1.1.4  mrg #endif
    1.1  mrg     address(const address& __a) noexcept : _M_uninit(), _M_is_v4(__a._M_is_v4)
    1.1  mrg     {
    1.1  mrg       if (_M_is_v4)
1.1.1.4  mrg 	std::_Construct(std::addressof(_M_v4), __a.to_v4());
    1.1  mrg       else
1.1.1.4  mrg 	std::_Construct(std::addressof(_M_v6), __a.to_v6());
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     constexpr
    1.1  mrg     address(const address_v4& __a) noexcept : _M_v4(__a), _M_is_v4(true) { }
    1.1  mrg
    1.1  mrg     constexpr
    1.1  mrg     address(const address_v6& __a) noexcept : _M_v6(__a), _M_is_v4(false) { }
    1.1  mrg
    1.1  mrg     // assignment:
    1.1  mrg     address&
    1.1  mrg     operator=(const address& __a) noexcept
    1.1  mrg     {
    1.1  mrg       if (__a._M_is_v4)
    1.1  mrg 	*this = __a.to_v4();
    1.1  mrg       else
    1.1  mrg 	*this = __a.to_v6();
    1.1  mrg       return *this;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     address&
    1.1  mrg     operator=(const address_v4& __a) noexcept
    1.1  mrg     {
1.1.1.4  mrg       std::_Construct(std::addressof(_M_v4), __a);
    1.1  mrg       _M_is_v4 = true;
    1.1  mrg       return *this;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     address&
    1.1  mrg     operator=(const address_v6& __a) noexcept
    1.1  mrg     {
1.1.1.4  mrg       std::_Construct(std::addressof(_M_v6), __a);
    1.1  mrg       _M_is_v4 = false;
    1.1  mrg       return *this;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     // members:
    1.1  mrg
    1.1  mrg     constexpr bool is_v4() const noexcept { return _M_is_v4; }
    1.1  mrg     constexpr bool is_v6() const noexcept { return !_M_is_v4; }
    1.1  mrg
    1.1  mrg     constexpr address_v4
    1.1  mrg     to_v4() const
    1.1  mrg     {
    1.1  mrg       if (!is_v4())
    1.1  mrg 	_GLIBCXX_THROW_OR_ABORT(bad_address_cast());
    1.1  mrg       return _M_v4;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     constexpr address_v6
    1.1  mrg     to_v6() const
    1.1  mrg     {
    1.1  mrg       if (!is_v6())
    1.1  mrg 	_GLIBCXX_THROW_OR_ABORT(bad_address_cast());
    1.1  mrg       return _M_v6;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_unspecified() const noexcept
    1.1  mrg     { return _M_is_v4 ? _M_v4.is_unspecified() : _M_v6.is_unspecified(); }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_loopback() const noexcept
    1.1  mrg     { return _M_is_v4 ? _M_v4.is_loopback() : _M_v6.is_loopback(); }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_multicast() const noexcept
    1.1  mrg     { return _M_is_v4 ? _M_v4.is_multicast() : _M_v6.is_multicast(); }
    1.1  mrg
    1.1  mrg     template<typename _Allocator = allocator<char>>
    1.1  mrg       __string_with<_Allocator>
    1.1  mrg       to_string(const _Allocator& __a = _Allocator()) const
    1.1  mrg       {
    1.1  mrg 	if (_M_is_v4)
    1.1  mrg 	  return to_v4().to_string(__a);
    1.1  mrg 	return to_v6().to_string(__a);
    1.1  mrg       }
    1.1  mrg
    1.1  mrg   private:
    1.1  mrg     template<typename _InternetProtocol>
    1.1  mrg       friend class basic_endpoint;
    1.1  mrg
    1.1  mrg     friend constexpr bool
    1.1  mrg     operator==(const address&, const address&) noexcept;
    1.1  mrg
    1.1  mrg     friend constexpr bool
    1.1  mrg     operator<(const address&, const address&) noexcept;
    1.1  mrg
    1.1  mrg     union {
    1.1  mrg       address_v4 _M_v4;
    1.1  mrg       address_v6 _M_v6;
    1.1  mrg       bool	 _M_uninit;
    1.1  mrg     };
    1.1  mrg     bool _M_is_v4;
    1.1  mrg   };
    1.1  mrg
    1.1  mrg   /** ip::address_v4 comparisons
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator==(const address_v4& __a, const address_v4& __b) noexcept
    1.1  mrg   { return __a.to_uint() == __b.to_uint(); }
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator!=(const address_v4& __a, const address_v4& __b) noexcept
    1.1  mrg   { return !(__a == __b); }
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator< (const address_v4& __a, const address_v4& __b) noexcept
    1.1  mrg   { return __a.to_uint() < __b.to_uint(); }
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator> (const address_v4& __a, const address_v4& __b) noexcept
    1.1  mrg   { return __b < __a; }
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator<=(const address_v4& __a, const address_v4& __b) noexcept
    1.1  mrg   { return !(__b < __a); }
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator>=(const address_v4& __a, const address_v4& __b) noexcept
    1.1  mrg   { return !(__a < __b); }
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /** ip::address_v6 comparisons
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator==(const address_v6& __a, const address_v6& __b) noexcept
    1.1  mrg   {
    1.1  mrg     const auto& __aa = __a._M_bytes;
    1.1  mrg     const auto& __bb = __b._M_bytes;
    1.1  mrg     int __i = 0;
    1.1  mrg     for (; __i < 16 && __aa[__i] == __bb[__i]; ++__i)
    1.1  mrg       ;
    1.1  mrg     return __i == 16 ? __a.scope_id() == __b.scope_id() : false;
    1.1  mrg   }
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator!=(const address_v6& __a, const address_v6& __b) noexcept
    1.1  mrg   { return !(__a == __b); }
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator< (const address_v6& __a, const address_v6& __b) noexcept
    1.1  mrg   {
    1.1  mrg     const auto& __aa = __a._M_bytes;
    1.1  mrg     const auto& __bb = __b._M_bytes;
    1.1  mrg     int __i = 0;
    1.1  mrg     for (; __i < 16 && __aa[__i] == __bb[__i]; ++__i)
    1.1  mrg       ;
    1.1  mrg     return __i == 16 ? __a.scope_id() < __b.scope_id() : __aa[__i] < __bb[__i];
    1.1  mrg   }
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator> (const address_v6& __a, const address_v6& __b) noexcept
    1.1  mrg   { return __b < __a; }
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator<=(const address_v6& __a, const address_v6& __b) noexcept
    1.1  mrg   { return !(__b < __a); }
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator>=(const address_v6& __a, const address_v6& __b) noexcept
    1.1  mrg   { return !(__a < __b); }
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /** ip::address comparisons
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator==(const address& __a, const address& __b) noexcept
    1.1  mrg   {
    1.1  mrg     if (__a.is_v4())
    1.1  mrg       return __b.is_v4() ? __a._M_v4 == __b._M_v4 : false;
    1.1  mrg     return __b.is_v4() ? false : __a._M_v6 == __b._M_v6;
    1.1  mrg   }
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator!=(const address& __a, const address& __b) noexcept
    1.1  mrg   { return !(__a == __b); }
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator< (const address& __a, const address& __b) noexcept
    1.1  mrg   {
    1.1  mrg     if (__a.is_v4())
    1.1  mrg       return __b.is_v4() ? __a._M_v4 < __b._M_v4 : true;
    1.1  mrg     return __b.is_v4() ? false : __a._M_v6 < __b._M_v6;
    1.1  mrg   }
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator> (const address& __a, const address& __b) noexcept
    1.1  mrg   { return __b < __a; }
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator<=(const address& __a, const address& __b) noexcept
    1.1  mrg   { return !(__b < __a); }
    1.1  mrg
    1.1  mrg   constexpr bool
    1.1  mrg   operator>=(const address& __a, const address& __b) noexcept
    1.1  mrg   { return !(__a < __b); }
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /** ip::address_v4 creation
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   constexpr address_v4
    1.1  mrg   make_address_v4(const address_v4::bytes_type& __b)
    1.1  mrg   { return address_v4{__b}; }
    1.1  mrg
    1.1  mrg   constexpr address_v4
    1.1  mrg   make_address_v4(address_v4::uint_type __val)
    1.1  mrg   { return address_v4{__val}; }
    1.1  mrg
    1.1  mrg   constexpr address_v4
    1.1  mrg   make_address_v4(v4_mapped_t, const address_v6& __a)
    1.1  mrg   {
    1.1  mrg     if (!__a.is_v4_mapped())
    1.1  mrg       _GLIBCXX_THROW_OR_ABORT(bad_address_cast());
    1.1  mrg
    1.1  mrg     const auto __v6b = __a.to_bytes();
    1.1  mrg     return address_v4::bytes_type(__v6b[12], __v6b[13], __v6b[14], __v6b[15]);
    1.1  mrg   }
    1.1  mrg
    1.1  mrg   inline address_v4
    1.1  mrg   make_address_v4(const char* __str, error_code& __ec) noexcept
    1.1  mrg   {
1.1.1.4  mrg #ifdef _GLIBCXX_HAVE_ARPA_INET_H
    1.1  mrg     address_v4 __a;
    1.1  mrg     const int __res = ::inet_pton(AF_INET, __str, &__a._M_addr);
    1.1  mrg     if (__res == 1)
    1.1  mrg       {
    1.1  mrg 	__ec.clear();
    1.1  mrg 	return __a;
    1.1  mrg       }
    1.1  mrg     if (__res == 0)
    1.1  mrg       __ec = std::make_error_code(std::errc::invalid_argument);
    1.1  mrg     else
    1.1  mrg       __ec.assign(errno, generic_category());
1.1.1.4  mrg #else
1.1.1.4  mrg     __ec = std::make_error_code(__unsupported_err());
1.1.1.4  mrg #endif
    1.1  mrg     return {};
    1.1  mrg   }
    1.1  mrg
    1.1  mrg   inline address_v4
    1.1  mrg   make_address_v4(const char* __str)
    1.1  mrg   { return make_address_v4(__str, __throw_on_error{"make_address_v4"}); }
    1.1  mrg
    1.1  mrg   inline address_v4
    1.1  mrg   make_address_v4(const string& __str, error_code& __ec) noexcept
    1.1  mrg   { return make_address_v4(__str.c_str(), __ec); }
    1.1  mrg
    1.1  mrg   inline address_v4
    1.1  mrg   make_address_v4(const string& __str)
    1.1  mrg   { return make_address_v4(__str.c_str()); }
    1.1  mrg
    1.1  mrg   inline address_v4
    1.1  mrg   make_address_v4(string_view __str, error_code& __ec) noexcept
    1.1  mrg   {
1.1.1.4  mrg     char __buf[16]; // INET_ADDRSTRLEN isn't defined on Windows
    1.1  mrg     auto __len = __str.copy(__buf, sizeof(__buf));
    1.1  mrg     if (__len == sizeof(__buf))
    1.1  mrg       {
    1.1  mrg 	__ec = std::make_error_code(std::errc::invalid_argument);
    1.1  mrg 	return {};
    1.1  mrg       }
    1.1  mrg     __ec.clear();
    1.1  mrg     __buf[__len] = '\0';
    1.1  mrg     return make_address_v4(__buf, __ec);
    1.1  mrg   }
    1.1  mrg
    1.1  mrg   inline address_v4
    1.1  mrg   make_address_v4(string_view __str)
    1.1  mrg   { return make_address_v4(__str, __throw_on_error{"make_address_v4"}); }
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /** ip::address_v6 creation
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   constexpr address_v6
    1.1  mrg   make_address_v6(const address_v6::bytes_type& __b, scope_id_type __scope = 0)
    1.1  mrg   { return address_v6{__b, __scope}; }
    1.1  mrg
    1.1  mrg   constexpr address_v6
    1.1  mrg   make_address_v6(v4_mapped_t, const address_v4& __a) noexcept
    1.1  mrg   {
    1.1  mrg     const address_v4::bytes_type __v4b = __a.to_bytes();
    1.1  mrg     address_v6::bytes_type __v6b(0, 0, 0, 0, 0, 0, 0, 0,
    1.1  mrg 				 0, 0, 0xFF, 0xFF,
    1.1  mrg 				 __v4b[0], __v4b[1], __v4b[2], __v4b[3]);
    1.1  mrg     return address_v6(__v6b);
    1.1  mrg   }
    1.1  mrg
    1.1  mrg   inline address_v6
    1.1  mrg   __make_address_v6(const char* __addr, const char* __scope, error_code& __ec)
    1.1  mrg   {
1.1.1.4  mrg #ifdef _GLIBCXX_HAVE_ARPA_INET_H
    1.1  mrg     address_v6::bytes_type __b;
1.1.1.4  mrg     const int __res = ::inet_pton(AF_INET6, __addr, __b.data());
    1.1  mrg     if (__res == 1)
    1.1  mrg       {
    1.1  mrg 	__ec.clear();
    1.1  mrg 	if (!__scope)
    1.1  mrg 	  {
    1.1  mrg 	    return { __b };
    1.1  mrg 	  }
    1.1  mrg
    1.1  mrg 	char* __eptr;
    1.1  mrg 	unsigned long __val = std::strtoul(__scope, &__eptr, 10);
    1.1  mrg 	if (__eptr != __scope && !*__eptr
    1.1  mrg 	    && __val <= numeric_limits<scope_id_type>::max())
    1.1  mrg 	  {
    1.1  mrg 	    return { __b, static_cast<scope_id_type>(__val) };
    1.1  mrg 	  }
    1.1  mrg 	__ec = std::make_error_code(std::errc::invalid_argument);
    1.1  mrg       }
    1.1  mrg     else if (__res == 0)
    1.1  mrg       __ec = std::make_error_code(std::errc::invalid_argument);
    1.1  mrg     else
    1.1  mrg       __ec.assign(errno, generic_category());
1.1.1.4  mrg #else
1.1.1.4  mrg     __ec = std::make_error_code(__unsupported_err());
1.1.1.4  mrg #endif
    1.1  mrg     return {};
    1.1  mrg   }
    1.1  mrg
    1.1  mrg   inline address_v6
    1.1  mrg   make_address_v6(const char* __str, error_code& __ec) noexcept
    1.1  mrg   {
    1.1  mrg     auto __p = __builtin_strchr(__str, '%');
    1.1  mrg     if (__p == nullptr)
    1.1  mrg       return __make_address_v6(__str, nullptr, __ec);
    1.1  mrg     char __buf[64];
    1.1  mrg     char* __out = __buf;
    1.1  mrg     bool __skip_leading_zero = true;
    1.1  mrg     while (__str < __p && __out < std::end(__buf))
    1.1  mrg       {
    1.1  mrg 	if (!__skip_leading_zero || *__str != '0')
    1.1  mrg 	  {
    1.1  mrg 	    if (*__str == ':' || *__str == '.')
    1.1  mrg 	      __skip_leading_zero = true;
    1.1  mrg 	    else
    1.1  mrg 	      __skip_leading_zero = false;
    1.1  mrg 	    *__out = *__str;
    1.1  mrg 	  }
    1.1  mrg 	__str++;
    1.1  mrg       }
    1.1  mrg     if (__out == std::end(__buf))
1.1.1.2  mrg       {
1.1.1.2  mrg 	__ec = std::make_error_code(std::errc::invalid_argument);
1.1.1.2  mrg 	return {};
1.1.1.2  mrg       }
    1.1  mrg     else
    1.1  mrg       {
    1.1  mrg 	*__out = '\0';
    1.1  mrg 	return __make_address_v6(__buf, __p + 1, __ec);
    1.1  mrg       }
    1.1  mrg   }
    1.1  mrg
    1.1  mrg   inline address_v6
    1.1  mrg   make_address_v6(const char* __str)
    1.1  mrg   { return make_address_v6(__str, __throw_on_error{"make_address_v6"}); }
    1.1  mrg
    1.1  mrg   inline address_v6
    1.1  mrg   make_address_v6(const string& __str, error_code& __ec) noexcept
    1.1  mrg   {
    1.1  mrg     auto __pos = __str.find('%');
    1.1  mrg     if (__pos == string::npos)
    1.1  mrg       return __make_address_v6(__str.c_str(), nullptr, __ec);
    1.1  mrg     char __buf[64];
    1.1  mrg     char* __out = __buf;
    1.1  mrg     bool __skip_leading_zero = true;
    1.1  mrg     size_t __n = 0;
    1.1  mrg     while (__n < __pos && __out < std::end(__buf))
    1.1  mrg       {
    1.1  mrg 	if (!__skip_leading_zero || __str[__n] != '0')
    1.1  mrg 	  {
    1.1  mrg 	    if (__str[__n] == ':' || __str[__n] == '.')
    1.1  mrg 	      __skip_leading_zero = true;
    1.1  mrg 	    else
    1.1  mrg 	      __skip_leading_zero = false;
    1.1  mrg 	    *__out = __str[__n];
    1.1  mrg 	  }
    1.1  mrg 	__n++;
    1.1  mrg       }
    1.1  mrg     if (__out == std::end(__buf))
1.1.1.2  mrg       {
1.1.1.2  mrg 	__ec = std::make_error_code(std::errc::invalid_argument);
1.1.1.2  mrg 	return {};
1.1.1.2  mrg       }
    1.1  mrg     else
    1.1  mrg       {
    1.1  mrg 	*__out = '\0';
    1.1  mrg 	return __make_address_v6(__buf, __str.c_str() + __pos + 1, __ec);
    1.1  mrg       }
    1.1  mrg   }
    1.1  mrg
    1.1  mrg   inline address_v6
    1.1  mrg   make_address_v6(const string& __str)
    1.1  mrg   { return make_address_v6(__str, __throw_on_error{"make_address_v6"}); }
    1.1  mrg
    1.1  mrg   inline address_v6
    1.1  mrg   make_address_v6(string_view __str, error_code& __ec) noexcept
    1.1  mrg   {
    1.1  mrg     char __buf[64];
    1.1  mrg     char* __out = __buf;
    1.1  mrg     char* __scope = nullptr;
    1.1  mrg     bool __skip_leading_zero = true;
    1.1  mrg     size_t __n = 0;
    1.1  mrg     while (__n < __str.length() && __out < std::end(__buf))
    1.1  mrg       {
    1.1  mrg 	if (__str[__n] == '%')
    1.1  mrg 	  {
    1.1  mrg 	    if (__scope)
    1.1  mrg 	      __out = std::end(__buf);
    1.1  mrg 	    else
    1.1  mrg 	      {
    1.1  mrg 		*__out = '\0';
    1.1  mrg 		__scope = ++__out;
    1.1  mrg 		__skip_leading_zero = true;
    1.1  mrg 	      }
    1.1  mrg 	  }
    1.1  mrg 	else if (!__skip_leading_zero || __str[__n] != '0')
    1.1  mrg 	  {
    1.1  mrg 	    if (__str[__n] == ':' || __str[__n] == '.')
    1.1  mrg 	      __skip_leading_zero = true;
    1.1  mrg 	    else
    1.1  mrg 	      __skip_leading_zero = false;
    1.1  mrg 	    *__out = __str[__n];
    1.1  mrg 	    __out++;
    1.1  mrg 	  }
    1.1  mrg 	__n++;
    1.1  mrg       }
    1.1  mrg     if (__out == std::end(__buf))
1.1.1.2  mrg       {
1.1.1.2  mrg 	__ec = std::make_error_code(std::errc::invalid_argument);
1.1.1.2  mrg 	return {};
1.1.1.2  mrg       }
    1.1  mrg     else
    1.1  mrg       {
    1.1  mrg 	*__out = '\0';
    1.1  mrg 	return __make_address_v6(__buf, __scope, __ec);
    1.1  mrg       }
    1.1  mrg   }
    1.1  mrg
    1.1  mrg   inline address_v6
    1.1  mrg   make_address_v6(string_view __str)
    1.1  mrg   { return make_address_v6(__str, __throw_on_error{"make_address_v6"}); }
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /** ip::address creation
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   inline address
    1.1  mrg   make_address(const char* __str, error_code& __ec) noexcept
    1.1  mrg   {
    1.1  mrg     address __a;
    1.1  mrg     address_v6 __v6a = make_address_v6(__str, __ec);
    1.1  mrg     if (!__ec)
    1.1  mrg       __a = __v6a;
    1.1  mrg     else
    1.1  mrg     {
    1.1  mrg       address_v4 __v4a = make_address_v4(__str, __ec);
    1.1  mrg       if (!__ec)
    1.1  mrg 	__a = __v4a;
    1.1  mrg     }
    1.1  mrg     return __a;
    1.1  mrg   }
    1.1  mrg
    1.1  mrg   inline address
    1.1  mrg   make_address(const char* __str)
    1.1  mrg   { return make_address(__str, __throw_on_error{"make_address"}); }
    1.1  mrg
    1.1  mrg   inline address
1.1.1.6  mrg   make_address(const string& __str, error_code& __ec) noexcept
1.1.1.6  mrg   { return make_address(__str.c_str(), __ec); }
    1.1  mrg
    1.1  mrg   inline address
    1.1  mrg   make_address(const string& __str)
    1.1  mrg   { return make_address(__str, __throw_on_error{"make_address"}); }
    1.1  mrg
    1.1  mrg   inline address
    1.1  mrg   make_address(string_view __str, error_code& __ec) noexcept
    1.1  mrg   {
    1.1  mrg     if (__str.rfind('\0') != string_view::npos)
    1.1  mrg       return make_address(__str.data(), __ec);
    1.1  mrg     return make_address(__str.to_string(), __ec); // TODO don't allocate
    1.1  mrg   }
    1.1  mrg
    1.1  mrg   inline address
    1.1  mrg   make_address(string_view __str)
    1.1  mrg   { return make_address(__str, __throw_on_error{"make_address"}); }
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /// ip::address I/O
    1.1  mrg   template<typename _CharT, typename _Traits>
    1.1  mrg     inline basic_ostream<_CharT, _Traits>&
    1.1  mrg     operator<<(basic_ostream<_CharT, _Traits>& __os, const address& __a)
    1.1  mrg     { return __os << __a.to_string(); }
    1.1  mrg
    1.1  mrg   /// ip::address_v4 I/O
    1.1  mrg   template<typename _CharT, typename _Traits>
    1.1  mrg     inline basic_ostream<_CharT, _Traits>&
    1.1  mrg     operator<<(basic_ostream<_CharT, _Traits>& __os, const address_v4& __a)
    1.1  mrg     { return __os << __a.to_string(); }
    1.1  mrg
    1.1  mrg   /// ip::address_v6 I/O
    1.1  mrg   template<typename _CharT, typename _Traits>
    1.1  mrg     inline basic_ostream<_CharT, _Traits>&
    1.1  mrg     operator<<(basic_ostream<_CharT, _Traits>& __os, const address_v6& __a)
    1.1  mrg     { return __os << __a.to_string(); }
    1.1  mrg
    1.1  mrg   template<typename> class basic_address_iterator; // not defined
    1.1  mrg
    1.1  mrg   template<> class basic_address_iterator<address_v4>
    1.1  mrg   {
    1.1  mrg   public:
    1.1  mrg     // types:
1.1.1.4  mrg     using value_type = address_v4;
1.1.1.4  mrg     using difference_type = ptrdiff_t;
1.1.1.4  mrg     using pointer = const address_v4*;
1.1.1.4  mrg     using reference = const address_v4&;
1.1.1.4  mrg     using iterator_category = input_iterator_tag;
    1.1  mrg
    1.1  mrg     // constructors:
    1.1  mrg     basic_address_iterator(const address_v4& __a) noexcept
    1.1  mrg     : _M_address(__a) { }
    1.1  mrg
    1.1  mrg     // members:
    1.1  mrg     reference operator*() const noexcept { return _M_address; }
    1.1  mrg     pointer operator->() const noexcept { return &_M_address; }
    1.1  mrg
    1.1  mrg     basic_address_iterator&
    1.1  mrg     operator++() noexcept
    1.1  mrg     {
    1.1  mrg       _M_address = value_type(_M_address.to_uint() + 1);
    1.1  mrg       return *this;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     basic_address_iterator operator++(int) noexcept
    1.1  mrg     {
    1.1  mrg       auto __tmp = *this;
    1.1  mrg       ++*this;
    1.1  mrg       return __tmp;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     basic_address_iterator& operator--() noexcept
    1.1  mrg     {
    1.1  mrg       _M_address = value_type(_M_address.to_uint() - 1);
    1.1  mrg       return *this;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     basic_address_iterator
    1.1  mrg     operator--(int) noexcept
    1.1  mrg     {
    1.1  mrg       auto __tmp = *this;
    1.1  mrg       --*this;
    1.1  mrg       return __tmp;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     bool
    1.1  mrg     operator==(const basic_address_iterator& __rhs) const noexcept
    1.1  mrg     { return _M_address == __rhs._M_address; }
    1.1  mrg
    1.1  mrg     bool
    1.1  mrg     operator!=(const basic_address_iterator& __rhs) const noexcept
    1.1  mrg     { return _M_address != __rhs._M_address; }
    1.1  mrg
    1.1  mrg   private:
    1.1  mrg     address_v4 _M_address;
    1.1  mrg   };
    1.1  mrg
1.1.1.4  mrg   using address_v4_iterator = basic_address_iterator<address_v4>;
    1.1  mrg
    1.1  mrg   template<> class basic_address_iterator<address_v6>
    1.1  mrg   {
    1.1  mrg   public:
    1.1  mrg     // types:
1.1.1.4  mrg     using value_type = address_v6;
1.1.1.4  mrg     using difference_type = ptrdiff_t;
1.1.1.4  mrg     using pointer = const address_v6*;
1.1.1.4  mrg     using reference = const address_v6&;
1.1.1.4  mrg     using iterator_category = input_iterator_tag;
    1.1  mrg
    1.1  mrg     // constructors:
    1.1  mrg     basic_address_iterator(const address_v6& __a) noexcept
    1.1  mrg     : _M_address(__a) { }
    1.1  mrg
    1.1  mrg     // members:
    1.1  mrg     reference operator*() const noexcept { return _M_address; }
    1.1  mrg     pointer operator->() const noexcept { return &_M_address; }
    1.1  mrg
    1.1  mrg     basic_address_iterator&
    1.1  mrg     operator++() noexcept; // TODO
    1.1  mrg
    1.1  mrg     basic_address_iterator
    1.1  mrg     operator++(int) noexcept
    1.1  mrg     {
    1.1  mrg       auto __tmp = *this;
    1.1  mrg       ++*this;
    1.1  mrg       return __tmp;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     basic_address_iterator&
    1.1  mrg     operator--() noexcept; // TODO
    1.1  mrg
    1.1  mrg     basic_address_iterator
    1.1  mrg     operator--(int) noexcept
    1.1  mrg     {
    1.1  mrg       auto __tmp = *this;
    1.1  mrg       --*this;
    1.1  mrg       return __tmp;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     bool
    1.1  mrg     operator==(const basic_address_iterator& __rhs) const noexcept
    1.1  mrg     { return _M_address == __rhs._M_address; }
    1.1  mrg
    1.1  mrg     bool
    1.1  mrg     operator!=(const basic_address_iterator& __rhs) const noexcept
    1.1  mrg     { return _M_address != __rhs._M_address; }
    1.1  mrg
    1.1  mrg   private:
    1.1  mrg     address_v6 _M_address;
    1.1  mrg   };
    1.1  mrg
1.1.1.4  mrg   using address_v6_iterator = basic_address_iterator<address_v6>;
    1.1  mrg
    1.1  mrg   template<typename> class basic_address_range; // not defined
    1.1  mrg
    1.1  mrg   /** An IPv6 address range.
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   template<> class basic_address_range<address_v4>
    1.1  mrg   {
    1.1  mrg   public:
    1.1  mrg     // types:
    1.1  mrg
1.1.1.4  mrg     using iterator = basic_address_iterator<address_v4>;
    1.1  mrg
    1.1  mrg     // constructors:
    1.1  mrg
    1.1  mrg     basic_address_range() noexcept : _M_begin({}), _M_end({}) { }
    1.1  mrg
    1.1  mrg     basic_address_range(const address_v4& __first,
    1.1  mrg                         const address_v4& __last) noexcept
    1.1  mrg     : _M_begin(__first), _M_end(__last) { }
    1.1  mrg
    1.1  mrg     // members:
    1.1  mrg
    1.1  mrg     iterator begin() const noexcept { return _M_begin; }
    1.1  mrg     iterator end() const noexcept { return _M_end; }
    1.1  mrg     _GLIBCXX_NODISCARD bool empty() const noexcept { return _M_begin == _M_end; }
    1.1  mrg
    1.1  mrg     size_t
    1.1  mrg     size() const noexcept { return _M_end->to_uint() - _M_begin->to_uint(); }
    1.1  mrg
    1.1  mrg     iterator
    1.1  mrg     find(const address_v4& __addr) const noexcept
    1.1  mrg     {
    1.1  mrg       if (*_M_begin <= __addr && __addr < *_M_end)
    1.1  mrg 	return iterator{__addr};
    1.1  mrg       return end();
    1.1  mrg     }
    1.1  mrg
    1.1  mrg   private:
    1.1  mrg     iterator _M_begin;
    1.1  mrg     iterator _M_end;
    1.1  mrg   };
    1.1  mrg
1.1.1.4  mrg   using address_v4_range = basic_address_range<address_v4>;
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /** An IPv6 address range.
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   template<> class basic_address_range<address_v6>
    1.1  mrg   {
    1.1  mrg   public:
    1.1  mrg     // types:
    1.1  mrg
1.1.1.4  mrg     using iterator = basic_address_iterator<address_v6>;
    1.1  mrg
    1.1  mrg     // constructors:
    1.1  mrg
    1.1  mrg     basic_address_range() noexcept : _M_begin({}), _M_end({}) { }
    1.1  mrg     basic_address_range(const address_v6& __first,
    1.1  mrg                         const address_v6& __last) noexcept
    1.1  mrg     : _M_begin(__first), _M_end(__last) { }
    1.1  mrg
    1.1  mrg     // members:
    1.1  mrg
    1.1  mrg     iterator begin() const noexcept { return _M_begin; }
    1.1  mrg     iterator end() const noexcept { return _M_end; }
    1.1  mrg     _GLIBCXX_NODISCARD bool empty() const noexcept { return _M_begin == _M_end; }
    1.1  mrg
    1.1  mrg     iterator
    1.1  mrg     find(const address_v6& __addr) const noexcept
    1.1  mrg     {
    1.1  mrg       if (*_M_begin <= __addr && __addr < *_M_end)
    1.1  mrg 	return iterator{__addr};
    1.1  mrg       return end();
    1.1  mrg     }
    1.1  mrg
    1.1  mrg   private:
    1.1  mrg     iterator _M_begin;
    1.1  mrg     iterator _M_end;
    1.1  mrg   };
    1.1  mrg
1.1.1.4  mrg   using address_v6_range = basic_address_range<address_v6>;
    1.1  mrg
1.1.1.3  mrg   /// @}
1.1.1.2  mrg
1.1.1.6  mrg   constexpr bool
    1.1  mrg   operator==(const network_v4& __a, const network_v4& __b) noexcept;
    1.1  mrg
1.1.1.6  mrg   constexpr bool
    1.1  mrg   operator==(const network_v6& __a, const network_v6& __b) noexcept;
    1.1  mrg
    1.1  mrg
    1.1  mrg   /// An IPv4 network address.
    1.1  mrg   class network_v4
    1.1  mrg   {
    1.1  mrg   public:
    1.1  mrg     // constructors:
    1.1  mrg     constexpr network_v4() noexcept : _M_addr(), _M_prefix_len(0) { }
    1.1  mrg
    1.1  mrg     constexpr
    1.1  mrg     network_v4(const address_v4& __addr, int __prefix_len)
    1.1  mrg     : _M_addr(__addr), _M_prefix_len(__prefix_len)
    1.1  mrg     {
    1.1  mrg       if (_M_prefix_len < 0 || _M_prefix_len > 32)
    1.1  mrg 	__throw_out_of_range("network_v4: invalid prefix length");
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     constexpr
    1.1  mrg     network_v4(const address_v4& __addr, const address_v4& __mask)
    1.1  mrg     : _M_addr(__addr), _M_prefix_len(__builtin_popcount(__mask.to_uint()))
    1.1  mrg     {
    1.1  mrg       if (_M_prefix_len != 0)
    1.1  mrg 	{
    1.1  mrg 	  address_v4::uint_type __mask_uint = __mask.to_uint();
    1.1  mrg 	  if (__builtin_ctz(__mask_uint) != (32 - _M_prefix_len))
    1.1  mrg 	    __throw_invalid_argument("network_v4: invalid mask");
    1.1  mrg 	  if ((__mask_uint & 0x80000000) == 0)
    1.1  mrg 	    __throw_invalid_argument("network_v4: invalid mask");
    1.1  mrg 	}
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     // members:
    1.1  mrg
    1.1  mrg     constexpr address_v4 address() const noexcept { return _M_addr; }
    1.1  mrg     constexpr int prefix_length() const noexcept { return _M_prefix_len; }
    1.1  mrg
    1.1  mrg     constexpr address_v4
    1.1  mrg     netmask() const noexcept
    1.1  mrg     {
1.1.1.6  mrg       address_v4 __m;
1.1.1.6  mrg       if (_M_prefix_len)
1.1.1.6  mrg 	__m = address_v4(0xFFFFFFFFu << (32 - _M_prefix_len));
1.1.1.6  mrg       return __m;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     constexpr address_v4
    1.1  mrg     network() const noexcept
    1.1  mrg     { return address_v4{_M_addr.to_uint() & netmask().to_uint()}; }
    1.1  mrg
    1.1  mrg     constexpr address_v4
    1.1  mrg     broadcast() const noexcept
1.1.1.6  mrg     {
1.1.1.6  mrg       auto __b = _M_addr.to_uint();
1.1.1.6  mrg       if (_M_prefix_len < 32)
1.1.1.6  mrg 	__b |= 0xFFFFFFFFu >> _M_prefix_len;
1.1.1.6  mrg       return address_v4{__b};
1.1.1.6  mrg     }
    1.1  mrg
    1.1  mrg     address_v4_range
    1.1  mrg     hosts() const noexcept
    1.1  mrg     {
    1.1  mrg       if (is_host())
    1.1  mrg 	return { address(), *++address_v4_iterator(address()) };
    1.1  mrg       return { network(), broadcast() };
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     constexpr network_v4
    1.1  mrg     canonical() const noexcept
    1.1  mrg     { return network_v4(network(), prefix_length()); }
    1.1  mrg
    1.1  mrg     constexpr bool is_host() const noexcept { return _M_prefix_len == 32; }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_subnet_of(const network_v4& __other) const noexcept
    1.1  mrg     {
    1.1  mrg       if (__other.prefix_length() < prefix_length())
    1.1  mrg 	{
    1.1  mrg 	  network_v4 __net(address(), __other.prefix_length());
    1.1  mrg 	  return __net.canonical() == __other.canonical();
    1.1  mrg 	}
    1.1  mrg       return false;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     template<typename _Allocator = allocator<char>>
    1.1  mrg       __string_with<_Allocator>
    1.1  mrg       to_string(const _Allocator& __a = _Allocator()) const
    1.1  mrg       {
1.1.1.6  mrg 	auto __str = address().to_string(__a);
1.1.1.6  mrg 	const unsigned __addrlen = __str.length();
1.1.1.6  mrg 	const unsigned __preflenlen = _M_prefix_len >= 10 ? 2 : 1;
1.1.1.6  mrg 	__str.resize(__addrlen + 1 + __preflenlen);
1.1.1.6  mrg 	__str[__addrlen] = '/';
1.1.1.6  mrg 	std::__detail::__to_chars_10_impl(&__str.front() + __addrlen + 1,
1.1.1.6  mrg 					  __preflenlen,
1.1.1.6  mrg 					  (unsigned char)_M_prefix_len);
1.1.1.6  mrg 	return __str;
    1.1  mrg       }
    1.1  mrg
    1.1  mrg   private:
    1.1  mrg     address_v4 _M_addr;
    1.1  mrg     int _M_prefix_len;
    1.1  mrg   };
    1.1  mrg
    1.1  mrg   /// An IPv6 network address.
    1.1  mrg   class network_v6
    1.1  mrg   {
    1.1  mrg   public:
    1.1  mrg     // constructors:
    1.1  mrg     constexpr network_v6() noexcept : _M_addr(), _M_prefix_len(0) { }
    1.1  mrg
    1.1  mrg     constexpr
    1.1  mrg     network_v6(const address_v6& __addr, int __prefix_len)
    1.1  mrg     : _M_addr(__addr), _M_prefix_len(__prefix_len)
    1.1  mrg     {
    1.1  mrg       if (_M_prefix_len < 0 || _M_prefix_len > 128)
    1.1  mrg 	__throw_out_of_range("network_v6: invalid prefix length");
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     // members:
    1.1  mrg     constexpr address_v6 address() const noexcept { return _M_addr; }
    1.1  mrg     constexpr int prefix_length() const noexcept { return _M_prefix_len; }
    1.1  mrg
1.1.1.5  mrg     _GLIBCXX17_CONSTEXPR address_v6
1.1.1.5  mrg     network() const noexcept
1.1.1.5  mrg     {
1.1.1.5  mrg       address_v6::bytes_type __bytes = _M_addr.to_bytes();
1.1.1.5  mrg       int __nbytes = (_M_prefix_len + 7) / 8;
1.1.1.5  mrg       for (int __n = __nbytes; __n < 16; ++__n)
1.1.1.5  mrg 	__bytes[__n] = 0;
1.1.1.5  mrg       if (int __zbits = (__nbytes * 8) - _M_prefix_len)
1.1.1.5  mrg 	__bytes[__nbytes - 1] &= 0xFF << __zbits;
1.1.1.5  mrg       return address_v6(__bytes, _M_addr.scope_id());
1.1.1.5  mrg     }
    1.1  mrg
    1.1  mrg     address_v6_range
    1.1  mrg     hosts() const noexcept
    1.1  mrg     {
    1.1  mrg       if (is_host())
    1.1  mrg 	return { address(), *++address_v6_iterator(address()) };
1.1.1.5  mrg
1.1.1.5  mrg       address_v6::bytes_type __bytes = _M_addr.to_bytes();
1.1.1.5  mrg       int __nbytes = (_M_prefix_len + 7) / 8;
1.1.1.5  mrg       for (int __n = __nbytes; __n < 16; ++__n)
1.1.1.5  mrg 	__bytes[__n] = 0xFF;
1.1.1.5  mrg       if (int __bits = (__nbytes * 8) - _M_prefix_len)
1.1.1.5  mrg 	__bytes[__nbytes - 1] |= (1 << __bits) - 1;
1.1.1.5  mrg       address_v6 __last(__bytes, _M_addr.scope_id());
1.1.1.5  mrg       return { network(), *++address_v6_iterator(__last) };
    1.1  mrg     }
    1.1  mrg
1.1.1.5  mrg     _GLIBCXX17_CONSTEXPR network_v6
    1.1  mrg     canonical() const noexcept
    1.1  mrg     { return network_v6{network(), prefix_length()}; }
    1.1  mrg
    1.1  mrg     constexpr bool is_host() const noexcept { return _M_prefix_len == 128; }
    1.1  mrg
    1.1  mrg     constexpr bool
    1.1  mrg     is_subnet_of(const network_v6& __other) const noexcept
    1.1  mrg     {
    1.1  mrg       if (__other.prefix_length() < prefix_length())
    1.1  mrg 	{
    1.1  mrg 	  network_v6 __net(address(), __other.prefix_length());
    1.1  mrg 	  return __net.canonical() == __other.canonical();
    1.1  mrg 	}
    1.1  mrg       return false;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg     template<typename _Allocator = allocator<char>>
    1.1  mrg       __string_with<_Allocator>
    1.1  mrg       to_string(const _Allocator& __a = _Allocator()) const
    1.1  mrg       {
    1.1  mrg 	return address().to_string(__a) + '/'
1.1.1.5  mrg 		 + std::to_string(prefix_length()).c_str();
    1.1  mrg       }
    1.1  mrg
    1.1  mrg   private:
    1.1  mrg     address_v6 _M_addr;
    1.1  mrg     int _M_prefix_len;
    1.1  mrg   };
    1.1  mrg
    1.1  mrg
    1.1  mrg   /** ip::network_v4 comparisons
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
1.1.1.6  mrg   constexpr bool
    1.1  mrg   operator==(const network_v4& __a, const network_v4& __b) noexcept
    1.1  mrg   {
    1.1  mrg     return __a.address() == __b.address()
    1.1  mrg       && __a.prefix_length() == __b.prefix_length();
    1.1  mrg   }
    1.1  mrg
1.1.1.6  mrg   constexpr bool
    1.1  mrg   operator!=(const network_v4& __a, const network_v4& __b) noexcept
    1.1  mrg   { return !(__a == __b); }
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /** ip::network_v6 comparisons
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
1.1.1.6  mrg   constexpr bool
    1.1  mrg   operator==(const network_v6& __a, const network_v6& __b) noexcept
    1.1  mrg   {
    1.1  mrg     return __a.address() == __b.address()
    1.1  mrg       && __a.prefix_length() == __b.prefix_length();
    1.1  mrg   }
    1.1  mrg
1.1.1.6  mrg   constexpr bool
    1.1  mrg   operator!=(const network_v6& __a, const network_v6& __b) noexcept
    1.1  mrg   { return !(__a == __b); }
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /** ip::network_v4 creation
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   inline network_v4
    1.1  mrg   make_network_v4(const address_v4& __a, int __prefix_len)
    1.1  mrg   { return network_v4{__a, __prefix_len}; }
    1.1  mrg
1.1.1.3  mrg   inline network_v4
    1.1  mrg   make_network_v4(const address_v4& __a, const address_v4& __mask)
    1.1  mrg   { return network_v4{ __a, __mask }; }
    1.1  mrg
    1.1  mrg   network_v4 make_network_v4(const char*, error_code&) noexcept; // TODO
    1.1  mrg
    1.1  mrg   inline network_v4
    1.1  mrg   make_network_v4(const char* __str)
    1.1  mrg   { return make_network_v4(__str, __throw_on_error{"make_network_v4"}); }
    1.1  mrg
    1.1  mrg   network_v4 make_network_v4(const string&, error_code&) noexcept; // TODO
    1.1  mrg
    1.1  mrg   inline network_v4
    1.1  mrg   make_network_v4(const string& __str)
    1.1  mrg   { return make_network_v4(__str, __throw_on_error{"make_network_v4"}); }
    1.1  mrg
    1.1  mrg   network_v4 make_network_v4(string_view, error_code&) noexcept; // TODO
    1.1  mrg
    1.1  mrg   inline network_v4
    1.1  mrg   make_network_v4(string_view __str)
    1.1  mrg   { return make_network_v4(__str, __throw_on_error{"make_network_v4"}); }
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /** ip::network_v6 creation
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   inline network_v6
    1.1  mrg   make_network_v6(const address_v6& __a, int __prefix_len)
    1.1  mrg   { return network_v6{__a, __prefix_len}; }
    1.1  mrg
    1.1  mrg   network_v6 make_network_v6(const char*, error_code&) noexcept; // TODO
    1.1  mrg
    1.1  mrg   inline network_v6
    1.1  mrg   make_network_v6(const char* __str)
    1.1  mrg   { return make_network_v6(__str, __throw_on_error{"make_network_v6"}); }
    1.1  mrg
    1.1  mrg   network_v6 make_network_v6(const string&, error_code&) noexcept; // TODO
    1.1  mrg
    1.1  mrg   inline network_v6
    1.1  mrg   make_network_v6(const string& __str)
    1.1  mrg   { return make_network_v6(__str, __throw_on_error{"make_network_v6"}); }
    1.1  mrg
    1.1  mrg   network_v6 make_network_v6(string_view, error_code&) noexcept; // TODO
    1.1  mrg
    1.1  mrg   inline network_v6
    1.1  mrg   make_network_v6(string_view __str)
    1.1  mrg   { return make_network_v6(__str, __throw_on_error{"make_network_v6"}); }
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /// ip::network_v4 I/O
    1.1  mrg   template<typename _CharT, typename _Traits>
    1.1  mrg     inline basic_ostream<_CharT, _Traits>&
    1.1  mrg     operator<<(basic_ostream<_CharT, _Traits>& __os, const network_v4& __net)
    1.1  mrg     { return __os << __net.to_string(); }
    1.1  mrg
    1.1  mrg   /// ip::network_v6 I/O
    1.1  mrg   template<typename _CharT, typename _Traits>
    1.1  mrg     inline basic_ostream<_CharT, _Traits>&
    1.1  mrg     operator<<(basic_ostream<_CharT, _Traits>& __os, const network_v6& __net)
    1.1  mrg     { return __os << __net.to_string(); }
    1.1  mrg
1.1.1.5  mrg #if defined IPPROTO_TCP || defined  IPPROTO_UDP
    1.1  mrg   /// An IP endpoint.
    1.1  mrg   template<typename _InternetProtocol>
    1.1  mrg     class basic_endpoint
    1.1  mrg     {
    1.1  mrg     public:
    1.1  mrg       // types:
1.1.1.4  mrg       using protocol_type = _InternetProtocol;
    1.1  mrg
    1.1  mrg       // constructors:
    1.1  mrg
1.1.1.6  mrg       _GLIBCXX20_CONSTEXPR
    1.1  mrg       basic_endpoint() noexcept : _M_data()
1.1.1.6  mrg       {
1.1.1.6  mrg 	_M_data._M_v4.sin_family = protocol_type::v4().family();
1.1.1.6  mrg 	// If in_addr contains a union, make the correct member active:
1.1.1.6  mrg 	if (std::__is_constant_evaluated())
1.1.1.6  mrg 	  std::_Construct(&_M_data._M_v4.sin_addr.s_addr);
1.1.1.6  mrg       }
    1.1  mrg
1.1.1.6  mrg       _GLIBCXX20_CONSTEXPR
    1.1  mrg       basic_endpoint(const protocol_type& __proto,
    1.1  mrg 		     port_type __port_num) noexcept
    1.1  mrg       : _M_data()
    1.1  mrg       {
1.1.1.6  mrg 	if (__proto == protocol_type::v4())
1.1.1.6  mrg 	  {
1.1.1.6  mrg 	    _M_data._M_v4.sin_family = protocol_type::v4().family();
1.1.1.6  mrg 	    _M_data._M_v4.sin_port = address_v4::_S_hton_16(__port_num);
1.1.1.6  mrg 	    if (std::__is_constant_evaluated())
1.1.1.6  mrg 	      std::_Construct(&_M_data._M_v4.sin_addr.s_addr);
1.1.1.6  mrg 	  }
1.1.1.6  mrg 	else if (__proto == protocol_type::v6())
1.1.1.6  mrg 	  {
1.1.1.6  mrg 	    std::_Construct(&_M_data._M_v6);
1.1.1.6  mrg 	    _M_data._M_v6.sin6_family = __proto.family();
1.1.1.6  mrg 	    _M_data._M_v6.sin6_port = address_v4::_S_hton_16(__port_num);
1.1.1.6  mrg 	    _M_data._M_v6.sin6_scope_id = 0;
1.1.1.6  mrg 	    if (std::__is_constant_evaluated())
1.1.1.6  mrg 	      std::_Construct(&_M_data._M_v6.sin6_addr.s6_addr);
1.1.1.6  mrg 	  }
1.1.1.6  mrg 	else
1.1.1.6  mrg 	  {
1.1.1.6  mrg 	    __glibcxx_assert(__proto == protocol_type::v4()
1.1.1.6  mrg 			       || __proto == protocol_type::v6());
    1.1  mrg
1.1.1.6  mrg 	  }
    1.1  mrg       }
    1.1  mrg
1.1.1.6  mrg       _GLIBCXX20_CONSTEXPR
    1.1  mrg       basic_endpoint(const ip::address& __addr,
    1.1  mrg 		     port_type __port_num) noexcept
    1.1  mrg       : _M_data()
    1.1  mrg       {
    1.1  mrg 	if (__addr.is_v4())
    1.1  mrg 	  {
    1.1  mrg 	    _M_data._M_v4.sin_family = protocol_type::v4().family();
    1.1  mrg 	    _M_data._M_v4.sin_port = address_v4::_S_hton_16(__port_num);
1.1.1.6  mrg 	    std::_Construct(&_M_data._M_v4.sin_addr.s_addr,
1.1.1.6  mrg 			    __addr._M_v4._M_addr);
    1.1  mrg 	  }
    1.1  mrg 	else
    1.1  mrg 	  {
1.1.1.6  mrg 	    std::_Construct(&_M_data._M_v6);
    1.1  mrg 	    _M_data._M_v6.sin6_family = protocol_type::v6().family();
    1.1  mrg 	    _M_data._M_v6.sin6_port = address_v4::_S_hton_16(__port_num);
1.1.1.6  mrg 	    if (std::__is_constant_evaluated())
1.1.1.6  mrg 	      std::_Construct(&_M_data._M_v6.sin6_addr.s6_addr);
1.1.1.6  mrg 	    uint8_t* __s6a = _M_data._M_v6.sin6_addr.s6_addr;
1.1.1.6  mrg 	    for (int __i = 0; __i < 16; ++__i)
1.1.1.6  mrg 	      __s6a[__i] = __addr._M_v6._M_bytes[__i];
    1.1  mrg 	    _M_data._M_v6.sin6_scope_id = __addr._M_v6._M_scope_id;
    1.1  mrg 	  }
    1.1  mrg       }
    1.1  mrg
    1.1  mrg       // members:
1.1.1.6  mrg
    1.1  mrg       constexpr protocol_type protocol() const noexcept
    1.1  mrg       {
1.1.1.4  mrg 	return _M_is_v6() ? protocol_type::v6() : protocol_type::v4();
    1.1  mrg       }
    1.1  mrg
    1.1  mrg       constexpr ip::address
    1.1  mrg       address() const noexcept
    1.1  mrg       {
1.1.1.4  mrg 	if (_M_is_v6())
    1.1  mrg 	  {
1.1.1.6  mrg 	    address_v6 __v6;
1.1.1.6  mrg 	    const uint8_t* __s6a = _M_data._M_v6.sin6_addr.s6_addr;
1.1.1.6  mrg 	    for (int __i = 0; __i < 16; ++__i)
1.1.1.6  mrg 	      __v6._M_bytes[__i] = __s6a[__i];
1.1.1.6  mrg 	    __v6._M_scope_id = _M_data._M_v6.sin6_scope_id;
1.1.1.6  mrg 	    return __v6;
    1.1  mrg 	  }
    1.1  mrg 	else
    1.1  mrg 	  {
1.1.1.6  mrg 	    address_v4 __v4;
1.1.1.6  mrg 	    __v4._M_addr = _M_data._M_v4.sin_addr.s_addr;
1.1.1.6  mrg 	    return __v4;
    1.1  mrg 	  }
    1.1  mrg       }
    1.1  mrg
    1.1  mrg       void
    1.1  mrg       address(const ip::address& __addr) noexcept
    1.1  mrg       {
    1.1  mrg 	if (__addr.is_v6())
    1.1  mrg 	  {
1.1.1.6  mrg 	    std::_Construct(&_M_data._M_v6);
    1.1  mrg 	    _M_data._M_v6.sin6_family = protocol_type::v6().family();
    1.1  mrg 	    __builtin_memcpy(_M_data._M_v6.sin6_addr.s6_addr,
    1.1  mrg 			     __addr._M_v6._M_bytes.data(), 16);
    1.1  mrg 	    _M_data._M_v6.sin6_scope_id = __addr._M_v6._M_scope_id;
    1.1  mrg 	  }
    1.1  mrg 	else
    1.1  mrg 	  {
1.1.1.6  mrg 	    std::_Construct(&_M_data._M_v4);
    1.1  mrg 	    _M_data._M_v4.sin_family = protocol_type::v4().family();
    1.1  mrg 	    _M_data._M_v4.sin_addr.s_addr = __addr._M_v4._M_addr;
    1.1  mrg 	  }
    1.1  mrg       }
    1.1  mrg
    1.1  mrg       constexpr port_type
    1.1  mrg       port() const noexcept
1.1.1.6  mrg       {
1.1.1.6  mrg 	port_type __p = 0;
1.1.1.6  mrg 	if (_M_is_v6())
1.1.1.6  mrg 	  __p = _M_data._M_v6.sin6_port;
1.1.1.6  mrg 	else
1.1.1.6  mrg 	  __p = _M_data._M_v4.sin_port;
1.1.1.6  mrg 	return address_v4::_S_ntoh_16(__p);
1.1.1.6  mrg       }
    1.1  mrg
    1.1  mrg       void
    1.1  mrg       port(port_type __port_num) noexcept
1.1.1.6  mrg       {
1.1.1.6  mrg 	__port_num = address_v4::_S_hton_16(__port_num);
1.1.1.6  mrg 	if (_M_is_v6())
1.1.1.6  mrg 	  _M_data._M_v6.sin6_port = __port_num;
1.1.1.6  mrg 	else
1.1.1.6  mrg 	  _M_data._M_v4.sin_port = __port_num;
1.1.1.6  mrg       }
    1.1  mrg
    1.1  mrg       void* data() noexcept { return &_M_data; }
1.1.1.4  mrg
    1.1  mrg       const void* data() const noexcept { return &_M_data; }
1.1.1.4  mrg
1.1.1.6  mrg       constexpr size_t
1.1.1.6  mrg       size() const noexcept
1.1.1.4  mrg       { return _M_is_v6() ? sizeof(sockaddr_in6) : sizeof(sockaddr_in); }
    1.1  mrg
    1.1  mrg       void
    1.1  mrg       resize(size_t __s)
    1.1  mrg       {
1.1.1.4  mrg 	if (__s != size())
    1.1  mrg 	  __throw_length_error("net::ip::basic_endpoint::resize");
    1.1  mrg       }
    1.1  mrg
    1.1  mrg       constexpr size_t capacity() const noexcept { return sizeof(_M_data); }
    1.1  mrg
    1.1  mrg     private:
    1.1  mrg       union
    1.1  mrg       {
    1.1  mrg 	sockaddr_in	_M_v4;
    1.1  mrg 	sockaddr_in6	_M_v6;
    1.1  mrg       } _M_data;
1.1.1.4  mrg
1.1.1.6  mrg       constexpr bool
1.1.1.6  mrg       _M_is_v6() const noexcept
1.1.1.6  mrg       {
1.1.1.6  mrg 	// For constexpr eval we can just detect which union member is active.
1.1.1.6  mrg 	// i.e. emulate P2641R1's std::is_active_member(&_M_data._M_v6)).
1.1.1.6  mrg 	if (std::__is_constant_evaluated())
1.1.1.6  mrg 	  return __builtin_constant_p(_M_data._M_v6.sin6_family);
1.1.1.6  mrg 	return _M_data._M_v6.sin6_family == AF_INET6;
1.1.1.6  mrg       }
    1.1  mrg     };
    1.1  mrg
    1.1  mrg   /** basic_endpoint comparisons
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   template<typename _InternetProtocol>
1.1.1.6  mrg     constexpr bool
    1.1  mrg     operator==(const basic_endpoint<_InternetProtocol>& __a,
    1.1  mrg 	       const basic_endpoint<_InternetProtocol>& __b)
    1.1  mrg     { return __a.address() == __b.address() && __a.port() == __b.port(); }
    1.1  mrg
    1.1  mrg   template<typename _InternetProtocol>
1.1.1.6  mrg     constexpr bool
    1.1  mrg     operator!=(const basic_endpoint<_InternetProtocol>& __a,
    1.1  mrg 	       const basic_endpoint<_InternetProtocol>& __b)
    1.1  mrg     { return !(__a == __b); }
    1.1  mrg
    1.1  mrg   template<typename _InternetProtocol>
1.1.1.6  mrg     constexpr bool
    1.1  mrg     operator< (const basic_endpoint<_InternetProtocol>& __a,
    1.1  mrg 	       const basic_endpoint<_InternetProtocol>& __b)
    1.1  mrg     {
    1.1  mrg       return __a.address() < __b.address()
    1.1  mrg 	|| (!(__b.address() < __a.address()) && __a.port() < __b.port());
    1.1  mrg     }
    1.1  mrg
    1.1  mrg   template<typename _InternetProtocol>
1.1.1.6  mrg     constexpr bool
    1.1  mrg     operator> (const basic_endpoint<_InternetProtocol>& __a,
    1.1  mrg 	       const basic_endpoint<_InternetProtocol>& __b)
    1.1  mrg     { return __b < __a; }
    1.1  mrg
    1.1  mrg   template<typename _InternetProtocol>
1.1.1.6  mrg     constexpr bool
    1.1  mrg     operator<=(const basic_endpoint<_InternetProtocol>& __a,
    1.1  mrg 	       const basic_endpoint<_InternetProtocol>& __b)
    1.1  mrg     { return !(__b < __a); }
    1.1  mrg
    1.1  mrg   template<typename _InternetProtocol>
1.1.1.6  mrg     constexpr bool
    1.1  mrg     operator>=(const basic_endpoint<_InternetProtocol>& __a,
    1.1  mrg 	       const basic_endpoint<_InternetProtocol>& __b)
    1.1  mrg     { return !(__a < __b); }
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /// basic_endpoint I/O
    1.1  mrg   template<typename _CharT, typename _Traits, typename _InternetProtocol>
    1.1  mrg     inline basic_ostream<_CharT, _Traits>&
    1.1  mrg     operator<<(basic_ostream<_CharT, _Traits>& __os,
    1.1  mrg 	       const basic_endpoint<_InternetProtocol>& __ep)
    1.1  mrg     {
    1.1  mrg       basic_ostringstream<_CharT, _Traits> __ss;
    1.1  mrg       if (__ep.protocol()
    1.1  mrg 	  == basic_endpoint<_InternetProtocol>::protocol_type::v6())
    1.1  mrg 	__ss << '[' << __ep.address() << ']';
    1.1  mrg       else
    1.1  mrg 	__ss << __ep.address();
    1.1  mrg       __ss << ':' << __ep.port();
    1.1  mrg       __os << __ss.str();
    1.1  mrg       return __os;
    1.1  mrg     }
    1.1  mrg
    1.1  mrg   /** Type representing a single result of name/address resolution.
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   template<typename _InternetProtocol>
    1.1  mrg     class basic_resolver_entry
    1.1  mrg     {
    1.1  mrg     public:
    1.1  mrg       // types:
1.1.1.4  mrg       using protocol_type = _InternetProtocol;
1.1.1.4  mrg       using endpoint_type = typename _InternetProtocol::endpoint;
    1.1  mrg
    1.1  mrg       // constructors:
    1.1  mrg       basic_resolver_entry() { }
    1.1  mrg
    1.1  mrg       basic_resolver_entry(const endpoint_type& __ep,
    1.1  mrg 			   string_view __h, string_view __s)
    1.1  mrg       : _M_ep(__ep), _M_host(__h), _M_svc(__s) { }
    1.1  mrg
    1.1  mrg       // members:
    1.1  mrg       endpoint_type endpoint() const { return _M_ep; }
    1.1  mrg       operator endpoint_type() const { return _M_ep; }
    1.1  mrg
    1.1  mrg       template<typename _Allocator = allocator<char>>
    1.1  mrg 	__string_with<_Allocator>
    1.1  mrg 	host_name(const _Allocator& __a = _Allocator()) const
    1.1  mrg 	{ return { _M_host, __a }; }
    1.1  mrg
    1.1  mrg       template<typename _Allocator = allocator<char>>
    1.1  mrg 	__string_with<_Allocator>
    1.1  mrg 	service_name(const _Allocator& __a = _Allocator()) const
    1.1  mrg 	{ return { _M_svc, __a }; }
    1.1  mrg
    1.1  mrg     private:
    1.1  mrg       basic_endpoint<_InternetProtocol> _M_ep;
    1.1  mrg       string _M_host;
    1.1  mrg       string _M_svc;
    1.1  mrg     };
    1.1  mrg
    1.1  mrg   template<typename _InternetProtocol>
    1.1  mrg     inline bool
    1.1  mrg     operator==(const basic_resolver_entry<_InternetProtocol>& __a,
    1.1  mrg 	       const basic_resolver_entry<_InternetProtocol>& __b)
    1.1  mrg     {
    1.1  mrg       return __a.endpoint() == __b.endpoint()
    1.1  mrg 	&& __a.host_name() == __b.host_name()
    1.1  mrg 	&& __a.service_name() == __b.service_name();
    1.1  mrg     }
    1.1  mrg
    1.1  mrg   template<typename _InternetProtocol>
    1.1  mrg     inline bool
    1.1  mrg     operator!=(const basic_resolver_entry<_InternetProtocol>& __a,
    1.1  mrg 	       const basic_resolver_entry<_InternetProtocol>& __b)
    1.1  mrg     { return !(__a == __b); }
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /** Base class defining flags for name/address resolution.
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   class resolver_base
    1.1  mrg   {
    1.1  mrg   public:
1.1.1.4  mrg     enum flags : int { };
1.1.1.4  mrg     static constexpr flags passive		= (flags)AI_PASSIVE;
1.1.1.4  mrg     static constexpr flags canonical_name	= (flags)AI_CANONNAME;
1.1.1.4  mrg     static constexpr flags numeric_host		= (flags)AI_NUMERICHOST;
    1.1  mrg #ifdef AI_NUMERICSERV
1.1.1.4  mrg     static constexpr flags numeric_service	= (flags)AI_NUMERICSERV;
    1.1  mrg #endif
1.1.1.4  mrg #ifdef AI_V4MAPPED
1.1.1.4  mrg     static constexpr flags v4_mapped		= (flags)AI_V4MAPPED;
1.1.1.4  mrg #endif
1.1.1.4  mrg #ifdef AI_ALL
1.1.1.4  mrg     static constexpr flags all_matching		= (flags)AI_ALL;
1.1.1.4  mrg #endif
1.1.1.4  mrg #ifdef AI_ADDRCONFIG
1.1.1.4  mrg     static constexpr flags address_configured	= (flags)AI_ADDRCONFIG;
    1.1  mrg #endif
1.1.1.4  mrg
1.1.1.4  mrg     friend constexpr flags
1.1.1.4  mrg     operator&(flags __f1, flags __f2) noexcept
1.1.1.4  mrg     { return flags( int(__f1) & int(__f2) ); }
1.1.1.4  mrg
1.1.1.4  mrg     friend constexpr flags
1.1.1.4  mrg     operator|(flags __f1, flags __f2) noexcept
1.1.1.4  mrg     { return flags( int(__f1) | int(__f2) ); }
1.1.1.4  mrg
1.1.1.4  mrg     friend constexpr flags
1.1.1.4  mrg     operator^(flags __f1, flags __f2) noexcept
1.1.1.4  mrg     { return flags( int(__f1) ^ int(__f2) ); }
1.1.1.4  mrg
1.1.1.4  mrg     friend constexpr flags
1.1.1.4  mrg     operator~(flags __f) noexcept
1.1.1.4  mrg     { return flags( ~int(__f) ); }
1.1.1.4  mrg
1.1.1.4  mrg     friend constexpr flags&
1.1.1.4  mrg     operator&=(flags& __f1, flags __f2) noexcept
1.1.1.4  mrg     { return __f1 = (__f1 & __f2); }
1.1.1.4  mrg
1.1.1.4  mrg     friend constexpr flags&
1.1.1.4  mrg     operator|=(flags& __f1, flags __f2) noexcept
1.1.1.4  mrg     { return __f1 = (__f1 | __f2); }
1.1.1.4  mrg
1.1.1.4  mrg     friend constexpr flags&
1.1.1.4  mrg     operator^=(flags& __f1, flags __f2) noexcept
1.1.1.4  mrg     { return __f1 = (__f1 ^ __f2); }
    1.1  mrg
    1.1  mrg   protected:
    1.1  mrg     resolver_base() = default;
    1.1  mrg     ~resolver_base() = default;
    1.1  mrg   };
    1.1  mrg
1.1.1.4  mrg   // TODO define resolver_base::flags static constants in .so for C++14 mode
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /** Container for results of name/address resolution.
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   template<typename _InternetProtocol>
    1.1  mrg     class basic_resolver_results
    1.1  mrg     {
    1.1  mrg     public:
    1.1  mrg       // types:
1.1.1.4  mrg       using protocol_type = _InternetProtocol;
1.1.1.4  mrg       using endpoint_type = typename protocol_type::endpoint;
1.1.1.4  mrg       using value_type = basic_resolver_entry<protocol_type>;
1.1.1.4  mrg       using const_reference = const value_type&;
1.1.1.4  mrg       using reference = value_type&;
1.1.1.4  mrg       using const_iterator = typename forward_list<value_type>::const_iterator;
1.1.1.4  mrg       using iterator = const_iterator;
1.1.1.4  mrg       using difference_type = ptrdiff_t;
1.1.1.4  mrg       using size_type = size_t;
    1.1  mrg
    1.1  mrg       // construct / copy / destroy:
    1.1  mrg
    1.1  mrg       basic_resolver_results() = default;
    1.1  mrg
    1.1  mrg       basic_resolver_results(const basic_resolver_results&) = default;
    1.1  mrg
    1.1  mrg       basic_resolver_results(basic_resolver_results&&) noexcept = default;
    1.1  mrg
    1.1  mrg       basic_resolver_results&
    1.1  mrg       operator=(const basic_resolver_results&) = default;
    1.1  mrg
    1.1  mrg       basic_resolver_results&
    1.1  mrg       operator=(basic_resolver_results&&) = default;
    1.1  mrg
    1.1  mrg       ~basic_resolver_results() = default;
    1.1  mrg
    1.1  mrg       // size:
    1.1  mrg       size_type size() const noexcept { return _M_size; }
    1.1  mrg       size_type max_size() const noexcept { return _M_results.max_size(); }
1.1.1.2  mrg
1.1.1.2  mrg       _GLIBCXX_NODISCARD bool
1.1.1.2  mrg       empty() const noexcept { return _M_results.empty(); }
    1.1  mrg
    1.1  mrg       // element access:
    1.1  mrg       const_iterator begin() const { return _M_results.begin(); }
    1.1  mrg       const_iterator end() const { return _M_results.end(); }
    1.1  mrg       const_iterator cbegin() const { return _M_results.begin(); }
    1.1  mrg       const_iterator cend() const { return _M_results.end(); }
    1.1  mrg
    1.1  mrg       // swap:
    1.1  mrg       void
    1.1  mrg       swap(basic_resolver_results& __that) noexcept
    1.1  mrg       { _M_results.swap(__that._M_results); }
    1.1  mrg
    1.1  mrg     private:
    1.1  mrg       friend class basic_resolver<protocol_type>;
    1.1  mrg
    1.1  mrg       basic_resolver_results(string_view, string_view, resolver_base::flags,
    1.1  mrg 			     error_code&, protocol_type* = nullptr);
    1.1  mrg
    1.1  mrg       basic_resolver_results(const endpoint_type&, error_code&);
    1.1  mrg
    1.1  mrg       forward_list<value_type> _M_results;
    1.1  mrg       size_t _M_size = 0;
    1.1  mrg     };
    1.1  mrg
    1.1  mrg   template<typename _InternetProtocol>
    1.1  mrg     inline bool
    1.1  mrg     operator==(const basic_resolver_results<_InternetProtocol>& __a,
    1.1  mrg 	       const basic_resolver_results<_InternetProtocol>& __b)
    1.1  mrg     {
    1.1  mrg       return __a.size() == __b.size()
    1.1  mrg 	&& std::equal(__a.begin(), __a.end(), __b.begin());
    1.1  mrg     }
    1.1  mrg
    1.1  mrg   template<typename _InternetProtocol>
    1.1  mrg     inline bool
    1.1  mrg     operator!=(const basic_resolver_results<_InternetProtocol>& __a,
    1.1  mrg 	       const basic_resolver_results<_InternetProtocol>& __b)
    1.1  mrg     { return !(__a == __b); }
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg   /// Perform name/address resolution.
    1.1  mrg   template<typename _InternetProtocol>
    1.1  mrg     class basic_resolver : public resolver_base
    1.1  mrg     {
    1.1  mrg     public:
    1.1  mrg       // types:
    1.1  mrg
1.1.1.4  mrg       using executor_type = io_context::executor_type;
1.1.1.4  mrg       using protocol_type = _InternetProtocol;
1.1.1.4  mrg       using endpoint_type = typename _InternetProtocol::endpoint;
1.1.1.4  mrg       using results_type = basic_resolver_results<_InternetProtocol>;
    1.1  mrg
    1.1  mrg       // construct / copy / destroy:
    1.1  mrg
    1.1  mrg       explicit basic_resolver(io_context& __ctx) : _M_ctx(&__ctx) { }
    1.1  mrg
    1.1  mrg       basic_resolver(const basic_resolver&) = delete;
    1.1  mrg
    1.1  mrg       basic_resolver(basic_resolver&& __rhs) noexcept
    1.1  mrg       : _M_ctx(__rhs._M_ctx)
    1.1  mrg       { } // TODO move state/tasks etc.
    1.1  mrg
    1.1  mrg       ~basic_resolver() { cancel(); }
    1.1  mrg
    1.1  mrg       basic_resolver& operator=(const basic_resolver&) = delete;
    1.1  mrg
    1.1  mrg       basic_resolver& operator=(basic_resolver&& __rhs)
    1.1  mrg       {
    1.1  mrg 	cancel();
    1.1  mrg 	_M_ctx = __rhs._M_ctx;
    1.1  mrg 	// TODO move state/tasks etc.
    1.1  mrg 	return *this;
    1.1  mrg       }
    1.1  mrg
    1.1  mrg       // basic_resolver operations:
    1.1  mrg
    1.1  mrg       executor_type get_executor() noexcept { return _M_ctx->get_executor(); }
    1.1  mrg
    1.1  mrg       void cancel() { } // TODO
    1.1  mrg
    1.1  mrg       results_type
    1.1  mrg       resolve(string_view __host_name, string_view __service_name)
    1.1  mrg       {
    1.1  mrg 	return resolve(__host_name, __service_name, resolver_base::flags(),
    1.1  mrg 		       __throw_on_error{"basic_resolver::resolve"});
    1.1  mrg       }
    1.1  mrg
    1.1  mrg       results_type
    1.1  mrg       resolve(string_view __host_name, string_view __service_name,
    1.1  mrg 	      error_code& __ec)
    1.1  mrg       {
    1.1  mrg 	return resolve(__host_name, __service_name, resolver_base::flags(),
    1.1  mrg 		       __ec);
    1.1  mrg       }
    1.1  mrg
    1.1  mrg       results_type
    1.1  mrg       resolve(string_view __host_name, string_view __service_name, flags __f)
    1.1  mrg       {
    1.1  mrg 	return resolve(__host_name, __service_name, __f,
    1.1  mrg 		       __throw_on_error{"basic_resolver::resolve"});
    1.1  mrg       }
    1.1  mrg
    1.1  mrg       results_type
    1.1  mrg       resolve(string_view __host_name, string_view __service_name, flags __f,
    1.1  mrg 	      error_code& __ec)
    1.1  mrg       { return {__host_name, __service_name, __f, __ec}; }
    1.1  mrg
    1.1  mrg       template<typename _CompletionToken>
    1.1  mrg 	__deduced_t<_CompletionToken, void(error_code, results_type)>
    1.1  mrg 	async_resolve(string_view __host_name, string_view __service_name,
    1.1  mrg 		      _CompletionToken&& __token)
    1.1  mrg 	{
    1.1  mrg 	  return async_resolve(__host_name, __service_name,
    1.1  mrg 			       resolver_base::flags(),
    1.1  mrg 			       forward<_CompletionToken>(__token));
    1.1  mrg 	}
    1.1  mrg
    1.1  mrg       template<typename _CompletionToken>
    1.1  mrg 	__deduced_t<_CompletionToken, void(error_code, results_type)>
    1.1  mrg 	async_resolve(string_view __host_name, string_view __service_name,
    1.1  mrg 		      flags __f, _CompletionToken&& __token); // TODO
    1.1  mrg
    1.1  mrg       results_type
    1.1  mrg       resolve(const protocol_type& __protocol,
    1.1  mrg 	      string_view __host_name, string_view __service_name)
    1.1  mrg       {
    1.1  mrg 	return resolve(__protocol, __host_name, __service_name,
    1.1  mrg 		       resolver_base::flags(),
    1.1  mrg 		       __throw_on_error{"basic_resolver::resolve"});
    1.1  mrg       }
    1.1  mrg
    1.1  mrg       results_type
    1.1  mrg       resolve(const protocol_type& __protocol,
    1.1  mrg 	      string_view __host_name, string_view __service_name,
    1.1  mrg 	      error_code& __ec)
    1.1  mrg       {
    1.1  mrg 	return resolve(__protocol, __host_name, __service_name,
    1.1  mrg 		       resolver_base::flags(), __ec);
    1.1  mrg       }
    1.1  mrg
    1.1  mrg       results_type
    1.1  mrg       resolve(const protocol_type& __protocol,
    1.1  mrg 	      string_view __host_name, string_view __service_name, flags __f)
    1.1  mrg       {
    1.1  mrg 	return resolve(__protocol, __host_name, __service_name, __f,
    1.1  mrg 		       __throw_on_error{"basic_resolver::resolve"});
    1.1  mrg       }
    1.1  mrg
    1.1  mrg       results_type
    1.1  mrg       resolve(const protocol_type& __protocol,
    1.1  mrg 	      string_view __host_name, string_view __service_name,
    1.1  mrg 	      flags __f, error_code& __ec)
    1.1  mrg       { return {__host_name, __service_name, __f, __ec, &__protocol}; }
    1.1  mrg
    1.1  mrg       template<typename _CompletionToken>
    1.1  mrg 	__deduced_t<_CompletionToken, void(error_code, results_type)>
    1.1  mrg 	async_resolve(const protocol_type& __protocol,
    1.1  mrg 		      string_view __host_name, string_view __service_name,
    1.1  mrg 		      _CompletionToken&& __token)
    1.1  mrg 	{
    1.1  mrg 	  return async_resolve(__protocol, __host_name, __service_name,
    1.1  mrg 			       resolver_base::flags(),
    1.1  mrg 			       forward<_CompletionToken>(__token));
    1.1  mrg 	}
    1.1  mrg
    1.1  mrg       template<typename _CompletionToken>
    1.1  mrg 	__deduced_t<_CompletionToken, void(error_code, results_type)>
    1.1  mrg 	async_resolve(const protocol_type& __protocol,
    1.1  mrg 		      string_view __host_name, string_view __service_name,
    1.1  mrg 		      flags __f, _CompletionToken&& __token); // TODO
    1.1  mrg
    1.1  mrg       results_type
    1.1  mrg       resolve(const endpoint_type& __ep)
    1.1  mrg       { return resolve(__ep, __throw_on_error{"basic_resolver::resolve"}); }
    1.1  mrg
    1.1  mrg       results_type
    1.1  mrg       resolve(const endpoint_type& __ep, error_code& __ec)
    1.1  mrg       { return { __ep, __ec }; }
    1.1  mrg
    1.1  mrg       template<typename _CompletionToken> // TODO
    1.1  mrg 	__deduced_t<_CompletionToken, void(error_code, results_type)>
    1.1  mrg 	async_resolve(const endpoint_type& __ep, _CompletionToken&& __token);
    1.1  mrg
    1.1  mrg     private:
    1.1  mrg       io_context* _M_ctx;
    1.1  mrg     };
    1.1  mrg
    1.1  mrg   /// Private constructor to synchronously resolve host and service names.
    1.1  mrg   template<typename _InternetProtocol>
    1.1  mrg     basic_resolver_results<_InternetProtocol>::
    1.1  mrg     basic_resolver_results(string_view __host_name, string_view __service_name,
    1.1  mrg 			   resolver_base::flags __f, error_code& __ec,
    1.1  mrg 			   protocol_type* __protocol)
    1.1  mrg     {
    1.1  mrg #ifdef _GLIBCXX_HAVE_NETDB_H
    1.1  mrg       string __host;
    1.1  mrg       const char* __h = __host_name.data()
    1.1  mrg 	? (__host = __host_name.to_string()).c_str()
    1.1  mrg 	: nullptr;
    1.1  mrg       string __svc;
    1.1  mrg       const char* __s = __service_name.data()
    1.1  mrg 	? (__svc = __service_name.to_string()).c_str()
    1.1  mrg 	: nullptr;
    1.1  mrg
    1.1  mrg       ::addrinfo __hints{ };
    1.1  mrg       __hints.ai_flags = static_cast<int>(__f);
    1.1  mrg       if (__protocol)
    1.1  mrg 	{
    1.1  mrg 	  __hints.ai_family = __protocol->family();
    1.1  mrg 	  __hints.ai_socktype = __protocol->type();
    1.1  mrg 	  __hints.ai_protocol = __protocol->protocol();
    1.1  mrg 	}
    1.1  mrg       else
    1.1  mrg 	{
    1.1  mrg 	  auto __p = endpoint_type{}.protocol();
    1.1  mrg 	  __hints.ai_family = AF_UNSPEC;
    1.1  mrg 	  __hints.ai_socktype = __p.type();
    1.1  mrg 	  __hints.ai_protocol = __p.protocol();
    1.1  mrg 	}
    1.1  mrg
    1.1  mrg       struct __scoped_addrinfo
    1.1  mrg       {
    1.1  mrg 	~__scoped_addrinfo() { if (_M_p) ::freeaddrinfo(_M_p); }
    1.1  mrg 	::addrinfo* _M_p = nullptr;
    1.1  mrg       } __sai;
    1.1  mrg
    1.1  mrg       if (int __err = ::getaddrinfo(__h, __s, &__hints, &__sai._M_p))
    1.1  mrg 	{
1.1.1.4  mrg 	  __ec = ip::__make_resolver_error_code(__err, errno);
    1.1  mrg 	  return;
    1.1  mrg 	}
    1.1  mrg       __ec.clear();
    1.1  mrg
    1.1  mrg       endpoint_type __ep;
    1.1  mrg       auto __tail = _M_results.before_begin();
    1.1  mrg       for (auto __ai = __sai._M_p; __ai != nullptr; __ai = __ai->ai_next)
    1.1  mrg 	{
    1.1  mrg 	  if (__ai->ai_family == AF_INET || __ai->ai_family == AF_INET6)
    1.1  mrg 	    {
    1.1  mrg 	      if (__ai->ai_addrlen <= __ep.capacity())
    1.1  mrg 		__builtin_memcpy(__ep.data(), __ai->ai_addr, __ai->ai_addrlen);
    1.1  mrg 	      __ep.resize(__ai->ai_addrlen);
    1.1  mrg 	      __tail = _M_results.emplace_after(__tail, __ep, __host, __svc);
    1.1  mrg 	      _M_size++;
    1.1  mrg 	    }
    1.1  mrg 	}
    1.1  mrg #else
    1.1  mrg       __ec = std::make_error_code(errc::operation_not_supported);
    1.1  mrg #endif
    1.1  mrg     }
    1.1  mrg
    1.1  mrg   /// Private constructor to synchronously resolve an endpoint.
    1.1  mrg   template<typename _InternetProtocol>
    1.1  mrg     basic_resolver_results<_InternetProtocol>::
    1.1  mrg     basic_resolver_results(const endpoint_type& __ep, error_code& __ec)
    1.1  mrg     {
    1.1  mrg #ifdef _GLIBCXX_HAVE_NETDB_H
1.1.1.4  mrg       char __host_name[1025];	// glibc NI_MAXHOST
1.1.1.4  mrg       char __service_name[32];  // glibc NI_MAXSERV
    1.1  mrg       int __flags = 0;
    1.1  mrg       if (__ep.protocol().type() == SOCK_DGRAM)
    1.1  mrg 	__flags |= NI_DGRAM;
    1.1  mrg       auto __sa = static_cast<const sockaddr*>(__ep.data());
    1.1  mrg       int __err = ::getnameinfo(__sa, __ep.size(),
    1.1  mrg 				__host_name, sizeof(__host_name),
    1.1  mrg 				__service_name, sizeof(__service_name),
    1.1  mrg 				__flags);
    1.1  mrg       if (__err)
    1.1  mrg 	{
    1.1  mrg 	  __flags |= NI_NUMERICSERV;
    1.1  mrg 	  __err = ::getnameinfo(__sa, __ep.size(),
    1.1  mrg 				__host_name, sizeof(__host_name),
    1.1  mrg 				__service_name, sizeof(__service_name),
    1.1  mrg 				__flags);
    1.1  mrg 	}
    1.1  mrg       if (__err)
1.1.1.4  mrg 	__ec = ip::__make_resolver_error_code(__err, errno);
    1.1  mrg       else
    1.1  mrg 	{
    1.1  mrg 	  __ec.clear();
    1.1  mrg 	  _M_results.emplace_front(__ep, __host_name, __service_name);
    1.1  mrg 	  _M_size = 1;
    1.1  mrg 	}
    1.1  mrg #else
    1.1  mrg       __ec = std::make_error_code(errc::operation_not_supported);
    1.1  mrg #endif
    1.1  mrg     }
1.1.1.5  mrg #endif // IPPROTO_TCP || IPPROTO_UDP
    1.1  mrg
    1.1  mrg   /** The name of the local host.
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
    1.1  mrg   template<typename _Allocator>
    1.1  mrg     __string_with<_Allocator>
    1.1  mrg     host_name(const _Allocator& __a, error_code& __ec)
    1.1  mrg     {
    1.1  mrg #ifdef HOST_NAME_MAX
    1.1  mrg       constexpr size_t __maxlen = HOST_NAME_MAX;
    1.1  mrg #else
    1.1  mrg       constexpr size_t __maxlen = 256;
    1.1  mrg #endif
    1.1  mrg       char __buf[__maxlen + 1];
    1.1  mrg       if (::gethostname(__buf, __maxlen) == -1)
    1.1  mrg 	__ec.assign(errno, generic_category());
    1.1  mrg       __buf[__maxlen] = '\0';
    1.1  mrg       return { __buf, __a };
    1.1  mrg     }
    1.1  mrg
    1.1  mrg   template<typename _Allocator>
    1.1  mrg     inline __string_with<_Allocator>
    1.1  mrg     host_name(const _Allocator& __a)
    1.1  mrg     { return host_name(__a, __throw_on_error{"host_name"}); }
    1.1  mrg
    1.1  mrg   inline string
    1.1  mrg   host_name(error_code& __ec)
    1.1  mrg   { return host_name(std::allocator<char>{}, __ec); }
    1.1  mrg
    1.1  mrg   inline string
    1.1  mrg   host_name()
    1.1  mrg   { return host_name(std::allocator<char>{}, __throw_on_error{"host_name"}); }
    1.1  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
1.1.1.4  mrg #ifdef IPPROTO_TCP
    1.1  mrg   /// The TCP byte-stream protocol.
    1.1  mrg   class tcp
    1.1  mrg   {
    1.1  mrg   public:
    1.1  mrg     // types:
1.1.1.4  mrg     using endpoint = basic_endpoint<tcp>;	 ///< A TCP endpoint.
1.1.1.4  mrg     using resolver = basic_resolver<tcp>;	 ///< A TCP resolver.
1.1.1.4  mrg     using socket = basic_stream_socket<tcp>;	 ///< A TCP socket.
1.1.1.4  mrg     using acceptor = basic_socket_acceptor<tcp>; ///< A TCP acceptor.
1.1.1.6  mrg     using iostream = basic_socket_iostream<tcp>; ///< A TCP iostream.
    1.1  mrg
1.1.1.4  mrg #ifdef TCP_NODELAY
    1.1  mrg     /// Disable coalescing of small segments (i.e. the Nagle algorithm).
    1.1  mrg     struct no_delay : __sockopt_crtp<no_delay, bool>
    1.1  mrg     {
    1.1  mrg       using __sockopt_crtp::__sockopt_crtp;
1.1.1.4  mrg       using __sockopt_crtp::operator=;
    1.1  mrg
    1.1  mrg       static const int _S_level = IPPROTO_TCP;
    1.1  mrg       static const int _S_name = TCP_NODELAY;
    1.1  mrg     };
    1.1  mrg #endif
    1.1  mrg
    1.1  mrg     // static members:
    1.1  mrg
    1.1  mrg     /// A protocol object representing IPv4 TCP.
    1.1  mrg     static constexpr tcp v4() noexcept { return tcp(AF_INET); }
    1.1  mrg     /// A protocol object representing IPv6 TCP.
    1.1  mrg     static constexpr tcp v6() noexcept { return tcp(AF_INET6); }
    1.1  mrg
    1.1  mrg     tcp() = delete;
    1.1  mrg
    1.1  mrg     constexpr int family() const noexcept { return _M_family; }
    1.1  mrg     constexpr int type() const noexcept { return SOCK_STREAM; }
    1.1  mrg     constexpr int protocol() const noexcept { return IPPROTO_TCP; }
    1.1  mrg
    1.1  mrg   private:
    1.1  mrg     constexpr explicit tcp(int __family) : _M_family(__family) { }
    1.1  mrg
    1.1  mrg     int _M_family;
    1.1  mrg   };
    1.1  mrg
    1.1  mrg   /** tcp comparisons
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
1.1.1.4  mrg   constexpr bool
1.1.1.4  mrg   operator==(const tcp& __a, const tcp& __b) noexcept
    1.1  mrg   { return __a.family() == __b.family(); }
    1.1  mrg
1.1.1.4  mrg   constexpr bool
1.1.1.4  mrg   operator!=(const tcp& __a, const tcp& __b) noexcept
    1.1  mrg   { return !(__a == __b); }
    1.1  mrg
1.1.1.3  mrg   /// @}
1.1.1.4  mrg #endif // IPPROTO_TCP
    1.1  mrg
1.1.1.4  mrg #ifdef IPPROTO_UDP
    1.1  mrg   /// The UDP datagram protocol.
    1.1  mrg   class udp
    1.1  mrg   {
    1.1  mrg   public:
    1.1  mrg     // types:
1.1.1.4  mrg     using endpoint = basic_endpoint<udp>;
1.1.1.4  mrg     using resolver = basic_resolver<udp>;
1.1.1.4  mrg     using socket = basic_datagram_socket<udp>;
    1.1  mrg
    1.1  mrg     // static members:
    1.1  mrg     static constexpr udp v4() noexcept { return udp(AF_INET); }
    1.1  mrg     static constexpr udp v6() noexcept { return udp(AF_INET6); }
    1.1  mrg
    1.1  mrg     udp() = delete;
    1.1  mrg
    1.1  mrg     constexpr int family() const noexcept { return _M_family; }
    1.1  mrg     constexpr int type() const noexcept { return SOCK_DGRAM; }
    1.1  mrg     constexpr int protocol() const noexcept { return IPPROTO_UDP; }
    1.1  mrg
    1.1  mrg   private:
    1.1  mrg     constexpr explicit udp(int __family) : _M_family(__family) { }
    1.1  mrg
    1.1  mrg     int _M_family;
    1.1  mrg   };
    1.1  mrg
    1.1  mrg   /** udp comparisons
    1.1  mrg    * @{
    1.1  mrg    */
    1.1  mrg
1.1.1.4  mrg   constexpr bool
1.1.1.4  mrg   operator==(const udp& __a, const udp& __b) noexcept
    1.1  mrg   { return __a.family() == __b.family(); }
    1.1  mrg
1.1.1.4  mrg   constexpr bool
1.1.1.4  mrg   operator!=(const udp& __a, const udp& __b) noexcept
    1.1  mrg   { return !(__a == __b); }
    1.1  mrg
1.1.1.3  mrg   /// @}
1.1.1.4  mrg #endif // IPPROTO_UDP
1.1.1.4  mrg
1.1.1.4  mrg #if defined IPPROTO_IP && defined IPPROTO_IPV6
    1.1  mrg
    1.1  mrg   /// Restrict a socket created for an IPv6 protocol to IPv6 only.
1.1.1.4  mrg   class v6_only : public __sockopt_crtp<v6_only, bool>
    1.1  mrg   {
1.1.1.4  mrg   public:
    1.1  mrg     using __sockopt_crtp::__sockopt_crtp;
1.1.1.4  mrg     using __sockopt_crtp::operator=;
    1.1  mrg
1.1.1.4  mrg   private:
1.1.1.4  mrg     friend __sockopt_crtp<v6_only, bool>;
    1.1  mrg     static const int _S_level = IPPROTO_IPV6;
    1.1  mrg     static const int _S_name = IPV6_V6ONLY;
    1.1  mrg   };
    1.1  mrg
    1.1  mrg   namespace unicast
    1.1  mrg   {
    1.1  mrg     /// Set the default number of hops (TTL) for outbound datagrams.
1.1.1.4  mrg     class hops : public __sockopt_crtp<hops>
    1.1  mrg     {
1.1.1.4  mrg     public:
    1.1  mrg       using __sockopt_crtp::__sockopt_crtp;
1.1.1.4  mrg       using __sockopt_crtp::operator=;
    1.1  mrg
    1.1  mrg       template<typename _Protocol>
    1.1  mrg 	int
    1.1  mrg 	level(const _Protocol& __p) const noexcept
    1.1  mrg 	{ return __p.family() == AF_INET6 ? IPPROTO_IPV6 : IPPROTO_IP; }
    1.1  mrg
    1.1  mrg       template<typename _Protocol>
    1.1  mrg 	int
    1.1  mrg 	name(const _Protocol& __p) const noexcept
    1.1  mrg 	{ return __p.family() == AF_INET6 ? IPV6_UNICAST_HOPS : IP_TTL; }
    1.1  mrg     };
    1.1  mrg   } // namespace unicast
    1.1  mrg
    1.1  mrg   namespace multicast
    1.1  mrg   {
1.1.1.4  mrg     class __mcastopt
    1.1  mrg     {
1.1.1.4  mrg     public:
    1.1  mrg       explicit
1.1.1.4  mrg       __mcastopt(const address& __grp) noexcept
1.1.1.4  mrg       : __mcastopt(__grp.is_v4() ? __mcastopt(__grp.to_v4()) : __mcastopt(__grp.to_v6()))
1.1.1.4  mrg       { }
    1.1  mrg
    1.1  mrg       explicit
1.1.1.4  mrg       __mcastopt(const address_v4& __grp,
1.1.1.4  mrg 		 const address_v4& __iface = address_v4::any()) noexcept
1.1.1.4  mrg       {
1.1.1.4  mrg #if __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__
1.1.1.4  mrg 	_M_v4.imr_multiaddr.s_addr = __grp.to_uint();
1.1.1.4  mrg 	_M_v4.imr_interface.s_addr = __iface.to_uint();
1.1.1.4  mrg #else
1.1.1.4  mrg 	_M_v4.imr_multiaddr.s_addr = __builtin_bswap32(__grp.to_uint());
1.1.1.4  mrg 	_M_v4.imr_interface.s_addr = __builtin_bswap32(__iface.to_uint());
1.1.1.4  mrg #endif
1.1.1.4  mrg       }
    1.1  mrg
    1.1  mrg       explicit
1.1.1.4  mrg       __mcastopt(const address_v6& __grp, unsigned int __iface = 0) noexcept
1.1.1.4  mrg       {
1.1.1.4  mrg 	const auto __addr = __grp.to_bytes();
1.1.1.4  mrg 	__builtin_memcpy(_M_v6.ipv6mr_multiaddr.s6_addr, __addr.data(), 16);
1.1.1.4  mrg 	_M_v6.ipv6mr_interface = __iface;
1.1.1.4  mrg       }
    1.1  mrg
    1.1  mrg       template<typename _Protocol>
    1.1  mrg 	int
    1.1  mrg 	level(const _Protocol& __p) const noexcept
    1.1  mrg 	{ return __p.family() == AF_INET6 ? IPPROTO_IPV6 : IPPROTO_IP; }
    1.1  mrg
    1.1  mrg       template<typename _Protocol>
    1.1  mrg 	const void*
1.1.1.4  mrg 	data(const _Protocol& __p) const noexcept
1.1.1.4  mrg 	{ return __p.family() == AF_INET6 ? &_M_v6 : &_M_v4; }
    1.1  mrg
    1.1  mrg       template<typename _Protocol>
    1.1  mrg 	size_t
    1.1  mrg 	size(const _Protocol& __p) const noexcept
1.1.1.4  mrg 	{ return __p.family() == AF_INET6 ? sizeof(_M_v6) : sizeof(_M_v4); }
    1.1  mrg
1.1.1.4  mrg     private:
1.1.1.4  mrg       ipv6_mreq _M_v6 = {};
1.1.1.4  mrg       ip_mreq _M_v4 = {};
    1.1  mrg     };
    1.1  mrg
1.1.1.4  mrg     /// Request that a socket joins a multicast group.
1.1.1.4  mrg     class join_group : private __mcastopt
    1.1  mrg     {
1.1.1.4  mrg     public:
1.1.1.4  mrg       using __mcastopt::__mcastopt;
1.1.1.4  mrg       using __mcastopt::level;
1.1.1.4  mrg       using __mcastopt::data;
1.1.1.4  mrg       using __mcastopt::size;
    1.1  mrg
    1.1  mrg       template<typename _Protocol>
    1.1  mrg 	int
    1.1  mrg 	name(const _Protocol& __p) const noexcept
    1.1  mrg 	{
1.1.1.4  mrg 	  if (__p.family() == AF_INET6)
1.1.1.4  mrg 	    return IPV6_JOIN_GROUP;
1.1.1.4  mrg 	  return IP_ADD_MEMBERSHIP;
    1.1  mrg 	}
1.1.1.4  mrg     };
    1.1  mrg
1.1.1.4  mrg     /// Request that a socket leaves a multicast group.
1.1.1.4  mrg     class leave_group : private __mcastopt
1.1.1.4  mrg     {
1.1.1.4  mrg     public:
1.1.1.4  mrg       using __mcastopt::__mcastopt;
1.1.1.4  mrg       using __mcastopt::level;
1.1.1.4  mrg       using __mcastopt::data;
1.1.1.4  mrg       using __mcastopt::size;
    1.1  mrg
    1.1  mrg       template<typename _Protocol>
1.1.1.4  mrg 	int
1.1.1.4  mrg 	name(const _Protocol& __p) const noexcept
    1.1  mrg 	{
1.1.1.4  mrg 	  if (__p.family() == AF_INET6)
1.1.1.4  mrg 	    return IPV6_LEAVE_GROUP;
1.1.1.4  mrg 	  return IP_DROP_MEMBERSHIP;
    1.1  mrg 	}
    1.1  mrg     };
    1.1  mrg
    1.1  mrg     /// Specify the network interface for outgoing multicast datagrams.
    1.1  mrg     class outbound_interface
    1.1  mrg     {
1.1.1.4  mrg     public:
    1.1  mrg       explicit
1.1.1.4  mrg       outbound_interface(const address_v4& __v4) noexcept
1.1.1.4  mrg       {
1.1.1.4  mrg #if __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__
1.1.1.4  mrg 	_M_v4.s_addr = __v4.to_uint();
1.1.1.4  mrg #else
1.1.1.4  mrg 	_M_v4.s_addr = __builtin_bswap32(__v4.to_uint());
1.1.1.4  mrg #endif
1.1.1.4  mrg       }
    1.1  mrg
    1.1  mrg       explicit
1.1.1.4  mrg       outbound_interface(unsigned int __v6) noexcept
1.1.1.4  mrg       : _M_v4(), _M_v6(__v6)
1.1.1.4  mrg       { }
    1.1  mrg
    1.1  mrg       template<typename _Protocol>
    1.1  mrg 	int
    1.1  mrg 	level(const _Protocol& __p) const noexcept
    1.1  mrg 	{ return __p.family() == AF_INET6 ? IPPROTO_IPV6 : IPPROTO_IP; }
    1.1  mrg
    1.1  mrg       template<typename _Protocol>
    1.1  mrg 	int
    1.1  mrg 	name(const _Protocol& __p) const noexcept
    1.1  mrg 	{
    1.1  mrg 	  return __p.family() == AF_INET6
    1.1  mrg 	    ? IPV6_MULTICAST_IF : IP_MULTICAST_IF;
    1.1  mrg 	}
    1.1  mrg
    1.1  mrg       template<typename _Protocol>
    1.1  mrg 	const void*
1.1.1.4  mrg 	data(const _Protocol& __p) const noexcept
1.1.1.4  mrg 	{ return __p.family() == AF_INET6 ? &_M_v6 : &_M_v4; }
    1.1  mrg
    1.1  mrg       template<typename _Protocol>
    1.1  mrg 	size_t
    1.1  mrg 	size(const _Protocol& __p) const noexcept
1.1.1.4  mrg 	{ return __p.family() == AF_INET6 ? sizeof(_M_v6) : sizeof(_M_v4); }
    1.1  mrg
1.1.1.4  mrg     private:
1.1.1.4  mrg       in_addr _M_v4;
1.1.1.4  mrg       unsigned _M_v6 = 0;
    1.1  mrg     };
    1.1  mrg
    1.1  mrg     /// Set the default number of hops (TTL) for outbound datagrams.
1.1.1.4  mrg     class hops : public __sockopt_crtp<hops>
    1.1  mrg     {
1.1.1.4  mrg     public:
    1.1  mrg       using __sockopt_crtp::__sockopt_crtp;
1.1.1.4  mrg       using __sockopt_crtp::operator=;
    1.1  mrg
    1.1  mrg       template<typename _Protocol>
    1.1  mrg 	int
    1.1  mrg 	level(const _Protocol& __p) const noexcept
    1.1  mrg 	{ return __p.family() == AF_INET6 ? IPPROTO_IPV6 : IPPROTO_IP; }
    1.1  mrg
    1.1  mrg       template<typename _Protocol>
    1.1  mrg 	int
    1.1  mrg 	name(const _Protocol& __p) const noexcept
    1.1  mrg 	{
    1.1  mrg 	  return __p.family() == AF_INET6
    1.1  mrg 	    ? IPV6_MULTICAST_HOPS : IP_MULTICAST_TTL;
    1.1  mrg 	}
    1.1  mrg     };
    1.1  mrg
    1.1  mrg     /// Set whether datagrams are delivered back to the local application.
1.1.1.4  mrg     class enable_loopback : public __sockopt_crtp<enable_loopback, bool>
    1.1  mrg     {
1.1.1.4  mrg     public:
    1.1  mrg       using __sockopt_crtp::__sockopt_crtp;
1.1.1.4  mrg       using __sockopt_crtp::operator=;
    1.1  mrg
    1.1  mrg       template<typename _Protocol>
    1.1  mrg 	int
    1.1  mrg 	level(const _Protocol& __p) const noexcept
    1.1  mrg 	{ return __p.family() == AF_INET6 ? IPPROTO_IPV6 : IPPROTO_IP; }
    1.1  mrg
    1.1  mrg       template<typename _Protocol>
    1.1  mrg 	int
    1.1  mrg 	name(const _Protocol& __p) const noexcept
    1.1  mrg 	{
    1.1  mrg 	  return __p.family() == AF_INET6
    1.1  mrg 	    ? IPV6_MULTICAST_LOOP : IP_MULTICAST_LOOP;
    1.1  mrg 	}
    1.1  mrg     };
    1.1  mrg
    1.1  mrg   } // namespace multicast
    1.1  mrg
1.1.1.4  mrg #endif // IPPROTO_IP && IPPROTO_IPV6
1.1.1.4  mrg
1.1.1.3  mrg   /// @}
    1.1  mrg
    1.1  mrg } // namespace ip
    1.1  mrg } // namespace v1
    1.1  mrg } // namespace net
    1.1  mrg } // namespace experimental
    1.1  mrg
    1.1  mrg   template<>
    1.1  mrg     struct is_error_condition_enum<experimental::net::v1::ip::resolver_errc>
    1.1  mrg     : public true_type {};
    1.1  mrg
    1.1  mrg   // hash support
    1.1  mrg   template<typename _Tp> struct hash;
    1.1  mrg   template<>
    1.1  mrg     struct hash<experimental::net::v1::ip::address>
    1.1  mrg     : __hash_base<size_t, experimental::net::v1::ip::address>
    1.1  mrg     {
    1.1  mrg       size_t
1.1.1.4  mrg       operator()(const experimental::net::v1::ip::address& __a) const
    1.1  mrg       {
    1.1  mrg 	if (__a.is_v4())
    1.1  mrg 	  return _Hash_impl::hash(__a.to_v4());
    1.1  mrg 	else
    1.1  mrg 	  return _Hash_impl::hash(__a.to_v6());
    1.1  mrg       }
    1.1  mrg     };
    1.1  mrg
    1.1  mrg   template<>
    1.1  mrg     struct hash<experimental::net::v1::ip::address_v4>
    1.1  mrg     : __hash_base<size_t, experimental::net::v1::ip::address_v4>
    1.1  mrg     {
    1.1  mrg       size_t
1.1.1.4  mrg       operator()(const experimental::net::v1::ip::address_v4& __a) const
    1.1  mrg       { return _Hash_impl::hash(__a.to_bytes()); }
    1.1  mrg     };
    1.1  mrg
    1.1  mrg   template<> struct hash<experimental::net::v1::ip::address_v6>
    1.1  mrg     : __hash_base<size_t, experimental::net::v1::ip::address_v6>
    1.1  mrg     {
    1.1  mrg       size_t
1.1.1.4  mrg       operator()(const experimental::net::v1::ip::address_v6& __a) const
    1.1  mrg       { return _Hash_impl::hash(__a.to_bytes()); }
    1.1  mrg     };
    1.1  mrg
    1.1  mrg _GLIBCXX_END_NAMESPACE_VERSION
    1.1  mrg } // namespace std
    1.1  mrg
    1.1  mrg #endif // C++14
    1.1  mrg
    1.1  mrg #endif // _GLIBCXX_EXPERIMENTAL_INTERNET