// -*- C++ -*- // Copyright (C) 2015-2021 Free Software Foundation, Inc. // // This file is part of the GNU ISO C++ Library. This library is free // software; you can redistribute it and/or modify it under the // terms of the GNU General Public License as published by the // Free Software Foundation; either version 3, or (at your option) // any later version. // This library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // Under Section 7 of GPL version 3, you are granted additional // permissions described in the GCC Runtime Library Exception, version // 3.1, as published by the Free Software Foundation. // You should have received a copy of the GNU General Public License and // a copy of the GCC Runtime Library Exception along with this program; // see the files COPYING3 and COPYING.RUNTIME respectively. If not, see // . /** @file experimental/socket * This is a TS C++ Library header. * @ingroup networking-ts */ #ifndef _GLIBCXX_EXPERIMENTAL_SOCKET #define _GLIBCXX_EXPERIMENTAL_SOCKET #pragma GCC system_header #if __cplusplus >= 201402L #include #include #include #include #include #include #include #if _GLIBCXX_HAVE_UNISTD_H # include # ifdef _GLIBCXX_HAVE_SYS_SOCKET_H # include // socket etc # endif # ifdef _GLIBCXX_HAVE_SYS_IOCTL_H # include // ioctl # endif # ifdef _GLIBCXX_HAVE_SYS_UIO_H # include // iovec # endif # ifdef _GLIBCXX_HAVE_POLL_H # include // poll, pollfd, POLLIN, POLLOUT, POLLERR # endif # ifdef _GLIBCXX_HAVE_FCNTL_H # include // fcntl, F_GETFL, F_SETFL # endif #endif namespace std _GLIBCXX_VISIBILITY(default) { _GLIBCXX_BEGIN_NAMESPACE_VERSION namespace experimental { namespace net { inline namespace v1 { /** @addtogroup networking-ts * @{ */ enum class socket_errc { // TODO decide values already_open = 3, not_found = 4 }; } // namespace v1 } // namespace net } // namespace experimental template<> struct is_error_code_enum : public true_type {}; namespace experimental { namespace net { inline namespace v1 { const error_category& socket_category() noexcept { struct __cat : error_category { const char* name() const noexcept { return "socket"; } std::string message(int __e) const { if (__e == (int)socket_errc::already_open) return "already open"; else if (__e == (int)socket_errc::not_found) return "endpoint not found"; return "socket error"; } virtual void __message(int) { } // TODO dual ABI XXX }; static __cat __c; return __c; } inline error_code make_error_code(socket_errc __e) noexcept { return error_code(static_cast(__e), socket_category()); } inline error_condition make_error_condition(socket_errc __e) noexcept { return error_condition(static_cast(__e), socket_category()); } // TODO GettableSocket reqs // TODO SettableSocket reqs // TODO BooleanSocketOption reqs // TODO IntegerSocketOption reqs // TODO IoControlCommand reqs // TODO ConnectCondition reqs /** @brief Sockets * @{ */ class socket_base { public: #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H struct broadcast : __sockopt_crtp { using __sockopt_crtp::__sockopt_crtp; static const int _S_level = SOL_SOCKET; static const int _S_name = SO_BROADCAST; }; struct debug : __sockopt_crtp { using __sockopt_crtp::__sockopt_crtp; static const int _S_level = SOL_SOCKET; static const int _S_name = SO_DEBUG; }; struct do_not_route : __sockopt_crtp { using __sockopt_crtp::__sockopt_crtp; static const int _S_level = SOL_SOCKET; static const int _S_name = SO_DONTROUTE; }; struct keep_alive : __sockopt_crtp { using __sockopt_crtp::__sockopt_crtp; static const int _S_level = SOL_SOCKET; static const int _S_name = SO_KEEPALIVE; }; struct linger : __sockopt_crtp { using __sockopt_crtp::__sockopt_crtp; linger() noexcept = default; linger(bool __e, chrono::seconds __t) noexcept { enabled(__e); timeout(__t); } bool enabled() const noexcept { return _M_value.l_onoff != 0; } void enabled(bool __e) noexcept { _M_value.l_onoff = int(__e); } chrono::seconds timeout() const noexcept { return chrono::seconds(_M_value.l_linger); } void timeout(chrono::seconds __t) noexcept { _M_value.l_linger = __t.count(); } static const int _S_level = SOL_SOCKET; static const int _S_name = SO_LINGER; }; struct out_of_band_inline : __sockopt_crtp { using __sockopt_crtp::__sockopt_crtp; static const int _S_level = SOL_SOCKET; static const int _S_name = SO_OOBINLINE; }; struct receive_buffer_size : __sockopt_crtp { using __sockopt_crtp::__sockopt_crtp; static const int _S_level = SOL_SOCKET; static const int _S_name = SO_RCVBUF; }; struct receive_low_watermark : __sockopt_crtp { using __sockopt_crtp::__sockopt_crtp; static const int _S_level = SOL_SOCKET; static const int _S_name = SO_RCVLOWAT; }; struct reuse_address : __sockopt_crtp { using __sockopt_crtp::__sockopt_crtp; static const int _S_level = SOL_SOCKET; static const int _S_name = SO_REUSEADDR; }; struct send_buffer_size : __sockopt_crtp { using __sockopt_crtp::__sockopt_crtp; static const int _S_level = SOL_SOCKET; static const int _S_name = SO_SNDBUF; }; struct send_low_watermark : __sockopt_crtp { using __sockopt_crtp::__sockopt_crtp; static const int _S_level = SOL_SOCKET; static const int _S_name = SO_SNDLOWAT; }; enum shutdown_type : int { __shutdown_receive = SHUT_RD, __shutdown_send = SHUT_WR, __shutdown_both = SHUT_RDWR }; static constexpr shutdown_type shutdown_receive = __shutdown_receive; static constexpr shutdown_type shutdown_send = __shutdown_send; static constexpr shutdown_type shutdown_both = __shutdown_both; #ifdef _GLIBCXX_HAVE_POLL_H enum wait_type : int { __wait_read = POLLIN, __wait_write = POLLOUT, __wait_error = POLLERR }; static constexpr wait_type wait_read = __wait_read; static constexpr wait_type wait_write = __wait_write; static constexpr wait_type wait_error = __wait_error; #endif enum message_flags : int { __message_peek = MSG_PEEK, __message_oob = MSG_OOB, __message_dontroute = MSG_DONTROUTE }; static constexpr message_flags message_peek = __message_peek; static constexpr message_flags message_out_of_band = __message_oob; static constexpr message_flags message_do_not_route = __message_dontroute; static const int max_listen_connections = SOMAXCONN; #endif protected: socket_base() = default; ~socket_base() = default; #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H struct __msg_hdr : ::msghdr { #ifdef IOV_MAX using __iovec_array = array<::iovec, IOV_MAX>; #elif _GLIBCXX_HAVE_UNISTD_H struct __iovec_array { __iovec_array() : _M_ptr(new ::iovec[size()]) { } ::iovec& operator[](size_t __n) noexcept { return _M_ptr[__n]; } ::iovec* data() noexcept { return _M_ptr.get(); } static size_t size() { static const size_t __iov_max = ::sysconf(_SC_IOV_MAX); return __iov_max; } private: unique_ptr<::iovec[]> _M_ptr; }; #else using __iovec_array = array<::iovec, 16>; #endif __iovec_array _M_iov; template explicit __msg_hdr(const _BufferSequence& __buffers) : msghdr() { auto __buf = net::buffer_sequence_begin(__buffers); const auto __bufend = net::buffer_sequence_end(__buffers); size_t __len = 0; while (__buf != __bufend && __len != _M_iov.size()) { _M_iov[__len].iov_base = (void*)__buf->data(); _M_iov[__len].iov_len = __buf->size(); ++__buf; ++__len; } this->msg_iovlen = __len; this->msg_iov = _M_iov.data(); } template __msg_hdr(const _BufferSequence& __buffers, const _Endpoint& __ep) : __msg_hdr(__buffers) { this->msg_name = __ep.data(); this->msg_namelen = __ep.size(); } }; #endif }; constexpr socket_base::message_flags operator&(socket_base::message_flags __f1, socket_base::message_flags __f2) { return socket_base::message_flags( int(__f1) & int(__f2) ); } constexpr socket_base::message_flags operator|(socket_base::message_flags __f1, socket_base::message_flags __f2) { return socket_base::message_flags( int(__f1) | int(__f2) ); } constexpr socket_base::message_flags operator^(socket_base::message_flags __f1, socket_base::message_flags __f2) { return socket_base::message_flags( int(__f1) ^ int(__f2) ); } constexpr socket_base::message_flags operator~(socket_base::message_flags __f) { return socket_base::message_flags( ~int(__f) ); } inline socket_base::message_flags& operator&=(socket_base::message_flags& __f1, socket_base::message_flags __f2) { return __f1 = (__f1 & __f2); } inline socket_base::message_flags& operator|=(socket_base::message_flags& __f1, socket_base::message_flags __f2) { return __f1 = (__f1 | __f2); } inline socket_base::message_flags& operator^=(socket_base::message_flags& __f1, socket_base::message_flags __f2) { return __f1 = (__f1 ^ __f2); } #if _GLIBCXX_HAVE_UNISTD_H class __socket_impl { protected: using executor_type = io_context::executor_type; using native_handle_type = int; explicit __socket_impl(io_context& __ctx) : _M_ctx(std::addressof(__ctx)) { } __socket_impl(__socket_impl&& __rhs) : _M_ctx(__rhs._M_ctx), _M_sockfd(std::exchange(__rhs._M_sockfd, -1)), _M_bits(std::exchange(__rhs._M_bits, {})) { } __socket_impl& operator=(__socket_impl&& __rhs) { _M_ctx = __rhs._M_ctx; _M_sockfd = std::exchange(__rhs._M_sockfd, -1); _M_bits = std::exchange(__rhs._M_bits, {}); return *this; } ~__socket_impl() = default; __socket_impl(const __socket_impl&) = delete; __socket_impl& operator=(const __socket_impl&) = delete; executor_type get_executor() noexcept { return _M_ctx->get_executor(); } native_handle_type native_handle() noexcept { return _M_sockfd; } bool is_open() const noexcept { return _M_sockfd != -1; } void close(error_code& __ec) { if (is_open()) { cancel(__ec); if (!__ec) { if (::close(_M_sockfd) == -1) __ec.assign(errno, generic_category()); else { get_executor().context()._M_remove_fd(_M_sockfd); _M_sockfd = -1; } } } } void cancel(error_code& __ec) { _M_ctx->cancel(_M_sockfd, __ec); } void non_blocking(bool __mode, error_code&) { _M_bits.non_blocking = __mode; } bool non_blocking() const { return _M_bits.non_blocking; } void native_non_blocking(bool __mode, error_code& __ec) { #ifdef _GLIBCXX_HAVE_FCNTL_H int __flags = ::fcntl(_M_sockfd, F_GETFL, 0); if (__flags >= 0) { if (__mode) __flags |= O_NONBLOCK; else __flags &= ~O_NONBLOCK; __flags = ::fcntl(_M_sockfd, F_SETFL, __flags); } if (__flags == -1) __ec.assign(errno, generic_category()); else { __ec.clear(); _M_bits.native_non_blocking = __mode; } #else __ec = std::make_error_code(std::errc::not_supported); #endif } bool native_non_blocking() const { #ifdef _GLIBCXX_HAVE_FCNTL_H if (_M_bits.native_non_blocking == -1) { const int __flags = ::fcntl(_M_sockfd, F_GETFL, 0); if (__flags == -1) return 0; _M_bits.native_non_blocking = __flags & O_NONBLOCK; } return _M_bits.native_non_blocking; #else return false; #endif } io_context* _M_ctx; int _M_sockfd{-1}; struct { unsigned non_blocking : 1; mutable signed native_non_blocking : 2; unsigned enable_connection_aborted : 1; } _M_bits{}; }; template class __basic_socket_impl : public __socket_impl { using __base = __socket_impl; protected: using protocol_type = _Protocol; using endpoint_type = typename protocol_type::endpoint; explicit __basic_socket_impl(io_context& __ctx) : __base(__ctx) { } __basic_socket_impl(__basic_socket_impl&&) = default; template __basic_socket_impl(__basic_socket_impl<_OtherProtocol>&& __rhs) : __base(std::move(__rhs)), _M_protocol(std::move(__rhs._M_protocol)) { } __basic_socket_impl& operator=(__basic_socket_impl&& __rhs) { if (this == std::addressof(__rhs)) return *this; _M_close(); __base::operator=(std::move(__rhs)); return *this; } ~__basic_socket_impl() { _M_close(); } __basic_socket_impl(const __basic_socket_impl&) = delete; __basic_socket_impl& operator=(const __basic_socket_impl&) = delete; void open(const protocol_type& __protocol, error_code& __ec) { #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H if (is_open()) __ec = socket_errc::already_open; else { _M_protocol = __protocol; _M_sockfd = ::socket(__protocol.family(), __protocol.type(), __protocol.protocol()); if (is_open()) { get_executor().context()._M_add_fd(_M_sockfd); __ec.clear(); } else __ec.assign(errno, std::generic_category()); } #else __ec = std::make_error_code(errc::operation_not_supported); #endif } void assign(const protocol_type& __protocol, const native_handle_type& __native_socket, error_code& __ec) { if (is_open()) __ec = socket_errc::already_open; else { _M_protocol = __protocol; _M_bits.native_non_blocking = -1; _M_sockfd = __native_socket; if (is_open()) { get_executor().context()._M_add_fd(_M_sockfd); __ec.clear(); } else __ec.assign(errno, std::generic_category()); } } native_handle_type release(error_code& __ec) { __glibcxx_assert(is_open()); cancel(__ec); return std::exchange(_M_sockfd, -1); } template void set_option(const _SettableSocketOption& __option, error_code& __ec) { int __result = ::setsockopt(_M_sockfd, __option.level(_M_protocol), __option.name(_M_protocol), __option.data(_M_protocol), __option.size(_M_protocol)); if (__result == -1) __ec.assign(errno, generic_category()); else __ec.clear(); } template void get_option(_GettableSocketOption& __option, error_code& __ec) const { int __result = ::getsockopt(_M_sockfd, __option.level(_M_protocol), __option.name(_M_protocol), __option.data(_M_protocol), __option.size(_M_protocol)); if (__result == -1) __ec.assign(errno, generic_category()); else __ec.clear(); } template void io_control(_IoControlCommand& __command, error_code& __ec) { #ifdef _GLIBCXX_HAVE_SYS_IOCTL_H int __result = ::ioctl(_M_sockfd, __command.name(), __command.data()); if (__result == -1) __ec.assign(errno, generic_category()); else __ec.clear(); #else __ec = std::make_error_code(std::errc::not_supported); #endif } endpoint_type local_endpoint(error_code& __ec) const { endpoint_type __endpoint; #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H socklen_t __endpoint_len = __endpoint.capacity(); if (::getsockname(_M_sockfd, (sockaddr*)__endpoint.data(), &__endpoint_len) == -1) { __ec.assign(errno, generic_category()); return endpoint_type{}; } __ec.clear(); __endpoint.resize(__endpoint_len); #else __ec = std::make_error_code(errc::operation_not_supported); #endif return __endpoint; } void bind(const endpoint_type& __endpoint, error_code& __ec) { #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H if (::bind(_M_sockfd, (sockaddr*)__endpoint.data(), __endpoint.size()) == -1) __ec.assign(errno, generic_category()); else __ec.clear(); #else __ec = std::make_error_code(errc::operation_not_supported); #endif } _Protocol _M_protocol{ endpoint_type{}.protocol() }; private: void _M_close() { if (is_open()) { error_code __ec; cancel(__ec); set_option(socket_base::linger{false, chrono::seconds{}}, __ec); ::close(_M_sockfd); } } }; template class basic_socket : public socket_base, private __basic_socket_impl<_Protocol> { using __base = __basic_socket_impl<_Protocol>; public: // types: using executor_type = io_context::executor_type; using native_handle_type = int; using protocol_type = _Protocol; using endpoint_type = typename protocol_type::endpoint; static_assert(__detail::__protocol, "protocol_type meets the Protocol requirements"); // basic_socket operations: executor_type get_executor() noexcept { return __base::get_executor(); } native_handle_type native_handle() noexcept { return __base::native_handle(); } void open(const protocol_type& __protocol = protocol_type()) { open(__protocol, __throw_on_error{"basic_socket::open"}); } void open(const protocol_type& __protocol, error_code& __ec) { __base::open(__protocol, __ec); } void assign(const protocol_type& __protocol, const native_handle_type& __native_socket) { assign(__protocol, __native_socket, __throw_on_error{"basic_socket::assign"}); } void assign(const protocol_type& __protocol, const native_handle_type& __native_socket, error_code& __ec) { __base::assign(__protocol, __native_socket, __ec); } native_handle_type release() { return release(__throw_on_error{"basic_socket::release"}); } native_handle_type release(error_code& __ec) { return __base::release(__ec); } _GLIBCXX_NODISCARD bool is_open() const noexcept { return __base::is_open(); } void close() { close(__throw_on_error{"basic_socket::close"}); } void close(error_code& __ec) { __base::close(__ec); } void cancel() { cancel(__throw_on_error{"basic_socket::cancel"}); } void cancel(error_code& __ec) { __base::cancel(__ec); } template void set_option(const _SettableSocketOption& __option) { set_option(__option, __throw_on_error{"basic_socket::set_option"}); } template void set_option(const _SettableSocketOption& __option, error_code& __ec) { __base::set_option(__option, __ec); } template void get_option(_GettableSocketOption& __option) const { get_option(__option, __throw_on_error{"basic_socket::get_option"}); } template void get_option(_GettableSocketOption& __option, error_code& __ec) const { __base::get_option(__option, __ec); } template void io_control(_IoControlCommand& __command) { io_control(__command, __throw_on_error{"basic_socket::io_control"}); } template void io_control(_IoControlCommand& __command, error_code& __ec) { __base::io_control(__command, __ec); } void non_blocking(bool __mode) { non_blocking(__mode, __throw_on_error{"basic_socket::non_blocking"}); } void non_blocking(bool __mode, error_code& __ec) { __base::non_blocking(__mode, __ec); } bool non_blocking() const { return __base::non_blocking(); } void native_non_blocking(bool __mode) { native_non_blocking(__mode, __throw_on_error{ "basic_socket::native_non_blocking"}); } void native_non_blocking(bool __mode, error_code& __ec) { __base::native_non_blocking(__mode, __ec); } bool native_non_blocking() const { return __base::native_non_blocking(); } bool at_mark() const { return at_mark(__throw_on_error{"basic_socket::at_mark"}); } bool at_mark(error_code& __ec) const { #ifdef _GLIBCXX_HAVE_SOCKATMARK const int __result = ::sockatmark(native_handle()); if (__result == -1) { __ec.assign(errno, generic_category()); return false; } __ec.clear(); return (bool)__result; #else __ec = std::make_error_code(errc::operation_not_supported); return false; #endif } size_t available() const { return available(__throw_on_error{"basic_socket::available"}); } size_t available(error_code& __ec) const { if (!is_open()) { __ec = std::make_error_code(errc::bad_file_descriptor); return 0; } #if defined _GLIBCXX_HAVE_SYS_IOCTL_H && defined FIONREAD int __avail = 0; if (::ioctl(this->_M_sockfd, FIONREAD, &__avail) == -1) { __ec.assign(errno, generic_category()); return 0; } __ec.clear(); return __avail; #else return 0; #endif } void bind(const endpoint_type& __endpoint) { return bind(__endpoint, __throw_on_error{"basic_socket::bind"}); } void bind(const endpoint_type& __endpoint, error_code& __ec) { __base::bind(__endpoint, __ec); } void shutdown(shutdown_type __what) { return shutdown(__what, __throw_on_error{"basic_socket::shutdown"}); } void shutdown(shutdown_type __what, error_code& __ec) { #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H if (::shutdown(native_handle(), static_cast(__what)) == -1) __ec.assign(errno, generic_category()); else __ec.clear(); #else __ec = std::make_error_code(errc::operation_not_supported); #endif } endpoint_type local_endpoint() const { return local_endpoint( __throw_on_error{"basic_socket::local_endpoint"}); } endpoint_type local_endpoint(error_code& __ec) const { return __base::local_endpoint(__ec); } endpoint_type remote_endpoint() const { return remote_endpoint( __throw_on_error{"basic_socket::remote_endpoint"}); } endpoint_type remote_endpoint(error_code& __ec) const { endpoint_type __endpoint; #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H socklen_t __endpoint_len = __endpoint.capacity(); if (::getpeername(this->_M_sockfd, (sockaddr*)__endpoint.data(), &__endpoint_len) == -1) { __ec.assign(errno, generic_category()); return endpoint_type{}; } __ec.clear(); __endpoint.resize(__endpoint_len); #else __ec = std::make_error_code(errc::operation_not_supported); #endif return __endpoint; } void connect(const endpoint_type& __endpoint) { return connect(__endpoint, __throw_on_error{"basic_socket::connect"}); } void connect(const endpoint_type& __endpoint, error_code& __ec) { #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H if (!is_open()) { open(__endpoint.protocol(), __ec); if (__ec) return; } if (::connect(native_handle(), (const sockaddr*)__endpoint.data(), __endpoint.size()) == -1) __ec.assign(errno, generic_category()); else __ec.clear(); #else __ec = std::make_error_code(errc::operation_not_supported); #endif } template __deduced_t<_CompletionToken, void(error_code)> async_connect(const endpoint_type& __endpoint, _CompletionToken&& __token) { async_completion<_CompletionToken, void(error_code)> __init{__token}; if (!is_open()) { error_code __ec; open(__endpoint.protocol(), __ec); if (__ec) { auto __ex = net::get_associated_executor( __init.completion_handler, get_executor()); auto __a = get_associated_allocator( __init.completion_handler, std::allocator()); __ex.post( [__h = std::move(__init.completion_handler), __ec] () mutable { __h(__ec); }, __a); return __init.result.get(); } } get_executor().context().async_wait( native_handle(), socket_base::wait_read, [__h = std::move(__init.completion_handler), __ep = std::move(__endpoint), __fd = native_handle()] (error_code __ec) mutable { #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H if (!__ec && ::connect(__fd, (const sockaddr*)__ep.data(), __ep.size()) == -1) __ec.assign(errno, generic_category()); #else __ec = std::make_error_code(errc::operation_not_supported); #endif __h(__ec); }); return __init.result.get(); } void wait(wait_type __w) { return wait(__w, __throw_on_error{"basic_socket::wait"}); } void wait(wait_type __w, error_code& __ec) { #ifdef _GLIBCXX_HAVE_POLL_H ::pollfd __fd; __fd.fd = native_handle(); __fd.events = static_cast(__w); int __res = ::poll(&__fd, 1, -1); if (__res == -1) __ec.assign(errno, generic_category()); else __ec.clear(); #else __ec = std::make_error_code(errc::operation_not_supported); #endif } template __deduced_t<_CompletionToken, void(error_code)> async_wait(wait_type __w, _CompletionToken&& __token) { async_completion<_CompletionToken, void(error_code)> __init{__token}; get_executor().context().async_wait( native_handle(), static_cast(__w), [__h = std::move(__init.completion_handler)] (error_code __ec) mutable { __h(__ec); }); return __init.result.get(); } protected: // construct / copy / destroy: using __base::__base; explicit basic_socket(io_context& __ctx) : __base(__ctx) { } basic_socket(io_context& __ctx, const protocol_type& __protocol) : __base(__ctx) { open(__protocol); } basic_socket(io_context& __ctx, const endpoint_type& __endpoint) : basic_socket(__ctx, __endpoint.protocol()) { bind(__endpoint); } basic_socket(io_context& __ctx, const protocol_type& __protocol, const native_handle_type& __native_socket) : __base(__ctx) { assign(__protocol, __native_socket); } basic_socket(const basic_socket&) = delete; basic_socket(basic_socket&& __rhs) = default; template>> basic_socket(basic_socket<_OtherProtocol>&& __rhs) : __base(std::move(__rhs)) { } ~basic_socket() = default; basic_socket& operator=(const basic_socket&) = delete; basic_socket& operator=(basic_socket&& __rhs) = default; template enable_if_t::value, basic_socket&> operator=(basic_socket<_OtherProtocol>&& __rhs) { return *this = basic_socket{std::move(__rhs)}; } }; template class basic_datagram_socket : public basic_socket<_Protocol> { using __base = basic_socket<_Protocol>; public: // types: using native_handle_type = int; using protocol_type = _Protocol; using endpoint_type = typename protocol_type::endpoint; // construct / copy / destroy: explicit basic_datagram_socket(io_context& __ctx) : __base(__ctx) { } basic_datagram_socket(io_context& __ctx, const protocol_type& __protocol) : __base(__ctx, __protocol) { } basic_datagram_socket(io_context& __ctx, const endpoint_type& __endpoint) : __base(__ctx, __endpoint) { } basic_datagram_socket(io_context& __ctx, const protocol_type& __protocol, const native_handle_type& __native_socket) : __base(__ctx, __protocol, __native_socket) { } basic_datagram_socket(const basic_datagram_socket&) = delete; basic_datagram_socket(basic_datagram_socket&& __rhs) = default; template>> basic_datagram_socket(basic_datagram_socket<_OtherProtocol>&& __rhs) : __base(std::move(__rhs)) { } ~basic_datagram_socket() = default; basic_datagram_socket& operator=(const basic_datagram_socket&) = delete; basic_datagram_socket& operator=(basic_datagram_socket&& __rhs) = default; template enable_if_t::value, basic_datagram_socket&> operator=(basic_datagram_socket<_OtherProtocol>&& __rhs) { __base::operator=(std::move(__rhs)); return *this; } // basic_datagram_socket operations: template size_t receive(const _MutableBufferSequence& __buffers) { return receive(__buffers, socket_base::message_flags(), __throw_on_error{"basic_datagram_socket::receive"}); } template size_t receive(const _MutableBufferSequence& __buffers, error_code& __ec) { return receive(__buffers, socket_base::message_flags(), __ec); } template size_t receive(const _MutableBufferSequence& __buffers, socket_base::message_flags __flags) { return receive(__buffers, __flags, __throw_on_error{"basic_datagram_socket::receive"}); } template size_t receive(const _MutableBufferSequence& __buffers, socket_base::message_flags __flags, error_code& __ec) { #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H socket_base::__msg_hdr __msg(__buffers); ssize_t __result = ::recvmsg(this->native_handle(), &__msg, static_cast(__flags)); if (__result == -1) { __ec.assign(errno, generic_category()); return 0; } __ec.clear(); return __result; #else __ec = std::make_error_code(errc::operation_not_supported); return 0; #endif } template __deduced_t<_CompletionToken, void(error_code, size_t)> async_receive(const _MutableBufferSequence& __buffers, _CompletionToken&& __token) { return async_receive(__buffers, socket_base::message_flags(), std::forward<_CompletionToken>(__token)); } template __deduced_t<_CompletionToken, void(error_code, size_t)> async_receive(const _MutableBufferSequence& __buffers, socket_base::message_flags __flags, _CompletionToken&& __token) { async_completion<_CompletionToken, void(error_code, size_t)> __init{__token}; this->get_executor().context().async_wait(this->native_handle(), socket_base::wait_read, [__h = std::move(__init.completion_handler), &__buffers, __flags = static_cast(__flags), __fd = this->native_handle()] (error_code __ec) mutable { if (__ec) { __h(__ec); return; } #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H socket_base::__msg_hdr __msg(__buffers); ssize_t __result = ::recvmsg(__fd, &__msg, __flags); if (__result == -1) { __ec.assign(errno, generic_category()); __result = 0; } else __ec.clear(); __h(__ec, __result); #else __h(std::make_error_code(errc::operation_not_supported), 0); #endif }); return __init.result.get(); } template size_t receive_from(const _MutableBufferSequence& __buffers, endpoint_type& __sender) { return receive_from(__buffers, __sender, socket_base::message_flags(), __throw_on_error{ "basic_datagram_socket::receive_from"}); } template size_t receive_from(const _MutableBufferSequence& __buffers, endpoint_type& __sender, error_code& __ec) { return receive_from(__buffers, __sender, socket_base::message_flags(), __ec); } template size_t receive_from(const _MutableBufferSequence& __buffers, endpoint_type& __sender, socket_base::message_flags __flags) { return receive_from(__buffers, __sender, __flags, __throw_on_error{ "basic_datagram_socket::receive_from"}); } template size_t receive_from(const _MutableBufferSequence& __buffers, endpoint_type& __sender, socket_base::message_flags __flags, error_code& __ec) { #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H socket_base::__msg_hdr __msg(__buffers, __sender); ssize_t __result = ::recvmsg(this->native_handle(), &__msg, static_cast(__flags)); if (__result == -1) { __ec.assign(errno, generic_category()); return 0; } __ec.clear(); __sender.resize(__msg.msg_namelen); return __result; #else __ec = std::make_error_code(errc::operation_not_supported); return 0; #endif } template __deduced_t<_CompletionToken, void(error_code, size_t)> async_receive_from(const _MutableBufferSequence& __buffers, endpoint_type& __sender, _CompletionToken&& __token) { return async_receive_from(__buffers, __sender, socket_base::message_flags(), std::forward<_CompletionToken>(__token)); } template __deduced_t<_CompletionToken, void(error_code, size_t)> async_receive_from(const _MutableBufferSequence& __buffers, endpoint_type& __sender, socket_base::message_flags __flags, _CompletionToken&& __token) { async_completion<_CompletionToken, void(error_code, size_t)> __init{__token}; this->get_executor().context().async_wait( this->native_handle(), socket_base::wait_read, [__h = std::move(__init.completion_handler), &__buffers, __flags = static_cast(__flags), __sender = std::move(__sender), __fd = this->native_handle()] (error_code __ec) mutable { if (__ec) { __h(__ec); return; } #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H socket_base::__msg_hdr __msg(__buffers, __sender); ssize_t __result = ::recvmsg(__fd, &__msg, __flags); if (__result == -1) { __ec.assign(errno, generic_category()); __result = 0; } else { __ec.clear(); __sender.resize(__msg.msg_namelen); } __h(__ec, __result); #else __h(std::make_error_code(errc::operation_not_supported), 0); #endif }); return __init.result.get(); } template size_t send(const _ConstBufferSequence& __buffers) { return send(__buffers, socket_base::message_flags(), __throw_on_error{"basic_datagram_socket::send"}); } template size_t send(const _ConstBufferSequence& __buffers, error_code& __ec) { return send(__buffers, socket_base::message_flags(), __ec); } template size_t send(const _ConstBufferSequence& __buffers, socket_base::message_flags __flags) { return send(__buffers, __flags, __throw_on_error{"basic_datagram_socket::send"}); } template size_t send(const _ConstBufferSequence& __buffers, socket_base::message_flags __flags, error_code& __ec) { #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H socket_base::__msg_hdr __msg(__buffers); ssize_t __result = ::sendmsg(this->native_handle(), &__msg, static_cast(__flags)); if (__result == -1) { __ec.assign(errno, generic_category()); return 0; } __ec.clear(); return __result; #else __ec = std::make_error_code(errc::operation_not_supported); return 0; #endif } template __deduced_t<_CompletionToken, void(error_code, size_t)> async_send(const _ConstBufferSequence& __buffers, _CompletionToken&& __token) { return async_send(__buffers, socket_base::message_flags(), std::forward<_CompletionToken>(__token)); } template __deduced_t<_CompletionToken, void(error_code, size_t)> async_send(const _ConstBufferSequence& __buffers, socket_base::message_flags __flags, _CompletionToken&& __token) { async_completion<_CompletionToken, void(error_code, size_t)> __init{__token}; this->get_executor().context().async_wait( this->native_handle(), socket_base::wait_write, [__h = std::move(__init.completion_handler), &__buffers, __flags = static_cast(__flags), __fd = this->native_handle()] (error_code __ec) mutable { if (__ec) { __h(__ec); return; } #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H socket_base::__msg_hdr __msg(__buffers); ssize_t __result = ::sendmsg(__fd, &__msg, __flags); if (__result == -1) { __ec.assign(errno, generic_category()); __result = 0; } else __ec.clear(); __h(__ec, __result); #else __h(std::make_error_code(errc::operation_not_supported), 0); #endif }); return __init.result.get(); } template size_t send_to(const _ConstBufferSequence& __buffers, const endpoint_type& __recipient) { return send_to(__buffers, __recipient, socket_base::message_flags(), __throw_on_error{"basic_datagram_socket::send_to"}); } template size_t send_to(const _ConstBufferSequence& __buffers, const endpoint_type& __recipient, error_code& __ec) { return send_to(__buffers, __recipient, socket_base::message_flags(), __ec); } template size_t send_to(const _ConstBufferSequence& __buffers, const endpoint_type& __recipient, socket_base::message_flags __flags) { return send_to(__buffers, __recipient, __flags, __throw_on_error{"basic_datagram_socket::send_to"}); } template size_t send_to(const _ConstBufferSequence& __buffers, const endpoint_type& __recipient, socket_base::message_flags __flags, error_code& __ec) { #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H socket_base::__msg_hdr __msg(__buffers, __recipient); ssize_t __result = ::sendmsg(this->native_handle(), &__msg, static_cast(__flags)); if (__result == -1) { __ec.assign(errno, generic_category()); return 0; } __ec.clear(); __recipient.resize(__msg.msg_namelen); return __result; #else __ec = std::make_error_code(errc::operation_not_supported); return 0; #endif } template __deduced_t<_CompletionToken, void(error_code, size_t)> async_send_to(const _ConstBufferSequence& __buffers, const endpoint_type& __recipient, _CompletionToken&& __token) { return async_send_to(__buffers, __recipient, socket_base::message_flags(), std::forward<_CompletionToken>(__token)); } template __deduced_t<_CompletionToken, void(error_code, size_t)> async_send_to(const _ConstBufferSequence& __buffers, const endpoint_type& __recipient, socket_base::message_flags __flags, _CompletionToken&& __token) { async_completion<_CompletionToken, void(error_code, size_t)> __init{__token}; this->get_executor().context().async_wait( this->native_handle(), socket_base::wait_write, [__h = std::move(__init.completion_handler), &__buffers, __flags = static_cast(__flags), __recipient = std::move(__recipient), __fd = this->native_handle()] (error_code __ec) mutable { if (__ec) { __h(__ec); return; } #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H socket_base::__msg_hdr __msg(__buffers, __recipient); ssize_t __result = ::sendmsg(__fd, &__msg, __flags); if (__result == -1) { __ec.assign(errno, generic_category()); __result = 0; } else { __ec.clear(); __recipient.resize(__msg.msg_namelen); } __h(__ec, __result); #else __h(std::make_error_code(errc::operation_not_supported), 0); #endif }); return __init.result.get(); } }; template class basic_stream_socket : public basic_socket<_Protocol> { using __base = basic_socket<_Protocol>; public: // types: using native_handle_type = int; using protocol_type = _Protocol; using endpoint_type = typename protocol_type::endpoint; // construct / copy / destroy: explicit basic_stream_socket(io_context& __ctx) : __base(__ctx) { } basic_stream_socket(io_context& __ctx, const protocol_type& __protocol) : __base(__ctx, __protocol) { } basic_stream_socket(io_context& __ctx, const endpoint_type& __endpoint) : __base(__ctx, __endpoint) { } basic_stream_socket(io_context& __ctx, const protocol_type& __protocol, const native_handle_type& __native_socket) : __base(__ctx, __protocol, __native_socket) { } basic_stream_socket(const basic_stream_socket&) = delete; basic_stream_socket(basic_stream_socket&& __rhs) = default; template>> basic_stream_socket(basic_stream_socket<_OtherProtocol>&& __rhs) : __base(std::move(__rhs)) { } ~basic_stream_socket() = default; basic_stream_socket& operator=(const basic_stream_socket&) = delete; basic_stream_socket& operator=(basic_stream_socket&& __rhs) = default; template enable_if_t::value, basic_stream_socket&> operator=(basic_stream_socket<_OtherProtocol>&& __rhs) { __base::operator=(std::move(__rhs)); return *this; } // basic_stream_socket operations: template size_t receive(const _MutableBufferSequence& __buffers) { return receive(__buffers, socket_base::message_flags(), __throw_on_error{"basic_stream_socket::receive"}); } template size_t receive(const _MutableBufferSequence& __buffers, error_code& __ec) { return receive(__buffers, socket_base::message_flags(), __ec); } template size_t receive(const _MutableBufferSequence& __buffers, socket_base::message_flags __flags) { return receive(__buffers, __flags, __throw_on_error{"basic_stream_socket::receive"}); } template size_t receive(const _MutableBufferSequence& __buffers, socket_base::message_flags __flags, error_code& __ec) { if (__buffer_empty(__buffers)) { __ec.clear(); return 0; } #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H socket_base::__msg_hdr __msg(__buffers); ssize_t __result = ::recvmsg(this->native_handle(), &__msg, static_cast(__flags)); if (__result >= 0) { __ec.clear(); return __result; } __ec.assign(errno, generic_category()); #else __ec = std::make_error_code(errc::operation_not_supported); #endif return 0; } template __deduced_t<_CompletionToken, void(error_code, size_t)> async_receive(const _MutableBufferSequence& __buffers, _CompletionToken&& __token) { return async_receive(__buffers, socket_base::message_flags(), std::forward<_CompletionToken>(__token)); } template __deduced_t<_CompletionToken, void(error_code, size_t)> async_receive(const _MutableBufferSequence& __buffers, socket_base::message_flags __flags, _CompletionToken&& __token) { async_completion<_CompletionToken, void(error_code, size_t)> __init{__token}; if (__buffer_empty(__buffers)) { auto __ex = net::get_associated_executor( __init.completion_handler, this->get_executor()); auto __a = get_associated_allocator( __init.completion_handler, std::allocator()); __ex.post( [__h=std::move(__init.completion_handler)] () mutable { __h(error_code{}, 0); }, __a); return __init.result.get(); } this->get_executor().context().async_wait(this->native_handle(), socket_base::wait_read, [__h = std::move(__init.completion_handler), &__buffers, __flags = static_cast(__flags), __fd = this->native_handle()] (error_code __ec) mutable { if (__ec) { __h(__ec); return; } #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H socket_base::__msg_hdr __msg(__buffers); ssize_t __result = ::recvmsg(__fd, &__msg, __flags); if (__result == -1) { __ec.assign(errno, generic_category()); __result = 0; } else __ec.clear(); __h(__ec, __result); #else __h(std::make_error_code(errc::operation_not_supported), 0); #endif }); return __init.result.get(); } template size_t send(const _ConstBufferSequence& __buffers) { return send(__buffers, socket_base::message_flags(), __throw_on_error{"basic_stream_socket::send"}); } template size_t send(const _ConstBufferSequence& __buffers, error_code& __ec) { return send(__buffers, socket_base::message_flags(), __ec); } template size_t send(const _ConstBufferSequence& __buffers, socket_base::message_flags __flags) { return send(__buffers, socket_base::message_flags(), __throw_on_error{"basic_stream_socket::send"}); } template size_t send(const _ConstBufferSequence& __buffers, socket_base::message_flags __flags, error_code& __ec) { if (__buffer_empty(__buffers)) { __ec.clear(); return 0; } #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H socket_base::__msg_hdr __msg(__buffers); ssize_t __result = ::sendmsg(this->native_handle(), &__msg, static_cast(__flags)); if (__result >= 0) { __ec.clear(); return __result; } __ec.assign(errno, generic_category()); #else __ec = std::make_error_code(errc::operation_not_supported); #endif return 0; } template __deduced_t<_CompletionToken, void(error_code, size_t)> async_send(const _ConstBufferSequence& __buffers, _CompletionToken&& __token) { return async_send(__buffers, socket_base::message_flags(), std::forward<_CompletionToken>(__token)); } template __deduced_t<_CompletionToken, void(error_code, size_t)> async_send(const _ConstBufferSequence& __buffers, socket_base::message_flags __flags, _CompletionToken&& __token) { async_completion<_CompletionToken, void(error_code, size_t)> __init{__token}; if (__buffer_empty(__buffers)) { auto __ex = net::get_associated_executor( __init.completion_handler, this->get_executor()); auto __a = get_associated_allocator( __init.completion_handler, std::allocator()); __ex.post( [__h=std::move(__init.completion_handler)] () mutable { __h(error_code{}, 0); }, __a); return __init.result.get(); } this->get_executor().context().async_wait(this->native_handle(), socket_base::wait_write, [__h = std::move(__init.completion_handler), &__buffers, __flags = static_cast(__flags), __fd = this->native_handle()] (error_code __ec) mutable { if (__ec) { __h(__ec); return; } #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H socket_base::__msg_hdr __msg(__buffers); ssize_t __result = ::sendmsg(__fd, &__msg, __flags); if (__result == -1) { __ec.assign(errno, generic_category()); __result = 0; } else __ec.clear(); __h(__ec, __result); #else __h(std::make_error_code(errc::operation_not_supported), 0); #endif }); return __init.result.get(); } template size_t read_some(const _MutableBufferSequence& __buffers) { return receive(__buffers, __throw_on_error{"basic_stream_socket::read_some"}); } template size_t read_some(const _MutableBufferSequence& __buffers, error_code& __ec) { return receive(__buffers, __ec); } template __deduced_t<_CompletionToken, void(error_code, size_t)> async_read_some(const _MutableBufferSequence& __buffers, _CompletionToken&& __token) { return async_receive(__buffers, std::forward<_CompletionToken>(__token)); } template size_t write_some(const _ConstBufferSequence& __buffers) { return send(__buffers, __throw_on_error{"basic_stream_socket:write_some"}); } template size_t write_some(const _ConstBufferSequence& __buffers, error_code& __ec) { return send(__buffers, __ec); } template __deduced_t<_CompletionToken, void(error_code, size_t)> async_write_some(const _ConstBufferSequence& __buffers, _CompletionToken&& __token) { return async_send(__buffers, std::forward<_CompletionToken>(__token)); } }; template class basic_socket_acceptor : public socket_base, private __basic_socket_impl<_AcceptableProtocol> { using __base = __basic_socket_impl<_AcceptableProtocol>; public: // types: using executor_type = io_context::executor_type; using native_handle_type = int; using protocol_type = _AcceptableProtocol; using endpoint_type = typename protocol_type::endpoint; using socket_type = typename protocol_type::socket; static_assert(__detail::__acceptable_protocol, "protocol_type meets the AcceptableProtocol requirements"); // construct / copy / destroy: explicit basic_socket_acceptor(io_context& __ctx) : __base(__ctx), _M_protocol(endpoint_type{}.protocol()) { } basic_socket_acceptor(io_context& __ctx, const protocol_type& __protocol) : __base(__ctx), _M_protocol(__protocol) { open(__protocol); } basic_socket_acceptor(io_context& __ctx, const endpoint_type& __endpoint, bool __reuse_addr = true) : basic_socket_acceptor(__ctx, __endpoint.protocol()) { if (__reuse_addr) set_option(reuse_address(true)); bind(__endpoint); listen(); } basic_socket_acceptor(io_context& __ctx, const protocol_type& __protocol, const native_handle_type& __native_acceptor) : basic_socket_acceptor(__ctx, __protocol) { assign(__protocol, __native_acceptor); } basic_socket_acceptor(const basic_socket_acceptor&) = delete; basic_socket_acceptor(basic_socket_acceptor&&) = default; template>> basic_socket_acceptor(basic_socket_acceptor<_OtherProtocol>&& __rhs) : __base(std::move(__rhs)) { } ~basic_socket_acceptor() = default; basic_socket_acceptor& operator=(const basic_socket_acceptor&) = delete; basic_socket_acceptor& operator=(basic_socket_acceptor&&) = default; template enable_if_t::value, basic_socket_acceptor&> operator=(basic_socket_acceptor<_OtherProtocol>&& __rhs) { __base::operator=(std::move(__rhs)); return *this; } // basic_socket_acceptor operations: executor_type get_executor() noexcept { return __base::get_executor(); } native_handle_type native_handle() noexcept { return __base::native_handle(); } void open(const protocol_type& __protocol = protocol_type()) { open(__protocol, __throw_on_error{"basic_socket_acceptor::open"}); } void open(const protocol_type& __protocol, error_code& __ec) { __base::open(__protocol, __ec); } void assign(const protocol_type& __protocol, const native_handle_type& __native_acceptor) { assign(__protocol, __native_acceptor, __throw_on_error{"basic_socket_acceptor::assign"}); } void assign(const protocol_type& __protocol, const native_handle_type& __native_acceptor, error_code& __ec) { __base::assign(__protocol, __native_acceptor, __ec); } native_handle_type release() { return release(__throw_on_error{"basic_socket_acceptor::release"}); } native_handle_type release(error_code& __ec) { return __base::release(__ec); } _GLIBCXX_NODISCARD bool is_open() const noexcept { return __base::is_open(); } void close() { close(__throw_on_error{"basic_socket_acceptor::close"}); } void close(error_code& __ec) { __base::_close(__ec); } void cancel() { cancel(__throw_on_error{"basic_socket_acceptor::cancel"}); } void cancel(error_code& __ec) { __base::cancel(__ec); } template void set_option(const _SettableSocketOption& __option) { set_option(__option, __throw_on_error{"basic_socket_acceptor::set_option"}); } template void set_option(const _SettableSocketOption& __option, error_code& __ec) { __base::set_option(__option, __ec); } template void get_option(_GettableSocketOption& __option) const { get_option(__option, __throw_on_error{"basic_socket_acceptor::get_option"}); } template void get_option(_GettableSocketOption& __option, error_code& __ec) const { __base::get_option(__option, __ec); } template void io_control(_IoControlCommand& __command) { io_control(__command, __throw_on_error{"basic_socket_acceptor::io_control"}); } template void io_control(_IoControlCommand& __command, error_code& __ec) { __base::io_control(__command, __ec); } void non_blocking(bool __mode) { non_blocking(__mode, __throw_on_error{"basic_socket_acceptor::non_blocking"}); } void non_blocking(bool __mode, error_code& __ec) { __base::non_blocking(__mode, __ec); } bool non_blocking() const { return __base::non_blocking(); } void native_non_blocking(bool __mode) { native_non_blocking(__mode, __throw_on_error{ "basic_socket_acceptor::native_non_blocking"}); } void native_non_blocking(bool __mode, error_code& __ec) { __base::native_non_blocking(__mode, __ec); } bool native_non_blocking() const { return __base::native_non_blocking(); } void bind(const endpoint_type& __endpoint) { return bind(__endpoint, __throw_on_error{"basic_socket_acceptor::bind"}); } void bind(const endpoint_type& __endpoint, error_code& __ec) { __base::bind(__endpoint, __ec); } void listen(int __backlog = max_listen_connections) { return listen(__backlog, __throw_on_error{"basic_socket_acceptor::listen"}); } void listen(int __backlog, error_code& __ec) { #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H if (::listen(native_handle(), __backlog) == -1) __ec.assign(errno, generic_category()); else __ec.clear(); #else __ec = std::make_error_code(errc::operation_not_supported); #endif } endpoint_type local_endpoint() const { return local_endpoint( __throw_on_error{"basic_socket_acceptor::local_endpoint"}); } endpoint_type local_endpoint(error_code& __ec) const { return __base::local_endpoint(__ec); } void enable_connection_aborted(bool __mode) { __base::_M_bits.enable_connection_aborted = __mode; } bool enable_connection_aborted() const { return __base::_M_bits.enable_connection_aborted; } socket_type accept() { return accept(__throw_on_error{"basic_socket_acceptor::accept"}); } socket_type accept(error_code& __ec) { return accept(get_executor().context(), __ec); } socket_type accept(io_context& __ctx) { return accept(__ctx, __throw_on_error{"basic_socket_acceptor::accept"}); } socket_type accept(io_context& __ctx, error_code& __ec) { #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H do { int __h = ::accept(native_handle(), nullptr, 0); if (__h != -1) { __ec.clear(); return socket_type{__ctx, _M_protocol, __h}; } } while (errno == ECONNABORTED && enable_connection_aborted()); __ec.assign(errno, generic_category()); #else __ec = std::make_error_code(errc::operation_not_supported); #endif return socket_type{__ctx}; } template __deduced_t<_CompletionToken, void(error_code, socket_type)> async_accept(_CompletionToken&& __token) { return async_accept(get_executor().context(), std::forward<_CompletionToken>(__token)); } template __deduced_t<_CompletionToken, void(error_code, socket_type)> async_accept(io_context& __ctx, _CompletionToken&& __token) { async_completion<_CompletionToken, void(error_code, socket_type)> __init{__token}; __ctx.get_executor().context().async_wait(native_handle(), socket_base::wait_read, [__h = std::move(__init.completion_handler), __connabort = enable_connection_aborted(), __fd = native_handle(), __protocol = _M_protocol, &__ctx ] (error_code __ec) mutable { if (__ec) { __h(__ec, socket_type(__ctx)); return; } #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H do { int __newfd = ::accept(__fd, nullptr, 0); if (__newfd != -1) { __ec.clear(); __h(__ec, socket_type{__ctx, __protocol, __newfd}); return; } } while (errno == ECONNABORTED && __connabort); __ec.assign(errno, generic_category()); __h(__ec, socket_type(__ctx)); #else __h(std::make_error_code(errc::operation_not_supported), 0); #endif }); return __init.result.get(); } socket_type accept(endpoint_type& __endpoint) { return accept(get_executor().context(), __endpoint, __throw_on_error{"basic_socket_acceptor::accept"}); } socket_type accept(endpoint_type& __endpoint, error_code& __ec) { return accept(get_executor().context(), __endpoint, __ec); } socket_type accept(io_context& __ctx, endpoint_type& __endpoint) { return accept(__ctx, __endpoint, __throw_on_error{"basic_socket_acceptor::accept"}); } socket_type accept(io_context& __ctx, endpoint_type& __endpoint, error_code& __ec) { #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H do { socklen_t __len = __endpoint.capacity(); int __h = ::accept(native_handle(), (sockaddr*)__endpoint.data(), &__len); if (__h != -1) { __endpoint.resize(__len); return socket_type{__ctx, _M_protocol, __h}; } } while (errno == ECONNABORTED && enable_connection_aborted()); __ec.assign(errno, generic_category()); #else __ec = std::make_error_code(errc::operation_not_supported); #endif return socket_type{__ctx}; } template __deduced_t<_CompletionToken, void(error_code, socket_type)> async_accept(endpoint_type& __endpoint, _CompletionToken&& __token) { return async_accept(get_executor().context(), __endpoint, std::forward<_CompletionToken>(__token)); } template __deduced_t<_CompletionToken, void(error_code, socket_type)> async_accept(io_context& __ctx, endpoint_type& __endpoint, _CompletionToken&& __token) { async_completion<_CompletionToken, void(error_code, socket_type)> __init{__token}; __ctx.get_executor().context().async_wait(native_handle(), socket_base::wait_read, [__h = std::move(__init.completion_handler), __ep = std::move(__endpoint), __connabort = enable_connection_aborted(), __fd = native_handle(), &__ctx ] (error_code __ec) mutable { if (__ec) { __h(__ec, socket_type(__ctx)); return; } #ifdef _GLIBCXX_HAVE_SYS_SOCKET_H do { socklen_t __len = __ep.capacity(); int __newfd = ::accept(__fd, __ep.data, &__len); if (__newfd != -1) { __ep.resize(__len); auto __protocol = __ep.protocol(); __ec.clear(); __h(__ec, socket_type{__ctx, __protocol, __newfd}); return; } } while (errno == ECONNABORTED && __connabort); __ec.assign(errno, generic_category()); #else __ec = std::make_error_code(errc::operation_not_supported); #endif __h(__ec, socket_type(__ctx)); }); return __init.result.get(); } void wait(wait_type __w) { wait(__w, __throw_on_error{"basic_socket_acceptor::wait"}); } void wait(wait_type __w, error_code& __ec) { #ifdef _GLIBCXX_HAVE_POLL_H ::pollfd __fds; __fds.fd = native_handle(); __fds.events = __w; // __w | POLLIN; if (::poll(&__fds, 1, -1) == -1) __ec.assign(errno, generic_category()); else __ec.clear(); #else __ec = std::make_error_code(errc::operation_not_supported); #endif } template __deduced_t<_CompletionToken, void(error_code)> async_wait(wait_type __w, _CompletionToken&& __token) { async_completion<_CompletionToken, void(error_code)> __init{__token}; get_executor().context().async_wait( native_handle(), static_cast(__w), [__h = std::move(__init.completion_handler)] (error_code __ec) mutable { __h(__ec); }); return __init.result.get(); } private: protocol_type _M_protocol; }; /// @} /** @brief Socket streams * @{ */ template class basic_socket_streambuf : public basic_streambuf { public: // types: using protocol_type = _Protocol; using endpoint_type = typename protocol_type::endpoint; using clock_type = _Clock; using time_point = typename clock_type::time_point; using duration = typename clock_type::duration; using wait_traits_type = _WaitTraits; // construct / copy / destroy: basic_socket_streambuf() : _M_socket(_S_ctx()) { } explicit basic_socket_streambuf(basic_stream_socket __s) : _M_socket(std::move(__s)) { } basic_socket_streambuf(const basic_socket_streambuf&) = delete; basic_socket_streambuf(basic_socket_streambuf&& __rhs); // TODO virtual ~basic_socket_streambuf(); // TODO basic_socket_streambuf& operator=(const basic_socket_streambuf&) = delete; basic_socket_streambuf& operator=(basic_socket_streambuf&& __rhs); // TODO // members: basic_socket_streambuf* connect(const endpoint_type& __e); // TODO template basic_socket_streambuf* connect(_Args&&... ); // TODO basic_socket_streambuf* close(); // TODO basic_socket& socket() { return _M_socket; } error_code error() const noexcept { return _M_ec; } time_point expiry() const { return _M_expiry; } void expires_at(const time_point& __t) { _M_expiry = __t; } void expires_after(const duration& __d) { expires_at(clock_type::now() + __d); } protected: // overridden virtual functions: // TODO virtual int_type underflow() override; virtual int_type pbackfail(int_type __c = traits_type::eof()) override; virtual int_type overflow(int_type __c = traits_type::eof()) override; virtual int sync() override; virtual streambuf* setbuf(char_type* __s, streamsize __n) override; private: static io_context& _S_ctx() { static io_context __ctx; return __ctx; } basic_stream_socket _M_socket; error_code _M_ec; time_point _M_expiry{ time_point::max() }; }; template class basic_socket_iostream : public basic_iostream { using __streambuf_type = basic_socket_streambuf<_Protocol, _Clock, _WaitTraits>; public: // types: using protocol_type = _Protocol; using endpoint_type = typename protocol_type::endpoint; using clock_type = _Clock; using time_point = typename clock_type::time_point; using duration = typename clock_type::duration; using wait_traits_type = _WaitTraits; // construct / copy / destroy: // TODO base-from-member ? basic_socket_iostream() : basic_iostream(nullptr), _M_sb() { this->init(std::addressof(_M_sb)); this->setf(std::ios::unitbuf); } explicit basic_socket_iostream(basic_stream_socket __s) : basic_iostream(nullptr), _M_sb(std::move(__s)) { this->init(std::addressof(_M_sb)); this->setf(std::ios::unitbuf); } basic_socket_iostream(const basic_socket_iostream&) = delete; basic_socket_iostream(basic_socket_iostream&& __rhs) : basic_iostream(nullptr), _M_sb(std::move(__rhs._M_sb)) // XXX ??? ^^^^^^^ { // XXX ??? this->init(std::addressof(_M_sb)); this->set_rbduf(std::addressof(_M_sb)); } template explicit basic_socket_iostream(_Args&&... __args) : basic_iostream(nullptr), _M_sb() { this->init(std::addressof(_M_sb)); this->setf(std::ios::unitbuf); connect(forward<_Args>(__args)...); } basic_socket_iostream& operator=(const basic_socket_iostream&) = delete; basic_socket_iostream& operator=(basic_socket_iostream&& __rhs); // TODO // members: template void connect(_Args&&... __args) { if (rdbuf()->connect(forward<_Args>(__args)...) == nullptr) this->setstate(failbit); } void close() { if (rdbuf()->close() == nullptr) this->setstate(failbit); } basic_socket_streambuf* rdbuf() const { return const_cast<__streambuf_type*>(std::addressof(_M_sb)); } basic_socket& socket() { return rdbuf()->socket(); } error_code error() const noexcept { return rdbuf()->error(); } time_point expiry() const { return rdbuf()->expiry(); } void expires_at(const time_point& __t) { rdbuf()->expires_at(__t); } void expires_after(const duration& __d) { rdbuf()->expires_after(__d); } private: __streambuf_type _M_sb; }; /// @} /** @brief synchronous connect operations * @{ */ template inline typename _Protocol::endpoint connect(basic_socket<_Protocol>& __s, const _EndpointSequence& __endpoints, _ConnectCondition __c, error_code& __ec) { __ec.clear(); bool __found = false; for (auto& __ep : __endpoints) { if (__c(__ec, __ep)) { __found = true; __s.close(__ec); if (!__ec) __s.open(__ep.protocol(), __ec); if (!__ec) __s.connect(__ep, __ec); if (!__ec) return __ep; } } if (!__found) __ec = socket_errc::not_found; return typename _Protocol::endpoint{}; } template inline _InputIterator connect(basic_socket<_Protocol>& __s, _InputIterator __first, _InputIterator __last, _ConnectCondition __c, error_code& __ec) { __ec.clear(); bool __found = false; for (auto __i = __first; __i != __last; ++__i) { if (__c(__ec, *__i)) { __found = true; __s.close(__ec); if (!__ec) __s.open(typename _Protocol::endpoint(*__i).protocol(), __ec); if (!__ec) __s.connect(*__i, __ec); if (!__ec) return __i; } } if (!__found) __ec = socket_errc::not_found; return __last; } template inline typename _Protocol::endpoint connect(basic_socket<_Protocol>& __s, const _EndpointSequence& __endpoints, _ConnectCondition __c) { return net::connect(__s, __endpoints, __c, __throw_on_error{"connect"}); } template inline _InputIterator connect(basic_socket<_Protocol>& __s, _InputIterator __first, _InputIterator __last, _ConnectCondition __c) { return net::connect(__s, __first, __last, __c, __throw_on_error{"connect"}); } template inline typename _Protocol::endpoint connect(basic_socket<_Protocol>& __s, const _EndpointSequence& __endpoints) { return net::connect(__s, __endpoints, [](auto, auto){ return true; }, __throw_on_error{"connect"}); } template inline typename _Protocol::endpoint connect(basic_socket<_Protocol>& __s, const _EndpointSequence& __endpoints, error_code& __ec) { return net::connect(__s, __endpoints, [](auto, auto){ return true; }, __ec); } template inline _InputIterator connect(basic_socket<_Protocol>& __s, _InputIterator __first, _InputIterator __last) { return net::connect(__s, __first, __last, [](auto, auto){ return true; }, __throw_on_error{"connect"}); } template inline _InputIterator connect(basic_socket<_Protocol>& __s, _InputIterator __first, _InputIterator __last, error_code& __ec) { return net::connect(__s, __first, __last, [](auto, auto){ return true; }, __ec); } /// @} /** @brief asynchronous connect operations * @{ */ template inline __deduced_t<_CompletionToken, void(error_code, typename _Protocol::endpoint)> async_connect(basic_socket<_Protocol>& __s, const _EndpointSequence& __endpoints, _ConnectCondition __c, _CompletionToken&& __token); // TODO template inline __deduced_t<_CompletionToken, void(error_code, typename _Protocol::endpoint)> async_connect(basic_socket<_Protocol>& __s, const _EndpointSequence& __endpoints, _CompletionToken&& __token) { return net::async_connect(__s, __endpoints, [](auto, auto){ return true; }, forward<_CompletionToken>(__token)); } template inline __deduced_t<_CompletionToken, void(error_code, _InputIterator)> async_connect(basic_socket<_Protocol>& __s, _InputIterator __first, _InputIterator __last, _ConnectCondition __c, _CompletionToken&& __token); // TODO template inline __deduced_t<_CompletionToken, void(error_code, _InputIterator)> async_connect(basic_socket<_Protocol>& __s, _InputIterator __first, _InputIterator __last, _CompletionToken&& __token) { return net::async_connect(__s, __first, __last, [](auto, auto){ return true; }, forward<_CompletionToken>(__token)); } /// @} #endif // _GLIBCXX_HAVE_UNISTD_H /// @} } // namespace v1 } // namespace net } // namespace experimental _GLIBCXX_END_NAMESPACE_VERSION } // namespace std #endif // C++14 #endif // _GLIBCXX_EXPERIMENTAL_SOCKET