DriveHQ Start Menu
Cloud Drive Mapping
Folder Sync
Cloud Backup
True Drop Box
FTP/SFTP Hosting
Group Account
DriveHQ Start Menu
Online File Server
My Storage
|
Manage Shares
|
Publishes
|
Drop Boxes
|
Group Account
WebDAV Drive Mapping
Cloud Drive Home
|
WebDAV Guide
|
Drive Mapping Tool
|
Drive Mapping URL
Complete Data Backup
Backup Guide
|
Online Backup Tool
|
Cloud-to-Cloud Backup
FTP, Email & Web Service
FTP Home
|
FTP Hosting FAQ
|
Email Hosting
|
EmailManager
|
Web Hosting
Help & Resources
About
|
Enterprise Service
|
Partnership
|
Comparisons
|
Support
Quick Links
Security and Privacy
Download Software
Service Manual
Use Cases
Group Account
Online Help
Blog
Contact
Cloud Surveillance
Sign Up
Login
Features
Business Features
Online File Server
FTP Hosting
Cloud Drive Mapping
Cloud File Backup
Email Backup & Hosting
Cloud File Sharing
Folder Synchronization
Group Management
True Drop Box
Full-text Search
AD Integration/SSO
Mobile Access
IP Camera & DVR Solution
More...
Personal Features
Personal Cloud Drive
Backup All Devices
Mobile APPs
Personal Web Hosting
Sub-Account (for Kids)
Home/PC/Kids Monitoring
More...
Software
DriveHQ Drive Mapping Tool
DriveHQ FileManager
DriveHQ Online Backup
DriveHQ Mobile Apps
Pricing
Business Plans & Pricing
Personal Plans & Pricing
Price Comparison with Others
Feature Comparison with Others
Install Mobile App
Sign up
Creating account...
Invalid character in username! Only 0-9, a-z, A-Z, _, -, . allowed.
Username is required!
Invalid email address!
E-mail is required!
Password is required!
Password is invalid!
Password and confirmation do not match.
Confirm password is required!
I accept
Membership Agreement
Please read the Membership Agreement and check "I accept"!
Free Quick Sign-up
Sign-up Page
Log in
Signing in...
Username or e-mail address is required!
Password is required!
Keep me logged in
Quick Login
Forgot Password
Up
Upload
Download
Share
Publish
New Folder
New File
Copy
Cut
Delete
Paste
Rate
Upgrade
Rotate
Effect
Edit
Slide
History
// // win_iocp_socket_service.hpp // ~~~~~~~~~~~~~~~~~~~~~~~~~~~ // // Copyright (c) 2003-2008 Christopher M. Kohlhoff (chris at kohlhoff dot com) // // Distributed under the Boost Software License, Version 1.0. (See accompanying // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt) // #ifndef BOOST_ASIO_DETAIL_WIN_IOCP_SOCKET_SERVICE_HPP #define BOOST_ASIO_DETAIL_WIN_IOCP_SOCKET_SERVICE_HPP #if defined(_MSC_VER) && (_MSC_VER >= 1200) # pragma once #endif // defined(_MSC_VER) && (_MSC_VER >= 1200) #include <boost/asio/detail/push_options.hpp> #include <boost/asio/detail/win_iocp_io_service_fwd.hpp> #if defined(BOOST_ASIO_HAS_IOCP) #include <boost/asio/detail/push_options.hpp> #include <cstring> #include <boost/shared_ptr.hpp> #include <boost/weak_ptr.hpp> #include <boost/asio/detail/pop_options.hpp> #include <boost/asio/buffer.hpp> #include <boost/asio/error.hpp> #include <boost/asio/io_service.hpp> #include <boost/asio/socket_base.hpp> #include <boost/asio/detail/bind_handler.hpp> #include <boost/asio/detail/handler_alloc_helpers.hpp> #include <boost/asio/detail/handler_invoke_helpers.hpp> #include <boost/asio/detail/mutex.hpp> #include <boost/asio/detail/select_reactor.hpp> #include <boost/asio/detail/socket_holder.hpp> #include <boost/asio/detail/socket_ops.hpp> #include <boost/asio/detail/socket_types.hpp> #include <boost/asio/detail/win_iocp_io_service.hpp> namespace boost { namespace asio { namespace detail { template <typename Protocol> class win_iocp_socket_service : public boost::asio::detail::service_base<win_iocp_socket_service<Protocol> > { public: // The protocol type. typedef Protocol protocol_type; // The endpoint type. typedef typename Protocol::endpoint endpoint_type; // Base class for all operations. typedef win_iocp_io_service::operation operation; struct noop_deleter { void operator()(void*) {} }; typedef boost::shared_ptr<void> shared_cancel_token_type; typedef boost::weak_ptr<void> weak_cancel_token_type; // The native type of a socket. class native_type { public: native_type(socket_type s) : socket_(s), have_remote_endpoint_(false) { } native_type(socket_type s, const endpoint_type& ep) : socket_(s), have_remote_endpoint_(true), remote_endpoint_(ep) { } void operator=(socket_type s) { socket_ = s; have_remote_endpoint_ = false; remote_endpoint_ = endpoint_type(); } operator socket_type() const { return socket_; } HANDLE as_handle() const { return reinterpret_cast<HANDLE>(socket_); } bool have_remote_endpoint() const { return have_remote_endpoint_; } endpoint_type remote_endpoint() const { return remote_endpoint_; } private: socket_type socket_; bool have_remote_endpoint_; endpoint_type remote_endpoint_; }; // The implementation type of the socket. class implementation_type { public: // Default constructor. implementation_type() : socket_(invalid_socket), flags_(0), cancel_token_(), protocol_(endpoint_type().protocol()), next_(0), prev_(0) { } private: // Only this service will have access to the internal values. friend class win_iocp_socket_service; // The native socket representation. native_type socket_; enum { enable_connection_aborted = 1, // User wants connection_aborted errors. close_might_block = 2, // User set linger option for blocking close. user_set_non_blocking = 4 // The user wants a non-blocking socket. }; // Flags indicating the current state of the socket. unsigned char flags_; // We use a shared pointer as a cancellation token here to work around the // broken Windows support for cancellation. MSDN says that when you call // closesocket any outstanding WSARecv or WSASend operations will complete // with the error ERROR_OPERATION_ABORTED. In practice they complete with // ERROR_NETNAME_DELETED, which means you can't tell the difference between // a local cancellation and the socket being hard-closed by the peer. shared_cancel_token_type cancel_token_; // The protocol associated with the socket. protocol_type protocol_; #if defined(BOOST_ASIO_ENABLE_CANCELIO) // The ID of the thread from which it is safe to cancel asynchronous // operations. 0 means no asynchronous operations have been started yet. // ~0 means asynchronous operations have been started from more than one // thread, and cancellation is not supported for the socket. DWORD safe_cancellation_thread_id_; #endif // defined(BOOST_ASIO_ENABLE_CANCELIO) // Pointers to adjacent socket implementations in linked list. implementation_type* next_; implementation_type* prev_; }; // The type of the reactor used for connect operations. typedef detail::select_reactor<true> reactor_type; // The maximum number of buffers to support in a single operation. enum { max_buffers = 64 < max_iov_len ? 64 : max_iov_len }; // Constructor. win_iocp_socket_service(boost::asio::io_service& io_service) : boost::asio::detail::service_base< win_iocp_socket_service<Protocol> >(io_service), iocp_service_(boost::asio::use_service<win_iocp_io_service>(io_service)), reactor_(0), mutex_(), impl_list_(0) { } // Destroy all user-defined handler objects owned by the service. void shutdown_service() { // Close all implementations, causing all operations to complete. boost::asio::detail::mutex::scoped_lock lock(mutex_); implementation_type* impl = impl_list_; while (impl) { boost::system::error_code ignored_ec; close_for_destruction(*impl); impl = impl->next_; } } // Construct a new socket implementation. void construct(implementation_type& impl) { impl.socket_ = invalid_socket; impl.flags_ = 0; impl.cancel_token_.reset(); #if defined(BOOST_ASIO_ENABLE_CANCELIO) impl.safe_cancellation_thread_id_ = 0; #endif // defined(BOOST_ASIO_ENABLE_CANCELIO) // Insert implementation into linked list of all implementations. boost::asio::detail::mutex::scoped_lock lock(mutex_); impl.next_ = impl_list_; impl.prev_ = 0; if (impl_list_) impl_list_->prev_ = &impl; impl_list_ = &impl; } // Destroy a socket implementation. void destroy(implementation_type& impl) { close_for_destruction(impl); // Remove implementation from linked list of all implementations. boost::asio::detail::mutex::scoped_lock lock(mutex_); if (impl_list_ == &impl) impl_list_ = impl.next_; if (impl.prev_) impl.prev_->next_ = impl.next_; if (impl.next_) impl.next_->prev_= impl.prev_; impl.next_ = 0; impl.prev_ = 0; } // Open a new socket implementation. boost::system::error_code open(implementation_type& impl, const protocol_type& protocol, boost::system::error_code& ec) { if (is_open(impl)) { ec = boost::asio::error::already_open; return ec; } socket_holder sock(socket_ops::socket(protocol.family(), protocol.type(), protocol.protocol(), ec)); if (sock.get() == invalid_socket) return ec; HANDLE sock_as_handle = reinterpret_cast<HANDLE>(sock.get()); iocp_service_.register_handle(sock_as_handle); impl.socket_ = sock.release(); impl.flags_ = 0; impl.cancel_token_.reset(static_cast<void*>(0), noop_deleter()); impl.protocol_ = protocol; ec = boost::system::error_code(); return ec; } // Assign a native socket to a socket implementation. boost::system::error_code assign(implementation_type& impl, const protocol_type& protocol, const native_type& native_socket, boost::system::error_code& ec) { if (is_open(impl)) { ec = boost::asio::error::already_open; return ec; } iocp_service_.register_handle(native_socket.as_handle()); impl.socket_ = native_socket; impl.flags_ = 0; impl.cancel_token_.reset(static_cast<void*>(0), noop_deleter()); impl.protocol_ = protocol; ec = boost::system::error_code(); return ec; } // Determine whether the socket is open. bool is_open(const implementation_type& impl) const { return impl.socket_ != invalid_socket; } // Destroy a socket implementation. boost::system::error_code close(implementation_type& impl, boost::system::error_code& ec) { if (is_open(impl)) { // Check if the reactor was created, in which case we need to close the // socket on the reactor as well to cancel any operations that might be // running there. reactor_type* reactor = static_cast<reactor_type*>( interlocked_compare_exchange_pointer( reinterpret_cast<void**>(&reactor_), 0, 0)); if (reactor) reactor->close_descriptor(impl.socket_); if (socket_ops::close(impl.socket_, ec) == socket_error_retval) return ec; impl.socket_ = invalid_socket; impl.flags_ = 0; impl.cancel_token_.reset(); #if defined(BOOST_ASIO_ENABLE_CANCELIO) impl.safe_cancellation_thread_id_ = 0; #endif // defined(BOOST_ASIO_ENABLE_CANCELIO) } ec = boost::system::error_code(); return ec; } // Get the native socket representation. native_type native(implementation_type& impl) { return impl.socket_; } // Cancel all operations associated with the socket. boost::system::error_code cancel(implementation_type& impl, boost::system::error_code& ec) { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; } else if (FARPROC cancel_io_ex_ptr = ::GetProcAddress( ::GetModuleHandleA("KERNEL32"), "CancelIoEx")) { // The version of Windows supports cancellation from any thread. typedef BOOL (WINAPI* cancel_io_ex_t)(HANDLE, LPOVERLAPPED); cancel_io_ex_t cancel_io_ex = (cancel_io_ex_t)cancel_io_ex_ptr; socket_type sock = impl.socket_; HANDLE sock_as_handle = reinterpret_cast<HANDLE>(sock); if (!cancel_io_ex(sock_as_handle, 0)) { DWORD last_error = ::GetLastError(); if (last_error == ERROR_NOT_FOUND) { // ERROR_NOT_FOUND means that there were no operations to be // cancelled. We swallow this error to match the behaviour on other // platforms. ec = boost::system::error_code(); } else { ec = boost::system::error_code(last_error, boost::asio::error::get_system_category()); } } else { ec = boost::system::error_code(); } } #if defined(BOOST_ASIO_ENABLE_CANCELIO) else if (impl.safe_cancellation_thread_id_ == 0) { // No operations have been started, so there's nothing to cancel. ec = boost::system::error_code(); } else if (impl.safe_cancellation_thread_id_ == ::GetCurrentThreadId()) { // Asynchronous operations have been started from the current thread only, // so it is safe to try to cancel them using CancelIo. socket_type sock = impl.socket_; HANDLE sock_as_handle = reinterpret_cast<HANDLE>(sock); if (!::CancelIo(sock_as_handle)) { DWORD last_error = ::GetLastError(); ec = boost::system::error_code(last_error, boost::asio::error::get_system_category()); } else { ec = boost::system::error_code(); } } else { // Asynchronous operations have been started from more than one thread, // so cancellation is not safe. ec = boost::asio::error::operation_not_supported; } #else // defined(BOOST_ASIO_ENABLE_CANCELIO) else { // Cancellation is not supported as CancelIo may not be used. ec = boost::asio::error::operation_not_supported; } #endif // defined(BOOST_ASIO_ENABLE_CANCELIO) return ec; } // Determine whether the socket is at the out-of-band data mark. bool at_mark(const implementation_type& impl, boost::system::error_code& ec) const { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return false; } boost::asio::detail::ioctl_arg_type value = 0; socket_ops::ioctl(impl.socket_, SIOCATMARK, &value, ec); return ec ? false : value != 0; } // Determine the number of bytes available for reading. std::size_t available(const implementation_type& impl, boost::system::error_code& ec) const { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return 0; } boost::asio::detail::ioctl_arg_type value = 0; socket_ops::ioctl(impl.socket_, FIONREAD, &value, ec); return ec ? static_cast<std::size_t>(0) : static_cast<std::size_t>(value); } // Bind the socket to the specified local endpoint. boost::system::error_code bind(implementation_type& impl, const endpoint_type& endpoint, boost::system::error_code& ec) { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return ec; } socket_ops::bind(impl.socket_, endpoint.data(), endpoint.size(), ec); return ec; } // Place the socket into the state where it will listen for new connections. boost::system::error_code listen(implementation_type& impl, int backlog, boost::system::error_code& ec) { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return ec; } socket_ops::listen(impl.socket_, backlog, ec); return ec; } // Set a socket option. template <typename Option> boost::system::error_code set_option(implementation_type& impl, const Option& option, boost::system::error_code& ec) { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return ec; } if (option.level(impl.protocol_) == custom_socket_option_level && option.name(impl.protocol_) == enable_connection_aborted_option) { if (option.size(impl.protocol_) != sizeof(int)) { ec = boost::asio::error::invalid_argument; } else { if (*reinterpret_cast<const int*>(option.data(impl.protocol_))) impl.flags_ |= implementation_type::enable_connection_aborted; else impl.flags_ &= ~implementation_type::enable_connection_aborted; ec = boost::system::error_code(); } return ec; } else { if (option.level(impl.protocol_) == SOL_SOCKET && option.name(impl.protocol_) == SO_LINGER) { const ::linger* linger_option = reinterpret_cast<const ::linger*>(option.data(impl.protocol_)); if (linger_option->l_onoff != 0 && linger_option->l_linger != 0) impl.flags_ |= implementation_type::close_might_block; else impl.flags_ &= ~implementation_type::close_might_block; } socket_ops::setsockopt(impl.socket_, option.level(impl.protocol_), option.name(impl.protocol_), option.data(impl.protocol_), option.size(impl.protocol_), ec); return ec; } } // Set a socket option. template <typename Option> boost::system::error_code get_option(const implementation_type& impl, Option& option, boost::system::error_code& ec) const { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return ec; } if (option.level(impl.protocol_) == custom_socket_option_level && option.name(impl.protocol_) == enable_connection_aborted_option) { if (option.size(impl.protocol_) != sizeof(int)) { ec = boost::asio::error::invalid_argument; } else { int* target = reinterpret_cast<int*>(option.data(impl.protocol_)); if (impl.flags_ & implementation_type::enable_connection_aborted) *target = 1; else *target = 0; option.resize(impl.protocol_, sizeof(int)); ec = boost::system::error_code(); } return ec; } else { size_t size = option.size(impl.protocol_); socket_ops::getsockopt(impl.socket_, option.level(impl.protocol_), option.name(impl.protocol_), option.data(impl.protocol_), &size, ec); if (!ec) option.resize(impl.protocol_, size); return ec; } } // Perform an IO control command on the socket. template <typename IO_Control_Command> boost::system::error_code io_control(implementation_type& impl, IO_Control_Command& command, boost::system::error_code& ec) { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return ec; } socket_ops::ioctl(impl.socket_, command.name(), static_cast<ioctl_arg_type*>(command.data()), ec); if (!ec && command.name() == static_cast<int>(FIONBIO)) { if (command.get()) impl.flags_ |= implementation_type::user_set_non_blocking; else impl.flags_ &= ~implementation_type::user_set_non_blocking; } return ec; } // Get the local endpoint. endpoint_type local_endpoint(const implementation_type& impl, boost::system::error_code& ec) const { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return endpoint_type(); } endpoint_type endpoint; std::size_t addr_len = endpoint.capacity(); if (socket_ops::getsockname(impl.socket_, endpoint.data(), &addr_len, ec)) return endpoint_type(); endpoint.resize(addr_len); return endpoint; } // Get the remote endpoint. endpoint_type remote_endpoint(const implementation_type& impl, boost::system::error_code& ec) const { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return endpoint_type(); } if (impl.socket_.have_remote_endpoint()) { // Check if socket is still connected. DWORD connect_time = 0; size_t connect_time_len = sizeof(connect_time); if (socket_ops::getsockopt(impl.socket_, SOL_SOCKET, SO_CONNECT_TIME, &connect_time, &connect_time_len, ec) == socket_error_retval) { return endpoint_type(); } if (connect_time == 0xFFFFFFFF) { ec = boost::asio::error::not_connected; return endpoint_type(); } ec = boost::system::error_code(); return impl.socket_.remote_endpoint(); } else { endpoint_type endpoint; std::size_t addr_len = endpoint.capacity(); if (socket_ops::getpeername(impl.socket_, endpoint.data(), &addr_len, ec)) return endpoint_type(); endpoint.resize(addr_len); return endpoint; } } /// Disable sends or receives on the socket. boost::system::error_code shutdown(implementation_type& impl, socket_base::shutdown_type what, boost::system::error_code& ec) { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return ec; } socket_ops::shutdown(impl.socket_, what, ec); return ec; } // Send the given data to the peer. Returns the number of bytes sent. template <typename ConstBufferSequence> size_t send(implementation_type& impl, const ConstBufferSequence& buffers, socket_base::message_flags flags, boost::system::error_code& ec) { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return 0; } // Copy buffers into WSABUF array. ::WSABUF bufs[max_buffers]; typename ConstBufferSequence::const_iterator iter = buffers.begin(); typename ConstBufferSequence::const_iterator end = buffers.end(); DWORD i = 0; size_t total_buffer_size = 0; for (; iter != end && i < max_buffers; ++iter, ++i) { boost::asio::const_buffer buffer(*iter); bufs[i].len = static_cast<u_long>(boost::asio::buffer_size(buffer)); bufs[i].buf = const_cast<char*>( boost::asio::buffer_cast<const char*>(buffer)); total_buffer_size += boost::asio::buffer_size(buffer); } // A request to receive 0 bytes on a stream socket is a no-op. if (impl.protocol_.type() == SOCK_STREAM && total_buffer_size == 0) { ec = boost::system::error_code(); return 0; } // Send the data. DWORD bytes_transferred = 0; int result = ::WSASend(impl.socket_, bufs, i, &bytes_transferred, flags, 0, 0); if (result != 0) { DWORD last_error = ::WSAGetLastError(); if (last_error == ERROR_NETNAME_DELETED) last_error = WSAECONNRESET; else if (last_error == ERROR_PORT_UNREACHABLE) last_error = WSAECONNREFUSED; ec = boost::system::error_code(last_error, boost::asio::error::get_system_category()); return 0; } ec = boost::system::error_code(); return bytes_transferred; } template <typename ConstBufferSequence, typename Handler> class send_operation : public operation { public: send_operation(win_iocp_io_service& io_service, weak_cancel_token_type cancel_token, const ConstBufferSequence& buffers, Handler handler) : operation(io_service, &send_operation<ConstBufferSequence, Handler>::do_completion_impl, &send_operation<ConstBufferSequence, Handler>::destroy_impl), work_(io_service.get_io_service()), cancel_token_(cancel_token), buffers_(buffers), handler_(handler) { } private: static void do_completion_impl(operation* op, DWORD last_error, size_t bytes_transferred) { // Take ownership of the operation object. typedef send_operation<ConstBufferSequence, Handler> op_type; op_type* handler_op(static_cast<op_type*>(op)); typedef handler_alloc_traits<Handler, op_type> alloc_traits; handler_ptr<alloc_traits> ptr(handler_op->handler_, handler_op); #if defined(BOOST_ASIO_ENABLE_BUFFER_DEBUGGING) // Check whether buffers are still valid. typename ConstBufferSequence::const_iterator iter = handler_op->buffers_.begin(); typename ConstBufferSequence::const_iterator end = handler_op->buffers_.end(); while (iter != end) { boost::asio::const_buffer buffer(*iter); boost::asio::buffer_cast<const char*>(buffer); ++iter; } #endif // defined(BOOST_ASIO_ENABLE_BUFFER_DEBUGGING) // Map non-portable errors to their portable counterparts. boost::system::error_code ec(last_error, boost::asio::error::get_system_category()); if (ec.value() == ERROR_NETNAME_DELETED) { if (handler_op->cancel_token_.expired()) ec = boost::asio::error::operation_aborted; else ec = boost::asio::error::connection_reset; } else if (ec.value() == ERROR_PORT_UNREACHABLE) { ec = boost::asio::error::connection_refused; } // Make a copy of the handler so that the memory can be deallocated before // the upcall is made. Handler handler(handler_op->handler_); // Free the memory associated with the handler. ptr.reset(); // Call the handler. boost_asio_handler_invoke_helpers::invoke( detail::bind_handler(handler, ec, bytes_transferred), &handler); } static void destroy_impl(operation* op) { // Take ownership of the operation object. typedef send_operation<ConstBufferSequence, Handler> op_type; op_type* handler_op(static_cast<op_type*>(op)); typedef handler_alloc_traits<Handler, op_type> alloc_traits; handler_ptr<alloc_traits> ptr(handler_op->handler_, handler_op); } boost::asio::io_service::work work_; weak_cancel_token_type cancel_token_; ConstBufferSequence buffers_; Handler handler_; }; // Start an asynchronous send. The data being sent must be valid for the // lifetime of the asynchronous operation. template <typename ConstBufferSequence, typename Handler> void async_send(implementation_type& impl, const ConstBufferSequence& buffers, socket_base::message_flags flags, Handler handler) { if (!is_open(impl)) { this->get_io_service().post(bind_handler(handler, boost::asio::error::bad_descriptor, 0)); return; } #if defined(BOOST_ASIO_ENABLE_CANCELIO) // Update the ID of the thread from which cancellation is safe. if (impl.safe_cancellation_thread_id_ == 0) impl.safe_cancellation_thread_id_ = ::GetCurrentThreadId(); else if (impl.safe_cancellation_thread_id_ != ::GetCurrentThreadId()) impl.safe_cancellation_thread_id_ = ~DWORD(0); #endif // defined(BOOST_ASIO_ENABLE_CANCELIO) // Allocate and construct an operation to wrap the handler. typedef send_operation<ConstBufferSequence, Handler> value_type; typedef handler_alloc_traits<Handler, value_type> alloc_traits; raw_handler_ptr<alloc_traits> raw_ptr(handler); handler_ptr<alloc_traits> ptr(raw_ptr, iocp_service_, impl.cancel_token_, buffers, handler); // Copy buffers into WSABUF array. ::WSABUF bufs[max_buffers]; typename ConstBufferSequence::const_iterator iter = buffers.begin(); typename ConstBufferSequence::const_iterator end = buffers.end(); DWORD i = 0; size_t total_buffer_size = 0; for (; iter != end && i < max_buffers; ++iter, ++i) { boost::asio::const_buffer buffer(*iter); bufs[i].len = static_cast<u_long>(boost::asio::buffer_size(buffer)); bufs[i].buf = const_cast<char*>( boost::asio::buffer_cast<const char*>(buffer)); total_buffer_size += boost::asio::buffer_size(buffer); } // A request to receive 0 bytes on a stream socket is a no-op. if (impl.protocol_.type() == SOCK_STREAM && total_buffer_size == 0) { boost::asio::io_service::work work(this->get_io_service()); ptr.reset(); boost::system::error_code error; iocp_service_.post(bind_handler(handler, error, 0)); return; } // Send the data. DWORD bytes_transferred = 0; int result = ::WSASend(impl.socket_, bufs, i, &bytes_transferred, flags, ptr.get(), 0); DWORD last_error = ::WSAGetLastError(); // Check if the operation completed immediately. if (result != 0 && last_error != WSA_IO_PENDING) { boost::asio::io_service::work work(this->get_io_service()); ptr.reset(); boost::system::error_code ec(last_error, boost::asio::error::get_system_category()); iocp_service_.post(bind_handler(handler, ec, bytes_transferred)); } else { ptr.release(); } } // Send a datagram to the specified endpoint. Returns the number of bytes // sent. template <typename ConstBufferSequence> size_t send_to(implementation_type& impl, const ConstBufferSequence& buffers, const endpoint_type& destination, socket_base::message_flags flags, boost::system::error_code& ec) { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return 0; } // Copy buffers into WSABUF array. ::WSABUF bufs[max_buffers]; typename ConstBufferSequence::const_iterator iter = buffers.begin(); typename ConstBufferSequence::const_iterator end = buffers.end(); DWORD i = 0; for (; iter != end && i < max_buffers; ++iter, ++i) { boost::asio::const_buffer buffer(*iter); bufs[i].len = static_cast<u_long>(boost::asio::buffer_size(buffer)); bufs[i].buf = const_cast<char*>( boost::asio::buffer_cast<const char*>(buffer)); } // Send the data. DWORD bytes_transferred = 0; int result = ::WSASendTo(impl.socket_, bufs, i, &bytes_transferred, flags, destination.data(), static_cast<int>(destination.size()), 0, 0); if (result != 0) { DWORD last_error = ::WSAGetLastError(); if (last_error == ERROR_PORT_UNREACHABLE) last_error = WSAECONNREFUSED; ec = boost::system::error_code(last_error, boost::asio::error::get_system_category()); return 0; } ec = boost::system::error_code(); return bytes_transferred; } template <typename ConstBufferSequence, typename Handler> class send_to_operation : public operation { public: send_to_operation(win_iocp_io_service& io_service, const ConstBufferSequence& buffers, Handler handler) : operation(io_service, &send_to_operation<ConstBufferSequence, Handler>::do_completion_impl, &send_to_operation<ConstBufferSequence, Handler>::destroy_impl), work_(io_service.get_io_service()), buffers_(buffers), handler_(handler) { } private: static void do_completion_impl(operation* op, DWORD last_error, size_t bytes_transferred) { // Take ownership of the operation object. typedef send_to_operation<ConstBufferSequence, Handler> op_type; op_type* handler_op(static_cast<op_type*>(op)); typedef handler_alloc_traits<Handler, op_type> alloc_traits; handler_ptr<alloc_traits> ptr(handler_op->handler_, handler_op); #if defined(BOOST_ASIO_ENABLE_BUFFER_DEBUGGING) // Check whether buffers are still valid. typename ConstBufferSequence::const_iterator iter = handler_op->buffers_.begin(); typename ConstBufferSequence::const_iterator end = handler_op->buffers_.end(); while (iter != end) { boost::asio::const_buffer buffer(*iter); boost::asio::buffer_cast<const char*>(buffer); ++iter; } #endif // defined(BOOST_ASIO_ENABLE_BUFFER_DEBUGGING) // Map non-portable errors to their portable counterparts. boost::system::error_code ec(last_error, boost::asio::error::get_system_category()); if (ec.value() == ERROR_PORT_UNREACHABLE) { ec = boost::asio::error::connection_refused; } // Make a copy of the handler so that the memory can be deallocated before // the upcall is made. Handler handler(handler_op->handler_); // Free the memory associated with the handler. ptr.reset(); // Call the handler. boost_asio_handler_invoke_helpers::invoke( detail::bind_handler(handler, ec, bytes_transferred), &handler); } static void destroy_impl(operation* op) { // Take ownership of the operation object. typedef send_to_operation<ConstBufferSequence, Handler> op_type; op_type* handler_op(static_cast<op_type*>(op)); typedef handler_alloc_traits<Handler, op_type> alloc_traits; handler_ptr<alloc_traits> ptr(handler_op->handler_, handler_op); } boost::asio::io_service::work work_; ConstBufferSequence buffers_; Handler handler_; }; // Start an asynchronous send. The data being sent must be valid for the // lifetime of the asynchronous operation. template <typename ConstBufferSequence, typename Handler> void async_send_to(implementation_type& impl, const ConstBufferSequence& buffers, const endpoint_type& destination, socket_base::message_flags flags, Handler handler) { if (!is_open(impl)) { this->get_io_service().post(bind_handler(handler, boost::asio::error::bad_descriptor, 0)); return; } #if defined(BOOST_ASIO_ENABLE_CANCELIO) // Update the ID of the thread from which cancellation is safe. if (impl.safe_cancellation_thread_id_ == 0) impl.safe_cancellation_thread_id_ = ::GetCurrentThreadId(); else if (impl.safe_cancellation_thread_id_ != ::GetCurrentThreadId()) impl.safe_cancellation_thread_id_ = ~DWORD(0); #endif // defined(BOOST_ASIO_ENABLE_CANCELIO) // Allocate and construct an operation to wrap the handler. typedef send_to_operation<ConstBufferSequence, Handler> value_type; typedef handler_alloc_traits<Handler, value_type> alloc_traits; raw_handler_ptr<alloc_traits> raw_ptr(handler); handler_ptr<alloc_traits> ptr(raw_ptr, iocp_service_, buffers, handler); // Copy buffers into WSABUF array. ::WSABUF bufs[max_buffers]; typename ConstBufferSequence::const_iterator iter = buffers.begin(); typename ConstBufferSequence::const_iterator end = buffers.end(); DWORD i = 0; for (; iter != end && i < max_buffers; ++iter, ++i) { boost::asio::const_buffer buffer(*iter); bufs[i].len = static_cast<u_long>(boost::asio::buffer_size(buffer)); bufs[i].buf = const_cast<char*>( boost::asio::buffer_cast<const char*>(buffer)); } // Send the data. DWORD bytes_transferred = 0; int result = ::WSASendTo(impl.socket_, bufs, i, &bytes_transferred, flags, destination.data(), static_cast<int>(destination.size()), ptr.get(), 0); DWORD last_error = ::WSAGetLastError(); // Check if the operation completed immediately. if (result != 0 && last_error != WSA_IO_PENDING) { boost::asio::io_service::work work(this->get_io_service()); ptr.reset(); boost::system::error_code ec(last_error, boost::asio::error::get_system_category()); iocp_service_.post(bind_handler(handler, ec, bytes_transferred)); } else { ptr.release(); } } // Receive some data from the peer. Returns the number of bytes received. template <typename MutableBufferSequence> size_t receive(implementation_type& impl, const MutableBufferSequence& buffers, socket_base::message_flags flags, boost::system::error_code& ec) { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return 0; } // Copy buffers into WSABUF array. ::WSABUF bufs[max_buffers]; typename MutableBufferSequence::const_iterator iter = buffers.begin(); typename MutableBufferSequence::const_iterator end = buffers.end(); DWORD i = 0; size_t total_buffer_size = 0; for (; iter != end && i < max_buffers; ++iter, ++i) { boost::asio::mutable_buffer buffer(*iter); bufs[i].len = static_cast<u_long>(boost::asio::buffer_size(buffer)); bufs[i].buf = boost::asio::buffer_cast<char*>(buffer); total_buffer_size += boost::asio::buffer_size(buffer); } // A request to receive 0 bytes on a stream socket is a no-op. if (impl.protocol_.type() == SOCK_STREAM && total_buffer_size == 0) { ec = boost::system::error_code(); return 0; } // Receive some data. DWORD bytes_transferred = 0; DWORD recv_flags = flags; int result = ::WSARecv(impl.socket_, bufs, i, &bytes_transferred, &recv_flags, 0, 0); if (result != 0) { DWORD last_error = ::WSAGetLastError(); if (last_error == ERROR_NETNAME_DELETED) last_error = WSAECONNRESET; else if (last_error == ERROR_PORT_UNREACHABLE) last_error = WSAECONNREFUSED; ec = boost::system::error_code(last_error, boost::asio::error::get_system_category()); return 0; } if (bytes_transferred == 0) { ec = boost::asio::error::eof; return 0; } ec = boost::system::error_code(); return bytes_transferred; } template <typename MutableBufferSequence, typename Handler> class receive_operation : public operation { public: receive_operation(win_iocp_io_service& io_service, weak_cancel_token_type cancel_token, const MutableBufferSequence& buffers, Handler handler) : operation(io_service, &receive_operation< MutableBufferSequence, Handler>::do_completion_impl, &receive_operation< MutableBufferSequence, Handler>::destroy_impl), work_(io_service.get_io_service()), cancel_token_(cancel_token), buffers_(buffers), handler_(handler) { } private: static void do_completion_impl(operation* op, DWORD last_error, size_t bytes_transferred) { // Take ownership of the operation object. typedef receive_operation<MutableBufferSequence, Handler> op_type; op_type* handler_op(static_cast<op_type*>(op)); typedef handler_alloc_traits<Handler, op_type> alloc_traits; handler_ptr<alloc_traits> ptr(handler_op->handler_, handler_op); #if defined(BOOST_ASIO_ENABLE_BUFFER_DEBUGGING) // Check whether buffers are still valid. typename MutableBufferSequence::const_iterator iter = handler_op->buffers_.begin(); typename MutableBufferSequence::const_iterator end = handler_op->buffers_.end(); while (iter != end) { boost::asio::mutable_buffer buffer(*iter); boost::asio::buffer_cast<char*>(buffer); ++iter; } #endif // defined(BOOST_ASIO_ENABLE_BUFFER_DEBUGGING) // Map non-portable errors to their portable counterparts. boost::system::error_code ec(last_error, boost::asio::error::get_system_category()); if (ec.value() == ERROR_NETNAME_DELETED) { if (handler_op->cancel_token_.expired()) ec = boost::asio::error::operation_aborted; else ec = boost::asio::error::connection_reset; } else if (ec.value() == ERROR_PORT_UNREACHABLE) { ec = boost::asio::error::connection_refused; } // Check for connection closed. else if (!ec && bytes_transferred == 0) { ec = boost::asio::error::eof; } // Make a copy of the handler so that the memory can be deallocated before // the upcall is made. Handler handler(handler_op->handler_); // Free the memory associated with the handler. ptr.reset(); // Call the handler. boost_asio_handler_invoke_helpers::invoke( detail::bind_handler(handler, ec, bytes_transferred), &handler); } static void destroy_impl(operation* op) { // Take ownership of the operation object. typedef receive_operation<MutableBufferSequence, Handler> op_type; op_type* handler_op(static_cast<op_type*>(op)); typedef handler_alloc_traits<Handler, op_type> alloc_traits; handler_ptr<alloc_traits> ptr(handler_op->handler_, handler_op); } boost::asio::io_service::work work_; weak_cancel_token_type cancel_token_; MutableBufferSequence buffers_; Handler handler_; }; // Start an asynchronous receive. The buffer for the data being received // must be valid for the lifetime of the asynchronous operation. template <typename MutableBufferSequence, typename Handler> void async_receive(implementation_type& impl, const MutableBufferSequence& buffers, socket_base::message_flags flags, Handler handler) { if (!is_open(impl)) { this->get_io_service().post(bind_handler(handler, boost::asio::error::bad_descriptor, 0)); return; } #if defined(BOOST_ASIO_ENABLE_CANCELIO) // Update the ID of the thread from which cancellation is safe. if (impl.safe_cancellation_thread_id_ == 0) impl.safe_cancellation_thread_id_ = ::GetCurrentThreadId(); else if (impl.safe_cancellation_thread_id_ != ::GetCurrentThreadId()) impl.safe_cancellation_thread_id_ = ~DWORD(0); #endif // defined(BOOST_ASIO_ENABLE_CANCELIO) // Allocate and construct an operation to wrap the handler. typedef receive_operation<MutableBufferSequence, Handler> value_type; typedef handler_alloc_traits<Handler, value_type> alloc_traits; raw_handler_ptr<alloc_traits> raw_ptr(handler); handler_ptr<alloc_traits> ptr(raw_ptr, iocp_service_, impl.cancel_token_, buffers, handler); // Copy buffers into WSABUF array. ::WSABUF bufs[max_buffers]; typename MutableBufferSequence::const_iterator iter = buffers.begin(); typename MutableBufferSequence::const_iterator end = buffers.end(); DWORD i = 0; size_t total_buffer_size = 0; for (; iter != end && i < max_buffers; ++iter, ++i) { boost::asio::mutable_buffer buffer(*iter); bufs[i].len = static_cast<u_long>(boost::asio::buffer_size(buffer)); bufs[i].buf = boost::asio::buffer_cast<char*>(buffer); total_buffer_size += boost::asio::buffer_size(buffer); } // A request to receive 0 bytes on a stream socket is a no-op. if (impl.protocol_.type() == SOCK_STREAM && total_buffer_size == 0) { boost::asio::io_service::work work(this->get_io_service()); ptr.reset(); boost::system::error_code error; iocp_service_.post(bind_handler(handler, error, 0)); return; } // Receive some data. DWORD bytes_transferred = 0; DWORD recv_flags = flags; int result = ::WSARecv(impl.socket_, bufs, i, &bytes_transferred, &recv_flags, ptr.get(), 0); DWORD last_error = ::WSAGetLastError(); if (result != 0 && last_error != WSA_IO_PENDING) { boost::asio::io_service::work work(this->get_io_service()); ptr.reset(); boost::system::error_code ec(last_error, boost::asio::error::get_system_category()); iocp_service_.post(bind_handler(handler, ec, bytes_transferred)); } else { ptr.release(); } } // Receive a datagram with the endpoint of the sender. Returns the number of // bytes received. template <typename MutableBufferSequence> size_t receive_from(implementation_type& impl, const MutableBufferSequence& buffers, endpoint_type& sender_endpoint, socket_base::message_flags flags, boost::system::error_code& ec) { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return 0; } // Copy buffers into WSABUF array. ::WSABUF bufs[max_buffers]; typename MutableBufferSequence::const_iterator iter = buffers.begin(); typename MutableBufferSequence::const_iterator end = buffers.end(); DWORD i = 0; for (; iter != end && i < max_buffers; ++iter, ++i) { boost::asio::mutable_buffer buffer(*iter); bufs[i].len = static_cast<u_long>(boost::asio::buffer_size(buffer)); bufs[i].buf = boost::asio::buffer_cast<char*>(buffer); } // Receive some data. DWORD bytes_transferred = 0; DWORD recv_flags = flags; int endpoint_size = static_cast<int>(sender_endpoint.capacity()); int result = ::WSARecvFrom(impl.socket_, bufs, i, &bytes_transferred, &recv_flags, sender_endpoint.data(), &endpoint_size, 0, 0); if (result != 0) { DWORD last_error = ::WSAGetLastError(); if (last_error == ERROR_PORT_UNREACHABLE) last_error = WSAECONNREFUSED; ec = boost::system::error_code(last_error, boost::asio::error::get_system_category()); return 0; } if (bytes_transferred == 0) { ec = boost::asio::error::eof; return 0; } sender_endpoint.resize(static_cast<std::size_t>(endpoint_size)); ec = boost::system::error_code(); return bytes_transferred; } template <typename MutableBufferSequence, typename Handler> class receive_from_operation : public operation { public: receive_from_operation(win_iocp_io_service& io_service, endpoint_type& endpoint, const MutableBufferSequence& buffers, Handler handler) : operation(io_service, &receive_from_operation< MutableBufferSequence, Handler>::do_completion_impl, &receive_from_operation< MutableBufferSequence, Handler>::destroy_impl), endpoint_(endpoint), endpoint_size_(static_cast<int>(endpoint.capacity())), work_(io_service.get_io_service()), buffers_(buffers), handler_(handler) { } int& endpoint_size() { return endpoint_size_; } private: static void do_completion_impl(operation* op, DWORD last_error, size_t bytes_transferred) { // Take ownership of the operation object. typedef receive_from_operation<MutableBufferSequence, Handler> op_type; op_type* handler_op(static_cast<op_type*>(op)); typedef handler_alloc_traits<Handler, op_type> alloc_traits; handler_ptr<alloc_traits> ptr(handler_op->handler_, handler_op); #if defined(BOOST_ASIO_ENABLE_BUFFER_DEBUGGING) // Check whether buffers are still valid. typename MutableBufferSequence::const_iterator iter = handler_op->buffers_.begin(); typename MutableBufferSequence::const_iterator end = handler_op->buffers_.end(); while (iter != end) { boost::asio::mutable_buffer buffer(*iter); boost::asio::buffer_cast<char*>(buffer); ++iter; } #endif // defined(BOOST_ASIO_ENABLE_BUFFER_DEBUGGING) // Map non-portable errors to their portable counterparts. boost::system::error_code ec(last_error, boost::asio::error::get_system_category()); if (ec.value() == ERROR_PORT_UNREACHABLE) { ec = boost::asio::error::connection_refused; } // Check for connection closed. if (!ec && bytes_transferred == 0) { ec = boost::asio::error::eof; } // Record the size of the endpoint returned by the operation. handler_op->endpoint_.resize(handler_op->endpoint_size_); // Make a copy of the handler so that the memory can be deallocated before // the upcall is made. Handler handler(handler_op->handler_); // Free the memory associated with the handler. ptr.reset(); // Call the handler. boost_asio_handler_invoke_helpers::invoke( detail::bind_handler(handler, ec, bytes_transferred), &handler); } static void destroy_impl(operation* op) { // Take ownership of the operation object. typedef receive_from_operation<MutableBufferSequence, Handler> op_type; op_type* handler_op(static_cast<op_type*>(op)); typedef handler_alloc_traits<Handler, op_type> alloc_traits; handler_ptr<alloc_traits> ptr(handler_op->handler_, handler_op); } endpoint_type& endpoint_; int endpoint_size_; boost::asio::io_service::work work_; MutableBufferSequence buffers_; Handler handler_; }; // Start an asynchronous receive. The buffer for the data being received and // the sender_endpoint object must both be valid for the lifetime of the // asynchronous operation. template <typename MutableBufferSequence, typename Handler> void async_receive_from(implementation_type& impl, const MutableBufferSequence& buffers, endpoint_type& sender_endp, socket_base::message_flags flags, Handler handler) { if (!is_open(impl)) { this->get_io_service().post(bind_handler(handler, boost::asio::error::bad_descriptor, 0)); return; } #if defined(BOOST_ASIO_ENABLE_CANCELIO) // Update the ID of the thread from which cancellation is safe. if (impl.safe_cancellation_thread_id_ == 0) impl.safe_cancellation_thread_id_ = ::GetCurrentThreadId(); else if (impl.safe_cancellation_thread_id_ != ::GetCurrentThreadId()) impl.safe_cancellation_thread_id_ = ~DWORD(0); #endif // defined(BOOST_ASIO_ENABLE_CANCELIO) // Allocate and construct an operation to wrap the handler. typedef receive_from_operation<MutableBufferSequence, Handler> value_type; typedef handler_alloc_traits<Handler, value_type> alloc_traits; raw_handler_ptr<alloc_traits> raw_ptr(handler); handler_ptr<alloc_traits> ptr(raw_ptr, iocp_service_, sender_endp, buffers, handler); // Copy buffers into WSABUF array. ::WSABUF bufs[max_buffers]; typename MutableBufferSequence::const_iterator iter = buffers.begin(); typename MutableBufferSequence::const_iterator end = buffers.end(); DWORD i = 0; for (; iter != end && i < max_buffers; ++iter, ++i) { boost::asio::mutable_buffer buffer(*iter); bufs[i].len = static_cast<u_long>(boost::asio::buffer_size(buffer)); bufs[i].buf = boost::asio::buffer_cast<char*>(buffer); } // Receive some data. DWORD bytes_transferred = 0; DWORD recv_flags = flags; int result = ::WSARecvFrom(impl.socket_, bufs, i, &bytes_transferred, &recv_flags, sender_endp.data(), &ptr.get()->endpoint_size(), ptr.get(), 0); DWORD last_error = ::WSAGetLastError(); if (result != 0 && last_error != WSA_IO_PENDING) { boost::asio::io_service::work work(this->get_io_service()); ptr.reset(); boost::system::error_code ec(last_error, boost::asio::error::get_system_category()); iocp_service_.post(bind_handler(handler, ec, bytes_transferred)); } else { ptr.release(); } } // Accept a new connection. template <typename Socket> boost::system::error_code accept(implementation_type& impl, Socket& peer, endpoint_type* peer_endpoint, boost::system::error_code& ec) { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return ec; } // We cannot accept a socket that is already open. if (peer.is_open()) { ec = boost::asio::error::already_open; return ec; } for (;;) { boost::system::error_code ec; socket_holder new_socket; std::size_t addr_len = 0; if (peer_endpoint) { addr_len = peer_endpoint->capacity(); new_socket.reset(socket_ops::accept(impl.socket_, peer_endpoint->data(), &addr_len, ec)); } else { new_socket.reset(socket_ops::accept(impl.socket_, 0, 0, ec)); } if (ec) { if (ec == boost::asio::error::connection_aborted && !(impl.flags_ & implementation_type::enable_connection_aborted)) { // Retry accept operation. continue; } else { return ec; } } if (peer_endpoint) peer_endpoint->resize(addr_len); peer.assign(impl.protocol_, new_socket.get(), ec); if (!ec) new_socket.release(); return ec; } } template <typename Socket, typename Handler> class accept_operation : public operation { public: accept_operation(win_iocp_io_service& io_service, socket_type socket, socket_type new_socket, Socket& peer, const protocol_type& protocol, endpoint_type* peer_endpoint, bool enable_connection_aborted, Handler handler) : operation(io_service, &accept_operation<Socket, Handler>::do_completion_impl, &accept_operation<Socket, Handler>::destroy_impl), io_service_(io_service), socket_(socket), new_socket_(new_socket), peer_(peer), protocol_(protocol), peer_endpoint_(peer_endpoint), work_(io_service.get_io_service()), enable_connection_aborted_(enable_connection_aborted), handler_(handler) { } socket_type new_socket() { return new_socket_.get(); } void* output_buffer() { return output_buffer_; } DWORD address_length() { return sizeof(sockaddr_storage_type) + 16; } private: static void do_completion_impl(operation* op, DWORD last_error, size_t bytes_transferred) { // Take ownership of the operation object. typedef accept_operation<Socket, Handler> op_type; op_type* handler_op(static_cast<op_type*>(op)); typedef handler_alloc_traits<Handler, op_type> alloc_traits; handler_ptr<alloc_traits> ptr(handler_op->handler_, handler_op); // Map Windows error ERROR_NETNAME_DELETED to connection_aborted. if (last_error == ERROR_NETNAME_DELETED) { last_error = WSAECONNABORTED; } // Restart the accept operation if we got the connection_aborted error // and the enable_connection_aborted socket option is not set. if (last_error == WSAECONNABORTED && !ptr.get()->enable_connection_aborted_) { // Reset OVERLAPPED structure. ptr.get()->Internal = 0; ptr.get()->InternalHigh = 0; ptr.get()->Offset = 0; ptr.get()->OffsetHigh = 0; ptr.get()->hEvent = 0; // Create a new socket for the next connection, since the AcceptEx call // fails with WSAEINVAL if we try to reuse the same socket. boost::system::error_code ec; ptr.get()->new_socket_.reset(); ptr.get()->new_socket_.reset(socket_ops::socket( ptr.get()->protocol_.family(), ptr.get()->protocol_.type(), ptr.get()->protocol_.protocol(), ec)); if (ptr.get()->new_socket() != invalid_socket) { // Accept a connection. DWORD bytes_read = 0; BOOL result = ::AcceptEx(ptr.get()->socket_, ptr.get()->new_socket(), ptr.get()->output_buffer(), 0, ptr.get()->address_length(), ptr.get()->address_length(), &bytes_read, ptr.get()); last_error = ::WSAGetLastError(); // Check if the operation completed immediately. if (!result && last_error != WSA_IO_PENDING) { if (last_error == ERROR_NETNAME_DELETED || last_error == WSAECONNABORTED) { // Post this handler so that operation will be restarted again. ptr.get()->io_service_.post_completion(ptr.get(), last_error, 0); ptr.release(); return; } else { // Operation already complete. Continue with rest of this handler. } } else { // Asynchronous operation has been successfully restarted. ptr.release(); return; } } } // Get the address of the peer. endpoint_type peer_endpoint; if (last_error == 0) { LPSOCKADDR local_addr = 0; int local_addr_length = 0; LPSOCKADDR remote_addr = 0; int remote_addr_length = 0; GetAcceptExSockaddrs(handler_op->output_buffer(), 0, handler_op->address_length(), handler_op->address_length(), &local_addr, &local_addr_length, &remote_addr, &remote_addr_length); if (static_cast<std::size_t>(remote_addr_length) > peer_endpoint.capacity()) { last_error = WSAEINVAL; } else { using namespace std; // For memcpy. memcpy(peer_endpoint.data(), remote_addr, remote_addr_length); peer_endpoint.resize(static_cast<std::size_t>(remote_addr_length)); } } // Need to set the SO_UPDATE_ACCEPT_CONTEXT option so that getsockname // and getpeername will work on the accepted socket. if (last_error == 0) { SOCKET update_ctx_param = handler_op->socket_; boost::system::error_code ec; if (socket_ops::setsockopt(handler_op->new_socket_.get(), SOL_SOCKET, SO_UPDATE_ACCEPT_CONTEXT, &update_ctx_param, sizeof(SOCKET), ec) != 0) { last_error = ec.value(); } } // If the socket was successfully accepted, transfer ownership of the // socket to the peer object. if (last_error == 0) { boost::system::error_code ec; handler_op->peer_.assign(handler_op->protocol_, native_type(handler_op->new_socket_.get(), peer_endpoint), ec); if (ec) last_error = ec.value(); else handler_op->new_socket_.release(); } // Pass endpoint back to caller. if (handler_op->peer_endpoint_) *handler_op->peer_endpoint_ = peer_endpoint; // Make a copy of the handler so that the memory can be deallocated before // the upcall is made. Handler handler(handler_op->handler_); // Free the memory associated with the handler. ptr.reset(); // Call the handler. boost::system::error_code ec(last_error, boost::asio::error::get_system_category()); boost_asio_handler_invoke_helpers::invoke( detail::bind_handler(handler, ec), &handler); } static void destroy_impl(operation* op) { // Take ownership of the operation object. typedef accept_operation<Socket, Handler> op_type; op_type* handler_op(static_cast<op_type*>(op)); typedef handler_alloc_traits<Handler, op_type> alloc_traits; handler_ptr<alloc_traits> ptr(handler_op->handler_, handler_op); } win_iocp_io_service& io_service_; socket_type socket_; socket_holder new_socket_; Socket& peer_; protocol_type protocol_; endpoint_type* peer_endpoint_; boost::asio::io_service::work work_; unsigned char output_buffer_[(sizeof(sockaddr_storage_type) + 16) * 2]; bool enable_connection_aborted_; Handler handler_; }; // Start an asynchronous accept. The peer and peer_endpoint objects // must be valid until the accept's handler is invoked. template <typename Socket, typename Handler> void async_accept(implementation_type& impl, Socket& peer, endpoint_type* peer_endpoint, Handler handler) { // Check whether acceptor has been initialised. if (!is_open(impl)) { this->get_io_service().post(bind_handler(handler, boost::asio::error::bad_descriptor)); return; } // Check that peer socket has not already been opened. if (peer.is_open()) { this->get_io_service().post(bind_handler(handler, boost::asio::error::already_open)); return; } #if defined(BOOST_ASIO_ENABLE_CANCELIO) // Update the ID of the thread from which cancellation is safe. if (impl.safe_cancellation_thread_id_ == 0) impl.safe_cancellation_thread_id_ = ::GetCurrentThreadId(); else if (impl.safe_cancellation_thread_id_ != ::GetCurrentThreadId()) impl.safe_cancellation_thread_id_ = ~DWORD(0); #endif // defined(BOOST_ASIO_ENABLE_CANCELIO) // Create a new socket for the connection. boost::system::error_code ec; socket_holder sock(socket_ops::socket(impl.protocol_.family(), impl.protocol_.type(), impl.protocol_.protocol(), ec)); if (sock.get() == invalid_socket) { this->get_io_service().post(bind_handler(handler, ec)); return; } // Allocate and construct an operation to wrap the handler. typedef accept_operation<Socket, Handler> value_type; typedef handler_alloc_traits<Handler, value_type> alloc_traits; raw_handler_ptr<alloc_traits> raw_ptr(handler); socket_type new_socket = sock.get(); bool enable_connection_aborted = (impl.flags_ & implementation_type::enable_connection_aborted); handler_ptr<alloc_traits> ptr(raw_ptr, iocp_service_, impl.socket_, new_socket, peer, impl.protocol_, peer_endpoint, enable_connection_aborted, handler); sock.release(); // Accept a connection. DWORD bytes_read = 0; BOOL result = ::AcceptEx(impl.socket_, ptr.get()->new_socket(), ptr.get()->output_buffer(), 0, ptr.get()->address_length(), ptr.get()->address_length(), &bytes_read, ptr.get()); DWORD last_error = ::WSAGetLastError(); // Check if the operation completed immediately. if (!result && last_error != WSA_IO_PENDING) { if (!enable_connection_aborted && (last_error == ERROR_NETNAME_DELETED || last_error == WSAECONNABORTED)) { // Post handler so that operation will be restarted again. We do not // perform the AcceptEx again here to avoid the possibility of starving // other handlers. iocp_service_.post_completion(ptr.get(), last_error, 0); ptr.release(); } else { boost::asio::io_service::work work(this->get_io_service()); ptr.reset(); boost::system::error_code ec(last_error, boost::asio::error::get_system_category()); iocp_service_.post(bind_handler(handler, ec)); } } else { ptr.release(); } } // Connect the socket to the specified endpoint. boost::system::error_code connect(implementation_type& impl, const endpoint_type& peer_endpoint, boost::system::error_code& ec) { if (!is_open(impl)) { ec = boost::asio::error::bad_descriptor; return ec; } // Perform the connect operation. socket_ops::connect(impl.socket_, peer_endpoint.data(), peer_endpoint.size(), ec); return ec; } template <typename Handler> class connect_handler { public: connect_handler(socket_type socket, bool user_set_non_blocking, boost::shared_ptr<bool> completed, boost::asio::io_service& io_service, reactor_type& reactor, Handler handler) : socket_(socket), user_set_non_blocking_(user_set_non_blocking), completed_(completed), io_service_(io_service), reactor_(reactor), work_(io_service), handler_(handler) { } bool operator()(const boost::system::error_code& result) { // Check whether a handler has already been called for the connection. // If it has, then we don't want to do anything in this handler. if (*completed_) return true; // Cancel the other reactor operation for the connection. *completed_ = true; reactor_.enqueue_cancel_ops_unlocked(socket_); // Check whether the operation was successful. if (result) { io_service_.post(bind_handler(handler_, result)); return true; } // Get the error code from the connect operation. int connect_error = 0; size_t connect_error_len = sizeof(connect_error); boost::system::error_code ec; if (socket_ops::getsockopt(socket_, SOL_SOCKET, SO_ERROR, &connect_error, &connect_error_len, ec) == socket_error_retval) { io_service_.post(bind_handler(handler_, ec)); return true; } // If connection failed then post the handler with the error code. if (connect_error) { ec = boost::system::error_code(connect_error, boost::asio::error::get_system_category()); io_service_.post(bind_handler(handler_, ec)); return true; } // Revert socket to blocking mode unless the user requested otherwise. if (!user_set_non_blocking_) { ioctl_arg_type non_blocking = 0; if (socket_ops::ioctl(socket_, FIONBIO, &non_blocking, ec)) { io_service_.post(bind_handler(handler_, ec)); return true; } } // Post the result of the successful connection operation. ec = boost::system::error_code(); io_service_.post(bind_handler(handler_, ec)); return true; } private: socket_type socket_; bool user_set_non_blocking_; boost::shared_ptr<bool> completed_; boost::asio::io_service& io_service_; reactor_type& reactor_; boost::asio::io_service::work work_; Handler handler_; }; // Start an asynchronous connect. template <typename Handler> void async_connect(implementation_type& impl, const endpoint_type& peer_endpoint, Handler handler) { if (!is_open(impl)) { this->get_io_service().post(bind_handler(handler, boost::asio::error::bad_descriptor)); return; } #if defined(BOOST_ASIO_ENABLE_CANCELIO) // Update the ID of the thread from which cancellation is safe. if (impl.safe_cancellation_thread_id_ == 0) impl.safe_cancellation_thread_id_ = ::GetCurrentThreadId(); else if (impl.safe_cancellation_thread_id_ != ::GetCurrentThreadId()) impl.safe_cancellation_thread_id_ = ~DWORD(0); #endif // defined(BOOST_ASIO_ENABLE_CANCELIO) // Check if the reactor was already obtained from the io_service. reactor_type* reactor = static_cast<reactor_type*>( interlocked_compare_exchange_pointer( reinterpret_cast<void**>(&reactor_), 0, 0)); if (!reactor) { reactor = &(boost::asio::use_service<reactor_type>( this->get_io_service())); interlocked_exchange_pointer( reinterpret_cast<void**>(&reactor_), reactor); } // Mark the socket as non-blocking so that the connection will take place // asynchronously. ioctl_arg_type non_blocking = 1; boost::system::error_code ec; if (socket_ops::ioctl(impl.socket_, FIONBIO, &non_blocking, ec)) { this->get_io_service().post(bind_handler(handler, ec)); return; } // Start the connect operation. if (socket_ops::connect(impl.socket_, peer_endpoint.data(), peer_endpoint.size(), ec) == 0) { // Revert socket to blocking mode unless the user requested otherwise. if (!(impl.flags_ & implementation_type::user_set_non_blocking)) { non_blocking = 0; socket_ops::ioctl(impl.socket_, FIONBIO, &non_blocking, ec); } // The connect operation has finished successfully so we need to post the // handler immediately. this->get_io_service().post(bind_handler(handler, ec)); } else if (ec == boost::asio::error::in_progress || ec == boost::asio::error::would_block) { // The connection is happening in the background, and we need to wait // until the socket becomes writeable. boost::shared_ptr<bool> completed(new bool(false)); reactor->start_write_and_except_ops(impl.socket_, connect_handler<Handler>( impl.socket_, (impl.flags_ & implementation_type::user_set_non_blocking) != 0, completed, this->get_io_service(), *reactor, handler)); } else { // Revert socket to blocking mode unless the user requested otherwise. if (!(impl.flags_ & implementation_type::user_set_non_blocking)) { non_blocking = 0; boost::system::error_code ignored_ec; socket_ops::ioctl(impl.socket_, FIONBIO, &non_blocking, ignored_ec); } // The connect operation has failed, so post the handler immediately. this->get_io_service().post(bind_handler(handler, ec)); } } private: // Helper function to close a socket when the associated object is being // destroyed. void close_for_destruction(implementation_type& impl) { if (is_open(impl)) { // Check if the reactor was created, in which case we need to close the // socket on the reactor as well to cancel any operations that might be // running there. reactor_type* reactor = static_cast<reactor_type*>( interlocked_compare_exchange_pointer( reinterpret_cast<void**>(&reactor_), 0, 0)); if (reactor) reactor->close_descriptor(impl.socket_); // The socket destructor must not block. If the user has changed the // linger option to block in the foreground, we will change it back to the // default so that the closure is performed in the background. if (impl.flags_ & implementation_type::close_might_block) { ::linger opt; opt.l_onoff = 0; opt.l_linger = 0; boost::system::error_code ignored_ec; socket_ops::setsockopt(impl.socket_, SOL_SOCKET, SO_LINGER, &opt, sizeof(opt), ignored_ec); } boost::system::error_code ignored_ec; socket_ops::close(impl.socket_, ignored_ec); impl.socket_ = invalid_socket; impl.flags_ = 0; impl.cancel_token_.reset(); #if defined(BOOST_ASIO_ENABLE_CANCELIO) impl.safe_cancellation_thread_id_ = 0; #endif // defined(BOOST_ASIO_ENABLE_CANCELIO) } } // Helper function to emulate InterlockedCompareExchangePointer functionality // for: // - very old Platform SDKs; and // - platform SDKs where MSVC's /Wp64 option causes spurious warnings. void* interlocked_compare_exchange_pointer(void** dest, void* exch, void* cmp) { #if defined(_M_IX86) return reinterpret_cast<void*>(InterlockedCompareExchange( reinterpret_cast<PLONG>(dest), reinterpret_cast<LONG>(exch), reinterpret_cast<LONG>(cmp))); #else return InterlockedCompareExchangePointer(dest, exch, cmp); #endif } // Helper function to emulate InterlockedExchangePointer functionality for: // - very old Platform SDKs; and // - platform SDKs where MSVC's /Wp64 option causes spurious warnings. void* interlocked_exchange_pointer(void** dest, void* val) { #if defined(_M_IX86) return reinterpret_cast<void*>(InterlockedExchange( reinterpret_cast<PLONG>(dest), reinterpret_cast<LONG>(val))); #else return InterlockedExchangePointer(dest, val); #endif } // The IOCP service used for running asynchronous operations and dispatching // handlers. win_iocp_io_service& iocp_service_; // The reactor used for performing connect operations. This object is created // only if needed. reactor_type* reactor_; // Mutex to protect access to the linked list of implementations. boost::asio::detail::mutex mutex_; // The head of a linked list of all implementations. implementation_type* impl_list_; }; } // namespace detail } // namespace asio } // namespace boost #endif // defined(BOOST_ASIO_HAS_IOCP) #include <boost/asio/detail/pop_options.hpp> #endif // BOOST_ASIO_DETAIL_WIN_IOCP_SOCKET_SERVICE_HPP
win_iocp_socket_service.hpp
Page URL
File URL
Prev
69/76
Next
Download
( 69 KB )
Note: The DriveHQ service banners will NOT be displayed if the file owner is a paid member.
Comments
Total ratings:
0
Average rating:
Not Rated
Would you like to comment?
Join DriveHQ
for a free account, or
Logon
if you are already a member.
