boost/asio/detail/reactor_op_queue.hpp
// // reactor_op_queue.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_REACTOR_OP_QUEUE_HPP #define BOOST_ASIO_DETAIL_REACTOR_OP_QUEUE_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/push_options.hpp> #include <memory> #include <boost/asio/detail/pop_options.hpp> #include <boost/asio/error.hpp> #include <boost/asio/detail/handler_alloc_helpers.hpp> #include <boost/asio/detail/hash_map.hpp> #include <boost/asio/detail/noncopyable.hpp> namespace boost { namespace asio { namespace detail { template <typename Descriptor> class reactor_op_queue : private noncopyable { public: // Constructor. reactor_op_queue() : operations_(), cancelled_operations_(0), complete_operations_(0) { } // Add a new operation to the queue. Returns true if this is the only // operation for the given descriptor, in which case the reactor's event // demultiplexing function call may need to be interrupted and restarted. template <typename Operation> bool enqueue_operation(Descriptor descriptor, Operation operation) { // Allocate and construct an object to wrap the handler. typedef handler_alloc_traits<Operation, op<Operation> > alloc_traits; raw_handler_ptr<alloc_traits> raw_ptr(operation); handler_ptr<alloc_traits> ptr(raw_ptr, descriptor, operation); typedef typename operation_map::iterator iterator; typedef typename operation_map::value_type value_type; std::pair<iterator, bool> entry = operations_.insert(value_type(descriptor, ptr.get())); if (entry.second) { ptr.release(); return true; } op_base* current_op = entry.first->second; while (current_op->next_) current_op = current_op->next_; current_op->next_ = ptr.release(); return false; } // Cancel all operations associated with the descriptor. Any operations // pending for the descriptor will be notified that they have been cancelled // next time perform_cancellations is called. Returns true if any operations // were cancelled, in which case the reactor's event demultiplexing function // may need to be interrupted and restarted. bool cancel_operations(Descriptor descriptor) { typename operation_map::iterator i = operations_.find(descriptor); if (i != operations_.end()) { op_base* last_op = i->second; while (last_op->next_) last_op = last_op->next_; last_op->next_ = cancelled_operations_; cancelled_operations_ = i->second; operations_.erase(i); return true; } return false; } // Whether there are no operations in the queue. bool empty() const { return operations_.empty(); } // Determine whether there are any operations associated with the descriptor. bool has_operation(Descriptor descriptor) const { return operations_.find(descriptor) != operations_.end(); } // Perform the first operation corresponding to the descriptor. Returns true // if there are more operations queued for the descriptor. bool perform_operation(Descriptor descriptor, const boost::system::error_code& result) { typename operation_map::iterator i = operations_.find(descriptor); if (i != operations_.end()) { op_base* this_op = i->second; i->second = this_op->next_; this_op->next_ = complete_operations_; complete_operations_ = this_op; bool done = this_op->perform(result); if (done) { // Operation has finished. if (i->second) { return true; } else { operations_.erase(i); return false; } } else { // Operation wants to be called again. Leave it at the front of the // queue for this descriptor, and remove from the completed list. complete_operations_ = this_op->next_; this_op->next_ = i->second; i->second = this_op; return true; } } return false; } // Perform all operations corresponding to the descriptor. void perform_all_operations(Descriptor descriptor, const boost::system::error_code& result) { typename operation_map::iterator i = operations_.find(descriptor); if (i != operations_.end()) { while (i->second) { op_base* this_op = i->second; i->second = this_op->next_; this_op->next_ = complete_operations_; complete_operations_ = this_op; bool done = this_op->perform(result); if (!done) { // Operation has not finished yet, so leave at front of queue, and // remove from the completed list. complete_operations_ = this_op->next_; this_op->next_ = i->second; i->second = this_op; return; } } operations_.erase(i); } } // Fill a descriptor set with the descriptors corresponding to each active // operation. template <typename Descriptor_Set> void get_descriptors(Descriptor_Set& descriptors) { typename operation_map::iterator i = operations_.begin(); while (i != operations_.end()) { Descriptor descriptor = i->first; ++i; if (!descriptors.set(descriptor)) { boost::system::error_code ec(error::fd_set_failure); perform_all_operations(descriptor, ec); } } } // Perform the operations corresponding to the ready file descriptors // contained in the given descriptor set. template <typename Descriptor_Set> void perform_operations_for_descriptors(const Descriptor_Set& descriptors, const boost::system::error_code& result) { typename operation_map::iterator i = operations_.begin(); while (i != operations_.end()) { typename operation_map::iterator op_iter = i++; if (descriptors.is_set(op_iter->first)) { op_base* this_op = op_iter->second; op_iter->second = this_op->next_; this_op->next_ = complete_operations_; complete_operations_ = this_op; bool done = this_op->perform(result); if (done) { if (!op_iter->second) operations_.erase(op_iter); } else { // Operation has not finished yet, so leave at front of queue, and // remove from the completed list. complete_operations_ = this_op->next_; this_op->next_ = op_iter->second; op_iter->second = this_op; } } } } // Perform any pending cancels for operations. void perform_cancellations() { while (cancelled_operations_) { op_base* this_op = cancelled_operations_; cancelled_operations_ = this_op->next_; this_op->next_ = complete_operations_; complete_operations_ = this_op; this_op->perform(boost::asio::error::operation_aborted); } } // Complete all operations that are waiting to be completed. void complete_operations() { while (complete_operations_) { op_base* next_op = complete_operations_->next_; complete_operations_->next_ = 0; complete_operations_->complete(); complete_operations_ = next_op; } } // Destroy all operations owned by the queue. void destroy_operations() { while (cancelled_operations_) { op_base* next_op = cancelled_operations_->next_; cancelled_operations_->next_ = 0; cancelled_operations_->destroy(); cancelled_operations_ = next_op; } while (complete_operations_) { op_base* next_op = complete_operations_->next_; complete_operations_->next_ = 0; complete_operations_->destroy(); complete_operations_ = next_op; } typename operation_map::iterator i = operations_.begin(); while (i != operations_.end()) { typename operation_map::iterator op_iter = i++; op_base* curr_op = op_iter->second; operations_.erase(op_iter); while (curr_op) { op_base* next_op = curr_op->next_; curr_op->next_ = 0; curr_op->destroy(); curr_op = next_op; } } } private: // Base class for reactor operations. A function pointer is used instead of // virtual functions to avoid the associated overhead. class op_base { public: // Get the descriptor associated with the operation. Descriptor descriptor() const { return descriptor_; } // Perform the operation. bool perform(const boost::system::error_code& result) { result_ = result; return perform_func_(this, result_, bytes_transferred_); } // Destroy the operation and post the handler. void complete() { complete_func_(this, result_, bytes_transferred_); } // Destroy the operation. void destroy() { destroy_func_(this); } protected: typedef bool (*perform_func_type)(op_base*, boost::system::error_code&, std::size_t&); typedef void (*complete_func_type)(op_base*, const boost::system::error_code&, std::size_t); typedef void (*destroy_func_type)(op_base*); // Construct an operation for the given descriptor. op_base(perform_func_type perform_func, complete_func_type complete_func, destroy_func_type destroy_func, Descriptor descriptor) : perform_func_(perform_func), complete_func_(complete_func), destroy_func_(destroy_func), descriptor_(descriptor), result_(), bytes_transferred_(0), next_(0) { } // Prevent deletion through this type. ~op_base() { } private: friend class reactor_op_queue<Descriptor>; // The function to be called to perform the operation. perform_func_type perform_func_; // The function to be called to delete the operation and post the handler. complete_func_type complete_func_; // The function to be called to delete the operation. destroy_func_type destroy_func_; // The descriptor associated with the operation. Descriptor descriptor_; // The result of the operation. boost::system::error_code result_; // The number of bytes transferred in the operation. std::size_t bytes_transferred_; // The next operation for the same file descriptor. op_base* next_; }; // Adaptor class template for operations. template <typename Operation> class op : public op_base { public: // Constructor. op(Descriptor descriptor, Operation operation) : op_base(&op<Operation>::do_perform, &op<Operation>::do_complete, &op<Operation>::do_destroy, descriptor), operation_(operation) { } // Perform the operation. static bool do_perform(op_base* base, boost::system::error_code& result, std::size_t& bytes_transferred) { return static_cast<op<Operation>*>(base)->operation_.perform( result, bytes_transferred); } // Destroy the operation and post the handler. static void do_complete(op_base* base, const boost::system::error_code& result, std::size_t bytes_transferred) { // Take ownership of the operation object. typedef op<Operation> this_type; this_type* this_op(static_cast<this_type*>(base)); typedef handler_alloc_traits<Operation, this_type> alloc_traits; handler_ptr<alloc_traits> ptr(this_op->operation_, this_op); // Make a copy of the error_code and the operation so that the memory can // be deallocated before the upcall is made. boost::system::error_code ec(result); Operation operation(this_op->operation_); // Free the memory associated with the operation. ptr.reset(); // Make the upcall. operation.complete(ec, bytes_transferred); } // Destroy the operation. static void do_destroy(op_base* base) { // Take ownership of the operation object. typedef op<Operation> this_type; this_type* this_op(static_cast<this_type*>(base)); typedef handler_alloc_traits<Operation, this_type> alloc_traits; handler_ptr<alloc_traits> ptr(this_op->operation_, this_op); // A sub-object of the operation may be the true owner of the memory // associated with the operation. Consequently, a local copy of the // operation is required to ensure that any owning sub-object remains // valid until after we have deallocated the memory here. Operation operation(this_op->operation_); (void)operation; // Free the memory associated with the operation. ptr.reset(); } private: Operation operation_; }; // The type for a map of operations. typedef hash_map<Descriptor, op_base*> operation_map; // The operations that are currently executing asynchronously. operation_map operations_; // The list of operations that have been cancelled. op_base* cancelled_operations_; // The list of operations waiting to be completed. op_base* complete_operations_; }; } // namespace detail } // namespace asio } // namespace boost #include <boost/asio/detail/pop_options.hpp> #endif // BOOST_ASIO_DETAIL_REACTOR_OP_QUEUE_HPP