/* Copyright (c) 2007-2016 Contributors as noted in the AUTHORS file This file is part of libzmq, the ZeroMQ core engine in C++. libzmq is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License (LGPL) as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. As a special exception, the Contributors give you permission to link this library with independent modules to produce an executable, regardless of the license terms of these independent modules, and to copy and distribute the resulting executable under terms of your choice, provided that you also meet, for each linked independent module, the terms and conditions of the license of that module. An independent module is a module which is not derived from or based on this library. If you modify this library, you must extend this exception to your version of the library. libzmq 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this program. If not, see . */ #ifndef __ZMQ_YPIPE_HPP_INCLUDED__ #define __ZMQ_YPIPE_HPP_INCLUDED__ #include "atomic_ptr.hpp" #include "yqueue.hpp" #include "ypipe_base.hpp" namespace zmq { // Lock-free queue implementation. // Only a single thread can read from the pipe at any specific moment. // Only a single thread can write to the pipe at any specific moment. // T is the type of the object in the queue. // N is granularity of the pipe, i.e. how many items are needed to // perform next memory allocation. template class ypipe_t ZMQ_FINAL : public ypipe_base_t { public: // Initialises the pipe. ypipe_t () { // Insert terminator element into the queue. _queue.push (); // Let all the pointers to point to the terminator. // (unless pipe is dead, in which case c is set to NULL). _r = _w = _f = &_queue.back (); _c.set (&_queue.back ()); } // Following function (write) deliberately copies uninitialised data // when used with zmq_msg. Initialising the VSM body for // non-VSM messages won't be good for performance. #ifdef ZMQ_HAVE_OPENVMS #pragma message save #pragma message disable(UNINIT) #endif // Write an item to the pipe. Don't flush it yet. If incomplete is // set to true the item is assumed to be continued by items // subsequently written to the pipe. Incomplete items are never // flushed down the stream. void write (const T &value_, bool incomplete_) { // Place the value to the queue, add new terminator element. _queue.back () = value_; _queue.push (); // Move the "flush up to here" poiter. if (!incomplete_) _f = &_queue.back (); } #ifdef ZMQ_HAVE_OPENVMS #pragma message restore #endif // Pop an incomplete item from the pipe. Returns true if such // item exists, false otherwise. bool unwrite (T *value_) { if (_f == &_queue.back ()) return false; _queue.unpush (); *value_ = _queue.back (); return true; } // Flush all the completed items into the pipe. Returns false if // the reader thread is sleeping. In that case, caller is obliged to // wake the reader up before using the pipe again. bool flush () { // If there are no un-flushed items, do nothing. if (_w == _f) return true; // Try to set 'c' to 'f'. if (_c.cas (_w, _f) != _w) { // Compare-and-swap was unseccessful because 'c' is NULL. // This means that the reader is asleep. Therefore we don't // care about thread-safeness and update c in non-atomic // manner. We'll return false to let the caller know // that reader is sleeping. _c.set (_f); _w = _f; return false; } // Reader is alive. Nothing special to do now. Just move // the 'first un-flushed item' pointer to 'f'. _w = _f; return true; } // Check whether item is available for reading. bool check_read () { // Was the value prefetched already? If so, return. if (&_queue.front () != _r && _r) return true; // There's no prefetched value, so let us prefetch more values. // Prefetching is to simply retrieve the // pointer from c in atomic fashion. If there are no // items to prefetch, set c to NULL (using compare-and-swap). _r = _c.cas (&_queue.front (), NULL); // If there are no elements prefetched, exit. // During pipe's lifetime r should never be NULL, however, // it can happen during pipe shutdown when items // are being deallocated. if (&_queue.front () == _r || !_r) return false; // There was at least one value prefetched. return true; } // Reads an item from the pipe. Returns false if there is no value. // available. bool read (T *value_) { // Try to prefetch a value. if (!check_read ()) return false; // There was at least one value prefetched. // Return it to the caller. *value_ = _queue.front (); _queue.pop (); return true; } // Applies the function fn to the first elemenent in the pipe // and returns the value returned by the fn. // The pipe mustn't be empty or the function crashes. bool probe (bool (*fn_) (const T &)) { const bool rc = check_read (); zmq_assert (rc); return (*fn_) (_queue.front ()); } protected: // Allocation-efficient queue to store pipe items. // Front of the queue points to the first prefetched item, back of // the pipe points to last un-flushed item. Front is used only by // reader thread, while back is used only by writer thread. yqueue_t _queue; // Points to the first un-flushed item. This variable is used // exclusively by writer thread. T *_w; // Points to the first un-prefetched item. This variable is used // exclusively by reader thread. T *_r; // Points to the first item to be flushed in the future. T *_f; // The single point of contention between writer and reader thread. // Points past the last flushed item. If it is NULL, // reader is asleep. This pointer should be always accessed using // atomic operations. atomic_ptr_t _c; ZMQ_NON_COPYABLE_NOR_MOVABLE (ypipe_t) }; } #endif