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552 lines
19 KiB
C++
552 lines
19 KiB
C++
// lock-free queue from
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// Michael, M. M. and Scott, M. L.,
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// "simple, fast and practical non-blocking and blocking concurrent queue algorithms"
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//
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// Copyright (C) 2008-2013 Tim Blechmann
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//
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// Distributed under the Boost Software License, Version 1.0. (See
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// accompanying file LICENSE_1_0.txt or copy at
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// http://www.boost.org/LICENSE_1_0.txt)
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#ifndef BOOST_LOCKFREE_FIFO_HPP_INCLUDED
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#define BOOST_LOCKFREE_FIFO_HPP_INCLUDED
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#include <boost/assert.hpp>
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#include <boost/static_assert.hpp>
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#include <boost/type_traits/has_trivial_assign.hpp>
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#include <boost/type_traits/has_trivial_destructor.hpp>
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#include <boost/config.hpp> // for BOOST_LIKELY & BOOST_ALIGNMENT
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#include <boost/lockfree/detail/atomic.hpp>
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#include <boost/lockfree/detail/copy_payload.hpp>
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#include <boost/lockfree/detail/freelist.hpp>
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#include <boost/lockfree/detail/parameter.hpp>
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#include <boost/lockfree/detail/tagged_ptr.hpp>
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#include <boost/lockfree/lockfree_forward.hpp>
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#ifdef BOOST_HAS_PRAGMA_ONCE
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#pragma once
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#endif
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#if defined(_MSC_VER)
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#pragma warning(push)
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#pragma warning(disable: 4324) // structure was padded due to __declspec(align())
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#endif
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namespace boost {
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namespace lockfree {
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namespace detail {
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typedef parameter::parameters<boost::parameter::optional<tag::allocator>,
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boost::parameter::optional<tag::capacity>
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> queue_signature;
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} /* namespace detail */
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/** The queue class provides a multi-writer/multi-reader queue, pushing and popping is lock-free,
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* construction/destruction has to be synchronized. It uses a freelist for memory management,
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* freed nodes are pushed to the freelist and not returned to the OS before the queue is destroyed.
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*
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* \b Policies:
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* - \ref boost::lockfree::fixed_sized, defaults to \c boost::lockfree::fixed_sized<false> \n
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* Can be used to completely disable dynamic memory allocations during push in order to ensure lockfree behavior. \n
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* If the data structure is configured as fixed-sized, the internal nodes are stored inside an array and they are addressed
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* by array indexing. This limits the possible size of the queue to the number of elements that can be addressed by the index
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* type (usually 2**16-2), but on platforms that lack double-width compare-and-exchange instructions, this is the best way
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* to achieve lock-freedom.
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*
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* - \ref boost::lockfree::capacity, optional \n
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* If this template argument is passed to the options, the size of the queue is set at compile-time.\n
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* This option implies \c fixed_sized<true>
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*
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* - \ref boost::lockfree::allocator, defaults to \c boost::lockfree::allocator<std::allocator<void>> \n
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* Specifies the allocator that is used for the internal freelist
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*
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* \b Requirements:
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* - T must have a copy constructor
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* - T must have a trivial assignment operator
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* - T must have a trivial destructor
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*
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* */
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#ifdef BOOST_NO_CXX11_VARIADIC_TEMPLATES
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template <typename T, class A0, class A1, class A2>
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#else
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template <typename T, typename ...Options>
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#endif
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class queue
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{
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private:
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#ifndef BOOST_DOXYGEN_INVOKED
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#ifdef BOOST_HAS_TRIVIAL_DESTRUCTOR
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BOOST_STATIC_ASSERT((boost::has_trivial_destructor<T>::value));
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#endif
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#ifdef BOOST_HAS_TRIVIAL_ASSIGN
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BOOST_STATIC_ASSERT((boost::has_trivial_assign<T>::value));
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#endif
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#ifdef BOOST_NO_CXX11_VARIADIC_TEMPLATES
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typedef typename detail::queue_signature::bind<A0, A1, A2>::type bound_args;
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#else
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typedef typename detail::queue_signature::bind<Options...>::type bound_args;
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#endif
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static const bool has_capacity = detail::extract_capacity<bound_args>::has_capacity;
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static const size_t capacity = detail::extract_capacity<bound_args>::capacity + 1; // the queue uses one dummy node
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static const bool fixed_sized = detail::extract_fixed_sized<bound_args>::value;
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static const bool node_based = !(has_capacity || fixed_sized);
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static const bool compile_time_sized = has_capacity;
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struct BOOST_ALIGNMENT(BOOST_LOCKFREE_CACHELINE_BYTES) node
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{
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typedef typename detail::select_tagged_handle<node, node_based>::tagged_handle_type tagged_node_handle;
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typedef typename detail::select_tagged_handle<node, node_based>::handle_type handle_type;
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node(T const & v, handle_type null_handle):
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data(v)//, next(tagged_node_handle(0, 0))
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{
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/* increment tag to avoid ABA problem */
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tagged_node_handle old_next = next.load(memory_order_relaxed);
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tagged_node_handle new_next (null_handle, old_next.get_next_tag());
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next.store(new_next, memory_order_release);
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}
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node (handle_type null_handle):
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next(tagged_node_handle(null_handle, 0))
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{}
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node(void)
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{}
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atomic<tagged_node_handle> next;
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T data;
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};
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typedef typename detail::extract_allocator<bound_args, node>::type node_allocator;
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typedef typename detail::select_freelist<node, node_allocator, compile_time_sized, fixed_sized, capacity>::type pool_t;
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typedef typename pool_t::tagged_node_handle tagged_node_handle;
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typedef typename detail::select_tagged_handle<node, node_based>::handle_type handle_type;
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void initialize(void)
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{
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node * n = pool.template construct<true, false>(pool.null_handle());
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tagged_node_handle dummy_node(pool.get_handle(n), 0);
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head_.store(dummy_node, memory_order_relaxed);
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tail_.store(dummy_node, memory_order_release);
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}
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struct implementation_defined
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{
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typedef node_allocator allocator;
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typedef std::size_t size_type;
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};
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#endif
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BOOST_DELETED_FUNCTION(queue(queue const&))
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BOOST_DELETED_FUNCTION(queue& operator= (queue const&))
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public:
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typedef T value_type;
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typedef typename implementation_defined::allocator allocator;
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typedef typename implementation_defined::size_type size_type;
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/**
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* \return true, if implementation is lock-free.
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*
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* \warning It only checks, if the queue head and tail nodes and the freelist can be modified in a lock-free manner.
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* On most platforms, the whole implementation is lock-free, if this is true. Using c++0x-style atomics, there is
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* no possibility to provide a completely accurate implementation, because one would need to test every internal
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* node, which is impossible if further nodes will be allocated from the operating system.
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* */
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bool is_lock_free (void) const
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{
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return head_.is_lock_free() && tail_.is_lock_free() && pool.is_lock_free();
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}
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//! Construct queue
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// @{
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queue(void):
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head_(tagged_node_handle(0, 0)),
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tail_(tagged_node_handle(0, 0)),
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pool(node_allocator(), capacity)
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{
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BOOST_ASSERT(has_capacity);
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initialize();
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}
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template <typename U>
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explicit queue(typename node_allocator::template rebind<U>::other const & alloc):
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head_(tagged_node_handle(0, 0)),
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tail_(tagged_node_handle(0, 0)),
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pool(alloc, capacity)
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{
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BOOST_STATIC_ASSERT(has_capacity);
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initialize();
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}
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explicit queue(allocator const & alloc):
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head_(tagged_node_handle(0, 0)),
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tail_(tagged_node_handle(0, 0)),
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pool(alloc, capacity)
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{
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BOOST_ASSERT(has_capacity);
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initialize();
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}
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// @}
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//! Construct queue, allocate n nodes for the freelist.
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// @{
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explicit queue(size_type n):
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head_(tagged_node_handle(0, 0)),
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tail_(tagged_node_handle(0, 0)),
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pool(node_allocator(), n + 1)
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{
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BOOST_ASSERT(!has_capacity);
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initialize();
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}
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template <typename U>
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queue(size_type n, typename node_allocator::template rebind<U>::other const & alloc):
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head_(tagged_node_handle(0, 0)),
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tail_(tagged_node_handle(0, 0)),
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pool(alloc, n + 1)
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{
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BOOST_STATIC_ASSERT(!has_capacity);
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initialize();
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}
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// @}
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/** \copydoc boost::lockfree::stack::reserve
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* */
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void reserve(size_type n)
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{
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pool.template reserve<true>(n);
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}
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/** \copydoc boost::lockfree::stack::reserve_unsafe
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* */
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void reserve_unsafe(size_type n)
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{
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pool.template reserve<false>(n);
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}
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/** Destroys queue, free all nodes from freelist.
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* */
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~queue(void)
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{
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T dummy;
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while(unsynchronized_pop(dummy))
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{}
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pool.template destruct<false>(head_.load(memory_order_relaxed));
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}
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/** Check if the queue is empty
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*
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* \return true, if the queue is empty, false otherwise
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* \note The result is only accurate, if no other thread modifies the queue. Therefore it is rarely practical to use this
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* value in program logic.
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* */
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bool empty(void) const
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{
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return pool.get_handle(head_.load()) == pool.get_handle(tail_.load());
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}
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/** Pushes object t to the queue.
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*
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* \post object will be pushed to the queue, if internal node can be allocated
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* \returns true, if the push operation is successful.
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*
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* \note Thread-safe. If internal memory pool is exhausted and the memory pool is not fixed-sized, a new node will be allocated
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* from the OS. This may not be lock-free.
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* */
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bool push(T const & t)
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{
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return do_push<false>(t);
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}
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/** Pushes object t to the queue.
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*
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* \post object will be pushed to the queue, if internal node can be allocated
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* \returns true, if the push operation is successful.
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*
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* \note Thread-safe and non-blocking. If internal memory pool is exhausted, operation will fail
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* \throws if memory allocator throws
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* */
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bool bounded_push(T const & t)
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{
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return do_push<true>(t);
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}
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private:
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#ifndef BOOST_DOXYGEN_INVOKED
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template <bool Bounded>
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bool do_push(T const & t)
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{
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node * n = pool.template construct<true, Bounded>(t, pool.null_handle());
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handle_type node_handle = pool.get_handle(n);
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if (n == NULL)
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return false;
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for (;;) {
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tagged_node_handle tail = tail_.load(memory_order_acquire);
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node * tail_node = pool.get_pointer(tail);
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tagged_node_handle next = tail_node->next.load(memory_order_acquire);
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node * next_ptr = pool.get_pointer(next);
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tagged_node_handle tail2 = tail_.load(memory_order_acquire);
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if (BOOST_LIKELY(tail == tail2)) {
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if (next_ptr == 0) {
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tagged_node_handle new_tail_next(node_handle, next.get_next_tag());
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if ( tail_node->next.compare_exchange_weak(next, new_tail_next) ) {
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tagged_node_handle new_tail(node_handle, tail.get_next_tag());
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tail_.compare_exchange_strong(tail, new_tail);
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return true;
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}
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}
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else {
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tagged_node_handle new_tail(pool.get_handle(next_ptr), tail.get_next_tag());
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tail_.compare_exchange_strong(tail, new_tail);
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}
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}
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}
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}
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#endif
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public:
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/** Pushes object t to the queue.
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*
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* \post object will be pushed to the queue, if internal node can be allocated
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* \returns true, if the push operation is successful.
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*
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* \note Not Thread-safe. If internal memory pool is exhausted and the memory pool is not fixed-sized, a new node will be allocated
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* from the OS. This may not be lock-free.
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* \throws if memory allocator throws
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* */
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bool unsynchronized_push(T const & t)
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{
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node * n = pool.template construct<false, false>(t, pool.null_handle());
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if (n == NULL)
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return false;
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for (;;) {
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tagged_node_handle tail = tail_.load(memory_order_relaxed);
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tagged_node_handle next = tail->next.load(memory_order_relaxed);
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node * next_ptr = next.get_ptr();
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if (next_ptr == 0) {
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tail->next.store(tagged_node_handle(n, next.get_next_tag()), memory_order_relaxed);
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tail_.store(tagged_node_handle(n, tail.get_next_tag()), memory_order_relaxed);
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return true;
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}
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else
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tail_.store(tagged_node_handle(next_ptr, tail.get_next_tag()), memory_order_relaxed);
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}
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}
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/** Pops object from queue.
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*
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* \post if pop operation is successful, object will be copied to ret.
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* \returns true, if the pop operation is successful, false if queue was empty.
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*
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* \note Thread-safe and non-blocking
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* */
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bool pop (T & ret)
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{
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return pop<T>(ret);
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}
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/** Pops object from queue.
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*
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* \pre type U must be constructible by T and copyable, or T must be convertible to U
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* \post if pop operation is successful, object will be copied to ret.
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* \returns true, if the pop operation is successful, false if queue was empty.
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*
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* \note Thread-safe and non-blocking
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* */
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template <typename U>
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bool pop (U & ret)
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{
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for (;;) {
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tagged_node_handle head = head_.load(memory_order_acquire);
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node * head_ptr = pool.get_pointer(head);
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tagged_node_handle tail = tail_.load(memory_order_acquire);
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tagged_node_handle next = head_ptr->next.load(memory_order_acquire);
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node * next_ptr = pool.get_pointer(next);
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tagged_node_handle head2 = head_.load(memory_order_acquire);
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if (BOOST_LIKELY(head == head2)) {
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if (pool.get_handle(head) == pool.get_handle(tail)) {
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if (next_ptr == 0)
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return false;
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tagged_node_handle new_tail(pool.get_handle(next), tail.get_next_tag());
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tail_.compare_exchange_strong(tail, new_tail);
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} else {
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if (next_ptr == 0)
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/* this check is not part of the original algorithm as published by michael and scott
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*
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* however we reuse the tagged_ptr part for the freelist and clear the next part during node
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* allocation. we can observe a null-pointer here.
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* */
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continue;
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detail::copy_payload(next_ptr->data, ret);
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tagged_node_handle new_head(pool.get_handle(next), head.get_next_tag());
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if (head_.compare_exchange_weak(head, new_head)) {
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pool.template destruct<true>(head);
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return true;
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}
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}
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}
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}
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}
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/** Pops object from queue.
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*
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* \post if pop operation is successful, object will be copied to ret.
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* \returns true, if the pop operation is successful, false if queue was empty.
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*
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* \note Not thread-safe, but non-blocking
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*
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* */
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bool unsynchronized_pop (T & ret)
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{
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return unsynchronized_pop<T>(ret);
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}
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/** Pops object from queue.
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*
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* \pre type U must be constructible by T and copyable, or T must be convertible to U
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* \post if pop operation is successful, object will be copied to ret.
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* \returns true, if the pop operation is successful, false if queue was empty.
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*
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* \note Not thread-safe, but non-blocking
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*
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* */
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template <typename U>
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bool unsynchronized_pop (U & ret)
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{
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for (;;) {
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tagged_node_handle head = head_.load(memory_order_relaxed);
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node * head_ptr = pool.get_pointer(head);
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tagged_node_handle tail = tail_.load(memory_order_relaxed);
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tagged_node_handle next = head_ptr->next.load(memory_order_relaxed);
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node * next_ptr = pool.get_pointer(next);
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if (pool.get_handle(head) == pool.get_handle(tail)) {
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if (next_ptr == 0)
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return false;
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tagged_node_handle new_tail(pool.get_handle(next), tail.get_next_tag());
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tail_.store(new_tail);
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} else {
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if (next_ptr == 0)
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/* this check is not part of the original algorithm as published by michael and scott
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*
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* however we reuse the tagged_ptr part for the freelist and clear the next part during node
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* allocation. we can observe a null-pointer here.
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* */
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continue;
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detail::copy_payload(next_ptr->data, ret);
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tagged_node_handle new_head(pool.get_handle(next), head.get_next_tag());
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head_.store(new_head);
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pool.template destruct<false>(head);
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return true;
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}
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}
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}
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/** consumes one element via a functor
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*
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* pops one element from the queue and applies the functor on this object
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*
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* \returns true, if one element was consumed
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*
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* \note Thread-safe and non-blocking, if functor is thread-safe and non-blocking
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* */
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template <typename Functor>
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bool consume_one(Functor & f)
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{
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T element;
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bool success = pop(element);
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if (success)
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f(element);
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return success;
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}
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/// \copydoc boost::lockfree::queue::consume_one(Functor & rhs)
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template <typename Functor>
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bool consume_one(Functor const & f)
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{
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T element;
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bool success = pop(element);
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if (success)
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f(element);
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return success;
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}
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/** consumes all elements via a functor
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*
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* sequentially pops all elements from the queue and applies the functor on each object
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*
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* \returns number of elements that are consumed
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*
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* \note Thread-safe and non-blocking, if functor is thread-safe and non-blocking
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* */
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|
template <typename Functor>
|
|
size_t consume_all(Functor & f)
|
|
{
|
|
size_t element_count = 0;
|
|
while (consume_one(f))
|
|
element_count += 1;
|
|
|
|
return element_count;
|
|
}
|
|
|
|
/// \copydoc boost::lockfree::queue::consume_all(Functor & rhs)
|
|
template <typename Functor>
|
|
size_t consume_all(Functor const & f)
|
|
{
|
|
size_t element_count = 0;
|
|
while (consume_one(f))
|
|
element_count += 1;
|
|
|
|
return element_count;
|
|
}
|
|
|
|
private:
|
|
#ifndef BOOST_DOXYGEN_INVOKED
|
|
atomic<tagged_node_handle> head_;
|
|
static const int padding_size = BOOST_LOCKFREE_CACHELINE_BYTES - sizeof(tagged_node_handle);
|
|
char padding1[padding_size];
|
|
atomic<tagged_node_handle> tail_;
|
|
char padding2[padding_size];
|
|
|
|
pool_t pool;
|
|
#endif
|
|
};
|
|
|
|
} /* namespace lockfree */
|
|
} /* namespace boost */
|
|
|
|
#if defined(_MSC_VER)
|
|
#pragma warning(pop)
|
|
#endif
|
|
|
|
#endif /* BOOST_LOCKFREE_FIFO_HPP_INCLUDED */
|