boost/thread/lock_algorithms.hpp
// 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) // (C) Copyright 2007 Anthony Williams // (C) Copyright 2011-2012 Vicente J. Botet Escriba #ifndef BOOST_THREAD_LOCK_ALGORITHMS_HPP #define BOOST_THREAD_LOCK_ALGORITHMS_HPP #include <boost/thread/detail/config.hpp> #include <boost/thread/lock_types.hpp> #include <boost/thread/lockable_traits.hpp> #include <algorithm> #include <iterator> #include <boost/config/abi_prefix.hpp> namespace boost { namespace detail { template <typename MutexType1, typename MutexType2> unsigned try_lock_internal(MutexType1& m1, MutexType2& m2) { boost::unique_lock<MutexType1> l1(m1, boost::try_to_lock); if (!l1) { return 1; } if (!m2.try_lock()) { return 2; } l1.release(); return 0; } template <typename MutexType1, typename MutexType2, typename MutexType3> unsigned try_lock_internal(MutexType1& m1, MutexType2& m2, MutexType3& m3) { boost::unique_lock<MutexType1> l1(m1, boost::try_to_lock); if (!l1) { return 1; } if (unsigned const failed_lock=try_lock_internal(m2,m3)) { return failed_lock + 1; } l1.release(); return 0; } template <typename MutexType1, typename MutexType2, typename MutexType3, typename MutexType4> unsigned try_lock_internal(MutexType1& m1, MutexType2& m2, MutexType3& m3, MutexType4& m4) { boost::unique_lock<MutexType1> l1(m1, boost::try_to_lock); if (!l1) { return 1; } if (unsigned const failed_lock=try_lock_internal(m2,m3,m4)) { return failed_lock + 1; } l1.release(); return 0; } template <typename MutexType1, typename MutexType2, typename MutexType3, typename MutexType4, typename MutexType5> unsigned try_lock_internal(MutexType1& m1, MutexType2& m2, MutexType3& m3, MutexType4& m4, MutexType5& m5) { boost::unique_lock<MutexType1> l1(m1, boost::try_to_lock); if (!l1) { return 1; } if (unsigned const failed_lock=try_lock_internal(m2,m3,m4,m5)) { return failed_lock + 1; } l1.release(); return 0; } template <typename MutexType1, typename MutexType2> unsigned lock_helper(MutexType1& m1, MutexType2& m2) { boost::unique_lock<MutexType1> l1(m1); if (!m2.try_lock()) { return 1; } l1.release(); return 0; } template <typename MutexType1, typename MutexType2, typename MutexType3> unsigned lock_helper(MutexType1& m1, MutexType2& m2, MutexType3& m3) { boost::unique_lock<MutexType1> l1(m1); if (unsigned const failed_lock=try_lock_internal(m2,m3)) { return failed_lock; } l1.release(); return 0; } template <typename MutexType1, typename MutexType2, typename MutexType3, typename MutexType4> unsigned lock_helper(MutexType1& m1, MutexType2& m2, MutexType3& m3, MutexType4& m4) { boost::unique_lock<MutexType1> l1(m1); if (unsigned const failed_lock=try_lock_internal(m2,m3,m4)) { return failed_lock; } l1.release(); return 0; } template <typename MutexType1, typename MutexType2, typename MutexType3, typename MutexType4, typename MutexType5> unsigned lock_helper(MutexType1& m1, MutexType2& m2, MutexType3& m3, MutexType4& m4, MutexType5& m5) { boost::unique_lock<MutexType1> l1(m1); if (unsigned const failed_lock=try_lock_internal(m2,m3,m4,m5)) { return failed_lock; } l1.release(); return 0; } } namespace detail { template <bool x> struct is_mutex_type_wrapper { }; template <typename MutexType1, typename MutexType2> void lock_impl(MutexType1& m1, MutexType2& m2, is_mutex_type_wrapper<true> ) { unsigned const lock_count = 2; unsigned lock_first = 0; for (;;) { switch (lock_first) { case 0: lock_first = detail::lock_helper(m1, m2); if (!lock_first) return; break; case 1: lock_first = detail::lock_helper(m2, m1); if (!lock_first) return; lock_first = (lock_first + 1) % lock_count; break; } } } template <typename Iterator> void lock_impl(Iterator begin, Iterator end, is_mutex_type_wrapper<false> ); } template <typename MutexType1, typename MutexType2> void lock(MutexType1& m1, MutexType2& m2) { detail::lock_impl(m1, m2, detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>()); } template <typename MutexType1, typename MutexType2> void lock(const MutexType1& m1, MutexType2& m2) { detail::lock_impl(m1, m2, detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>()); } template <typename MutexType1, typename MutexType2> void lock(MutexType1& m1, const MutexType2& m2) { detail::lock_impl(m1, m2, detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>()); } template <typename MutexType1, typename MutexType2> void lock(const MutexType1& m1, const MutexType2& m2) { detail::lock_impl(m1, m2, detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>()); } template <typename MutexType1, typename MutexType2, typename MutexType3> void lock(MutexType1& m1, MutexType2& m2, MutexType3& m3) { unsigned const lock_count = 3; unsigned lock_first = 0; for (;;) { switch (lock_first) { case 0: lock_first = detail::lock_helper(m1, m2, m3); if (!lock_first) return; break; case 1: lock_first = detail::lock_helper(m2, m3, m1); if (!lock_first) return; lock_first = (lock_first + 1) % lock_count; break; case 2: lock_first = detail::lock_helper(m3, m1, m2); if (!lock_first) return; lock_first = (lock_first + 2) % lock_count; break; } } } template <typename MutexType1, typename MutexType2, typename MutexType3, typename MutexType4> void lock(MutexType1& m1, MutexType2& m2, MutexType3& m3, MutexType4& m4) { unsigned const lock_count = 4; unsigned lock_first = 0; for (;;) { switch (lock_first) { case 0: lock_first = detail::lock_helper(m1, m2, m3, m4); if (!lock_first) return; break; case 1: lock_first = detail::lock_helper(m2, m3, m4, m1); if (!lock_first) return; lock_first = (lock_first + 1) % lock_count; break; case 2: lock_first = detail::lock_helper(m3, m4, m1, m2); if (!lock_first) return; lock_first = (lock_first + 2) % lock_count; break; case 3: lock_first = detail::lock_helper(m4, m1, m2, m3); if (!lock_first) return; lock_first = (lock_first + 3) % lock_count; break; } } } template <typename MutexType1, typename MutexType2, typename MutexType3, typename MutexType4, typename MutexType5> void lock(MutexType1& m1, MutexType2& m2, MutexType3& m3, MutexType4& m4, MutexType5& m5) { unsigned const lock_count = 5; unsigned lock_first = 0; for (;;) { switch (lock_first) { case 0: lock_first = detail::lock_helper(m1, m2, m3, m4, m5); if (!lock_first) return; break; case 1: lock_first = detail::lock_helper(m2, m3, m4, m5, m1); if (!lock_first) return; lock_first = (lock_first + 1) % lock_count; break; case 2: lock_first = detail::lock_helper(m3, m4, m5, m1, m2); if (!lock_first) return; lock_first = (lock_first + 2) % lock_count; break; case 3: lock_first = detail::lock_helper(m4, m5, m1, m2, m3); if (!lock_first) return; lock_first = (lock_first + 3) % lock_count; break; case 4: lock_first = detail::lock_helper(m5, m1, m2, m3, m4); if (!lock_first) return; lock_first = (lock_first + 4) % lock_count; break; } } } namespace detail { template <typename Mutex, bool x = is_mutex_type<Mutex>::value> struct try_lock_impl_return { typedef int type; }; template <typename Iterator> struct try_lock_impl_return<Iterator, false> { typedef Iterator type; }; template <typename MutexType1, typename MutexType2> int try_lock_impl(MutexType1& m1, MutexType2& m2, is_mutex_type_wrapper<true> ) { return ((int) detail::try_lock_internal(m1, m2)) - 1; } template <typename Iterator> Iterator try_lock_impl(Iterator begin, Iterator end, is_mutex_type_wrapper<false> ); } template <typename MutexType1, typename MutexType2> typename detail::try_lock_impl_return<MutexType1>::type try_lock(MutexType1& m1, MutexType2& m2) { return detail::try_lock_impl(m1, m2, detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>()); } template <typename MutexType1, typename MutexType2> typename detail::try_lock_impl_return<MutexType1>::type try_lock(const MutexType1& m1, MutexType2& m2) { return detail::try_lock_impl(m1, m2, detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>()); } template <typename MutexType1, typename MutexType2> typename detail::try_lock_impl_return<MutexType1>::type try_lock(MutexType1& m1, const MutexType2& m2) { return detail::try_lock_impl(m1, m2, detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>()); } template <typename MutexType1, typename MutexType2> typename detail::try_lock_impl_return<MutexType1>::type try_lock(const MutexType1& m1, const MutexType2& m2) { return detail::try_lock_impl(m1, m2, detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>()); } template <typename MutexType1, typename MutexType2, typename MutexType3> int try_lock(MutexType1& m1, MutexType2& m2, MutexType3& m3) { return ((int) detail::try_lock_internal(m1, m2, m3)) - 1; } template <typename MutexType1, typename MutexType2, typename MutexType3, typename MutexType4> int try_lock(MutexType1& m1, MutexType2& m2, MutexType3& m3, MutexType4& m4) { return ((int) detail::try_lock_internal(m1, m2, m3, m4)) - 1; } template <typename MutexType1, typename MutexType2, typename MutexType3, typename MutexType4, typename MutexType5> int try_lock(MutexType1& m1, MutexType2& m2, MutexType3& m3, MutexType4& m4, MutexType5& m5) { return ((int) detail::try_lock_internal(m1, m2, m3, m4, m5)) - 1; } namespace detail { template <typename Iterator> struct range_lock_guard { Iterator begin; Iterator end; range_lock_guard(Iterator begin_, Iterator end_) : begin(begin_), end(end_) { boost::lock(begin, end); } void release() { begin = end; } ~range_lock_guard() { for (; begin != end; ++begin) { begin->unlock(); } } }; template <typename Iterator> Iterator try_lock_impl(Iterator begin, Iterator end, is_mutex_type_wrapper<false> ) { if (begin == end) { return end; } typedef typename std::iterator_traits<Iterator>::value_type lock_type; unique_lock<lock_type> guard(*begin, try_to_lock); if (!guard.owns_lock()) { return begin; } Iterator const failed = boost::try_lock(++begin, end); if (failed == end) { guard.release(); } return failed; } } namespace detail { template <typename Iterator> void lock_impl(Iterator begin, Iterator end, is_mutex_type_wrapper<false> ) { typedef typename std::iterator_traits<Iterator>::value_type lock_type; if (begin == end) { return; } bool start_with_begin = true; Iterator second = begin; ++second; Iterator next = second; for (;;) { unique_lock<lock_type> begin_lock(*begin, defer_lock); if (start_with_begin) { begin_lock.lock(); Iterator const failed_lock = boost::try_lock(next, end); if (failed_lock == end) { begin_lock.release(); return; } start_with_begin = false; next = failed_lock; } else { detail::range_lock_guard<Iterator> guard(next, end); if (begin_lock.try_lock()) { Iterator const failed_lock = boost::try_lock(second, next); if (failed_lock == next) { begin_lock.release(); guard.release(); return; } start_with_begin = false; next = failed_lock; } else { start_with_begin = true; next = second; } } } } } } #include <boost/config/abi_suffix.hpp> #endif