boost/fiber/future/detail/shared_state.hpp
// Copyright Oliver Kowalke 2013. // 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_FIBERS_DETAIL_SHARED_STATE_H #define BOOST_FIBERS_DETAIL_SHARED_STATE_H #include <algorithm> #include <atomic> #include <chrono> #include <cstddef> #include <exception> #include <memory> #include <mutex> #include <type_traits> #include <boost/assert.hpp> #include <boost/config.hpp> #include <boost/intrusive_ptr.hpp> #include <boost/fiber/detail/config.hpp> #include <boost/fiber/future/future_status.hpp> #include <boost/fiber/condition_variable.hpp> #include <boost/fiber/exceptions.hpp> #include <boost/fiber/mutex.hpp> #ifdef BOOST_HAS_ABI_HEADERS # include BOOST_ABI_PREFIX #endif namespace boost { namespace fibers { namespace detail { class shared_state_base { private: std::atomic< std::size_t > use_count_{ 0 }; mutable condition_variable waiters_{}; protected: mutable mutex mtx_{}; bool ready_{ false }; std::exception_ptr except_{}; void mark_ready_and_notify_( std::unique_lock< mutex > & lk) noexcept { BOOST_ASSERT( lk.owns_lock() ); ready_ = true; lk.unlock(); waiters_.notify_all(); } void owner_destroyed_( std::unique_lock< mutex > & lk) { BOOST_ASSERT( lk.owns_lock() ); if ( ! ready_) { set_exception_( std::make_exception_ptr( broken_promise() ), lk); } } void set_exception_( std::exception_ptr except, std::unique_lock< mutex > & lk) { BOOST_ASSERT( lk.owns_lock() ); if ( BOOST_UNLIKELY( ready_) ) { throw promise_already_satisfied(); } except_ = except; mark_ready_and_notify_( lk); } std::exception_ptr get_exception_ptr_( std::unique_lock< mutex > & lk) { BOOST_ASSERT( lk.owns_lock() ); wait_( lk); return except_; } void wait_( std::unique_lock< mutex > & lk) const { BOOST_ASSERT( lk.owns_lock() ); waiters_.wait( lk, [this](){ return ready_; }); } template< typename Rep, typename Period > future_status wait_for_( std::unique_lock< mutex > & lk, std::chrono::duration< Rep, Period > const& timeout_duration) const { BOOST_ASSERT( lk.owns_lock() ); return waiters_.wait_for( lk, timeout_duration, [this](){ return ready_; }) ? future_status::ready : future_status::timeout; } template< typename Clock, typename Duration > future_status wait_until_( std::unique_lock< mutex > & lk, std::chrono::time_point< Clock, Duration > const& timeout_time) const { BOOST_ASSERT( lk.owns_lock() ); return waiters_.wait_until( lk, timeout_time, [this](){ return ready_; }) ? future_status::ready : future_status::timeout; } virtual void deallocate_future() noexcept = 0; public: shared_state_base() = default; virtual ~shared_state_base() = default; shared_state_base( shared_state_base const&) = delete; shared_state_base & operator=( shared_state_base const&) = delete; void owner_destroyed() { std::unique_lock< mutex > lk{ mtx_ }; owner_destroyed_( lk); } void set_exception( std::exception_ptr except) { std::unique_lock< mutex > lk{ mtx_ }; set_exception_( except, lk); } std::exception_ptr get_exception_ptr() { std::unique_lock< mutex > lk{ mtx_ }; return get_exception_ptr_( lk); } void wait() const { std::unique_lock< mutex > lk{ mtx_ }; wait_( lk); } template< typename Rep, typename Period > future_status wait_for( std::chrono::duration< Rep, Period > const& timeout_duration) const { std::unique_lock< mutex > lk{ mtx_ }; return wait_for_( lk, timeout_duration); } template< typename Clock, typename Duration > future_status wait_until( std::chrono::time_point< Clock, Duration > const& timeout_time) const { std::unique_lock< mutex > lk{ mtx_ }; return wait_until_( lk, timeout_time); } friend inline void intrusive_ptr_add_ref( shared_state_base * p) noexcept { p->use_count_.fetch_add( 1, std::memory_order_relaxed); } friend inline void intrusive_ptr_release( shared_state_base * p) noexcept { if ( 1 == p->use_count_.fetch_sub( 1, std::memory_order_release) ) { std::atomic_thread_fence( std::memory_order_acquire); p->deallocate_future(); } } }; template< typename R > class shared_state : public shared_state_base { private: typename std::aligned_storage< sizeof( R), alignof( R) >::type storage_{}; void set_value_( R const& value, std::unique_lock< mutex > & lk) { BOOST_ASSERT( lk.owns_lock() ); if ( BOOST_UNLIKELY( ready_) ) { throw promise_already_satisfied{}; } ::new ( static_cast< void * >( std::addressof( storage_) ) ) R( value ); mark_ready_and_notify_( lk); } void set_value_( R && value, std::unique_lock< mutex > & lk) { BOOST_ASSERT( lk.owns_lock() ); if ( BOOST_UNLIKELY( ready_) ) { throw promise_already_satisfied{}; } ::new ( static_cast< void * >( std::addressof( storage_) ) ) R( std::move( value) ); mark_ready_and_notify_( lk); } R & get_( std::unique_lock< mutex > & lk) { BOOST_ASSERT( lk.owns_lock() ); wait_( lk); if ( except_) { std::rethrow_exception( except_); } return * reinterpret_cast< R * >( std::addressof( storage_) ); } public: typedef intrusive_ptr< shared_state > ptr_type; shared_state() = default; virtual ~shared_state() { if ( ready_ && ! except_) { reinterpret_cast< R * >( std::addressof( storage_) )->~R(); } } shared_state( shared_state const&) = delete; shared_state & operator=( shared_state const&) = delete; void set_value( R const& value) { std::unique_lock< mutex > lk{ mtx_ }; set_value_( value, lk); } void set_value( R && value) { std::unique_lock< mutex > lk{ mtx_ }; set_value_( std::move( value), lk); } R & get() { std::unique_lock< mutex > lk{ mtx_ }; return get_( lk); } }; template< typename R > class shared_state< R & > : public shared_state_base { private: R * value_{ nullptr }; void set_value_( R & value, std::unique_lock< mutex > & lk) { BOOST_ASSERT( lk.owns_lock() ); if ( BOOST_UNLIKELY( ready_) ) { throw promise_already_satisfied(); } value_ = std::addressof( value); mark_ready_and_notify_( lk); } R & get_( std::unique_lock< mutex > & lk) { BOOST_ASSERT( lk.owns_lock() ); wait_( lk); if ( except_) { std::rethrow_exception( except_); } return * value_; } public: typedef intrusive_ptr< shared_state > ptr_type; shared_state() = default; virtual ~shared_state() = default; shared_state( shared_state const&) = delete; shared_state & operator=( shared_state const&) = delete; void set_value( R & value) { std::unique_lock< mutex > lk{ mtx_ }; set_value_( value, lk); } R & get() { std::unique_lock< mutex > lk{ mtx_ }; return get_( lk); } }; template<> class shared_state< void > : public shared_state_base { private: inline void set_value_( std::unique_lock< mutex > & lk) { BOOST_ASSERT( lk.owns_lock() ); if ( BOOST_UNLIKELY( ready_) ) { throw promise_already_satisfied(); } mark_ready_and_notify_( lk); } inline void get_( std::unique_lock< mutex > & lk) { BOOST_ASSERT( lk.owns_lock() ); wait_( lk); if ( except_) { std::rethrow_exception( except_); } } public: typedef intrusive_ptr< shared_state > ptr_type; shared_state() = default; virtual ~shared_state() = default; shared_state( shared_state const&) = delete; shared_state & operator=( shared_state const&) = delete; inline void set_value() { std::unique_lock< mutex > lk{ mtx_ }; set_value_( lk); } inline void get() { std::unique_lock< mutex > lk{ mtx_ }; get_( lk); } }; }}} #ifdef BOOST_HAS_ABI_HEADERS # include BOOST_ABI_SUFFIX #endif #endif // BOOST_FIBERS_DETAIL_SHARED_STATE_H