/// \file mingw.shared_mutex.h /// \brief Standard-compliant shared_mutex for MinGW /// /// (c) 2017 by Nathaniel J. McClatchey, Athens OH, United States /// \author Nathaniel J. McClatchey /// /// \copyright Simplified (2-clause) BSD License. /// /// \note This file may become part of the mingw-w64 runtime package. If/when /// this happens, the appropriate license will be added, i.e. this code will /// become dual-licensed, and the current BSD 2-clause license will stay. /// \note Target Windows version is determined by WINVER, which is determined in /// from _WIN32_WINNT, which can itself be set by the user. // Notes on the namespaces: // - The implementation can be accessed directly in the namespace // mingw_stdthread. // - Objects will be brought into namespace std by a using directive. This // will cause objects declared in std (such as MinGW's implementation) to // hide this implementation's definitions. // - To avoid poluting the namespace with implementation details, all objects // to be pushed into std will be placed in mingw_stdthread::visible. // The end result is that if MinGW supplies an object, it is automatically // used. If MinGW does not supply an object, this implementation's version will // instead be used. #ifndef MINGW_SHARED_MUTEX_H_ #define MINGW_SHARED_MUTEX_H_ #if !defined(__cplusplus) || (__cplusplus < 201103L) #error A C++11 compiler is required! #endif #include // For descriptive errors. #include // Implementing a shared_mutex without OS support will require atomic read- // modify-write capacity. #include // For timing in shared_lock and shared_timed_mutex. #include #include // Use MinGW's shared_lock class template, if it's available. Requires C++14. // If unavailable (eg. because this library is being used in C++11), then an // implementation of shared_lock is provided by this header. #if (__cplusplus >= 201402L) #include #endif // For defer_lock_t, adopt_lock_t, and try_to_lock_t #include "mingw.mutex.h" // For this_thread::yield. //#include "mingw.thread.h" // Might be able to use native Slim Reader-Writer (SRW) locks. #ifdef _WIN32 #include // Detect Windows version. #include #endif namespace mingw_stdthread { // Define a portable atomics-based shared_mutex namespace portable { class shared_mutex { typedef uint_fast16_t counter_type; std::atomic mCounter {0}; static constexpr counter_type kWriteBit = 1 << (std::numeric_limits::digits - 1); #if STDMUTEX_RECURSION_CHECKS // Runtime checker for verifying owner threads. Note: Exclusive mode only. _OwnerThread mOwnerThread {}; #endif public: typedef shared_mutex * native_handle_type; shared_mutex () = default; // No form of copying or moving should be allowed. shared_mutex (const shared_mutex&) = delete; shared_mutex & operator= (const shared_mutex&) = delete; ~shared_mutex () { // Terminate if someone tries to destroy an owned mutex. assert(mCounter.load(std::memory_order_relaxed) == 0); } void lock_shared (void) { counter_type expected = mCounter.load(std::memory_order_relaxed); do { // Delay if writing or if too many readers are attempting to read. if (expected >= kWriteBit - 1) { using namespace std; expected = mCounter.load(std::memory_order_relaxed); continue; } if (mCounter.compare_exchange_weak(expected, static_cast(expected + 1), std::memory_order_acquire, std::memory_order_relaxed)) break; } while (true); } bool try_lock_shared (void) { counter_type expected = mCounter.load(std::memory_order_relaxed) & static_cast(~kWriteBit); if (expected + 1 == kWriteBit) return false; else return mCounter.compare_exchange_strong( expected, static_cast(expected + 1), std::memory_order_acquire, std::memory_order_relaxed); } void unlock_shared (void) { using namespace std; #ifndef NDEBUG if (!(mCounter.fetch_sub(1, memory_order_release) & static_cast(~kWriteBit))) throw system_error(make_error_code(errc::operation_not_permitted)); #else mCounter.fetch_sub(1, memory_order_release); #endif } // Behavior is undefined if a lock was previously acquired. void lock (void) { #if STDMUTEX_RECURSION_CHECKS DWORD self = mOwnerThread.checkOwnerBeforeLock(); #endif using namespace std; // Might be able to use relaxed memory order... // Wait for the write-lock to be unlocked, then claim the write slot. counter_type current; while ((current = mCounter.fetch_or(kWriteBit, std::memory_order_acquire)) & kWriteBit); //this_thread::yield(); // Wait for readers to finish up. while (current != kWriteBit) { //this_thread::yield(); current = mCounter.load(std::memory_order_acquire); } #if STDMUTEX_RECURSION_CHECKS mOwnerThread.setOwnerAfterLock(self); #endif } bool try_lock (void) { #if STDMUTEX_RECURSION_CHECKS DWORD self = mOwnerThread.checkOwnerBeforeLock(); #endif counter_type expected = 0; bool ret = mCounter.compare_exchange_strong(expected, kWriteBit, std::memory_order_acquire, std::memory_order_relaxed); #if STDMUTEX_RECURSION_CHECKS if (ret) mOwnerThread.setOwnerAfterLock(self); #endif return ret; } void unlock (void) { #if STDMUTEX_RECURSION_CHECKS mOwnerThread.checkSetOwnerBeforeUnlock(); #endif using namespace std; #ifndef NDEBUG if (mCounter.load(memory_order_relaxed) != kWriteBit) throw system_error(make_error_code(errc::operation_not_permitted)); #endif mCounter.store(0, memory_order_release); } native_handle_type native_handle (void) { return this; } }; } // Namespace portable // The native shared_mutex implementation primarily uses features of Windows // Vista, but the features used for try_lock and try_lock_shared were not // introduced until Windows 7. To allow limited use while compiling for Vista, // I define the class without try_* functions in that case. // Only fully-featured implementations will be placed into namespace std. #if defined(_WIN32) && (WINVER >= _WIN32_WINNT_VISTA) namespace vista { class condition_variable_any; } namespace windows7 { // We already #include "mingw.mutex.h". May as well reduce redundancy. class shared_mutex : windows7::mutex { // Allow condition_variable_any (and only condition_variable_any) to treat a // shared_mutex as its base class. friend class vista::condition_variable_any; public: using windows7::mutex::native_handle_type; using windows7::mutex::lock; using windows7::mutex::unlock; using windows7::mutex::native_handle; void lock_shared (void) { AcquireSRWLockShared(native_handle()); } void unlock_shared (void) { ReleaseSRWLockShared(native_handle()); } // TryAcquireSRW functions are a Windows 7 feature. #if (WINVER >= _WIN32_WINNT_WIN7) bool try_lock_shared (void) { return TryAcquireSRWLockShared(native_handle()) != 0; } using windows7::mutex::try_lock; #endif }; } // Namespace windows7 #endif // Compiling for Vista #if (defined(_WIN32) && (WINVER >= _WIN32_WINNT_WIN7)) using windows7::shared_mutex; #else using portable::shared_mutex; #endif class shared_timed_mutex : shared_mutex { typedef shared_mutex Base; public: using Base::lock; using Base::try_lock; using Base::unlock; using Base::lock_shared; using Base::try_lock_shared; using Base::unlock_shared; template< class Clock, class Duration > bool try_lock_until ( const std::chrono::time_point& cutoff ) { do { if (try_lock()) return true; } while (std::chrono::steady_clock::now() < cutoff); return false; } template< class Rep, class Period > bool try_lock_for (const std::chrono::duration& rel_time) { return try_lock_until(std::chrono::steady_clock::now() + rel_time); } template< class Clock, class Duration > bool try_lock_shared_until ( const std::chrono::time_point& cutoff ) { do { if (try_lock_shared()) return true; } while (std::chrono::steady_clock::now() < cutoff); return false; } template< class Rep, class Period > bool try_lock_shared_for (const std::chrono::duration& rel_time) { return try_lock_shared_until(std::chrono::steady_clock::now() + rel_time); } }; #if __cplusplus >= 201402L using std::shared_lock; #else // If not supplied by shared_mutex (eg. because C++14 is not supported), I // supply the various helper classes that the header should have defined. template class shared_lock { Mutex * mMutex; bool mOwns; // Reduce code redundancy void verify_lockable (void) { using namespace std; if (mMutex == nullptr) throw system_error(make_error_code(errc::operation_not_permitted)); if (mOwns) throw system_error(make_error_code(errc::resource_deadlock_would_occur)); } public: typedef Mutex mutex_type; shared_lock (void) noexcept : mMutex(nullptr), mOwns(false) { } shared_lock (shared_lock && other) noexcept : mMutex(other.mutex_), mOwns(other.owns_) { other.mMutex = nullptr; other.mOwns = false; } explicit shared_lock (mutex_type & m) : mMutex(&m), mOwns(true) { mMutex->lock_shared(); } shared_lock (mutex_type & m, defer_lock_t) noexcept : mMutex(&m), mOwns(false) { } shared_lock (mutex_type & m, adopt_lock_t) : mMutex(&m), mOwns(true) { } shared_lock (mutex_type & m, try_to_lock_t) : mMutex(&m), mOwns(m.try_lock_shared()) { } template< class Rep, class Period > shared_lock( mutex_type& m, const std::chrono::duration& timeout_duration ) : mMutex(&m), mOwns(m.try_lock_shared_for(timeout_duration)) { } template< class Clock, class Duration > shared_lock( mutex_type& m, const std::chrono::time_point& timeout_time ) : mMutex(&m), mOwns(m.try_lock_shared_until(timeout_time)) { } shared_lock& operator= (shared_lock && other) noexcept { if (&other != this) { if (mOwns) mMutex->unlock_shared(); mMutex = other.mMutex; mOwns = other.mOwns; other.mMutex = nullptr; other.mOwns = false; } return *this; } ~shared_lock (void) { if (mOwns) mMutex->unlock_shared(); } shared_lock (const shared_lock &) = delete; shared_lock& operator= (const shared_lock &) = delete; // Shared locking void lock (void) { verify_lockable(); mMutex->lock_shared(); mOwns = true; } bool try_lock (void) { verify_lockable(); mOwns = mMutex->try_lock_shared(); return mOwns; } template< class Clock, class Duration > bool try_lock_until( const std::chrono::time_point& cutoff ) { verify_lockable(); do { mOwns = mMutex->try_lock_shared(); if (mOwns) return mOwns; } while (std::chrono::steady_clock::now() < cutoff); return false; } template< class Rep, class Period > bool try_lock_for (const std::chrono::duration& rel_time) { return try_lock_until(std::chrono::steady_clock::now() + rel_time); } void unlock (void) { using namespace std; if (!mOwns) throw system_error(make_error_code(errc::operation_not_permitted)); mMutex->unlock_shared(); mOwns = false; } // Modifiers void swap (shared_lock & other) noexcept { using namespace std; swap(mMutex, other.mMutex); swap(mOwns, other.mOwns); } mutex_type * release (void) noexcept { mutex_type * ptr = mMutex; mMutex = nullptr; mOwns = false; return ptr; } // Observers mutex_type * mutex (void) const noexcept { return mMutex; } bool owns_lock (void) const noexcept { return mOwns; } explicit operator bool () const noexcept { return owns_lock(); } }; template< class Mutex > void swap( shared_lock& lhs, shared_lock& rhs ) noexcept { lhs.swap(rhs); } #endif // C++11 } // Namespace mingw_stdthread namespace std { // Because of quirks of the compiler, the common "using namespace std;" // directive would flatten the namespaces and introduce ambiguity where there // was none. Direct specification (std::), however, would be unaffected. // Take the safe option, and include only in the presence of MinGW's win32 // implementation. #if (__cplusplus < 201703L) || (defined(__MINGW32__ ) && !defined(_GLIBCXX_HAS_GTHREADS)) using mingw_stdthread::shared_mutex; #endif #if (__cplusplus < 201402L) || (defined(__MINGW32__ ) && !defined(_GLIBCXX_HAS_GTHREADS)) using mingw_stdthread::shared_timed_mutex; using mingw_stdthread::shared_lock; #elif !defined(MINGW_STDTHREAD_REDUNDANCY_WARNING) // Skip repetition #define MINGW_STDTHREAD_REDUNDANCY_WARNING #pragma message "This version of MinGW seems to include a win32 port of\ pthreads, and probably already has C++ std threading classes implemented,\ based on pthreads. These classes, found in namespace std, are not overridden\ by the mingw-std-thread library. If you would still like to use this\ implementation (as it is more lightweight), use the classes provided in\ namespace mingw_stdthread." #endif } // Namespace std #endif // MINGW_SHARED_MUTEX_H_