/* Copyright 2005-2013 Intel Corporation. All Rights Reserved. This file is part of Threading Building Blocks. Threading Building Blocks is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License version 2 as published by the Free Software Foundation. Threading Building Blocks 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 General Public License for more details. You should have received a copy of the GNU General Public License along with Threading Building Blocks; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA As a special exception, you may use this file as part of a free software library without restriction. Specifically, if other files instantiate templates or use macros or inline functions from this file, or you compile this file and link it with other files to produce an executable, this file does not by itself cause the resulting executable to be covered by the GNU General Public License. This exception does not however invalidate any other reasons why the executable file might be covered by the GNU General Public License. */ #ifndef __TBB_spin_rw_mutex_H #define __TBB_spin_rw_mutex_H #include "tbb_stddef.h" #include "tbb_machine.h" #include "tbb_profiling.h" namespace tbb { class spin_rw_mutex_v3; typedef spin_rw_mutex_v3 spin_rw_mutex; //! Fast, unfair, spinning reader-writer lock with backoff and writer-preference /** @ingroup synchronization */ class spin_rw_mutex_v3 { //! @cond INTERNAL //! Internal acquire write lock. bool __TBB_EXPORTED_METHOD internal_acquire_writer(); //! Out of line code for releasing a write lock. /** This code has debug checking and instrumentation for Intel(R) Thread Checker and Intel(R) Thread Profiler. */ void __TBB_EXPORTED_METHOD internal_release_writer(); //! Internal acquire read lock. void __TBB_EXPORTED_METHOD internal_acquire_reader(); //! Internal upgrade reader to become a writer. bool __TBB_EXPORTED_METHOD internal_upgrade(); //! Out of line code for downgrading a writer to a reader. /** This code has debug checking and instrumentation for Intel(R) Thread Checker and Intel(R) Thread Profiler. */ void __TBB_EXPORTED_METHOD internal_downgrade(); //! Internal release read lock. void __TBB_EXPORTED_METHOD internal_release_reader(); //! Internal try_acquire write lock. bool __TBB_EXPORTED_METHOD internal_try_acquire_writer(); //! Internal try_acquire read lock. bool __TBB_EXPORTED_METHOD internal_try_acquire_reader(); //! @endcond public: //! Construct unacquired mutex. spin_rw_mutex_v3() : state(0) { #if TBB_USE_THREADING_TOOLS internal_construct(); #endif } #if TBB_USE_ASSERT //! Destructor asserts if the mutex is acquired, i.e. state is zero. ~spin_rw_mutex_v3() { __TBB_ASSERT( !state, "destruction of an acquired mutex"); }; #endif /* TBB_USE_ASSERT */ //! The scoped locking pattern /** It helps to avoid the common problem of forgetting to release lock. It also nicely provides the "node" for queuing locks. */ class scoped_lock : internal::no_copy { public: //! Construct lock that has not acquired a mutex. /** Equivalent to zero-initialization of *this. */ scoped_lock() : mutex(NULL), is_writer(false) {} //! Acquire lock on given mutex. scoped_lock( spin_rw_mutex& m, bool write = true ) : mutex(NULL) { acquire(m, write); } //! Release lock (if lock is held). ~scoped_lock() { if( mutex ) release(); } //! Acquire lock on given mutex. void acquire( spin_rw_mutex& m, bool write = true ) { __TBB_ASSERT( !mutex, "holding mutex already" ); is_writer = write; mutex = &m; if( write ) mutex->internal_acquire_writer(); else mutex->internal_acquire_reader(); } //! Upgrade reader to become a writer. /** Returns whether the upgrade happened without releasing and re-acquiring the lock */ bool upgrade_to_writer() { __TBB_ASSERT( mutex, "lock is not acquired" ); __TBB_ASSERT( !is_writer, "not a reader" ); is_writer = true; return mutex->internal_upgrade(); } //! Release lock. void release() { __TBB_ASSERT( mutex, "lock is not acquired" ); spin_rw_mutex *m = mutex; mutex = NULL; #if TBB_USE_THREADING_TOOLS||TBB_USE_ASSERT if( is_writer ) m->internal_release_writer(); else m->internal_release_reader(); #else if( is_writer ) __TBB_AtomicAND( &m->state, READERS ); else __TBB_FetchAndAddWrelease( &m->state, -(intptr_t)ONE_READER); #endif /* TBB_USE_THREADING_TOOLS||TBB_USE_ASSERT */ } //! Downgrade writer to become a reader. bool downgrade_to_reader() { __TBB_ASSERT( mutex, "lock is not acquired" ); __TBB_ASSERT( is_writer, "not a writer" ); #if TBB_USE_THREADING_TOOLS||TBB_USE_ASSERT mutex->internal_downgrade(); #else __TBB_FetchAndAddW( &mutex->state, ((intptr_t)ONE_READER-WRITER)); #endif /* TBB_USE_THREADING_TOOLS||TBB_USE_ASSERT */ is_writer = false; return true; } //! Try acquire lock on given mutex. bool try_acquire( spin_rw_mutex& m, bool write = true ) { __TBB_ASSERT( !mutex, "holding mutex already" ); bool result; is_writer = write; result = write? m.internal_try_acquire_writer() : m.internal_try_acquire_reader(); if( result ) mutex = &m; return result; } protected: //! The pointer to the current mutex that is held, or NULL if no mutex is held. spin_rw_mutex* mutex; //! If mutex!=NULL, then is_writer is true if holding a writer lock, false if holding a reader lock. /** Not defined if not holding a lock. */ bool is_writer; }; // Mutex traits static const bool is_rw_mutex = true; static const bool is_recursive_mutex = false; static const bool is_fair_mutex = false; // ISO C++0x compatibility methods //! Acquire writer lock void lock() {internal_acquire_writer();} //! Try acquiring writer lock (non-blocking) /** Return true if lock acquired; false otherwise. */ bool try_lock() {return internal_try_acquire_writer();} //! Release lock void unlock() { #if TBB_USE_THREADING_TOOLS||TBB_USE_ASSERT if( state&WRITER ) internal_release_writer(); else internal_release_reader(); #else if( state&WRITER ) __TBB_AtomicAND( &state, READERS ); else __TBB_FetchAndAddWrelease( &state, -(intptr_t)ONE_READER); #endif /* TBB_USE_THREADING_TOOLS||TBB_USE_ASSERT */ } // Methods for reader locks that resemble ISO C++0x compatibility methods. //! Acquire reader lock void lock_read() {internal_acquire_reader();} //! Try acquiring reader lock (non-blocking) /** Return true if reader lock acquired; false otherwise. */ bool try_lock_read() {return internal_try_acquire_reader();} private: typedef intptr_t state_t; static const state_t WRITER = 1; static const state_t WRITER_PENDING = 2; static const state_t READERS = ~(WRITER | WRITER_PENDING); static const state_t ONE_READER = 4; static const state_t BUSY = WRITER | READERS; //! State of lock /** Bit 0 = writer is holding lock Bit 1 = request by a writer to acquire lock (hint to readers to wait) Bit 2..N = number of readers holding lock */ state_t state; void __TBB_EXPORTED_METHOD internal_construct(); }; __TBB_DEFINE_PROFILING_SET_NAME(spin_rw_mutex) } // namespace tbb #endif /* __TBB_spin_rw_mutex_H */