// Copyright GoFrame Author(https://goframe.org). All Rights Reserved. // // This Source Code Form is subject to the terms of the MIT License. // If a copy of the MIT was not distributed with this file, // You can obtain one at https://github.com/gogf/gf. // Package gmutex implements graceful concurrent-safe mutex with more rich features. package gmutex import ( "math" "runtime" "github.com/gogf/gf/container/gtype" ) // The high level Mutex, which implements more rich features for mutex. type Mutex struct { state *gtype.Int32 // Indicates the state of mutex. -1: writing locked; > 1 reading locked. writer *gtype.Int32 // Pending writer count. reader *gtype.Int32 // Pending reader count. writing chan struct{} // Channel for writer blocking. reading chan struct{} // Channel for reader blocking. } // New creates and returns a new mutex. func New() *Mutex { return &Mutex{ state: gtype.NewInt32(), writer: gtype.NewInt32(), reader: gtype.NewInt32(), writing: make(chan struct{}, 1), reading: make(chan struct{}, math.MaxInt32), } } // Lock locks the mutex for writing purpose. // If the mutex is already locked by another goroutine for reading or writing, // it blocks until the lock is available. func (m *Mutex) Lock() { for { // Using CAS operation to get the writing lock atomically. if m.state.Cas(0, -1) { return } // It or else blocks to wait for the next chance. m.writer.Add(1) <-m.writing } } // Unlock unlocks writing lock on the mutex. // It is safe to be called multiple times even there's no locks. func (m *Mutex) Unlock() { if m.state.Cas(-1, 0) { // Note that there might be more than one goroutines can enter this block. var n int32 // Writing lock unlocks, then first check the blocked readers. // If there are readers blocked, it unlocks them with preemption. for { if n = m.reader.Val(); n > 0 { if m.reader.Cas(n, 0) { for ; n > 0; n-- { m.reading <- struct{}{} } break } else { runtime.Gosched() } } else { break } } // It then also kindly feeds the pending writers with one chance. if n = m.writer.Val(); n > 0 { if m.writer.Cas(n, n-1) { m.writing <- struct{}{} } } } } // TryLock tries locking the mutex for writing purpose. // It returns true immediately if success, or if there's a write/reading lock on the mutex, // it returns false immediately. func (m *Mutex) TryLock() bool { if m.state.Cas(0, -1) { return true } return false } // RLock locks mutex for reading purpose. // If the mutex is already locked for writing, // it blocks until the lock is available. func (m *Mutex) RLock() { var n int32 for { if n = m.state.Val(); n >= 0 { // If there's no writing lock currently, then do the reading lock checks. if m.state.Cas(n, n+1) { return } else { runtime.Gosched() } } else { // It or else pends the reader. m.reader.Add(1) <-m.reading } } } // RUnlock unlocks the reading lock on the mutex. // It is safe to be called multiple times even there's no locks. func (m *Mutex) RUnlock() { var n int32 for { if n = m.state.Val(); n >= 1 { if m.state.Cas(n, n-1) { break } else { runtime.Gosched() } } else { break } } // Reading lock unlocks, it then only check the blocked writers. // Note that it is not necessary to check the pending readers here. // means the state of mutex comes down to zero. if n == 1 { if n = m.writer.Val(); n > 0 { if m.writer.Cas(n, n-1) { m.writing <- struct{}{} } } } } // TryRLock tries locking the mutex for reading purpose. // It returns true immediately if success, or if there's a writing lock on the mutex, // it returns false immediately. func (m *Mutex) TryRLock() bool { var n int32 for { if n = m.state.Val(); n >= 0 { if m.state.Cas(n, n+1) { return true } else { runtime.Gosched() } } else { return false } } } // IsLocked checks whether the mutex is locked with writing or reading lock. // Note that the result might be changed after it's called, // so it cannot be the criterion for atomic operations. func (m *Mutex) IsLocked() bool { return m.state.Val() != 0 } // IsWLocked checks whether the mutex is locked by writing lock. // Note that the result might be changed after it's called, // so it cannot be the criterion for atomic operations. func (m *Mutex) IsWLocked() bool { return m.state.Val() < 0 } // IsRLocked checks whether the mutex is locked by reading lock. // Note that the result might be changed after it's called, // so it cannot be the criterion for atomic operations. func (m *Mutex) IsRLocked() bool { return m.state.Val() > 0 } // LockFunc locks the mutex for writing with given callback function . // If there's a write/reading lock the mutex, it will blocks until the lock is released. // // It releases the lock after is executed. func (m *Mutex) LockFunc(f func()) { m.Lock() defer m.Unlock() f() } // RLockFunc locks the mutex for reading with given callback function . // If there's a writing lock the mutex, it will blocks until the lock is released. // // It releases the lock after is executed. func (m *Mutex) RLockFunc(f func()) { m.RLock() defer m.RUnlock() f() } // TryLockFunc tries locking the mutex for writing with given callback function . // it returns true immediately if success, or if there's a write/reading lock on the mutex, // it returns false immediately. // // It releases the lock after is executed. func (m *Mutex) TryLockFunc(f func()) (result bool) { if m.TryLock() { result = true defer m.Unlock() f() } return } // TryRLockFunc tries locking the mutex for reading with given callback function . // It returns true immediately if success, or if there's a writing lock on the mutex, // it returns false immediately. // // It releases the lock after is executed. func (m *Mutex) TryRLockFunc(f func()) (result bool) { if m.TryRLock() { result = true defer m.RUnlock() f() } return }