package executors import ( "reflect" "sync" "sync/atomic" "time" "github.com/tal-tech/go-zero/core/lang" "github.com/tal-tech/go-zero/core/proc" "github.com/tal-tech/go-zero/core/syncx" "github.com/tal-tech/go-zero/core/threading" "github.com/tal-tech/go-zero/core/timex" ) const idleRound = 10 type ( // TaskContainer interface defines a type that can be used as the underlying // container that used to do periodical executions. TaskContainer interface { // AddTask adds the task into the container. // Returns true if the container needs to be flushed after the addition. AddTask(task interface{}) bool // Execute handles the collected tasks by the container when flushing. Execute(tasks interface{}) // RemoveAll removes the contained tasks, and return them. RemoveAll() interface{} } // A PeriodicalExecutor is an executor that periodically execute tasks. PeriodicalExecutor struct { commander chan interface{} interval time.Duration container TaskContainer waitGroup sync.WaitGroup // avoid race condition on waitGroup when calling wg.Add/Done/Wait(...) wgBarrier syncx.Barrier confirmChan chan lang.PlaceholderType inflight int32 guarded bool newTicker func(duration time.Duration) timex.Ticker lock sync.Mutex } ) // NewPeriodicalExecutor returns a PeriodicalExecutor with given interval and container. func NewPeriodicalExecutor(interval time.Duration, container TaskContainer) *PeriodicalExecutor { executor := &PeriodicalExecutor{ // buffer 1 to let the caller go quickly commander: make(chan interface{}, 1), interval: interval, container: container, confirmChan: make(chan lang.PlaceholderType), newTicker: func(d time.Duration) timex.Ticker { return timex.NewTicker(d) }, } proc.AddShutdownListener(func() { executor.Flush() }) return executor } // Add adds tasks into pe. func (pe *PeriodicalExecutor) Add(task interface{}) { if vals, ok := pe.addAndCheck(task); ok { pe.commander <- vals <-pe.confirmChan } } // Flush forces pe to execute tasks. func (pe *PeriodicalExecutor) Flush() bool { pe.enterExecution() return pe.executeTasks(func() interface{} { pe.lock.Lock() defer pe.lock.Unlock() return pe.container.RemoveAll() }()) } // Sync lets caller to run fn thread-safe with pe, especially for the underlying container. func (pe *PeriodicalExecutor) Sync(fn func()) { pe.lock.Lock() defer pe.lock.Unlock() fn() } // Wait waits the execution to be done. func (pe *PeriodicalExecutor) Wait() { pe.Flush() pe.wgBarrier.Guard(func() { pe.waitGroup.Wait() }) } func (pe *PeriodicalExecutor) addAndCheck(task interface{}) (interface{}, bool) { pe.lock.Lock() defer func() { if !pe.guarded { pe.guarded = true // defer to unlock quickly defer pe.backgroundFlush() } pe.lock.Unlock() }() if pe.container.AddTask(task) { atomic.AddInt32(&pe.inflight, 1) return pe.container.RemoveAll(), true } return nil, false } func (pe *PeriodicalExecutor) backgroundFlush() { threading.GoSafe(func() { // flush before quit goroutine to avoid missing tasks defer pe.Flush() ticker := pe.newTicker(pe.interval) defer ticker.Stop() var commanded bool last := timex.Now() for { select { case vals := <-pe.commander: commanded = true atomic.AddInt32(&pe.inflight, -1) pe.enterExecution() pe.confirmChan <- lang.Placeholder pe.executeTasks(vals) last = timex.Now() case <-ticker.Chan(): if commanded { commanded = false } else if pe.Flush() { last = timex.Now() } else if pe.shallQuit(last) { return } } } }) } func (pe *PeriodicalExecutor) doneExecution() { pe.waitGroup.Done() } func (pe *PeriodicalExecutor) enterExecution() { pe.wgBarrier.Guard(func() { pe.waitGroup.Add(1) }) } func (pe *PeriodicalExecutor) executeTasks(tasks interface{}) bool { defer pe.doneExecution() ok := pe.hasTasks(tasks) if ok { pe.container.Execute(tasks) } return ok } func (pe *PeriodicalExecutor) hasTasks(tasks interface{}) bool { if tasks == nil { return false } val := reflect.ValueOf(tasks) switch val.Kind() { case reflect.Array, reflect.Chan, reflect.Map, reflect.Slice: return val.Len() > 0 default: // unknown type, let caller execute it return true } } func (pe *PeriodicalExecutor) shallQuit(last time.Duration) (stop bool) { if timex.Since(last) <= pe.interval*idleRound { return } // checking pe.inflight and setting pe.guarded should be locked together pe.lock.Lock() if atomic.LoadInt32(&pe.inflight) == 0 { pe.guarded = false stop = true } pe.lock.Unlock() return }