package pool import ( "container/list" "context" "io" "sync" "time" ) var _ Pool = &List{} // List . type List struct { // New is an application supplied function for creating and configuring a // item. // // The item returned from new must not be in a special state // (subscribed to pubsub channel, transaction started, ...). New func(ctx context.Context) (io.Closer, error) // mu protects fields defined below. mu sync.Mutex cond chan struct{} closed bool active int // clean stale items cleanerCh chan struct{} // Stack of item with most recently used at the front. idles list.List // Config pool configuration conf *Config } // NewList creates a new pool. func NewList(c *Config) *List { // check Config if c == nil || c.Active < c.Idle { panic("config nil or Idle Must <= Active") } // new pool p := &List{conf: c} p.cond = make(chan struct{}) p.startCleanerLocked(time.Duration(c.IdleTimeout)) return p } // Reload reload config. func (p *List) Reload(c *Config) error { p.mu.Lock() //p.startCleanerLocked(time.Duration(c.IdleTimeout)) p.conf = c p.mu.Unlock() return nil } // startCleanerLocked func (p *List) startCleanerLocked(d time.Duration) { if d <= 0 { // if set 0, staleCleaner() will return directly return } if d < time.Duration(p.conf.IdleTimeout) && p.cleanerCh != nil { select { case p.cleanerCh <- struct{}{}: default: } } // run only one, clean stale items. if p.cleanerCh == nil { p.cleanerCh = make(chan struct{}, 1) go p.staleCleaner() } } // staleCleaner clean stale items proc. func (p *List) staleCleaner() { ticker := time.NewTicker(100 * time.Millisecond) for { select { case <-ticker.C: case <-p.cleanerCh: // maxLifetime was changed or db was closed. } p.mu.Lock() if p.closed || p.conf.IdleTimeout <= 0 { p.mu.Unlock() return } for i, n := 0, p.idles.Len(); i < n; i++ { e := p.idles.Back() if e == nil { // no possible break } ic := e.Value.(item) if !ic.expired(time.Duration(p.conf.IdleTimeout)) { // not need continue. break } p.idles.Remove(e) p.release() p.mu.Unlock() ic.c.Close() p.mu.Lock() } p.mu.Unlock() } } // Get returns a item from the idles List or // get a new item. func (p *List) Get(ctx context.Context) (io.Closer, error) { p.mu.Lock() if p.closed { p.mu.Unlock() return nil, ErrPoolClosed } for { // get idles item. for i, n := 0, p.idles.Len(); i < n; i++ { e := p.idles.Front() if e == nil { break } ic := e.Value.(item) p.idles.Remove(e) p.mu.Unlock() if !ic.expired(time.Duration(p.conf.IdleTimeout)) { return ic.c, nil } ic.c.Close() p.mu.Lock() p.release() } // Check for pool closed before dialing a new item. if p.closed { p.mu.Unlock() return nil, ErrPoolClosed } // new item if under limit. if p.conf.Active == 0 || p.active < p.conf.Active { newItem := p.New p.active++ p.mu.Unlock() c, err := newItem(ctx) if err != nil { p.mu.Lock() p.release() p.mu.Unlock() c = nil } return c, err } if p.conf.WaitTimeout == 0 && !p.conf.Wait { p.mu.Unlock() return nil, ErrPoolExhausted } wt := p.conf.WaitTimeout p.mu.Unlock() // slowpath: reset context timeout nctx := ctx cancel := func() {} if wt > 0 { _, nctx, cancel = wt.Shrink(ctx) } select { case <-nctx.Done(): cancel() return nil, nctx.Err() case <-p.cond: } cancel() p.mu.Lock() } } // Put put item into pool. func (p *List) Put(ctx context.Context, c io.Closer, forceClose bool) error { p.mu.Lock() if !p.closed && !forceClose { p.idles.PushFront(item{createdAt: nowFunc(), c: c}) if p.idles.Len() > p.conf.Idle { c = p.idles.Remove(p.idles.Back()).(item).c } else { c = nil } } if c == nil { p.signal() p.mu.Unlock() return nil } p.release() p.mu.Unlock() return c.Close() } // Close releases the resources used by the pool. func (p *List) Close() error { p.mu.Lock() idles := p.idles p.idles.Init() p.closed = true p.active -= idles.Len() p.mu.Unlock() for e := idles.Front(); e != nil; e = e.Next() { e.Value.(item).c.Close() } return nil } // release decrements the active count and signals waiters. The caller must // hold p.mu during the call. func (p *List) release() { p.active-- p.signal() } func (p *List) signal() { select { default: case p.cond <- struct{}{}: } }