Go Concurrency Patterns: Timing out, moving on

來源:互聯網
上載者:User
這是一個建立於 的文章,其中的資訊可能已經有所發展或是發生改變。

Go Concurrency Patterns: Timing out, moving on


Concurrent programming has its own idioms. A good example is timeouts. Although Go's channels do not support them directly, they are easy to implement. Say we want to receive from the channel ch, but want to wait at most one second for the value to arrive. We would start by creating a signalling channel and launching a goroutine that sleeps before sending on the channel:

timeout := make(chan bool, 1)go func() {    time.Sleep(1 * time.Second)    timeout <- true}()

We can then use a select statement to receive from either ch or timeout. If nothing arrives on ch after one second, the timeout case is selected and the attempt to read from ch is abandoned.

select {case <-ch:    // a read from ch has occurredcase <-timeout:    // the read from ch has timed out}

The timeout channel is buffered with space for 1 value, allowing the timeout goroutine to send to the channel and then exit. The goroutine doesn't know (or care) whether the value is received. This means the goroutine won't hang around forever if the chreceive happens before the timeout is reached. The timeout channel will eventually be deallocated by the garbage collector.

(In this example we used time.Sleep to demonstrate the mechanics of goroutines and channels. In real programs you should use ` time.After`, a function that returns a channel and sends on that channel after the specified duration.)

Let's look at another variation of this pattern. In this example we have a program that reads from multiple replicated databases simultaneously. The program needs only one of the answers, and it should accept the answer that arrives first.

The function Query takes a slice of database connections and a query string. It queries each of the databases in parallel and returns the first response it receives:

func Query(conns []Conn, query string) Result {    ch := make(chan Result, 1)    for _, conn := range conns {        go func(c Conn) {            select {            case ch <- c.DoQuery(query):            default:            }        }(conn)    }    return <-ch}

In this example, the closure does a non-blocking send, which it achieves by using the send operation in select statement with a default case. If the send cannot go through immediately the default case will be selected. Making the send non-blocking guarantees that none of the goroutines launched in the loop will hang around. However, if the result arrives before the main function has made it to the receive, the send could fail since no one is ready.

This problem is a textbook example of what is known as a race condition, but the fix is trivial. We just make sure to buffer the channel ch (by adding the buffer length as the second argument to make), guaranteeing that the first send has a place to put the value. This ensures the send will always succeed, and the first value to arrive will be retrieved regardless of the order of execution.

These two examples demonstrate the simplicity with which Go can express complex interactions between goroutines.

By Andrew Gerrand

來自牆外:

http://blog.golang.org/go-concurrency-patterns-timing-out-and

相關文章

聯繫我們

該頁面正文內容均來源於網絡整理,並不代表阿里雲官方的觀點,該頁面所提到的產品和服務也與阿里云無關,如果該頁面內容對您造成了困擾,歡迎寫郵件給我們,收到郵件我們將在5個工作日內處理。

如果您發現本社區中有涉嫌抄襲的內容,歡迎發送郵件至: info-contact@alibabacloud.com 進行舉報並提供相關證據,工作人員會在 5 個工作天內聯絡您,一經查實,本站將立刻刪除涉嫌侵權內容。

A Free Trial That Lets You Build Big!

Start building with 50+ products and up to 12 months usage for Elastic Compute Service

  • Sales Support

    1 on 1 presale consultation

  • After-Sales Support

    24/7 Technical Support 6 Free Tickets per Quarter Faster Response

  • Alibaba Cloud offers highly flexible support services tailored to meet your exact needs.