doc/articles/concurrency_patterns.html - go - Git at Google

 <!--{
 "Title": "Go Concurrency Patterns: Timing out, moving on",
 "Template": true
 }-->

 <p>
 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 <code>ch</code>, 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:
 </p>

 {{code "/doc/progs/timeout1.go" `/timeout :=/` `/STOP/`}}

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

 {{code "/doc/progs/timeout1.go" `/select {/` `/STOP/`}}

 <p>
 The <code>timeout</code> 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 <code>ch</code> receive happens before the
 timeout is reached. The <code>timeout</code> channel will eventually be
 deallocated by the garbage collector.
 </p>

 <p>
 (In this example we used <code>time.Sleep</code> to demonstrate the mechanics
 of goroutines and channels. In real programs you should use <code>
 <a href="/pkg/time/#After">time.After</a></code>, a function that returns
 a channel and sends on that channel after the specified duration.)
 </p>

 <p>
 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.
 </p>

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

 {{code "/doc/progs/timeout2.go" `/func Query/` `/STOP/`}}

 <p>
 In this example, the closure does a non-blocking send, which it achieves by
 using the send operation in <code>select</code> statement with a
 <code>default</code> 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.
 </p>

 <p>
 This problem is a textbook example of what is known as a
 <a href="https://en.wikipedia.org/wiki/Race_condition">race condition</a>, but
 the fix is trivial. We just make sure to buffer the channel <code>ch</code> (by
 adding the buffer length as the second argument to <a href="/pkg/builtin/#make">make</a>),
 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.
 </p>

 <p>
 These two examples demonstrate the simplicity with which Go can express complex
 interactions between goroutines.
 </p>
	<!--{
	"Title": "Go Concurrency Patterns: Timing out, moving on",
	"Template": true
	}-->

	<p>
	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 <code>ch</code>, 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:
	</p>

	{{code "/doc/progs/timeout1.go" `/timeout :=/` `/STOP/`}}

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

	{{code "/doc/progs/timeout1.go" `/select {/` `/STOP/`}}

	<p>
	The <code>timeout</code> 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 <code>ch</code> receive happens before the
	timeout is reached. The <code>timeout</code> channel will eventually be
	deallocated by the garbage collector.
	</p>

	<p>
	(In this example we used <code>time.Sleep</code> to demonstrate the mechanics
	of goroutines and channels. In real programs you should use <code>
	<a href="/pkg/time/#After">time.After</a></code>, a function that returns
	a channel and sends on that channel after the specified duration.)
	</p>

	<p>
	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.
	</p>

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

	{{code "/doc/progs/timeout2.go" `/func Query/` `/STOP/`}}

	<p>
	In this example, the closure does a non-blocking send, which it achieves by
	using the send operation in <code>select</code> statement with a
	<code>default</code> 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.
	</p>

	<p>
	This problem is a textbook example of what is known as a
	<a href="https://en.wikipedia.org/wiki/Race_condition">race condition</a>, but
	the fix is trivial. We just make sure to buffer the channel <code>ch</code> (by
	adding the buffer length as the second argument to <a href="/pkg/builtin/#make">make</a>),
	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.
	</p>

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