content/pipelines/sqbuffer.go - blog - Git at Google

 // +build OMIT

 package main

 import (
 	"fmt"
 	"sync"
 )

 // gen sends the values in nums on the returned channel, then closes it.
 func gen(nums ...int) <-chan int {
 	out := make(chan int, len(nums))
 	for _, n := range nums {
 		out <- n
 	}
 	close(out)
 	return out
 }

 // sq receives values from in, squares them, and sends them on the returned
 // channel, until in is closed.  Then sq closes the returned channel.
 func sq(in <-chan int) <-chan int {
 	out := make(chan int)
 	go func() {
 		for n := range in {
 			out <- n * n
 		}
 		close(out)
 	}()
 	return out
 }

 // merge receives values from each input channel and sends them on the returned
 // channel.  merge closes the returned channel after all the input values have
 // been sent.
 func merge(cs ...<-chan int) <-chan int {
 	var wg sync.WaitGroup
 	out := make(chan int, 1) // enough space for the unread inputs
 	// ... the rest is unchanged ...

 	// Start an output goroutine for each input channel in cs.  output
 	// copies values from c to out until c is closed, then calls wg.Done.
 	output := func(c <-chan int) {
 		for n := range c {
 			out <- n
 		}
 		wg.Done()
 	}
 	wg.Add(len(cs))
 	for _, c := range cs {
 		go output(c)
 	}

 	// Start a goroutine to close out once all the output goroutines are
 	// done.  This must start after the wg.Add call.
 	go func() {
 		wg.Wait()
 		close(out)
 	}()
 	return out
 }

 func main() {
 	in := gen(2, 3)

 	// Distribute the sq work across two goroutines that both read from in.
 	c1 := sq(in)
 	c2 := sq(in)

 	// Consume the first value from output.
 	out := merge(c1, c2)
 	fmt.Println(<-out) // 4 or 9
 	return
 	// The second value is sent into out's buffer, and all goroutines exit.
 }
	// +build OMIT

	package main

	import (
	"fmt"
	"sync"
	)

	// gen sends the values in nums on the returned channel, then closes it.
	func gen(nums ...int) <-chan int {
	out := make(chan int, len(nums))
	for _, n := range nums {
	out <- n
	}
	close(out)
	return out
	}

	// sq receives values from in, squares them, and sends them on the returned
	// channel, until in is closed. Then sq closes the returned channel.
	func sq(in <-chan int) <-chan int {
	out := make(chan int)
	go func() {
	for n := range in {
	out <- n * n
	}
	close(out)
	}()
	return out
	}

	// merge receives values from each input channel and sends them on the returned
	// channel. merge closes the returned channel after all the input values have
	// been sent.
	func merge(cs ...<-chan int) <-chan int {
	var wg sync.WaitGroup
	out := make(chan int, 1) // enough space for the unread inputs
	// ... the rest is unchanged ...

	// Start an output goroutine for each input channel in cs. output
	// copies values from c to out until c is closed, then calls wg.Done.
	output := func(c <-chan int) {
	for n := range c {
	out <- n
	}
	wg.Done()
	}
	wg.Add(len(cs))
	for _, c := range cs {
	go output(c)
	}

	// Start a goroutine to close out once all the output goroutines are
	// done. This must start after the wg.Add call.
	go func() {
	wg.Wait()
	close(out)
	}()
	return out
	}

	func main() {
	in := gen(2, 3)

	// Distribute the sq work across two goroutines that both read from in.
	c1 := sq(in)
	c2 := sq(in)

	// Consume the first value from output.
	out := merge(c1, c2)
	fmt.Println(<-out) // 4 or 9
	return
	// The second value is sent into out's buffer, and all goroutines exit.
	}