davidsnt · August 30, 2017 18:24
diff --git a/statefulroutines.go b/statefulroutines.go
 package main

 import (
 	"fmt"
 	"math/rand"
 	"sync/atomic"
 	"time"
 )

 // In this example our state will be owned by a single
 // goroutine. This will guarantee that the data is never
 // corrupted with concurrent access. In order to read or
 // write that state, other goroutines will send messages
 // to the owning goroutine and receive corresponding
 // replies. These `readOp` and `writeOp` `struct`s
 // encapsulate those requests and a way for the owning
 // goroutine to respond.
 type readOp struct {
 	key  int
 	resp chan int
 }
 type writeOp struct {
 	key  int
 	val  int
 	resp chan bool
 }

 func main() {

 	// As before we'll count how many operations we perform.
 	var readOps uint64 = 0
 	var writeOps uint64 = 0

 	// The `reads` and `writes` channels will be used by
 	// other goroutines to issue read and write requests,
 	// respectively.
 	reads := make(chan *readOp)
 	writes := make(chan *writeOp)

 	// Here is the goroutine that owns the `state`, which
 	// is a map as in the previous example but now private
 	// to the stateful goroutine. This goroutine repeatedly
 	// selects on the `reads` and `writes` channels,
 	// responding to requests as they arrive. A response
 	// is executed by first performing the requested
 	// operation and then sending a value on the response
 	// channel `resp` to indicate success (and the desired
 	// value in the case of `reads`).
 	go func() {
 		var state = make(map[int]int)
 		for {
 			select {
 			case read := <-reads:
 				read.resp <- state[read.key]
 			case write := <-writes:
 				state[write.key] = write.val
 				write.resp <- true
 			}
 		}
 	}()

 	// This starts 100 goroutines to issue reads to the
 	// state-owning goroutine via the `reads` channel.
 	// Each read requires constructing a `readOp`, sending
 	// it over the `reads` channel, and the receiving the
 	// result over the provided `resp` channel.
 	for r := 0; r < 100; r++ {
 		go func() {
 			for {
 				read := &readOp{
 					key:  rand.Intn(5),
 					resp: make(chan int)}
 				reads <- read
 				//writes the `readOp{}` to the `reads` channel.
 				<-read.resp
 				atomic.AddUint64(&readOps, 1)
 				time.Sleep(time.Millisecond)
 			}
 		}()
 	}

 	// We start 10 writes as well, using a similar
 	// approach.
 	for w := 0; w < 10; w++ {
 		go func() {
 			for {
 				write := &writeOp{
 					key:  rand.Intn(5),
 					val:  rand.Intn(100),
 					resp: make(chan bool)}
 				writes <- write
 				//waits for something to exist in the `write.resp` channel, it then reads it and immediately discards it. You could save it with `x := <-write.resp`.
 				<-write.resp
 				atomic.AddUint64(&writeOps, 1)
 				time.Sleep(time.Millisecond)
 			}
 		}()
 	}

 	// Let the goroutines work for a second.
 	time.Sleep(time.Second)

 	// Finally, capture and report the op counts.
 	readOpsFinal := atomic.LoadUint64(&readOps)
 	fmt.Println("readOps:", readOpsFinal)
 	writeOpsFinal := atomic.LoadUint64(&writeOps)
 	fmt.Println("writeOps:", writeOpsFinal)
 }
	package main

	import (
	"fmt"
	"math/rand"
	"sync/atomic"
	"time"
	)

	// In this example our state will be owned by a single
	// goroutine. This will guarantee that the data is never
	// corrupted with concurrent access. In order to read or
	// write that state, other goroutines will send messages
	// to the owning goroutine and receive corresponding
	// replies. These `readOp` and `writeOp` `struct`s
	// encapsulate those requests and a way for the owning
	// goroutine to respond.
	type readOp struct {
	key int
	resp chan int
	}
	type writeOp struct {
	key int
	val int
	resp chan bool
	}

	func main() {

	// As before we'll count how many operations we perform.
	var readOps uint64 = 0
	var writeOps uint64 = 0

	// The `reads` and `writes` channels will be used by
	// other goroutines to issue read and write requests,
	// respectively.
	reads := make(chan *readOp)
	writes := make(chan *writeOp)

	// Here is the goroutine that owns the `state`, which
	// is a map as in the previous example but now private
	// to the stateful goroutine. This goroutine repeatedly
	// selects on the `reads` and `writes` channels,
	// responding to requests as they arrive. A response
	// is executed by first performing the requested
	// operation and then sending a value on the response
	// channel `resp` to indicate success (and the desired
	// value in the case of `reads`).
	go func() {
	var state = make(map[int]int)
	for {
	select {
	case read := <-reads:
	read.resp <- state[read.key]
	case write := <-writes:
	state[write.key] = write.val
	write.resp <- true
	}
	}
	}()

	// This starts 100 goroutines to issue reads to the
	// state-owning goroutine via the `reads` channel.
	// Each read requires constructing a `readOp`, sending
	// it over the `reads` channel, and the receiving the
	// result over the provided `resp` channel.
	for r := 0; r < 100; r++ {
	go func() {
	for {
	read := &readOp{
	key: rand.Intn(5),
	resp: make(chan int)}
	reads <- read
	//writes the `readOp{}` to the `reads` channel.
	<-read.resp
	atomic.AddUint64(&readOps, 1)
	time.Sleep(time.Millisecond)
	}
	}()
	}

	// We start 10 writes as well, using a similar
	// approach.
	for w := 0; w < 10; w++ {
	go func() {
	for {
	write := &writeOp{
	key: rand.Intn(5),
	val: rand.Intn(100),
	resp: make(chan bool)}
	writes <- write
	//waits for something to exist in the `write.resp` channel, it then reads it and immediately discards it. You could save it with `x := <-write.resp`.
	<-write.resp
	atomic.AddUint64(&writeOps, 1)
	time.Sleep(time.Millisecond)
	}
	}()
	}

	// Let the goroutines work for a second.
	time.Sleep(time.Second)

	// Finally, capture and report the op counts.
	readOpsFinal := atomic.LoadUint64(&readOps)
	fmt.Println("readOps:", readOpsFinal)
	writeOpsFinal := atomic.LoadUint64(&writeOps)
	fmt.Println("writeOps:", writeOpsFinal)
	}