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golang常见的几种并发模型框架

时间:2019-07-18 13:31:20      阅读:144      评论:0      收藏:0      [点我收藏+]

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原文链接

package main
 
import (
	"fmt"
	"math/rand"
	"os"
	"runtime"
	"sync"
	"sync/atomic"
	"time"
)
 
type Scenario struct {
	Name        string
	Description []string
	Examples    []string
	RunExample  func()
}
var s1 = &Scenario{
	Name: "s1",
	Description: []string{
		"简单并发执行任务",
	},
	Examples: []string{
		"比如并发的请求后端某个接口",
	},
	RunExample: RunScenario1,
}
 
var s2 = &Scenario{
	Name: "s2",
	Description: []string{
		"持续一定时间的高并发模型",
	},
	Examples: []string{
		"在规定时间内,持续的高并发请求后端服务, 防止服务死循环",
	},
	RunExample: RunScenario2,
}
 
var s3 = &Scenario{
	Name: "s3",
	Description: []string{
		"基于大数据量的并发任务模型, goroutine worker pool",
	},
	Examples: []string{
		"比如技术支持要给某个客户删除几个TB/GB的文件",
	},
	RunExample: RunScenario3,
}
 
var s4 = &Scenario{
	Name: "s4",
	Description: []string{
		"等待异步任务执行结果(goroutine+select+channel)",
	},
	Examples: []string{
		"",
	},
	RunExample: RunScenario4,
}
 
var s5 = &Scenario{
	Name: "s5",
	Description: []string{
		"定时的反馈结果(Ticker)",
	},
	Examples: []string{
		"比如测试上传接口的性能,要实时给出指标: 吞吐率,IOPS,成功率等",
	},
	RunExample: RunScenario5,
}
 
var Scenarios []*Scenario
 
func init() {
	Scenarios = append(Scenarios, s1)
	Scenarios = append(Scenarios, s2)
	Scenarios = append(Scenarios, s3)
	Scenarios = append(Scenarios, s4)
	Scenarios = append(Scenarios, s5)
}
 
// 常用的并发与同步场景
func main() {
	if len(os.Args) == 1 {
		fmt.Println("请选择使用场景 ==> ")
		for _, sc := range Scenarios {
			fmt.Printf("场景: %s ,", sc.Name)
			printDescription(sc.Description)
		}
		return
	}
	for _, arg := range os.Args[1:] {
		sc := matchScenario(arg)
		if sc != nil {
			printDescription(sc.Description)
			printExamples(sc.Examples)
			sc.RunExample()
		}
	}
}
 
func printDescription(str []string) {
	fmt.Printf("场景描述: %s \n", str)
}
 
func printExamples(str []string) {
	fmt.Printf("场景举例: %s \n", str)
}
 
func matchScenario(name string) *Scenario {
	for _, sc := range Scenarios {
		if sc.Name == name {
			return sc
		}
	}
	return nil
}
 
var doSomething = func(i int) string {
	time.Sleep(time.Millisecond * time.Duration(10))
	fmt.Printf("Goroutine %d do things .... \n", i)
	return fmt.Sprintf("Goroutine %d", i)
}
 
var takeSomthing = func(res string) string {
	time.Sleep(time.Millisecond * time.Duration(10))
	tmp := fmt.Sprintf("Take result from %s.... \n", res)
	fmt.Println(tmp)
	return tmp
}
 
// 场景1: 简单并发任务
 
func RunScenario1() {
	count := 10
	var wg sync.WaitGroup
 
	for i := 0; i < count; i++ {
		wg.Add(1)
		go func(index int) {
			defer wg.Done()
			doSomething(index)
		}(i)
	}
 
	wg.Wait()
}
 
// 场景2: 按时间来持续并发
 
func RunScenario2() {
	timeout := time.Now().Add(time.Second * time.Duration(10))
	n := runtime.NumCPU()
 
	waitForAll := make(chan struct{})
	done := make(chan struct{})
	concurrentCount := make(chan struct{}, n)
 
	for i := 0; i < n; i++ {
		concurrentCount <- struct{}{}
	}
 
	go func() {
		for time.Now().Before(timeout) {
			<-done
			concurrentCount <- struct{}{}
		}
 
		waitForAll <- struct{}{}
	}()
 
	go func() {
		for {
			<-concurrentCount
			go func() {
				doSomething(rand.Intn(n))
				done <- struct{}{}
			}()
		}
	}()
 
	<-waitForAll
}
 
// 场景3:以 worker pool 方式 并发做事/发送请求
 
func RunScenario3() {
	numOfConcurrency := runtime.NumCPU()
	taskTool := 10
	jobs := make(chan int, taskTool)
	results := make(chan int, taskTool)
	var wg sync.WaitGroup
 
	// workExample
	workExampleFunc := func(id int, jobs <-chan int, results chan<- int, wg *sync.WaitGroup) {
		defer wg.Done()
		for job := range jobs {
			res := job * 2
			fmt.Printf("Worker %d do things, produce result %d \n", id, res)
			time.Sleep(time.Millisecond * time.Duration(100))
			results <- res
		}
	}
 
	for i := 0; i < numOfConcurrency; i++ {
		wg.Add(1)
		go workExampleFunc(i, jobs, results, &wg)
	}
	totalTasks := 100
 
	wg.Add(1)
	go func() {
		defer wg.Done()
		for i := 0; i < totalTasks; i++ {
			n := <-results
			fmt.Printf("Got results %d \n", n)
		}
		close(results)
	}()
 
	for i := 0; i < totalTasks; i++ {
		jobs <- i
	}
	close(jobs)
	wg.Wait()
}
 
// 场景4: 等待异步任务执行结果(goroutine+select+channel)
 
func RunScenario4() {
	sth := make(chan string)
	result := make(chan string)
	go func() {
		id := rand.Intn(100)
		for {
			sth <- doSomething(id)
		}
	}()
	go func() {
		for {
			result <- takeSomthing(<-sth)
		}
	}()
 
	select {
	case c := <-result:
		fmt.Printf("Got result %s ", c)
	case <-time.After(time.Duration(30 * time.Second)):
		fmt.Errorf("指定时间内都没有得到结果")
	}
}
 
var doUploadMock = func() bool {
	time.Sleep(time.Millisecond * time.Duration(100))
	n := rand.Intn(100)
	if n > 50 {
		return true
	} else {
		return false
	}
}
 
// 场景5: 定时的反馈结果(Ticker)
// 测试上传接口的性能,要实时给出指标: 吞吐率,成功率等
 
func RunScenario5() {
	totalSize := int64(0)
	totalCount := int64(0)
	totalErr := int64(0)
 
	concurrencyCount := runtime.NumCPU()
	stop := make(chan struct{})
	fileSizeExample := int64(10)
 
	timeout := 10 // seconds to stop
 
	go func() {
		for i := 0; i < concurrencyCount; i++ {
			go func(index int) {
				for {
					select {
					case <-stop:
						return
					default:
						break
					}
 
					res := doUploadMock()
					if res {
						atomic.AddInt64(&totalCount, 1)
						atomic.AddInt64(&totalSize, fileSizeExample)
					} else {
						atomic.AddInt64(&totalErr, 1)
					}
				}
			}(i)
		}
	}()
 
	t := time.NewTicker(time.Second)
	index := 0
	for {
		select {
		case <-t.C:
			index++
			tmpCount := atomic.LoadInt64(&totalCount)
			tmpSize := atomic.LoadInt64(&totalSize)
			tmpErr := atomic.LoadInt64(&totalErr)
			fmt.Printf("吞吐率: %d,成功率: %d \n", tmpSize/int64(index), tmpCount*100/(tmpCount+tmpErr))
			if index > timeout {
				t.Stop()
				close(stop)
				return
			}
		}
 
	}
}

  

 

golang常见的几种并发模型框架

标签:后端   second   成功   add   file   def   tin   定时   lang   

原文地址:https://www.cnblogs.com/-wenli/p/11206506.html

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