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相对于传统多线程模型、状态机模型、类PLC模型,逻辑结构紧凑清晰,开发效率极高,易于维护升级;
在golang语言的编程模式上设计开发,且进行必要的功能扩展;
自定义单/多线程调度,亦可主UI线程调度,方便逻辑与UI的交互;
自带高精度定时器、调度优先级、逻辑停止、逻辑暂停功能;
树形多任务调度,提高逻辑的可靠性;
单线程调度每秒100万次以上,从容应对千级IO点数;
已在多个项目中使用,稳定可靠。
using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
using System.Threading.Tasks;
using Go;
namespace WorkerFlow
{
class Program
{
static shared_strand strand;
static void Log(string msg)
{
Console.WriteLine($"{DateTime.Now.ToString("HH:mm:ss.fff")} {msg}");
}
static async Task Worker(string name, int time = 1000)
{
await generator.sleep(time);
Log(name);
}
//1 A、B、C依次串行
//A->B->C
static async Task Worker1()
{
await Worker("A");
await Worker("B");
await Worker("C");
}
//2 A、B、C全部并行,且依赖同一个strand(隐含参数,所有依赖同一个strand的任务都是线程安全的)
//A
//B
//C
static async Task Worker2()
{
generator.children children = new generator.children();
children.go(() => Worker("A"));
children.go(() => Worker("B"));
children.go(() => Worker("C"));
await children.wait_all();
}
//3 A执行完后,B、C再并行
// -->B
// |
//A->
// |
// -->C
static async Task Worker3()
{
await Worker("A");
generator.children children = new generator.children();
children.go(() => Worker("B"));
children.go(() => Worker("C"));
await children.wait_all();
}
//4 B、C都并行执行完后,再执行A
//B--
// |
// -->A
// |
//C--
static async Task Worker4()
{
generator.children children = new generator.children();
children.go(() => Worker("B"));
children.go(() => Worker("C"));
await children.wait_all();
await Worker("A");
}
//5 B、C任意一个执行完后,再执行A
//B--
// |
// >-->A
// |
//C--
static async Task Worker5()
{
generator.children children = new generator.children();
var B = children.tgo(() => Worker("B", 1000));
var C = children.tgo(() => Worker("C", 2000));
var task = await children.wait_any();
if (task == B)
{
Log("B成功");
}
else
{
Log("C成功");
}
await Worker("A");
}
//6 等待一个特定任务
static async Task Worker6()
{
generator.children children = new generator.children();
var A = children.tgo(() => Worker("A"));
var B = children.tgo(() => Worker("B"));
await children.wait(A);
}
//7 超时等待一个特定任务,然后中止所有任务
static async Task Worker7()
{
generator.children children = new generator.children();
var A = children.tgo(() => Worker("A", 1000));
var B = children.tgo(() => Worker("B", 2000));
if (await children.timed_wait(1500, A))
{
Log("成功");
}
else
{
Log("超时");
}
await children.stop();
}
//8 超时等待一组任务,然后中止所有任务
static async Task Worker8()
{
generator.children children = new generator.children();
children.go(() => Worker("A", 1000));
children.go(() => Worker("B", 2000));
var tasks = await children.timed_wait_all(1500);
await children.stop();
Log($"成功{tasks.Count}个");
}
//9 超时等待一组任务,然后中止所有任务,且在中止任务中就地善后处理
static async Task Worker9()
{
generator.children children = new generator.children();
children.go(() => Worker("A", 1000));
children.go(async delegate ()
{
try
{
await Worker("B", 2000);
}
catch (generator.stop_exception)
{
Log("B被中止");
await generator.sleep(500);
throw;
}
catch (System.Exception)
{
}
});
var task = await children.timed_wait_all(1500);
await children.stop();
Log($"成功{task.Count}个");
}
//10 嵌套任务
static async Task Worker10()
{
generator.children children = new generator.children();
children.go(async delegate ()
{
generator.children children1 = new generator.children();
children1.go(() => Worker("A"));
children1.go(() => Worker("B"));
await children1.wait_all();
});
children.go(async delegate ()
{
generator.children children1 = new generator.children();
children1.go(() => Worker("C"));
children1.go(() => Worker("D"));
await children1.wait_all();
});
await children.wait_all();
}
//11 嵌套中止
static async Task Worker11()
{
generator.children children = new generator.children();
children.go(() => Worker("A", 1000));
children.go(async delegate ()
{
try
{
generator.children children1 = new generator.children();
children1.go(async delegate ()
{
try
{
await Worker("B", 2000);
}
catch (generator.stop_exception)
{
Log("B被中止1");
await generator.sleep(500);
throw;
}
catch (System.Exception)
{
}
});
await children1.wait_all();
}
catch (generator.stop_exception)
{
Log("B被中止2");
throw;
}
catch (System.Exception)
{
}
});
await generator.sleep(1500);
await children.stop();
}
//12 并行执行且等待一组耗时算法
static async Task Worker12()
{
wait_group wg = new wait_group();
for (int i = 0; i < 2; i++)
{
wg.add();
int idx = i;
var _ = Task.Run(delegate ()
{
try
{
Log($"执行算法{idx}");
}
finally
{
wg.done();
}
});
}
await wg.wait();
Log("执行算法完成");
}
//13 串行执行耗时算法,耗时算法必需放在线程池中执行,否则依赖同一个strand的调度将不能及时
static async Task Worker13()
{
for (int i = 0; i < 2; i++)
{
await generator.send_task(() => Log($"执行算法{i}"));
}
}
static async Task MainWorker()
{
await Worker1();
await Worker2();
await Worker3();
await Worker4();
await Worker5();
await Worker6();
await Worker7();
await Worker8();
await Worker9();
await Worker10();
await Worker11();
await Worker12();
await Worker13();
}
static void Main(string[] args)
{
work_service work = new work_service();
strand = new work_strand(work);
generator.go(strand, MainWorker);
work.run();
Console.ReadKey();
}
}
}