C# 线程无法开启窗口的原因

時間: 2004/4/14作者: Robert參考: MSDN 電郵: zsc771120@yahoo.com.cn關鍵字: 线程 Form 开启 窗口 Show Thread Invoke目的: 幫助受 線程開啟窗口 出錯困擾的人   在 C# 里面, 主窗口拥有主线程, 主线程产生子线程监控 Socket 埠, 子线程一收到数据流就会给主线程发送一个事件, 创建一个窗口. 现在的情况是子线程能够收到数据流, 主窗口能够收到子线程发送过来的事件, 能够创建一个窗口. 这个窗口有问题: 窗口状态像死掉程序的窗口一样, 反白的. 开发碰到很棘手的问题, 寻找解决方法. 品味程序出错过程, 逐步跟踪程序执行过程, 每一行代码每一条语句全部执行, 怪了, 大白天碰到鬼了. 主窗口加入一个按钮, 按钮的作用就是执行主窗口的事件, 启动程序, 点击按钮, 程序正确创建一个窗口, 按照这个测试结果来看, 事件处理中的代码没有任何问题. 在执行程序, 跟踪, 寻找出错的过程. 我觉得程序没有问题, 不应该出现错误; 但是真的出错了, 说明程序一定有问题, 问题是什么呢, 没有答案; 想起以前高人语录: 计算器程序设计就是这么简单, 别管教授专家高手, 写程序出来到计算器上面一跑就知道谁的程序正确, 是骡子是马需要牵出来溜溜. 呀, 找不到答案, 转而上网, 到论坛尽量寻找这种错误相关信息, 时间浪费很多, 结果不是很好, 没有找到答案. 之后和 faust 聊天, 询问这种问题, 他指出一定是讯息回圈和线程之间交互这两个问题中的一个. 顺着 faust 的思路到论坛寻找答案, 很快找到相关讯息. 揭晓最终解决答案, 事件是一个同步处理过程, 就是说虽然子线程触发主窗口事件, 可是执行的线程仍然是子线程, 创建一个窗口 From frm1 = new Form(); Form.Show(); 能够执行, 可是无法收到 Windows Print() 事件, 所以窗口创建没有问题, 就是没有画出窗口上面的东东, 所以窗口像死掉的窗口一样, 反白的. 找到原因怎么处理问题呢? 在线程里面使用 delegateDefine delegateTest = new delegateDefine(this.m_from.eventFunction); this.m_from.Invoke(delegateTest); 就能正常执行程序了. 解决里面最重要的是 Invoke, 如果有兴趣可以看看 Invoke 的介绍. 从问题出现到问题搞定, 花费十个小时, 太辛苦了.     附: 异步委派程序设计范例 下列程序代码示范 .NET 异步程序设计的用法，使用简单类别将一些数字因子分解。 [C#] using System; using System.Threading; using System.Runtime.Remoting; using System.Runtime.Remoting.Messaging;   // Create an asynchronous delegate. public delegate bool FactorizingAsyncDelegate (          int factorizableNum,          ref int primefactor1,          ref int primefactor2);   // Create a class that factorizers the number. public class PrimeFactorizer {    public bool Factorize(                 int factorizableNum,                  ref int primefactor1,                 ref int primefactor2)    {       primefactor1 = 1;       primefactor2 = factorizableNum;         // Factorize using a low-tech approach.       for (int i=2;i<factorizableNum;i++)       {          if (0 == (factorizableNum % i))          {             primefactor1 = i;             primefactor2 = factorizableNum / i;             break;          }       }         if (1 == primefactor1 )          return false;       else          return true   ;    } }   // Class that receives a callback when the results are available. public class ProcessFactorizedNumber {    private int _ulNumber;      public ProcessFactorizedNumber(int number)    {       _ulNumber = number;    }      // Note that the qualifier is one-way.    [OneWayAttribute()]    public void FactorizedResults(IAsyncResult ar)    {       int factor1=0, factor2=0;         // Extract the delegate from the AsyncResult.        FactorizingAsyncDelegate fd = (FactorizingAsyncDelegate)((AsyncResult)ar).AsyncDelegate;         // Obtain the result.       fd.EndInvoke(ref factor1, ref factor2, ar);         // Output the results.       Console.WriteLine("On CallBack: Factors of {0} : {1} {2}",                     _ulNumber, factor1, factor2);    } }   // Class that shows variations of using Asynchronous public class Simple {    // The following demonstrates the Asynchronous Pattern using a callback.    public void FactorizeNumber1()    {       // The following is the client code.       PrimeFactorizer pf = new PrimeFactorizer();       FactorizingAsyncDelegate fd = new FactorizingAsyncDelegate (pf.Factorize);         int factorizableNum = 1000589023, temp=0;         // Create an instance of the class that is going       // to be called when the call completes.       ProcessFactorizedNumber fc = new ProcessFactorizedNumber(factorizableNum);         // Define the AsyncCallback delegate.       AsyncCallback cb = new AsyncCallback(fc.FactorizedResults);         // You can use any object as the state object.       Object state = new Object();         // Asynchronously invoke the Factorize method on pf.       IAsyncResult ar = fd.BeginInvoke(                            factorizableNum,                            ref temp,                            ref temp,                            cb,                            state);         //       // Do some other useful work.       //. . .    }      // The following demonstrates the Asynchronous Pattern using a BeginInvoke, followed by waiting with a time-out.    public void FactorizeNumber2()    {       // The following is the client code.       PrimeFactorizer pf = new PrimeFactorizer();       FactorizingAsyncDelegate fd = new FactorizingAsyncDelegate (pf.Factorize);         int factorizableNum = 1000589023, temp=0;         // Create an instance of the class that is going       // to be called when the call completes.       ProcessFactorizedNumber fc = new ProcessFactorizedNumber(factorizableNum);         // Define the AsyncCallback delegate.       AsyncCallback cb =       new AsyncCallback(fc.FactorizedResults);         // You can use any object as the state object.       Object state = new Object();         // Asynchronously invoke the Factorize method on pf.       IAsyncResult ar = fd.BeginInvoke(                         factorizableNum,                         ref temp,                         ref temp,                         null,                         null);         ar.AsyncWaitHandle.WaitOne(10000, false);         if (ar.IsCompleted)       {          int factor1=0, factor2=0;            // Obtain the result.          fd.EndInvoke(ref factor1, ref factor2, ar);            // Output the results.            Console.WriteLine("Sequential : Factors of {0} : {1} {2}",                        factorizableNum, factor1, factor2);         }    }        public static void Main(String[] args)    {       Simple simple = new Simple();       simple.FactorizeNumber1();       simple.FactorizeNumber2();    } }