线程池在VS2005中似乎没有数量限制, 但是WaitHandle.WaitAll()函数限制64线程. 需要超过的话可以使用嵌套线程.
PS资料:
CodeProject一篇关于线程池数量限制的文章.
Changing the default limit of 25 threads of ThreadPool class
using System;
using System.Threading;
public class Fibonacci
{
public Fibonacci(int n, ManualResetEvent doneEvent)
{
_n = n;
_doneEvent = doneEvent;
}
// 线程池线程启动要调用的函数
public void ThreadPoolCallback(Object threadContext)
{
int threadIndex = (int)threadContext;
Console.WriteLine("thread {0} started...", threadIndex);
_fibOfN = Calculate(_n);
Console.WriteLine("thread {0} result calculated...", threadIndex);
_doneEvent.Set();
}
// 线程计算过程 Recursive method that calculates the Nth Fibonacci number.
public int Calculate(int n)
{
if (n <= 1)
{
return n;
}
return Calculate(n - 1) + Calculate(n - 2);
}
public int N { get { return _n; } }
private int _n;
public int FibOfN { get { return _fibOfN; } }
private int _fibOfN;
private ManualResetEvent _doneEvent;
}
public class ThreadPoolExample
{
static void Main()
{
const int FibonacciCalculations = 64;
// 通知一个或多个正在等待的线程事件已经发生 ManualResetEvent
ManualResetEvent[] doneEvents = new ManualResetEvent[FibonacciCalculations];
Fibonacci[] fibArray = new Fibonacci[FibonacciCalculations];
Random r = new Random();
// 开始使用线程池
Console.WriteLine("launching {0} tasks...", FibonacciCalculations);
for (int i = 0; i < FibonacciCalculations; i++)
{
doneEvents[i] = new ManualResetEvent(false);
Fibonacci f = new Fibonacci(r.Next(20, 40), doneEvents[i]);
fibArray[i] = f;
ThreadPool.QueueUserWorkItem(f.ThreadPoolCallback, i);
}
// 等待线程池中所有计算完成
WaitHandle.WaitAll(doneEvents);
Console.WriteLine("All calculations are complete.");
// Display the results
for (int i = 0; i < FibonacciCalculations; i++)
{
Fibonacci f = fibArray[i];
Console.WriteLine("Fibonacci({0}) = {1}", f.N, f.FibOfN);
}
Console.ReadLine();
}
}
using System.Threading;
public class Fibonacci
{
public Fibonacci(int n, ManualResetEvent doneEvent)
{
_n = n;
_doneEvent = doneEvent;
}
// 线程池线程启动要调用的函数
public void ThreadPoolCallback(Object threadContext)
{
int threadIndex = (int)threadContext;
Console.WriteLine("thread {0} started...", threadIndex);
_fibOfN = Calculate(_n);
Console.WriteLine("thread {0} result calculated...", threadIndex);
_doneEvent.Set();
}
// 线程计算过程 Recursive method that calculates the Nth Fibonacci number.
public int Calculate(int n)
{
if (n <= 1)
{
return n;
}
return Calculate(n - 1) + Calculate(n - 2);
}
public int N { get { return _n; } }
private int _n;
public int FibOfN { get { return _fibOfN; } }
private int _fibOfN;
private ManualResetEvent _doneEvent;
}
public class ThreadPoolExample
{
static void Main()
{
const int FibonacciCalculations = 64;
// 通知一个或多个正在等待的线程事件已经发生 ManualResetEvent
ManualResetEvent[] doneEvents = new ManualResetEvent[FibonacciCalculations];
Fibonacci[] fibArray = new Fibonacci[FibonacciCalculations];
Random r = new Random();
// 开始使用线程池
Console.WriteLine("launching {0} tasks...", FibonacciCalculations);
for (int i = 0; i < FibonacciCalculations; i++)
{
doneEvents[i] = new ManualResetEvent(false);
Fibonacci f = new Fibonacci(r.Next(20, 40), doneEvents[i]);
fibArray[i] = f;
ThreadPool.QueueUserWorkItem(f.ThreadPoolCallback, i);
}
// 等待线程池中所有计算完成
WaitHandle.WaitAll(doneEvents);
Console.WriteLine("All calculations are complete.");
// Display the results
for (int i = 0; i < FibonacciCalculations; i++)
{
Fibonacci f = fibArray[i];
Console.WriteLine("Fibonacci({0}) = {1}", f.N, f.FibOfN);
}
Console.ReadLine();
}
}