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The following code demonstrates the use of .NET asynchronous programming using a simple class that factorizes some numbers.
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();
}
}
See Also
Using Delegates | Compiler and Common Language Runtime Support | Compiler-Supplied Delegate BeginInvoke and EndInvoke Methods