Parallel.Invoke
并行执行多个方法,只有在所有方法都执行后才会返回
static void Main(string[] args)
{
Parallel.Invoke(
() => ConvertEllipses(),
() => ConvertRectangles(),
() => ConvertLines(),
() => ConvertText());
System.Console.ReadLine();
}
static void ConvertEllipses()
{
System.Console.WriteLine("Ellipses converted.");
}
static void ConvertRectangles()
{
System.Console.WriteLine("Rectangles converted.");
}
static void ConvertLines()
{
System.Console.WriteLine("Lines converted.");
}
static void ConvertText()
{
System.Console.WriteLine("Text converted.");
}
{
Parallel.Invoke(
() => ConvertEllipses(),
() => ConvertRectangles(),
() => ConvertLines(),
() => ConvertText());
System.Console.ReadLine();
}
static void ConvertEllipses()
{
System.Console.WriteLine("Ellipses converted.");
}
static void ConvertRectangles()
{
System.Console.WriteLine("Rectangles converted.");
}
static void ConvertLines()
{
System.Console.WriteLine("Lines converted.");
}
static void ConvertText()
{
System.Console.WriteLine("Text converted.");
}
先给两段基本代码,方便后面理解。将Byte[]转成16进制表示的字符串private static string ConvertToHexString(Byte[] byteArray)
{
// Convert the byte array to hexadecimal string
var sb = new StringBuilder(byteArray.Length);
for (int i = 0; i < byteArray.Length; i++)
{
sb.Append(byteArray[i].ToString("X2"));
}
return sb.ToString();
}
{
// Convert the byte array to hexadecimal string
var sb = new StringBuilder(byteArray.Length);
for (int i = 0; i < byteArray.Length; i++)
{
sb.Append(byteArray[i].ToString("X2"));
}
return sb.ToString();
}
生成一些AES的Key,并计时
AesManaged在System.Security.Cryptography
Stopwatch和Debug在System.Diagnostics
private const int NUM_MD5_HASHES = 100000;
private static void GenerateAESKeys()
{
var sw = Stopwatch.StartNew();
var aesM = new AesManaged();
for (int i = 1; i <= NUM_AES_KEYS; i++)
{
aesM.GenerateKey();
byte[] result = aesM.Key;
string hexString = ConvertToHexString(result);
// Console.WriteLine("AES KEY: {0} ", hexString);
}
Debug.WriteLine("AES: " + sw.Elapsed.ToString());
}
Stopwatch和Debug在System.Diagnostics
private const int NUM_MD5_HASHES = 100000;
private static void GenerateAESKeys()
{
var sw = Stopwatch.StartNew();
var aesM = new AesManaged();
for (int i = 1; i <= NUM_AES_KEYS; i++)
{
aesM.GenerateKey();
byte[] result = aesM.Key;
string hexString = ConvertToHexString(result);
// Console.WriteLine("AES KEY: {0} ", hexString);
}
Debug.WriteLine("AES: " + sw.Elapsed.ToString());
}
Parallel.For
不支持浮点数和进步。无法保证迭代执行的顺序private static void ParallelGenerateAESKeys()
{
var sw = Stopwatch.StartNew();
Parallel.For(1, NUM_AES_KEYS + 1, (int i) =>
{
var aesM = new AesManaged();
byte[] result = aesM.Key;
string hexString = ConvertToHexString(result);
// Console.WriteLine(“AES KEY: {0} “, hexString);
});
Debug.WriteLine("AES: " + sw.Elapsed.ToString());
}
{
var sw = Stopwatch.StartNew();
Parallel.For(1, NUM_AES_KEYS + 1, (int i) =>
{
var aesM = new AesManaged();
byte[] result = aesM.Key;
string hexString = ConvertToHexString(result);
// Console.WriteLine(“AES KEY: {0} “, hexString);
});
Debug.WriteLine("AES: " + sw.Elapsed.ToString());
}
Parallel.ForEach
利用一个范围整数作为一组数据,通过一个分区器,把数据分成一组数据块。每一块的数据都通过循环的方式处理,而这些循环都是并行的。
private static void ParallelPartitionGenerateAESKeys()
{
var sw = Stopwatch.StartNew();
Parallel.ForEach(Partitioner.Create(1, NUM_AES_KEYS + 1), range =>
{
var aesM = new AesManaged();
Debug.WriteLine(
"AES Range ({0}, {1}. TimeOfDay before inner loop starts: {2})",
range.Item1, range.Item2,
DateTime.Now.TimeOfDay);
for (int i = range.Item1; i < range.Item2; i++)
{
aesM.GenerateKey();
byte[] result = aesM.Key;
string hexString = ConvertToHexString(result);
// Console.WriteLine(“AES KEY: {0} “, hexString);
}
});
Debug.WriteLine("AES: " + sw.Elapsed.ToString());
}
{
var sw = Stopwatch.StartNew();
Parallel.ForEach(Partitioner.Create(1, NUM_AES_KEYS + 1), range =>
{
var aesM = new AesManaged();
Debug.WriteLine(
"AES Range ({0}, {1}. TimeOfDay before inner loop starts: {2})",
range.Item1, range.Item2,
DateTime.Now.TimeOfDay);
for (int i = range.Item1; i < range.Item2; i++)
{
aesM.GenerateKey();
byte[] result = aesM.Key;
string hexString = ConvertToHexString(result);
// Console.WriteLine(“AES KEY: {0} “, hexString);
}
});
Debug.WriteLine("AES: " + sw.Elapsed.ToString());
}
根据内核数目优化分区
Parallel.ForEach(
Partitioner.Create(1,NUM_AES_KEYS,((int)(NUM_AES_KEYS / Environment.ProcessorCount) + 1)),
range =>
{
//...
});
Partitioner.Create(1,NUM_AES_KEYS,((int)(NUM_AES_KEYS / Environment.ProcessorCount) + 1)),
range =>
{
//...
});
使用IEnumerable数据源
private const int NUM_MD5_HASHES = 100000;
private static IEnumerable<int> GenerateMD5InputData()
{
return Enumerable.Range(1, NUM_MD5_HASHES);
}
private static void ParallelForEachGenerateMD5Hashes()
{
var sw = Stopwatch.StartNew();
var inputData = GenerateMD5InputData();
Parallel.ForEach(inputData, (int number) =>
{
var md5M = MD5.Create();
byte[] data =
Encoding.Unicode.GetBytes(
Environment.UserName + number.ToString());
byte[] result = md5M.ComputeHash(data);
string hexString = ConvertToHexString(result);
// Console.WriteLine("MD5 HASH: {0}", hexString);
});
Debug.WriteLine("MD5: " + sw.Elapsed.ToString());
}
private static IEnumerable<int> GenerateMD5InputData()
{
return Enumerable.Range(1, NUM_MD5_HASHES);
}
private static void ParallelForEachGenerateMD5Hashes()
{
var sw = Stopwatch.StartNew();
var inputData = GenerateMD5InputData();
Parallel.ForEach(inputData, (int number) =>
{
var md5M = MD5.Create();
byte[] data =
Encoding.Unicode.GetBytes(
Environment.UserName + number.ToString());
byte[] result = md5M.ComputeHash(data);
string hexString = ConvertToHexString(result);
// Console.WriteLine("MD5 HASH: {0}", hexString);
});
Debug.WriteLine("MD5: " + sw.Elapsed.ToString());
}
从并行循环中退出
在参数中使用ParallelLoopState,就可以使用loopState.Break();或者loopState.Stop();进行退出。其中的差别在于,假设调用Break的时候正在处理迭代100,那么可以保证小于100的迭代都被执行,而Stop不保证这个。
ParallelLoopResult作为返回值,可以知道是否是正常完成或者被Break的
ParallelLoopResult loopResult = Parallel.ForEach(inputData,
(int number, ParallelLoopState loopState) =>
{
//...
loopState.Break();
return;
//...
});
(int number, ParallelLoopState loopState) =>
{
//...
loopState.Break();
return;
//...
});
捕获并行循环的异常
try
{
loopResult = Parallel.ForEach(inputData,
(int number, ParallelLoopState loopState) =>
{
//...
throw new Exception();
//..
});
}
catch (AggregateException ex)
{
foreach (Exception innerEx in ex.InnerExceptions)
{
Debug.WriteLine(innerEx.ToString());
}
}
{
loopResult = Parallel.ForEach(inputData,
(int number, ParallelLoopState loopState) =>
{
//...
throw new Exception();
//..
});
}
catch (AggregateException ex)
{
foreach (Exception innerEx in ex.InnerExceptions)
{
Debug.WriteLine(innerEx.ToString());
}
}
ParaleelOption
用于修改并行度。
private static void ParallelGenerateAESKeysMaxDegree(int maxDegree)
{
var parallelOptions = new ParallelOptions();
parallelOptions.MaxDegreeOfParallelism = maxDegree;
var sw = Stopwatch.StartNew();
Parallel.For(1, NUM_AES_KEYS + 1, parallelOptions, (int i) =>
{
var aesM = new AesManaged();
byte[] result = aesM.Key;
string hexString = ConvertToHexString(result);
// Console.WriteLine(“AES KEY: {0} “, hexString);
});
Debug.WriteLine("AES: " + sw.Elapsed.ToString());
}
{
var parallelOptions = new ParallelOptions();
parallelOptions.MaxDegreeOfParallelism = maxDegree;
var sw = Stopwatch.StartNew();
Parallel.For(1, NUM_AES_KEYS + 1, parallelOptions, (int i) =>
{
var aesM = new AesManaged();
byte[] result = aesM.Key;
string hexString = ConvertToHexString(result);
// Console.WriteLine(“AES KEY: {0} “, hexString);
});
Debug.WriteLine("AES: " + sw.Elapsed.ToString());
}