异步文件 I/O

更新:2007 年 11 月

同步 I/O 意味着在 I/O 操作完成之前,方法被阻塞,I/O 操作完成后,方法返回其数据。使用异步 I/O,用户可以调用 BeginRead。主线程可以继续进行其他工作,稍后,用户将能够处理数据。另外,多个 I/O 请求可以被同时挂起。

要在此数据可用时得到通知,您可以调用 EndReadEndWrite,传入与您发出的 I/O 请求对应的 IAsyncResult。您还可以提供回调方法,该回调方法应调用 EndReadEndWrite 以计算读取或写入了多少字节。当许多 I/O 请求被同时挂起时,异步 I/O 可以提供较好的性能,但通常要求对您的应用程序进行一些重要的调整以使其正常工作。

Stream 类支持对同一流执行同步和异步混合读写,不论操作系统是否允许这样做。Stream 将以同步实现的名义提供异步读写操作的默认实现,并以异步实现的名义提供同步读写操作的默认实现。

当实现 Stream 的派生类时,需要为同步或异步 ReadWrite 方法提供实现。尽管允许重写 ReadWrite,并且异步方法(BeginReadEndReadBeginWriteEndWrite)的默认实现可配合同步方法的实现使用,但这样做不能提供最佳性能。同样,如果您提供了一个异步方法的实现,同步 ReadWrite 方法也将正常工作;但如果您专门实现同步方法,性能通常会更好。ReadByteWriteByte 的默认实现调用带有一个元素字节数组的同步 ReadWrite 方法。当从 Stream 派生类时,如果有内部字节缓冲区,强烈建议重写这些方法以访问内部缓冲区,这样性能将得到提高。

连接到后备存储器的流重写同步或异步 ReadWrite 方法,以获取默认情况下另一种方法的功能。如果流不支持异步或同步操作,实施者只需让适当的方法引发异常即可。

下面的示例是一个假设的批量图像处理器的异步实现,其后是同步实现的示例。本代码用于在目录中的每个文件上执行耗费 CPU 资源的操作。有关更多信息,请参见主题异步编程设计模式

Imports System
Imports System.IO
Imports System.Threading
Imports System.Runtime.InteropServices
Imports System.Runtime.Remoting.Messaging
Imports System.Security.Permissions



Module BulkImageProcAsync
    Dim ImageBaseName As String = "tmpImage-"
    Dim numImages As Integer = 200
    Dim numPixels As Integer = 512 * 512

    ' ProcessImage has a simple O(N) loop, and you can vary the number
    ' of times you repeat that loop to make the application more CPU-
    ' bound or more IO-bound.
    Dim processImageRepeats As Integer = 20

    ' Threads must decrement NumImagesToFinish, and protect
    ' their access to it through a mutex.
    Dim NumImagesToFinish As Integer = numImages
    Dim NumImagesMutex(-1) As [Object]
    ' WaitObject is signalled when all image processing is done.
    Dim WaitObject(-1) As [Object]

    Structure ImageStateObject
        Public pixels() As Byte
        Public imageNum As Integer
        Public fs As FileStream
    End Structure


    <SecurityPermissionAttribute(SecurityAction.Demand, Flags:=SecurityPermissionFlag.UnmanagedCode)> _
    Sub MakeImageFiles()
        Dim sides As Integer = Fix(Math.Sqrt(numPixels))
        Console.Write("Making {0} {1}x{1} images... ", numImages, sides)
        Dim pixels(numPixels) As Byte
        Dim i As Integer
        For i = 0 To numPixels
            pixels(i) = 255
        Next i
        Dim fs As FileStream
        For i = 0 To numImages
            fs = New FileStream(ImageBaseName + i.ToString() + ".tmp", FileMode.Create, FileAccess.Write, FileShare.None, 8192, False)
            fs.Write(pixels, 0, pixels.Length)
            FlushFileBuffers(fs.SafeFileHandle.DangerousGetHandle())
            fs.Close()
        Next i
        fs = Nothing
        Console.WriteLine("Done.")

    End Sub


    Sub ReadInImageCallback(ByVal asyncResult As IAsyncResult)
        Dim state As ImageStateObject = CType(asyncResult.AsyncState, ImageStateObject)
        Dim stream As Stream = state.fs
        Dim bytesRead As Integer = stream.EndRead(asyncResult)
        If bytesRead <> numPixels Then
            Throw New Exception(String.Format("In ReadInImageCallback, got the wrong number of " + "bytes from the image: {0}.", bytesRead))
        End If
        ProcessImage(state.pixels, state.imageNum)
        stream.Close()

        ' Now write out the image.  
        ' Using asynchronous I/O here appears not to be best practice.
        ' It ends up swamping the threadpool, because the threadpool
        ' threads are blocked on I/O requests that were just queued to
        ' the threadpool. 
        Dim fs As New FileStream(ImageBaseName + state.imageNum.ToString() + ".done", FileMode.Create, FileAccess.Write, FileShare.None, 4096, False)
        fs.Write(state.pixels, 0, numPixels)
        fs.Close()

        ' This application model uses too much memory.
        ' Releasing memory as soon as possible is a good idea, 
        ' especially global state.
        state.pixels = Nothing
        fs = Nothing
        ' Record that an image is finished now.
        SyncLock NumImagesMutex
            NumImagesToFinish -= 1
            If NumImagesToFinish = 0 Then
                Monitor.Enter(WaitObject)
                Monitor.Pulse(WaitObject)
                Monitor.Exit(WaitObject)
            End If
        End SyncLock

    End Sub


    Sub ProcessImage(ByVal pixels() As Byte, ByVal imageNum As Integer)
        Console.WriteLine("ProcessImage {0}", imageNum)
        Dim y As Integer
        ' Perform some CPU-intensive operation on the image.
        Dim x As Integer
        For x = 0 To processImageRepeats
            For y = 0 To numPixels
                pixels(y) = 1
            Next y
        Next x
        Console.WriteLine("ProcessImage {0} done.", imageNum)

    End Sub


    Sub ProcessImagesInBulk()
        Console.WriteLine("Processing images...  ")
        Dim t0 As Long = Environment.TickCount
        NumImagesToFinish = numImages
        Dim readImageCallback As New AsyncCallback(AddressOf ReadInImageCallback)
        Dim i As Integer
        For i = 0 To numImages
            Dim state As New ImageStateObject()
            state.pixels = New Byte(numPixels) {}
            state.imageNum = i
            ' Very large items are read only once, so you can make the 
            ' buffer on the FileStream very small to save memory.
            Dim fs As New FileStream(ImageBaseName + i.ToString() + ".tmp", FileMode.Open, FileAccess.Read, FileShare.Read, 1, True)
            state.fs = fs
            fs.BeginRead(state.pixels, 0, numPixels, readImageCallback, state)
        Next i

        ' Determine whether all images are done being processed.  
        ' If not, block until all are finished.
        Dim mustBlock As Boolean = False
        SyncLock NumImagesMutex
            If NumImagesToFinish > 0 Then
                mustBlock = True
            End If
        End SyncLock
        If mustBlock Then
            Console.WriteLine("All worker threads are queued. " + " Blocking until they complete. numLeft: {0}", NumImagesToFinish)
            Monitor.Enter(WaitObject)
            Monitor.Wait(WaitObject)
            Monitor.Exit(WaitObject)
        End If
        Dim t1 As Long = Environment.TickCount
        Console.WriteLine("Total time processing images: {0}ms", t1 - t0)

    End Sub


    Sub Cleanup()
        Dim i As Integer
        For i = 0 To numImages
            File.Delete(ImageBaseName + i.ToString + ".tmp")
            File.Delete(ImageBaseName + i.ToString + ".done")
        Next i

    End Sub


    Sub TryToClearDiskCache()
        ' Try to force all pending writes to disk, and clear the
        ' disk cache of any data.
        Dim bytes(100 * (1 << 20)) As Byte
        Dim i As Integer
        For i = 0 To bytes.Length - 1
            bytes(i) = 0
        Next i
        bytes = Nothing
        GC.Collect()
        Thread.Sleep(2000)

    End Sub


    Sub Main(ByVal args() As String)
        Console.WriteLine("Bulk image processing sample application," + " using asynchronous IO")
        Console.WriteLine("Simulates applying a simple " + "transformation to {0} ""images""", numImages)
        Console.WriteLine("(Async FileStream & Threadpool benchmark)")
        Console.WriteLine("Warning - this test requires {0} " + "bytes of temporary space", numPixels * numImages * 2)

        If args.Length = 1 Then
            processImageRepeats = Int32.Parse(args(0))
            Console.WriteLine("ProcessImage inner loop - {0}.", processImageRepeats)
        End If
        MakeImageFiles()
        TryToClearDiskCache()
        ProcessImagesInBulk()
        Cleanup()

    End Sub

    <DllImport("KERNEL32", SetLastError:=True)> _
    Sub FlushFileBuffers(ByVal handle As IntPtr)
    End Sub
End Module
using System;
using System.IO;
using System.Threading;
using System.Runtime.InteropServices;
using System.Runtime.Remoting.Messaging;
using System.Security.Permissions;

public class BulkImageProcAsync
{
    public const String ImageBaseName = "tmpImage-";
    public const int numImages = 200;
    public const int numPixels = 512 * 512;

    // ProcessImage has a simple O(N) loop, and you can vary the number
    // of times you repeat that loop to make the application more CPU-
    // bound or more IO-bound.
    public static int processImageRepeats = 20;

    // Threads must decrement NumImagesToFinish, and protect
    // their access to it through a mutex.
    public static int NumImagesToFinish = numImages;
    public static Object[] NumImagesMutex = new Object[0];
    // WaitObject is signalled when all image processing is done.
    public static Object[] WaitObject = new Object[0];
    public class ImageStateObject
    {
        public byte[] pixels;
        public int imageNum;
        public FileStream fs;
    }

    [SecurityPermissionAttribute(SecurityAction.Demand, Flags=SecurityPermissionFlag.UnmanagedCode)]
    public static void MakeImageFiles()
    {
        int sides = (int)Math.Sqrt(numPixels);
        Console.Write("Making {0} {1}x{1} images... ", numImages,
            sides);
        byte[] pixels = new byte[numPixels];
        int i;
        for (i = 0; i < numPixels; i++)
            pixels[i] = (byte)i;
        FileStream fs;
        for (i = 0; i < numImages; i++)
        {
            fs = new FileStream(ImageBaseName + i + ".tmp",
                FileMode.Create, FileAccess.Write, FileShare.None,
                8192, false);
            fs.Write(pixels, 0, pixels.Length);
            FlushFileBuffers(fs.SafeFileHandle.DangerousGetHandle());
            fs.Close();
        }
        fs = null;
        Console.WriteLine("Done.");
    }

    public static void ReadInImageCallback(IAsyncResult asyncResult)
    {
        ImageStateObject state = (ImageStateObject)asyncResult.AsyncState;
        Stream stream = state.fs;
        int bytesRead = stream.EndRead(asyncResult);
        if (bytesRead != numPixels)
            throw new Exception(String.Format
                ("In ReadInImageCallback, got the wrong number of " +
                "bytes from the image: {0}.", bytesRead));
        ProcessImage(state.pixels, state.imageNum);
        stream.Close();

        // Now write out the image.  
        // Using asynchronous I/O here appears not to be best practice.
        // It ends up swamping the threadpool, because the threadpool
        // threads are blocked on I/O requests that were just queued to
        // the threadpool. 
        FileStream fs = new FileStream(ImageBaseName + state.imageNum +
            ".done", FileMode.Create, FileAccess.Write, FileShare.None,
            4096, false);
        fs.Write(state.pixels, 0, numPixels);
        fs.Close();

        // This application model uses too much memory.
        // Releasing memory as soon as possible is a good idea, 
        // especially global state.
        state.pixels = null;
        fs = null;
        // Record that an image is finished now.
        lock (NumImagesMutex)
        {
            NumImagesToFinish--;
            if (NumImagesToFinish == 0)
            {
                Monitor.Enter(WaitObject);
                Monitor.Pulse(WaitObject);
                Monitor.Exit(WaitObject);
            }
        }
    }

    public static void ProcessImage(byte[] pixels, int imageNum)
    {
        Console.WriteLine("ProcessImage {0}", imageNum);
        int y;
        // Perform some CPU-intensive operation on the image.
        for (int x = 0; x < processImageRepeats; x += 1)
            for (y = 0; y < numPixels; y += 1)
                pixels[y] += 1;
        Console.WriteLine("ProcessImage {0} done.", imageNum);
    }

    public static void ProcessImagesInBulk()
    {
        Console.WriteLine("Processing images...  ");
        long t0 = Environment.TickCount;
        NumImagesToFinish = numImages;
        AsyncCallback readImageCallback = new
            AsyncCallback(ReadInImageCallback);
        for (int i = 0; i < numImages; i++)
        {
            ImageStateObject state = new ImageStateObject();
            state.pixels = new byte[numPixels];
            state.imageNum = i;
            // Very large items are read only once, so you can make the 
            // buffer on the FileStream very small to save memory.
            FileStream fs = new FileStream(ImageBaseName + i + ".tmp",
                FileMode.Open, FileAccess.Read, FileShare.Read, 1, true);
            state.fs = fs;
            fs.BeginRead(state.pixels, 0, numPixels, readImageCallback,
                state);
        }

        // Determine whether all images are done being processed.  
        // If not, block until all are finished.
        bool mustBlock = false;
        lock (NumImagesMutex)
        {
            if (NumImagesToFinish > 0)
                mustBlock = true;
        }
        if (mustBlock)
        {
            Console.WriteLine("All worker threads are queued. " +
                " Blocking until they complete. numLeft: {0}",
                NumImagesToFinish);
            Monitor.Enter(WaitObject);
            Monitor.Wait(WaitObject);
            Monitor.Exit(WaitObject);
        }
        long t1 = Environment.TickCount;
        Console.WriteLine("Total time processing images: {0}ms",
            (t1 - t0));
    }

    public static void Cleanup()
    {
        for (int i = 0; i < numImages; i++)
        {
            File.Delete(ImageBaseName + i + ".tmp");
            File.Delete(ImageBaseName + i + ".done");
        }
    }

    public static void TryToClearDiskCache()
    {
        // Try to force all pending writes to disk, and clear the
        // disk cache of any data.
        byte[] bytes = new byte[100 * (1 << 20)];
        for (int i = 0; i < bytes.Length; i++)
            bytes[i] = 0;
        bytes = null;
        GC.Collect();
        Thread.Sleep(2000);
    }

    public static void Main(String[] args)
    {
        Console.WriteLine("Bulk image processing sample application," +
            " using asynchronous IO");
        Console.WriteLine("Simulates applying a simple " +
            "transformation to {0} \"images\"", numImages);
        Console.WriteLine("(Async FileStream & Threadpool benchmark)");
        Console.WriteLine("Warning - this test requires {0} " +
            "bytes of temporary space", (numPixels * numImages * 2));

        if (args.Length == 1)
        {
            processImageRepeats = Int32.Parse(args[0]);
            Console.WriteLine("ProcessImage inner loop - {0}.",
                processImageRepeats);
        }
        MakeImageFiles();
        TryToClearDiskCache();
        ProcessImagesInBulk();
        Cleanup();
    }
    [DllImport("KERNEL32", SetLastError = true)]
    private static extern void FlushFileBuffers(IntPtr handle);
}

以下是同一假设的同步示例。

Imports System
Imports System.IO
Imports System.Threading
Imports System.Runtime.InteropServices
Imports System.Runtime.Remoting.Messaging
Imports System.Security.Permissions



Module BulkImageProcSync
    Dim ImageBaseName As String = "tmpImage-"
    Dim numImages As Integer = 200
    Dim numPixels As Integer = 512 * 512

    ' ProcessImage has a simple O(N) loop, and you can vary the number
    ' of times you repeat that loop to make the application more CPU-
    ' bound or more IO-bound.
    Dim processImageRepeats As Integer = 20

    <SecurityPermissionAttribute(SecurityAction.Demand, Flags:=SecurityPermissionFlag.UnmanagedCode)> _
    Sub MakeImageFiles()
        Dim sides As Integer = Fix(Math.Sqrt(numPixels))
        Console.Write("Making {0} {1}x{1} images... ", numImages, sides)
        Dim pixels(numPixels) As Byte
        Dim i As Integer
        For i = 0 To numPixels
            pixels(i) = 255
        Next i
        Dim fs As FileStream
        For i = 0 To numImages
            fs = New FileStream(ImageBaseName + i.ToString + ".tmp", FileMode.Create, FileAccess.Write, FileShare.None, 8192, False)
            fs.Write(pixels, 0, pixels.Length)
            FlushFileBuffers(fs.SafeFileHandle.DangerousGetHandle())
            fs.Close()
        Next i
        fs = Nothing
        Console.WriteLine("Done.")

    End Sub


    Sub ProcessImage(ByVal pixels() As Byte, ByVal imageNum As Integer)
        Console.WriteLine("ProcessImage {0}", imageNum)
        Dim y As Integer
        ' Perform some CPU-intensive operation on the image.
        Dim x As Integer
        For x = 0 To processImageRepeats
            For y = 0 To numPixels
                pixels(y) = 1
            Next y
        Next x
        Console.WriteLine("ProcessImage {0} done.", imageNum)

    End Sub


    Sub ProcessImagesInBulk()
        Console.WriteLine("Processing images... ")
        Dim t0 As Long = Environment.TickCount
        Dim pixels(numPixels) As Byte
        Dim input As FileStream
        Dim output As FileStream
        Dim i As Integer
        For i = 0 To numImages
            input = New FileStream(ImageBaseName + i.ToString + ".tmp", FileMode.Open, FileAccess.Read, FileShare.Read, 4196, False)
            input.Read(pixels, 0, numPixels)
            input.Close()
            ProcessImage(pixels, i)
            output = New FileStream(ImageBaseName + i.ToString + ".done", FileMode.Create, FileAccess.Write, FileShare.None, 4196, False)
            output.Write(pixels, 0, numPixels)
            output.Close()
        Next i
        input = Nothing
        output = Nothing
        Dim t1 As Long = Environment.TickCount
        Console.WriteLine("Total time processing images: {0}ms", t1 - t0)

    End Sub


    Sub Cleanup()
        Dim i As Integer
        For i = 0 To numImages
            File.Delete(ImageBaseName + i.ToString + ".tmp")
            File.Delete(ImageBaseName + i.ToString + ".done")
        Next i

    End Sub


    Sub TryToClearDiskCache()
        Dim bytes(100 * (1 << 20)) As Byte
        Dim i As Integer
        For i = 0 To bytes.Length - 1
            bytes(i) = 0
        Next i
        bytes = Nothing
        GC.Collect()
        Thread.Sleep(2000)

    End Sub


    Sub Main(ByVal args() As String)
        Console.WriteLine("Bulk image processing sample application," + " using synchronous I/O.")
        Console.WriteLine("Simulates applying a simple " + "transformation to {0} ""images.""", numImages)
        Console.WriteLine("(ie, Sync FileStream benchmark).")
        Console.WriteLine("Warning - this test requires {0} " + "bytes of temporary space", numPixels * numImages * 2)

        If args.Length = 1 Then
            processImageRepeats = Int32.Parse(args(0))
            Console.WriteLine("ProcessImage inner loop  {0}", processImageRepeats)
        End If

        MakeImageFiles()
        TryToClearDiskCache()
        ProcessImagesInBulk()
        Cleanup()

    End Sub


    <DllImport("KERNEL32", SetLastError:=True)> _
    Sub FlushFileBuffers(ByVal handle As IntPtr)
    End Sub
End Module
using System;
using System.IO;
using System.Threading;
using System.Runtime.InteropServices;
using System.Runtime.Remoting.Messaging;
using System.Security.Permissions;

public class BulkImageProcSync
{
    public const String ImageBaseName = "tmpImage-";
    public const int numImages = 200;
    public const int numPixels = 512 * 512;

    // ProcessImage has a simple O(N) loop, and you can vary the number
    // of times you repeat that loop to make the application more CPU-
    // bound or more IO-bound.
    public static int processImageRepeats = 20;

    [SecurityPermissionAttribute(SecurityAction.Demand, Flags=SecurityPermissionFlag.UnmanagedCode)]
    public static void MakeImageFiles()
    {
        int sides = (int)Math.Sqrt(numPixels);
        Console.Write("Making {0} {1}x{1} images... ", numImages,
            sides);
        byte[] pixels = new byte[numPixels];
        int i;
        for (i = 0; i < numPixels; i++)
            pixels[i] = (byte)i;
        FileStream fs;
        for (i = 0; i < numImages; i++)
        {
            fs = new FileStream(ImageBaseName + i + ".tmp",
                FileMode.Create, FileAccess.Write, FileShare.None,
                8192, false);
            fs.Write(pixels, 0, pixels.Length);
            FlushFileBuffers(fs.SafeFileHandle.DangerousGetHandle());
            fs.Close();
        }
        fs = null;
        Console.WriteLine("Done.");
    }

    public static void ProcessImage(byte[] pixels, int imageNum)
    {
        Console.WriteLine("ProcessImage {0}", imageNum);
        int y;
        // Perform some CPU-intensive operation on the image.
        for (int x = 0; x < processImageRepeats; x += 1)
            for (y = 0; y < numPixels; y += 1)
                pixels[y] += 1;
        Console.WriteLine("ProcessImage {0} done.", imageNum);
    }

    public static void ProcessImagesInBulk()
    {
        Console.WriteLine("Processing images... ");
        long t0 = Environment.TickCount;
        byte[] pixels = new byte[numPixels];
        FileStream input;
        FileStream output;
        for (int i = 0; i < numImages; i++)
        {
            input = new FileStream(ImageBaseName + i + ".tmp",
                FileMode.Open, FileAccess.Read, FileShare.Read,
                4196, false);
            input.Read(pixels, 0, numPixels);
            input.Close();
            ProcessImage(pixels, i);
            output = new FileStream(ImageBaseName + i + ".done",
                FileMode.Create, FileAccess.Write, FileShare.None,
                4196, false);
            output.Write(pixels, 0, numPixels);
            output.Close();
        }
        input = null;
        output = null;
        long t1 = Environment.TickCount;
        Console.WriteLine("Total time processing images: {0}ms",
            (t1 - t0));
    }

    public static void Cleanup()
    {
        for (int i = 0; i < numImages; i++)
        {
            File.Delete(ImageBaseName + i + ".tmp");
            File.Delete(ImageBaseName + i + ".done");
        }
    }

    public static void TryToClearDiskCache()
    {
        byte[] bytes = new byte[100 * (1 << 20)];
        for (int i = 0; i < bytes.Length; i++)
            bytes[i] = 0;
        bytes = null;
        GC.Collect();
        Thread.Sleep(2000);
    }

    public static void Main(String[] args)
    {
        Console.WriteLine("Bulk image processing sample application," +
            " using synchronous I/O.");
        Console.WriteLine("Simulates applying a simple " +
            "transformation to {0} \"images.\"", numImages);
        Console.WriteLine("(ie, Sync FileStream benchmark).");
        Console.WriteLine("Warning - this test requires {0} " +
            "bytes of temporary space", (numPixels * numImages * 2));

        if (args.Length == 1)
        {
            processImageRepeats = Int32.Parse(args[0]);
            Console.WriteLine("ProcessImage inner loop  {0}",
                processImageRepeats);
        }

        MakeImageFiles();
        TryToClearDiskCache();
        ProcessImagesInBulk();
        Cleanup();
    }

    [DllImport("KERNEL32", SetLastError = true)]
    private static extern void FlushFileBuffers(IntPtr handle);
}

请参见

参考

Stream

Stream.Read

Stream.Write

Stream.BeginRead

Stream.BeginWrite

Stream.EndRead

Stream.EndWrite

IAsyncResult

Mutex

其他资源

文件和流 I/O