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Como: Use SpinWait para implementar uma operação de duas fases de espera

O exemplo a seguir mostra como usar um System.Threading.SpinWait o objeto para implementar uma operação de espera de duas fases. Na primeira fase, o objeto de sincronização, um Latch, gira para alguns ciclos, enquanto ele verifica se o bloqueio se tornou disponível. Na segunda fase, se o bloqueio for disponibilizado, em seguida, a Wait método retorna sem usar o System.Threading.ManualResetEvent para executar sua espera; Caso contrário, Wait executa a espera.

Exemplo

Este exemplo mostra uma implementação muito básica de uma sincronização de trava primitivo. Você pode usar essa estrutura de dados quando os tempos de espera devem ser muito curta. Este exemplo é somente para propósitos de demonstração. Se você precisar de funcionalidade do tipo de trava em seu programa, considere o uso de System.Threading.ManualResetEventSlim.

#Const LOGGING = 1

Imports System
Imports System.Collections.Generic
Imports System.Diagnostics
Imports System.Linq
Imports System.Text
Imports System.Threading
Imports System.Threading.Tasks

Namespace CDS_Spinwait

    Class Latch

        ' 0 = unset, 1 = set
        Private m_state As Integer = 0

        Private m_ev = New ManualResetEvent(False)

#If LOGGING Then
        ' For fast logging with minimal impact on latch behavior.
        ' Spin counts greater than 20 might be encountered depending on machine config.
        Dim spinCountLog As Integer()

        Private totalKernelWaits As Integer = 0
        Public Sub New()
            ReDim spinCountLog(19)
        End Sub

        Public Sub PrintLog()

            For i As Integer = 0 To spinCountLog.Length - 1
                Console.WriteLine("Wait succeeded with spin count of {0} on {1} attempts", i, spinCountLog(i))
            Next
            Console.WriteLine("Wait used the kernel event on {0} attempts.", totalKernelWaits)
            Console.WriteLine("Logging complete")
        End Sub
#End If

        Public Sub SetLatch()

            ' Trace.WriteLine("Setlatch")
            Interlocked.Exchange(m_state, 1)
            m_ev.Set()
        End Sub


        Public Sub Wait()

            Trace.WriteLine("Wait timeout infinite")
            Wait(Timeout.Infinite)
        End Sub


        Public Function Wait(ByVal timeout As Integer) As Boolean

            ' Allocated on the stack.
            Dim spinner = New SpinWait()
            Dim watch As Stopwatch



            While (m_state = 0)

                ' Lazily allocate and start stopwatch to track timeout.
                watch = Stopwatch.StartNew()

                ' Spin only until the SpinWait is ready
                ' to initiate its own context switch.
                If (spinner.NextSpinWillYield = False) Then

                    spinner.SpinOnce()

                    ' Rather than let SpinWait do a context switch now,
                    '  we initiate the kernel Wait operation, because
                    ' we plan on doing this anyway.
                Else
#If LOGGING Then
                    Interlocked.Increment(totalKernelWaits)
#End If
                    ' Account for elapsed time.
                    Dim realTimeout As Long = timeout - watch.ElapsedMilliseconds

                    Debug.Assert(realTimeout <= Integer.MaxValue)
                    ' Do the wait.
                    If (realTimeout <= 0) Then

                        Trace.WriteLine("wait timed out.")
                        Return False
                    ElseIf m_ev.WaitOne(realTimeout) = False Then
                        Return False
                    End If

                End If

            End While

            ' Take the latch.

            Interlocked.Exchange(m_state, 0)


#If LOGGING Then
            Interlocked.Increment(spinCountLog(spinner.Count))
#End If


            Return True
        End Function
    End Class

    Class Program
        Shared latch = New Latch()
        Shared count As Integer = 2
        Shared cts = New CancellationTokenSource()

        Shared Sub TestMethod()

            While (cts.IsCancellationRequested = False And count < Integer.MaxValue - 1)

                ' Obtain the latch.
                If (latch.Wait(50)) Then
                    ' Do the work. Here we vary the workload a slight amount
                    ' to help cause varying spin counts in latch.
                    Dim d As Double = 0
                    If (count Mod 2 <> 0) Then
                        d = Math.Sqrt(count)
                    End If
                    Interlocked.Increment(count)

                    ' Release the latch.
                    latch.SetLatch()
                End If
            End While
        End Sub
        Shared Sub Main()
            ' Demonstrate latch with a simple scenario:
            ' two threads updating a shared integer and
            ' accessing a shared StringBuilder. Both operations
            ' are relatively fast, which enables the latch to
            ' demonstrate successful waits by spinning only. 
            latch.SetLatch()

            ' UI thread. Press 'c' to cancel the loop.
            Task.Factory.StartNew(Sub()
                                      Console.WriteLine("Wait a few seconds, then press 'c' to see results.")
                                      If (Console.ReadKey().KeyChar = "c"c) Then
                                          cts.Cancel()
                                      End If
                                  End Sub)

            Parallel.Invoke(
                Sub() TestMethod(),
               Sub() TestMethod(),
                Sub() TestMethod()
                )

#If LOGGING Then
            latch.PrintLog()
#End If
            Console.WriteLine(vbCrLf & "To exit, press the Enter key.")
            Console.ReadLine()
        End Sub
    End Class
End Namespace
#define LOGGING

using System;
using System.Collections.Generic;
using System.Diagnostics;
using System.Linq;
using System.Text;
using System.Threading;
using System.Threading.Tasks;

namespace CDS_Spinwait
{
    class Latch
    {
        // 0 = unset, 1 = set
        private volatile int m_state = 0;

        private ManualResetEvent m_ev = new ManualResetEvent(false);

#if LOGGING
        // For fast logging with minimal impact on latch behavior.
        // Spin counts greater than 20 might be encountered depending on machine config.
        private int[] spinCountLog = new int[20];
        private volatile int totalKernelWaits = 0;

        public void PrintLog()
        {

            for (int i = 0; i < spinCountLog.Length; i++)
            {
                Console.WriteLine("Wait succeeded with spin count of {0} on {1} attempts", i, spinCountLog[i]);
            }
            Console.WriteLine("Wait used the kernel event on {0} attempts.", totalKernelWaits);
            Console.WriteLine("Logging complete");
        }
#endif

        public void Set()
        {
            // Trace.WriteLine("Set");
            m_state = 1;
            m_ev.Set();
        }

        public void Wait()
        {
            Trace.WriteLine("Wait timeout infinite");
            Wait(Timeout.Infinite);
        }

        public bool Wait(int timeout)
        {
            // Allocated on the stack.
            SpinWait spinner = new SpinWait();
            Stopwatch watch;



            while (m_state == 0)
            {

                // Lazily allocate and start stopwatch to track timeout.
                watch = Stopwatch.StartNew();

                // Spin only until the SpinWait is ready
                // to initiate its own context switch.
                if (!spinner.NextSpinWillYield)
                {
                    spinner.SpinOnce();

                }
                // Rather than let SpinWait do a context switch now,
                //  we initiate the kernel Wait operation, because
                // we plan on doing this anyway.
                else
                {
                    totalKernelWaits++;
                    // Account for elapsed time.
                    int realTimeout = timeout - (int)watch.ElapsedMilliseconds;

                    // Do the wait.
                    if (realTimeout <= 0 || !m_ev.WaitOne(realTimeout))
                    {
                        Trace.WriteLine("wait timed out.");
                        return false;
                    }
                }
            }

            // Take the latch.
            m_state = 0;
            //   totalWaits++;

#if LOGGING
            spinCountLog[spinner.Count]++;
#endif


            return true;
        }
    }

    class Program
    {
        static Latch latch = new Latch();
        static int count = 2;
        static CancellationTokenSource cts = new CancellationTokenSource();

        static void TestMethod()
        {
            while (!cts.IsCancellationRequested)
            {
                // Obtain the latch.
                if (latch.Wait(50))
                {
                    // Do the work. Here we vary the workload a slight amount
                    // to help cause varying spin counts in latch.
                    double d = 0;
                    if (count % 2 != 0)
                    {
                        d = Math.Sqrt(count);
                    }
                    count++;

                    // Release the latch.
                    latch.Set();
                }
            }
        }
        static void Main(string[] args)
        {
            // Demonstrate latch with a simple scenario:
            // two threads updating a shared integer and
            // accessing a shared StringBuilder. Both operations
            // are relatively fast, which enables the latch to
            // demonstrate successful waits by spinning only. 

            latch.Set();


            // UI thread. Press 'c' to cancel the loop.
            Task.Factory.StartNew(() =>
            {
                Console.WriteLine("Press 'c' to cancel.");
                if (Console.ReadKey().KeyChar == 'c')
                {
                    cts.Cancel();

                }
            });

            Parallel.Invoke(

                () => TestMethod(),
                () => TestMethod(),
                () => TestMethod()
                );

#if LOGGING
            latch.PrintLog();
#endif
            Console.WriteLine("\r\nPress the Enter Key.");
            Console.ReadLine();
        }
    }
}

A trava usa o SpinWait o objeto para girar em vigor somente até a próxima chamada para SpinOnce faz com que o SpinWait para produzir a fatia de tempo do thread. Nesse ponto, a trava da causa o seu próprio alternância de contexto chamando WaitOne(Int32, Boolean) sobre o ManualResetEvent e passando o restante do valor de tempo limite.

A saída de log mostra a freqüência a trava foi capaz de aumentar o desempenho em adquirir o bloqueio sem usar o ManualResetEvent.

Consulte também

Outros recursos

SpinWait

Threading objetos e recursos