implab/ImplabNet Files · Implab/AbstractEvent.cs

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             AbstractEvent.cs
        
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      using System;

      using Implab.Parallels;

      using System.Threading;

      using System.Reflection;

      using System.Diagnostics;

      namespace Implab {

          /// <summary>

          /// Abstract class for creation of custom one-shot thread safe events.

          /// </summary>

          /// <remarks>

          /// <para>

          /// An event is something that should happen in the future and the

          /// triggering of the event causes execution of some pending actions 

          /// which are formely event handlers. One-shot events occur only once

          /// and any handler added after the event is triggered should run 

          /// without a delay.

          /// </para>

          /// <para>

          /// The lifecycle of the one-shot event is tipically consists of following

          /// phases.

          /// <list>

          /// <description>Pending state. This is the initial state of the event. Any

          /// handler added to the event will be queued for the future execution.

          /// </description>

          /// <description>Transitional state. This is intermediate state between pending

          /// and fulfilled states, during this state internal initialization and storing

          /// of the result occurs.

          /// </description>

          /// <description>Fulfilled state. The event contains the result, all queued

          /// handlers are signalled to run and newly added handlers are executed

          /// immediatelly.

          /// </description>

          /// </list>

          /// </para>

          /// </remarks>

          public abstract class AbstractEvent<THandler> where THandler : class {

              const int PendingState = 0;

              const int TransitionalState = 1;

              const int ResolvedState = 2;

              volatile int m_state;

              THandler m_handler;

              SimpleAsyncQueue<THandler> m_extraHandlers;

              public bool IsResolved {

                  get {

                      return m_state > TransitionalState;

                  }

              }

              #region state managment

              protected bool BeginTransit() {

                  return PendingState == Interlocked.CompareExchange(ref m_state, TransitionalState, PendingState);

              }

              protected void CompleteTransit() {

      #if DEBUG

                  if (TransitionalState != Interlocked.CompareExchange(ref m_state, ResolvedState, TransitionalState))

                      throw new InvalidOperationException("Can't complete transition when the object isn't in the transitional state");

      #else

                  m_state = state;

      #endif

                  Signal();

              }

              protected void WaitTransition() {

                  if (m_state == TransitionalState) {

                      SpinWait spin;

                      do {

                          spin.SpinOnce();

                      } while (m_state == TransitionalState);

                  }

              }

              protected abstract void SignalHandler(THandler handler);

              void Signal() {

                  THandler handler;

                  while (TryDequeueHandler(out handler))

                      SignalHandler(handler);

              }

              #endregion

              protected abstract Signal GetFulfillSignal();

              #region synchronization traits

              protected void WaitResult(int timeout) {

                  if (!(IsResolved || GetFulfillSignal().Wait(timeout)))

                      throw new TimeoutException();

              }

              #endregion

              #region handlers managment

              protected void AddHandler(THandler handler) {

                  if (IsResolved) {

                      // the promise is in the resolved state, just invoke the handler

                      SignalHandler(handler);

                  } else {

                      EnqueueHandler(handler);

                      if (IsResolved && TryDequeueHandler(out handler))

                          // if the promise have been resolved while we was adding the handler to the queue

                          // we can't guarantee that someone is still processing it

                          // therefore we need to fetch a handler from the queue and execute it

                          // note that fetched handler may be not the one that we have added

                          // even we can fetch no handlers at all :)

                          SignalHandler(handler);

                  }

              }

              void EnqueueHandler(THandler handler) {

                  if (Interlocked.CompareExchange(ref m_handler, handler, null) != null) {

                      if (m_extraHandlers == null)

                          // compare-exchange will protect from loosing already created queue

                          Interlocked.CompareExchange(ref m_extraHandlers, new SimpleAsyncQueue<THandler>(), null);

                      m_extraHandlers.Enqueue(handler);

                  }

              }

              bool TryDequeueHandler(out THandler handler) {

                  handler = Interlocked.Exchange(ref m_handler, null);

                  if (handler != null)

                      return true;

                  return m_extraHandlers != null && m_extraHandlers.TryDequeue(out handler);

              }

              #endregion

          }

      }

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				using System;
				using Implab.Parallels;
				using System.Threading;
				using System.Reflection;
				using System.Diagnostics;

				namespace Implab {
				/// <summary>
				/// Abstract class for creation of custom one-shot thread safe events.
				/// </summary>
				/// <remarks>
				/// <para>
				/// An event is something that should happen in the future and the
				/// triggering of the event causes execution of some pending actions
				/// which are formely event handlers. One-shot events occur only once
				/// and any handler added after the event is triggered should run
				/// without a delay.
				/// </para>
				/// <para>
				/// The lifecycle of the one-shot event is tipically consists of following
				/// phases.
				/// <list>
				/// <description>Pending state. This is the initial state of the event. Any
				/// handler added to the event will be queued for the future execution.
				/// </description>
				/// <description>Transitional state. This is intermediate state between pending
				/// and fulfilled states, during this state internal initialization and storing
				/// of the result occurs.
				/// </description>
				/// <description>Fulfilled state. The event contains the result, all queued
				/// handlers are signalled to run and newly added handlers are executed
				/// immediatelly.
				/// </description>
				/// </list>
				/// </para>
				/// </remarks>
				public abstract class AbstractEvent<THandler> where THandler : class {
				const int PendingState = 0;

				const int TransitionalState = 1;

				const int ResolvedState = 2;

				volatile int m_state;

				THandler m_handler;
				SimpleAsyncQueue<THandler> m_extraHandlers;

				public bool IsResolved {
				get {
				return m_state > TransitionalState;
				}
				}

				#region state managment
				protected bool BeginTransit() {
				return PendingState == Interlocked.CompareExchange(ref m_state, TransitionalState, PendingState);
				}

				protected void CompleteTransit() {
				#if DEBUG
				if (TransitionalState != Interlocked.CompareExchange(ref m_state, ResolvedState, TransitionalState))
				throw new InvalidOperationException("Can't complete transition when the object isn't in the transitional state");
				#else
				m_state = state;
				#endif
				Signal();
				}

				protected void WaitTransition() {
				if (m_state == TransitionalState) {
				SpinWait spin;
				do {
				spin.SpinOnce();
				} while (m_state == TransitionalState);
				}
				}


				protected abstract void SignalHandler(THandler handler);

				void Signal() {
				THandler handler;
				while (TryDequeueHandler(out handler))
				SignalHandler(handler);
				}

				#endregion

				protected abstract Signal GetFulfillSignal();

				#region synchronization traits
				protected void WaitResult(int timeout) {
				if (!(IsResolved \|\| GetFulfillSignal().Wait(timeout)))
				throw new TimeoutException();
				}


				#endregion

				#region handlers managment

				protected void AddHandler(THandler handler) {

				if (IsResolved) {
				// the promise is in the resolved state, just invoke the handler
				SignalHandler(handler);
				} else {
				EnqueueHandler(handler);

				if (IsResolved && TryDequeueHandler(out handler))
				// if the promise have been resolved while we was adding the handler to the queue
				// we can't guarantee that someone is still processing it
				// therefore we need to fetch a handler from the queue and execute it
				// note that fetched handler may be not the one that we have added
				// even we can fetch no handlers at all :)
				SignalHandler(handler);
				}

				}

				void EnqueueHandler(THandler handler) {
				if (Interlocked.CompareExchange(ref m_handler, handler, null) != null) {
				if (m_extraHandlers == null)
				// compare-exchange will protect from loosing already created queue
				Interlocked.CompareExchange(ref m_extraHandlers, new SimpleAsyncQueue<THandler>(), null);
				m_extraHandlers.Enqueue(handler);
				}
				}

				bool TryDequeueHandler(out THandler handler) {
				handler = Interlocked.Exchange(ref m_handler, null);
				if (handler != null)
				return true;
				return m_extraHandlers != null && m_extraHandlers.TryDequeue(out handler);
				}

				#endregion
				}
				}