uefi/linaro-edk2/Nt32Pkg/TimerDxe/Timer.c - device/linaro/hikey960 - Gitiles

 /**@file

 Copyright (c) 2006, Intel Corporation. All rights reserved.<BR>
 This program and the accompanying materials
 are licensed and made available under the terms and conditions of the BSD License
 which accompanies this distribution.  The full text of the license may be found at
 http://opensource.org/licenses/bsd-license.php

 THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,
 WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.

 Module Name:

   Timer.c

 Abstract:

   NT Emulation Timer Architectural Protocol Driver as defined in DXE CIS

   This Timer module uses an NT Thread to simulate the timer-tick driven
   timer service.  In the future, the Thread creation should possibly be
   abstracted by the CPU architectural protocol

 **/

 #include "Timer.h"

 //
 // Pointer to the CPU Architectural Protocol instance
 //
 EFI_CPU_ARCH_PROTOCOL   *mCpu;

 //
 // The Timer Architectural Protocol that this driver produces
 //
 EFI_TIMER_ARCH_PROTOCOL mTimer = {
   WinNtTimerDriverRegisterHandler,
   WinNtTimerDriverSetTimerPeriod,
   WinNtTimerDriverGetTimerPeriod,
   WinNtTimerDriverGenerateSoftInterrupt
 };

 //
 // Define a global that we can use to shut down the NT timer thread when
 // the timer is canceled.
 //
 BOOLEAN                 mCancelTimerThread = FALSE;

 //
 // The notification function to call on every timer interrupt
 //
 EFI_TIMER_NOTIFY        mTimerNotifyFunction = NULL;

 //
 // The current period of the timer interrupt
 //
 UINT64                  mTimerPeriod;

 //
 // The thread handle for this driver
 //
 HANDLE                  mNtMainThreadHandle;

 //
 // The timer value from the last timer interrupt
 //
 UINT32                  mNtLastTick;

 //
 // Critical section used to update varibles shared between the main thread and
 // the timer interrupt thread.
 //
 CRITICAL_SECTION        mNtCriticalSection;

 //
 // Worker Functions
 //
 UINT                    mMMTimerThreadID = 0;

 VOID
 CALLBACK
 MMTimerThread (
   UINT  wTimerID,
   UINT  msg,
   DWORD dwUser,
   DWORD dw1,
   DWORD dw2
   )
 /*++

 Routine Description:

   TODO: Add function description

 Arguments:

   wTimerID  - TODO: add argument description
   msg       - TODO: add argument description
   dwUser    - TODO: add argument description
   dw1       - TODO: add argument description
   dw2       - TODO: add argument description

 Returns:

   TODO: add return values

 --*/
 {
   EFI_TPL           OriginalTPL;
   UINT32            CurrentTick;
   UINT32            Delta;
   EFI_TIMER_NOTIFY  CallbackFunction;
   BOOLEAN           InterruptState;

   if (!mCancelTimerThread) {

     //
     // Suspend the main thread until we are done.
     // Enter the critical section before suspending
     // and leave the critical section after resuming
     // to avoid deadlock between main and timer thread.
     //
     gWinNt->EnterCriticalSection (&mNtCriticalSection);
     gWinNt->SuspendThread (mNtMainThreadHandle);

     //
     // If the timer thread is being canceled, then bail immediately.
     // We check again here because there's a small window of time from when
     // this thread was kicked off and when we suspended the main thread above.
     //
     if (mCancelTimerThread) {
       gWinNt->ResumeThread (mNtMainThreadHandle);
       gWinNt->LeaveCriticalSection (&mNtCriticalSection);
       gWinNt->timeKillEvent (wTimerID);
       mMMTimerThreadID = 0;
       return ;
     }

     mCpu->GetInterruptState (mCpu, &InterruptState);
     while (!InterruptState) {
       //
       //  Resume the main thread
       //
       gWinNt->ResumeThread (mNtMainThreadHandle);
       gWinNt->LeaveCriticalSection (&mNtCriticalSection);

       //
       //  Wait for interrupts to be enabled.
       //
       mCpu->GetInterruptState (mCpu, &InterruptState);
       while (!InterruptState) {
         gWinNt->Sleep (1);
         mCpu->GetInterruptState (mCpu, &InterruptState);
       }

       //
       //  Suspend the main thread until we are done
       //
       gWinNt->EnterCriticalSection (&mNtCriticalSection);
       gWinNt->SuspendThread (mNtMainThreadHandle);
       mCpu->GetInterruptState (mCpu, &InterruptState);
     }

     //
     //  Get the current system tick
     //
     CurrentTick = gWinNt->GetTickCount ();
     Delta       = CurrentTick - mNtLastTick;
     mNtLastTick = CurrentTick;

     //
     //  If delay was more then 1 second, ignore it (probably debugging case)
     //
     if (Delta < 1000) {

       OriginalTPL = gBS->RaiseTPL (TPL_HIGH_LEVEL);

       //
       //  Inform the firmware of an "timer interrupt".  The time
       //  expired since the last call is 10,000 times the number
       //  of ms.  (or 100ns units)
       //
       CallbackFunction = mTimerNotifyFunction;

       //
       // Only invoke the callback function if a Non-NULL handler has been
       // registered. Assume all other handlers are legal.
       //
       if (CallbackFunction != NULL) {
         CallbackFunction ((UINT64) (Delta * 10000));
       }

       gBS->RestoreTPL (OriginalTPL);

     }

     //
     //  Resume the main thread
     //
     gWinNt->ResumeThread (mNtMainThreadHandle);
     gWinNt->LeaveCriticalSection (&mNtCriticalSection);
   } else {
     gWinNt->timeKillEvent (wTimerID);
     mMMTimerThreadID = 0;
   }

 }

 UINT
 CreateNtTimer (
   VOID
   )
 /*++

 Routine Description:

    It is used to emulate a platform
   timer-driver interrupt handler.

 Returns:

   Timer ID

 --*/
 // TODO: function comment is missing 'Arguments:'
 {
   UINT32  SleepCount;

   //
   //  Set our thread priority higher than the "main" thread.
   //
   gWinNt->SetThreadPriority (
             gWinNt->GetCurrentThread (),
             THREAD_PRIORITY_HIGHEST
             );

   //
   //  Calc the appropriate interval
   //
   gWinNt->EnterCriticalSection (&mNtCriticalSection);
   SleepCount = (UINT32) (mTimerPeriod + 5000) / 10000;
   gWinNt->LeaveCriticalSection (&mNtCriticalSection);

   return gWinNt->timeSetEvent (
                   SleepCount,
                   0,
                   MMTimerThread,
                   (DWORD_PTR) NULL,
                   TIME_PERIODIC | TIME_KILL_SYNCHRONOUS | TIME_CALLBACK_FUNCTION
                   );

 }

 EFI_STATUS
 EFIAPI
 WinNtTimerDriverRegisterHandler (
   IN EFI_TIMER_ARCH_PROTOCOL           *This,
   IN EFI_TIMER_NOTIFY                  NotifyFunction
   )
 /*++

 Routine Description:

   This function registers the handler NotifyFunction so it is called every time
   the timer interrupt fires.  It also passes the amount of time since the last
   handler call to the NotifyFunction.  If NotifyFunction is NULL, then the
   handler is unregistered.  If the handler is registered, then EFI_SUCCESS is
   returned.  If the CPU does not support registering a timer interrupt handler,
   then EFI_UNSUPPORTED is returned.  If an attempt is made to register a handler
   when a handler is already registered, then EFI_ALREADY_STARTED is returned.
   If an attempt is made to unregister a handler when a handler is not registered,
   then EFI_INVALID_PARAMETER is returned.  If an error occurs attempting to
   register the NotifyFunction with the timer interrupt, then EFI_DEVICE_ERROR
   is returned.

 Arguments:

   This           - The EFI_TIMER_ARCH_PROTOCOL instance.

   NotifyFunction - The function to call when a timer interrupt fires.  This
                    function executes at TPL_HIGH_LEVEL.  The DXE Core will
                    register a handler for the timer interrupt, so it can know
                    how much time has passed.  This information is used to
                    signal timer based events.  NULL will unregister the handler.

 Returns:

   EFI_SUCCESS           - The timer handler was registered.

   EFI_UNSUPPORTED       - The platform does not support timer interrupts.

   EFI_ALREADY_STARTED   - NotifyFunction is not NULL, and a handler is already
                           registered.

   EFI_INVALID_PARAMETER - NotifyFunction is NULL, and a handler was not
                           previously registered.

   EFI_DEVICE_ERROR      - The timer handler could not be registered.

 --*/
 {
   //
   // Check for invalid parameters
   //
   if (NotifyFunction == NULL && mTimerNotifyFunction == NULL) {
     return EFI_INVALID_PARAMETER;
   }

   if (NotifyFunction != NULL && mTimerNotifyFunction != NULL) {
     return EFI_ALREADY_STARTED;
   }

   //
   // Use Critical Section to update the notification function that is
   // used from the timer interrupt thread.
   //
   gWinNt->EnterCriticalSection (&mNtCriticalSection);

   mTimerNotifyFunction = NotifyFunction;

   gWinNt->LeaveCriticalSection (&mNtCriticalSection);

   return EFI_SUCCESS;
 }

 EFI_STATUS
 EFIAPI
 WinNtTimerDriverSetTimerPeriod (
   IN EFI_TIMER_ARCH_PROTOCOL  *This,
   IN UINT64                   TimerPeriod
   )
 /*++

 Routine Description:

   This function adjusts the period of timer interrupts to the value specified
   by TimerPeriod.  If the timer period is updated, then the selected timer
   period is stored in EFI_TIMER.TimerPeriod, and EFI_SUCCESS is returned.  If
   the timer hardware is not programmable, then EFI_UNSUPPORTED is returned.
   If an error occurs while attempting to update the timer period, then the
   timer hardware will be put back in its state prior to this call, and
   EFI_DEVICE_ERROR is returned.  If TimerPeriod is 0, then the timer interrupt
   is disabled.  This is not the same as disabling the CPU's interrupts.
   Instead, it must either turn off the timer hardware, or it must adjust the
   interrupt controller so that a CPU interrupt is not generated when the timer
   interrupt fires.

 Arguments:

   This        - The EFI_TIMER_ARCH_PROTOCOL instance.

   TimerPeriod - The rate to program the timer interrupt in 100 nS units.  If
                 the timer hardware is not programmable, then EFI_UNSUPPORTED is
                 returned.  If the timer is programmable, then the timer period
                 will be rounded up to the nearest timer period that is supported
                 by the timer hardware.  If TimerPeriod is set to 0, then the
                 timer interrupts will be disabled.

 Returns:

   EFI_SUCCESS      - The timer period was changed.

   EFI_UNSUPPORTED  - The platform cannot change the period of the timer interrupt.

   EFI_DEVICE_ERROR - The timer period could not be changed due to a device error.

 --*/
 {

   //
   // If TimerPeriod is 0, then the timer thread should be canceled
   //
   if (TimerPeriod == 0) {
     //
     // Cancel the timer thread
     //
     gWinNt->EnterCriticalSection (&mNtCriticalSection);

     mCancelTimerThread = TRUE;

     gWinNt->LeaveCriticalSection (&mNtCriticalSection);

     //
     // Wait for the timer thread to exit
     //

     if (mMMTimerThreadID) {
       gWinNt->timeKillEvent (mMMTimerThreadID);
     }

     mMMTimerThreadID = 0;

     //
     // Update the timer period
     //
     gWinNt->EnterCriticalSection (&mNtCriticalSection);

     mTimerPeriod = TimerPeriod;

     gWinNt->LeaveCriticalSection (&mNtCriticalSection);

     //
     // NULL out the thread handle so it will be re-created if the timer is enabled again
     //

   } else if ((TimerPeriod > TIMER_MINIMUM_VALUE) && (TimerPeriod < TIMER_MAXIMUM_VALUE)) {
     //
     // If the TimerPeriod is valid, then create and/or adjust the period of the timer thread
     //
     gWinNt->EnterCriticalSection (&mNtCriticalSection);

     mTimerPeriod        = TimerPeriod;

     mCancelTimerThread  = FALSE;

     gWinNt->LeaveCriticalSection (&mNtCriticalSection);

     //
     //  Get the starting tick location if we are just starting the timer thread
     //
     mNtLastTick = gWinNt->GetTickCount ();

     if (mMMTimerThreadID) {
       gWinNt->timeKillEvent (mMMTimerThreadID);
     }

     mMMTimerThreadID  = 0;

     mMMTimerThreadID  = CreateNtTimer ();

   }

   return EFI_SUCCESS;
 }

 EFI_STATUS
 EFIAPI
 WinNtTimerDriverGetTimerPeriod (
   IN EFI_TIMER_ARCH_PROTOCOL            *This,
   OUT UINT64                            *TimerPeriod
   )
 /*++

 Routine Description:

   This function retrieves the period of timer interrupts in 100 ns units,
   returns that value in TimerPeriod, and returns EFI_SUCCESS.  If TimerPeriod
   is NULL, then EFI_INVALID_PARAMETER is returned.  If a TimerPeriod of 0 is
   returned, then the timer is currently disabled.

 Arguments:

   This        - The EFI_TIMER_ARCH_PROTOCOL instance.

   TimerPeriod - A pointer to the timer period to retrieve in 100 ns units.  If
                 0 is returned, then the timer is currently disabled.

 Returns:

   EFI_SUCCESS           - The timer period was returned in TimerPeriod.

   EFI_INVALID_PARAMETER - TimerPeriod is NULL.

 --*/
 {
   if (TimerPeriod == NULL) {
     return EFI_INVALID_PARAMETER;
   }

   *TimerPeriod = mTimerPeriod;

   return EFI_SUCCESS;
 }

 EFI_STATUS
 EFIAPI
 WinNtTimerDriverGenerateSoftInterrupt (
   IN EFI_TIMER_ARCH_PROTOCOL  *This
   )
 /*++

 Routine Description:

   This function generates a soft timer interrupt. If the platform does not support soft
   timer interrupts, then EFI_UNSUPPORTED is returned. Otherwise, EFI_SUCCESS is returned.
   If a handler has been registered through the EFI_TIMER_ARCH_PROTOCOL.RegisterHandler()
   service, then a soft timer interrupt will be generated. If the timer interrupt is
   enabled when this service is called, then the registered handler will be invoked. The
   registered handler should not be able to distinguish a hardware-generated timer
   interrupt from a software-generated timer interrupt.

 Arguments:

   This  -  The EFI_TIMER_ARCH_PROTOCOL instance.

 Returns:

   EFI_SUCCESS       - The soft timer interrupt was generated.

   EFI_UNSUPPORTEDT  - The platform does not support the generation of soft timer interrupts.

 --*/
 {
   return EFI_UNSUPPORTED;
 }


 EFI_STATUS
 EFIAPI
 WinNtTimerDriverInitialize (
   IN EFI_HANDLE        ImageHandle,
   IN EFI_SYSTEM_TABLE  *SystemTable
   )
 /*++

 Routine Description:

   Initialize the Timer Architectural Protocol driver

 Arguments:

   ImageHandle - ImageHandle of the loaded driver

   SystemTable - Pointer to the System Table

 Returns:

   EFI_SUCCESS           - Timer Architectural Protocol created

   EFI_OUT_OF_RESOURCES  - Not enough resources available to initialize driver.

   EFI_DEVICE_ERROR      - A device error occured attempting to initialize the driver.

 --*/
 {
   EFI_STATUS  Status;
   UINTN       Result;
   EFI_HANDLE  Handle;
   EFI_HANDLE  hSourceProcessHandle;
   EFI_HANDLE  hSourceHandle;
   EFI_HANDLE  hTargetProcessHandle;
   //
   // Make sure the Timer Architectural Protocol is not already installed in the system
   //
   ASSERT_PROTOCOL_ALREADY_INSTALLED (NULL, &gEfiTimerArchProtocolGuid);

   //
   // Get the CPU Architectural Protocol instance
   //
   Status = gBS->LocateProtocol (&gEfiCpuArchProtocolGuid, NULL, (VOID**)&mCpu);
   ASSERT_EFI_ERROR (Status);

   //
   //  Get our handle so the timer tick thread can suspend
   //
   hSourceProcessHandle = gWinNt->GetCurrentProcess ();
   hSourceHandle        = gWinNt->GetCurrentThread ();
   hTargetProcessHandle = gWinNt->GetCurrentProcess ();
   Result = gWinNt->DuplicateHandle (
                     hSourceProcessHandle,
                     hSourceHandle,
                     hTargetProcessHandle,
                     &mNtMainThreadHandle,
                     0,
                     FALSE,
                     DUPLICATE_SAME_ACCESS
                     );
   if (Result == 0) {
     return EFI_DEVICE_ERROR;
   }

   //
   // Initialize Critical Section used to update variables shared between the main
   // thread and the timer interrupt thread.
   //
   gWinNt->InitializeCriticalSection (&mNtCriticalSection);

   //
   // Start the timer thread at the default timer period
   //
   Status = mTimer.SetTimerPeriod (&mTimer, DEFAULT_TIMER_TICK_DURATION);
   if (EFI_ERROR (Status)) {
     gWinNt->DeleteCriticalSection (&mNtCriticalSection);
     return Status;
   }

   //
   // Install the Timer Architectural Protocol onto a new handle
   //
   Handle = NULL;
   Status = gBS->InstallProtocolInterface (
                   &Handle,
                   &gEfiTimerArchProtocolGuid,
                   EFI_NATIVE_INTERFACE,
                   &mTimer
                   );
   if (EFI_ERROR (Status)) {
     //
     // Cancel the timer
     //
     mTimer.SetTimerPeriod (&mTimer, 0);
     gWinNt->DeleteCriticalSection (&mNtCriticalSection);
     return Status;
   }

   return EFI_SUCCESS;
 }
	/**@file

	Copyright (c) 2006, Intel Corporation. All rights reserved.<BR>
	This program and the accompanying materials
	are licensed and made available under the terms and conditions of the BSD License
	which accompanies this distribution. The full text of the license may be found at
	http://opensource.org/licenses/bsd-license.php

	THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,
	WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.

	Module Name:

	Timer.c

	Abstract:

	NT Emulation Timer Architectural Protocol Driver as defined in DXE CIS

	This Timer module uses an NT Thread to simulate the timer-tick driven
	timer service. In the future, the Thread creation should possibly be
	abstracted by the CPU architectural protocol

	**/

	#include "Timer.h"

	//
	// Pointer to the CPU Architectural Protocol instance
	//
	EFI_CPU_ARCH_PROTOCOL *mCpu;

	//
	// The Timer Architectural Protocol that this driver produces
	//
	EFI_TIMER_ARCH_PROTOCOL mTimer = {
	WinNtTimerDriverRegisterHandler,
	WinNtTimerDriverSetTimerPeriod,
	WinNtTimerDriverGetTimerPeriod,
	WinNtTimerDriverGenerateSoftInterrupt
	};

	//
	// Define a global that we can use to shut down the NT timer thread when
	// the timer is canceled.
	//
	BOOLEAN mCancelTimerThread = FALSE;

	//
	// The notification function to call on every timer interrupt
	//
	EFI_TIMER_NOTIFY mTimerNotifyFunction = NULL;

	//
	// The current period of the timer interrupt
	//
	UINT64 mTimerPeriod;

	//
	// The thread handle for this driver
	//
	HANDLE mNtMainThreadHandle;

	//
	// The timer value from the last timer interrupt
	//
	UINT32 mNtLastTick;

	//
	// Critical section used to update varibles shared between the main thread and
	// the timer interrupt thread.
	//
	CRITICAL_SECTION mNtCriticalSection;

	//
	// Worker Functions
	//
	UINT mMMTimerThreadID = 0;

	VOID
	CALLBACK
	MMTimerThread (
	UINT wTimerID,
	UINT msg,
	DWORD dwUser,
	DWORD dw1,
	DWORD dw2
	)
	/*++

	Routine Description:

	TODO: Add function description

	Arguments:

	wTimerID - TODO: add argument description
	msg - TODO: add argument description
	dwUser - TODO: add argument description
	dw1 - TODO: add argument description
	dw2 - TODO: add argument description

	Returns:

	TODO: add return values

	--*/
	{
	EFI_TPL OriginalTPL;
	UINT32 CurrentTick;
	UINT32 Delta;
	EFI_TIMER_NOTIFY CallbackFunction;
	BOOLEAN InterruptState;

	if (!mCancelTimerThread) {

	//
	// Suspend the main thread until we are done.
	// Enter the critical section before suspending
	// and leave the critical section after resuming
	// to avoid deadlock between main and timer thread.
	//
	gWinNt->EnterCriticalSection (&mNtCriticalSection);
	gWinNt->SuspendThread (mNtMainThreadHandle);

	//
	// If the timer thread is being canceled, then bail immediately.
	// We check again here because there's a small window of time from when
	// this thread was kicked off and when we suspended the main thread above.
	//
	if (mCancelTimerThread) {
	gWinNt->ResumeThread (mNtMainThreadHandle);
	gWinNt->LeaveCriticalSection (&mNtCriticalSection);
	gWinNt->timeKillEvent (wTimerID);
	mMMTimerThreadID = 0;
	return ;
	}

	mCpu->GetInterruptState (mCpu, &InterruptState);
	while (!InterruptState) {
	//
	// Resume the main thread
	//
	gWinNt->ResumeThread (mNtMainThreadHandle);
	gWinNt->LeaveCriticalSection (&mNtCriticalSection);

	//
	// Wait for interrupts to be enabled.
	//
	mCpu->GetInterruptState (mCpu, &InterruptState);
	while (!InterruptState) {
	gWinNt->Sleep (1);
	mCpu->GetInterruptState (mCpu, &InterruptState);
	}

	//
	// Suspend the main thread until we are done
	//
	gWinNt->EnterCriticalSection (&mNtCriticalSection);
	gWinNt->SuspendThread (mNtMainThreadHandle);
	mCpu->GetInterruptState (mCpu, &InterruptState);
	}

	//
	// Get the current system tick
	//
	CurrentTick = gWinNt->GetTickCount ();
	Delta = CurrentTick - mNtLastTick;
	mNtLastTick = CurrentTick;

	//
	// If delay was more then 1 second, ignore it (probably debugging case)
	//
	if (Delta < 1000) {

	OriginalTPL = gBS->RaiseTPL (TPL_HIGH_LEVEL);

	//
	// Inform the firmware of an "timer interrupt". The time
	// expired since the last call is 10,000 times the number
	// of ms. (or 100ns units)
	//
	CallbackFunction = mTimerNotifyFunction;

	//
	// Only invoke the callback function if a Non-NULL handler has been
	// registered. Assume all other handlers are legal.
	//
	if (CallbackFunction != NULL) {
	CallbackFunction ((UINT64) (Delta * 10000));
	}

	gBS->RestoreTPL (OriginalTPL);

	}

	//
	// Resume the main thread
	//
	gWinNt->ResumeThread (mNtMainThreadHandle);
	gWinNt->LeaveCriticalSection (&mNtCriticalSection);
	} else {
	gWinNt->timeKillEvent (wTimerID);
	mMMTimerThreadID = 0;
	}

	}

	UINT
	CreateNtTimer (
	VOID
	)
	/*++

	Routine Description:

	It is used to emulate a platform
	timer-driver interrupt handler.

	Returns:

	Timer ID

	--*/
	// TODO: function comment is missing 'Arguments:'
	{
	UINT32 SleepCount;

	//
	// Set our thread priority higher than the "main" thread.
	//
	gWinNt->SetThreadPriority (
	gWinNt->GetCurrentThread (),
	THREAD_PRIORITY_HIGHEST
	);

	//
	// Calc the appropriate interval
	//
	gWinNt->EnterCriticalSection (&mNtCriticalSection);
	SleepCount = (UINT32) (mTimerPeriod + 5000) / 10000;
	gWinNt->LeaveCriticalSection (&mNtCriticalSection);

	return gWinNt->timeSetEvent (
	SleepCount,
	0,
	MMTimerThread,
	(DWORD_PTR) NULL,
	TIME_PERIODIC \| TIME_KILL_SYNCHRONOUS \| TIME_CALLBACK_FUNCTION
	);

	}

	EFI_STATUS
	EFIAPI
	WinNtTimerDriverRegisterHandler (
	IN EFI_TIMER_ARCH_PROTOCOL *This,
	IN EFI_TIMER_NOTIFY NotifyFunction
	)
	/*++

	Routine Description:

	This function registers the handler NotifyFunction so it is called every time
	the timer interrupt fires. It also passes the amount of time since the last
	handler call to the NotifyFunction. If NotifyFunction is NULL, then the
	handler is unregistered. If the handler is registered, then EFI_SUCCESS is
	returned. If the CPU does not support registering a timer interrupt handler,
	then EFI_UNSUPPORTED is returned. If an attempt is made to register a handler
	when a handler is already registered, then EFI_ALREADY_STARTED is returned.
	If an attempt is made to unregister a handler when a handler is not registered,
	then EFI_INVALID_PARAMETER is returned. If an error occurs attempting to
	register the NotifyFunction with the timer interrupt, then EFI_DEVICE_ERROR
	is returned.

	Arguments:

	This - The EFI_TIMER_ARCH_PROTOCOL instance.

	NotifyFunction - The function to call when a timer interrupt fires. This
	function executes at TPL_HIGH_LEVEL. The DXE Core will
	register a handler for the timer interrupt, so it can know
	how much time has passed. This information is used to
	signal timer based events. NULL will unregister the handler.

	Returns:

	EFI_SUCCESS - The timer handler was registered.

	EFI_UNSUPPORTED - The platform does not support timer interrupts.

	EFI_ALREADY_STARTED - NotifyFunction is not NULL, and a handler is already
	registered.

	EFI_INVALID_PARAMETER - NotifyFunction is NULL, and a handler was not
	previously registered.

	EFI_DEVICE_ERROR - The timer handler could not be registered.

	--*/
	{
	//
	// Check for invalid parameters
	//
	if (NotifyFunction == NULL && mTimerNotifyFunction == NULL) {
	return EFI_INVALID_PARAMETER;
	}

	if (NotifyFunction != NULL && mTimerNotifyFunction != NULL) {
	return EFI_ALREADY_STARTED;
	}

	//
	// Use Critical Section to update the notification function that is
	// used from the timer interrupt thread.
	//
	gWinNt->EnterCriticalSection (&mNtCriticalSection);

	mTimerNotifyFunction = NotifyFunction;

	gWinNt->LeaveCriticalSection (&mNtCriticalSection);

	return EFI_SUCCESS;
	}

	EFI_STATUS
	EFIAPI
	WinNtTimerDriverSetTimerPeriod (
	IN EFI_TIMER_ARCH_PROTOCOL *This,
	IN UINT64 TimerPeriod
	)
	/*++

	Routine Description:

	This function adjusts the period of timer interrupts to the value specified
	by TimerPeriod. If the timer period is updated, then the selected timer
	period is stored in EFI_TIMER.TimerPeriod, and EFI_SUCCESS is returned. If
	the timer hardware is not programmable, then EFI_UNSUPPORTED is returned.
	If an error occurs while attempting to update the timer period, then the
	timer hardware will be put back in its state prior to this call, and
	EFI_DEVICE_ERROR is returned. If TimerPeriod is 0, then the timer interrupt
	is disabled. This is not the same as disabling the CPU's interrupts.
	Instead, it must either turn off the timer hardware, or it must adjust the
	interrupt controller so that a CPU interrupt is not generated when the timer
	interrupt fires.

	Arguments:

	This - The EFI_TIMER_ARCH_PROTOCOL instance.

	TimerPeriod - The rate to program the timer interrupt in 100 nS units. If
	the timer hardware is not programmable, then EFI_UNSUPPORTED is
	returned. If the timer is programmable, then the timer period
	will be rounded up to the nearest timer period that is supported
	by the timer hardware. If TimerPeriod is set to 0, then the
	timer interrupts will be disabled.

	Returns:

	EFI_SUCCESS - The timer period was changed.

	EFI_UNSUPPORTED - The platform cannot change the period of the timer interrupt.

	EFI_DEVICE_ERROR - The timer period could not be changed due to a device error.

	--*/
	{

	//
	// If TimerPeriod is 0, then the timer thread should be canceled
	//
	if (TimerPeriod == 0) {
	//
	// Cancel the timer thread
	//
	gWinNt->EnterCriticalSection (&mNtCriticalSection);

	mCancelTimerThread = TRUE;

	gWinNt->LeaveCriticalSection (&mNtCriticalSection);

	//
	// Wait for the timer thread to exit
	//

	if (mMMTimerThreadID) {
	gWinNt->timeKillEvent (mMMTimerThreadID);
	}

	mMMTimerThreadID = 0;

	//
	// Update the timer period
	//
	gWinNt->EnterCriticalSection (&mNtCriticalSection);

	mTimerPeriod = TimerPeriod;

	gWinNt->LeaveCriticalSection (&mNtCriticalSection);

	//
	// NULL out the thread handle so it will be re-created if the timer is enabled again
	//

	} else if ((TimerPeriod > TIMER_MINIMUM_VALUE) && (TimerPeriod < TIMER_MAXIMUM_VALUE)) {
	//
	// If the TimerPeriod is valid, then create and/or adjust the period of the timer thread
	//
	gWinNt->EnterCriticalSection (&mNtCriticalSection);

	mTimerPeriod = TimerPeriod;

	mCancelTimerThread = FALSE;

	gWinNt->LeaveCriticalSection (&mNtCriticalSection);

	//
	// Get the starting tick location if we are just starting the timer thread
	//
	mNtLastTick = gWinNt->GetTickCount ();

	if (mMMTimerThreadID) {
	gWinNt->timeKillEvent (mMMTimerThreadID);
	}

	mMMTimerThreadID = 0;

	mMMTimerThreadID = CreateNtTimer ();

	}

	return EFI_SUCCESS;
	}

	EFI_STATUS
	EFIAPI
	WinNtTimerDriverGetTimerPeriod (
	IN EFI_TIMER_ARCH_PROTOCOL *This,
	OUT UINT64 *TimerPeriod
	)
	/*++

	Routine Description:

	This function retrieves the period of timer interrupts in 100 ns units,
	returns that value in TimerPeriod, and returns EFI_SUCCESS. If TimerPeriod
	is NULL, then EFI_INVALID_PARAMETER is returned. If a TimerPeriod of 0 is
	returned, then the timer is currently disabled.

	Arguments:

	This - The EFI_TIMER_ARCH_PROTOCOL instance.

	TimerPeriod - A pointer to the timer period to retrieve in 100 ns units. If
	0 is returned, then the timer is currently disabled.

	Returns:

	EFI_SUCCESS - The timer period was returned in TimerPeriod.

	EFI_INVALID_PARAMETER - TimerPeriod is NULL.

	--*/
	{
	if (TimerPeriod == NULL) {
	return EFI_INVALID_PARAMETER;
	}

	*TimerPeriod = mTimerPeriod;

	return EFI_SUCCESS;
	}

	EFI_STATUS
	EFIAPI
	WinNtTimerDriverGenerateSoftInterrupt (
	IN EFI_TIMER_ARCH_PROTOCOL *This
	)
	/*++

	Routine Description:

	This function generates a soft timer interrupt. If the platform does not support soft
	timer interrupts, then EFI_UNSUPPORTED is returned. Otherwise, EFI_SUCCESS is returned.
	If a handler has been registered through the EFI_TIMER_ARCH_PROTOCOL.RegisterHandler()
	service, then a soft timer interrupt will be generated. If the timer interrupt is
	enabled when this service is called, then the registered handler will be invoked. The
	registered handler should not be able to distinguish a hardware-generated timer
	interrupt from a software-generated timer interrupt.

	Arguments:

	This - The EFI_TIMER_ARCH_PROTOCOL instance.

	Returns:

	EFI_SUCCESS - The soft timer interrupt was generated.

	EFI_UNSUPPORTEDT - The platform does not support the generation of soft timer interrupts.

	--*/
	{
	return EFI_UNSUPPORTED;
	}


	EFI_STATUS
	EFIAPI
	WinNtTimerDriverInitialize (
	IN EFI_HANDLE ImageHandle,
	IN EFI_SYSTEM_TABLE *SystemTable
	)
	/*++

	Routine Description:

	Initialize the Timer Architectural Protocol driver

	Arguments:

	ImageHandle - ImageHandle of the loaded driver

	SystemTable - Pointer to the System Table

	Returns:

	EFI_SUCCESS - Timer Architectural Protocol created

	EFI_OUT_OF_RESOURCES - Not enough resources available to initialize driver.

	EFI_DEVICE_ERROR - A device error occured attempting to initialize the driver.

	--*/
	{
	EFI_STATUS Status;
	UINTN Result;
	EFI_HANDLE Handle;
	EFI_HANDLE hSourceProcessHandle;
	EFI_HANDLE hSourceHandle;
	EFI_HANDLE hTargetProcessHandle;
	//
	// Make sure the Timer Architectural Protocol is not already installed in the system
	//
	ASSERT_PROTOCOL_ALREADY_INSTALLED (NULL, &gEfiTimerArchProtocolGuid);

	//
	// Get the CPU Architectural Protocol instance
	//
	Status = gBS->LocateProtocol (&gEfiCpuArchProtocolGuid, NULL, (VOID**)&mCpu);
	ASSERT_EFI_ERROR (Status);

	//
	// Get our handle so the timer tick thread can suspend
	//
	hSourceProcessHandle = gWinNt->GetCurrentProcess ();
	hSourceHandle = gWinNt->GetCurrentThread ();
	hTargetProcessHandle = gWinNt->GetCurrentProcess ();
	Result = gWinNt->DuplicateHandle (
	hSourceProcessHandle,
	hSourceHandle,
	hTargetProcessHandle,
	&mNtMainThreadHandle,
	0,
	FALSE,
	DUPLICATE_SAME_ACCESS
	);
	if (Result == 0) {
	return EFI_DEVICE_ERROR;
	}

	//
	// Initialize Critical Section used to update variables shared between the main
	// thread and the timer interrupt thread.
	//
	gWinNt->InitializeCriticalSection (&mNtCriticalSection);

	//
	// Start the timer thread at the default timer period
	//
	Status = mTimer.SetTimerPeriod (&mTimer, DEFAULT_TIMER_TICK_DURATION);
	if (EFI_ERROR (Status)) {
	gWinNt->DeleteCriticalSection (&mNtCriticalSection);
	return Status;
	}

	//
	// Install the Timer Architectural Protocol onto a new handle
	//
	Handle = NULL;
	Status = gBS->InstallProtocolInterface (
	&Handle,
	&gEfiTimerArchProtocolGuid,
	EFI_NATIVE_INTERFACE,
	&mTimer
	);
	if (EFI_ERROR (Status)) {
	//
	// Cancel the timer
	//
	mTimer.SetTimerPeriod (&mTimer, 0);
	gWinNt->DeleteCriticalSection (&mNtCriticalSection);
	return Status;
	}

	return EFI_SUCCESS;
	}