FatPkg/EnhancedFatDxe/Misc.c - third_party/edk2 - Git at Google

 /** @file
   Miscellaneous functions.

 Copyright (c) 2005 - 2018, Intel Corporation. All rights reserved.<BR>
 SPDX-License-Identifier: BSD-2-Clause-Patent


 **/

 #include "Fat.h"
 UINT8  mMonthDays[] = { 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 };

 /**

   Create the task

   @param  IFile                 - The instance of the open file.
   @param  Token                 - A pointer to the token associated with the transaction.

   @return FAT_TASK *            - Return the task instance.

 **/
 FAT_TASK *
 FatCreateTask (
   FAT_IFILE           *IFile,
   EFI_FILE_IO_TOKEN   *Token
   )
 {
   FAT_TASK            *Task;

   Task = AllocateZeroPool (sizeof (*Task));
   if (Task != NULL) {
     Task->Signature   = FAT_TASK_SIGNATURE;
     Task->IFile       = IFile;
     Task->FileIoToken = Token;
     InitializeListHead (&Task->Subtasks);
     InitializeListHead (&Task->Link);
   }
   return Task;
 }

 /**

   Destroy the task.

   @param  Task                  - The task to be destroyed.

 **/
 VOID
 FatDestroyTask (
   FAT_TASK            *Task
   )
 {
   LIST_ENTRY          *Link;
   FAT_SUBTASK         *Subtask;

   Link = GetFirstNode (&Task->Subtasks);
   while (!IsNull (&Task->Subtasks, Link)) {
     Subtask = CR (Link, FAT_SUBTASK, Link, FAT_SUBTASK_SIGNATURE);
     Link = FatDestroySubtask (Subtask);
   }
   FreePool (Task);
 }

 /**

   Wait all non-blocking requests complete.

   @param  IFile                 - The instance of the open file.

 **/
 VOID
 FatWaitNonblockingTask (
   FAT_IFILE           *IFile
   )
 {
   BOOLEAN             TaskQueueEmpty;

   do {
     EfiAcquireLock (&FatTaskLock);
     TaskQueueEmpty = IsListEmpty (&IFile->Tasks);
     EfiReleaseLock (&FatTaskLock);
   } while (!TaskQueueEmpty);
 }

 /**

   Remove the subtask from subtask list.

   @param  Subtask               - The subtask to be removed.

   @return LIST_ENTRY *          - The next node in the list.

 **/
 LIST_ENTRY *
 FatDestroySubtask (
   FAT_SUBTASK         *Subtask
   )
 {
   LIST_ENTRY          *Link;

   gBS->CloseEvent (Subtask->DiskIo2Token.Event);

   Link = RemoveEntryList (&Subtask->Link);
   FreePool (Subtask);

   return Link;
 }

 /**

   Execute the task.

   @param  IFile                 - The instance of the open file.
   @param  Task                  - The task to be executed.

   @retval EFI_SUCCESS           - The task was executed successfully.
   @return other                 - An error occurred when executing the task.

 **/
 EFI_STATUS
 FatQueueTask (
   IN FAT_IFILE        *IFile,
   IN FAT_TASK         *Task
   )
 {
   EFI_STATUS          Status;
   LIST_ENTRY          *Link;
   LIST_ENTRY          *NextLink;
   FAT_SUBTASK         *Subtask;

   //
   // Sometimes the Task doesn't contain any subtasks, signal the event directly.
   //
   if (IsListEmpty (&Task->Subtasks)) {
     Task->FileIoToken->Status = EFI_SUCCESS;
     gBS->SignalEvent (Task->FileIoToken->Event);
     FreePool (Task);
     return EFI_SUCCESS;
   }

   EfiAcquireLock (&FatTaskLock);
   InsertTailList (&IFile->Tasks, &Task->Link);
   EfiReleaseLock (&FatTaskLock);

   Status = EFI_SUCCESS;
   //
   // Use NextLink to store the next link of the list, because Link might be remove from the
   // doubly-linked list and get freed in the end of current loop.
   //
   // Also, list operation APIs like IsNull() and GetNextNode() are avoided during the loop, since
   // they may check the validity of doubly-linked lists by traversing them. These APIs cannot
   // handle list elements being removed during the traverse.
   //
   for ( Link = GetFirstNode (&Task->Subtasks), NextLink = GetNextNode (&Task->Subtasks, Link)
       ; Link != &Task->Subtasks
       ; Link = NextLink, NextLink = Link->ForwardLink
       ) {
     Subtask = CR (Link, FAT_SUBTASK, Link, FAT_SUBTASK_SIGNATURE);
     if (Subtask->Write) {

       Status = IFile->OFile->Volume->DiskIo2->WriteDiskEx (
                                                 IFile->OFile->Volume->DiskIo2,
                                                 IFile->OFile->Volume->MediaId,
                                                 Subtask->Offset,
                                                 &Subtask->DiskIo2Token,
                                                 Subtask->BufferSize,
                                                 Subtask->Buffer
                                                 );
     } else {
       Status = IFile->OFile->Volume->DiskIo2->ReadDiskEx (
                                                 IFile->OFile->Volume->DiskIo2,
                                                 IFile->OFile->Volume->MediaId,
                                                 Subtask->Offset,
                                                 &Subtask->DiskIo2Token,
                                                 Subtask->BufferSize,
                                                 Subtask->Buffer
                                                 );
     }
     if (EFI_ERROR (Status)) {
       break;
     }
   }

   if (EFI_ERROR (Status)) {
     EfiAcquireLock (&FatTaskLock);
     //
     // Remove all the remaining subtasks when failure.
     // We shouldn't remove all the tasks because the non-blocking requests have
     // been submitted and cannot be canceled.
     //
     while (!IsNull (&Task->Subtasks, Link)) {
       Subtask = CR (Link, FAT_SUBTASK, Link, FAT_SUBTASK_SIGNATURE);
       Link = FatDestroySubtask (Subtask);
     }

     if (IsListEmpty (&Task->Subtasks)) {
       RemoveEntryList (&Task->Link);
       FreePool (Task);
     } else {
       //
       // If one or more subtasks have been already submitted, set FileIoToken
       // to NULL so that the callback won't signal the event.
       //
       Task->FileIoToken = NULL;
     }

     EfiReleaseLock (&FatTaskLock);
   }

   return Status;
 }

 /**

   Set the volume as dirty or not.

   @param  Volume                - FAT file system volume.
   @param  IoMode                - The access mode.
   @param  DirtyValue            - Set the volume as dirty or not.

   @retval EFI_SUCCESS           - Set the new FAT entry value successfully.
   @return other                 - An error occurred when operation the FAT entries.

 **/
 EFI_STATUS
 FatAccessVolumeDirty (
   IN FAT_VOLUME       *Volume,
   IN IO_MODE          IoMode,
   IN VOID             *DirtyValue
   )
 {
   UINTN WriteCount;

   WriteCount = Volume->FatEntrySize;
   return FatDiskIo (Volume, IoMode, Volume->FatPos + WriteCount, WriteCount, DirtyValue, NULL);
 }

 /**
   Invoke a notification event.

   @param  Event                 Event whose notification function is being invoked.
   @param  Context               The pointer to the notification function's context,
                                 which is implementation-dependent.

 **/
 VOID
 EFIAPI
 FatOnAccessComplete (
   IN  EFI_EVENT                Event,
   IN  VOID                     *Context
   )
 {
   EFI_STATUS             Status;
   FAT_SUBTASK            *Subtask;
   FAT_TASK               *Task;

   //
   // Avoid someone in future breaks the below assumption.
   //
   ASSERT (EfiGetCurrentTpl () == FatTaskLock.Tpl);

   Subtask = (FAT_SUBTASK *) Context;
   Task    = Subtask->Task;
   Status  = Subtask->DiskIo2Token.TransactionStatus;

   ASSERT (Task->Signature    == FAT_TASK_SIGNATURE);
   ASSERT (Subtask->Signature == FAT_SUBTASK_SIGNATURE);

   //
   // Remove the task unconditionally
   //
   FatDestroySubtask (Subtask);

   //
   // Task->FileIoToken is NULL which means the task will be ignored (just recycle the subtask and task memory).
   //
   if (Task->FileIoToken != NULL) {
     if (IsListEmpty (&Task->Subtasks) || EFI_ERROR (Status)) {
       Task->FileIoToken->Status = Status;
       gBS->SignalEvent (Task->FileIoToken->Event);
       //
       // Mark Task->FileIoToken to NULL so that the subtasks belonging to the task will be ignored.
       //
       Task->FileIoToken = NULL;
     }
   }

   if (IsListEmpty (&Task->Subtasks)) {
     RemoveEntryList (&Task->Link);
     FreePool (Task);
   }
 }

 /**

   General disk access function.

   @param  Volume                - FAT file system volume.
   @param  IoMode                - The access mode (disk read/write or cache access).
   @param  Offset                - The starting byte offset to read from.
   @param  BufferSize            - Size of Buffer.
   @param  Buffer                - Buffer containing read data.
   @param  Task                    point to task instance.

   @retval EFI_SUCCESS           - The operation is performed successfully.
   @retval EFI_VOLUME_CORRUPTED  - The access is
   @return Others                - The status of read/write the disk

 **/
 EFI_STATUS
 FatDiskIo (
   IN     FAT_VOLUME       *Volume,
   IN     IO_MODE          IoMode,
   IN     UINT64           Offset,
   IN     UINTN            BufferSize,
   IN OUT VOID             *Buffer,
   IN     FAT_TASK         *Task
   )
 {
   EFI_STATUS            Status;
   EFI_DISK_IO_PROTOCOL  *DiskIo;
   EFI_DISK_READ         IoFunction;
   FAT_SUBTASK           *Subtask;

   //
   // Verify the IO is in devices range
   //
   Status = EFI_VOLUME_CORRUPTED;
   if (Offset + BufferSize <= Volume->VolumeSize) {
     if (CACHE_ENABLED (IoMode)) {
       //
       // Access cache
       //
       Status = FatAccessCache (Volume, CACHE_TYPE (IoMode), RAW_ACCESS (IoMode), Offset, BufferSize, Buffer, Task);
     } else {
       //
       // Access disk directly
       //
       if (Task == NULL) {
         //
         // Blocking access
         //
         DiskIo      = Volume->DiskIo;
         IoFunction  = (IoMode == ReadDisk) ? DiskIo->ReadDisk : DiskIo->WriteDisk;
         Status      = IoFunction (DiskIo, Volume->MediaId, Offset, BufferSize, Buffer);
       } else {
         //
         // Non-blocking access
         //
         Subtask = AllocateZeroPool (sizeof (*Subtask));
         if (Subtask == NULL) {
           Status        = EFI_OUT_OF_RESOURCES;
         } else {
           Subtask->Signature  = FAT_SUBTASK_SIGNATURE;
           Subtask->Task       = Task;
           Subtask->Write      = (BOOLEAN) (IoMode == WriteDisk);
           Subtask->Offset     = Offset;
           Subtask->Buffer     = Buffer;
           Subtask->BufferSize = BufferSize;
           Status = gBS->CreateEvent (
                           EVT_NOTIFY_SIGNAL,
                           TPL_NOTIFY,
                           FatOnAccessComplete,
                           Subtask,
                           &Subtask->DiskIo2Token.Event
                           );
           if (!EFI_ERROR (Status)) {
             InsertTailList (&Task->Subtasks, &Subtask->Link);
           } else {
             FreePool (Subtask);
           }
         }
       }
     }
   }

   if (EFI_ERROR (Status)) {
     Volume->DiskError = TRUE;
     DEBUG ((EFI_D_ERROR, "FatDiskIo: error %r\n", Status));
   }

   return Status;
 }

 /**

   Lock the volume.

 **/
 VOID
 FatAcquireLock (
   VOID
   )
 {
   EfiAcquireLock (&FatFsLock);
 }

 /**

   Lock the volume.
   If the lock is already in the acquired state, then EFI_ACCESS_DENIED is returned.
   Otherwise, EFI_SUCCESS is returned.

   @retval EFI_SUCCESS           - The volume is locked.
   @retval EFI_ACCESS_DENIED     - The volume could not be locked because it is already locked.

 **/
 EFI_STATUS
 FatAcquireLockOrFail (
   VOID
   )
 {
   return EfiAcquireLockOrFail (&FatFsLock);
 }

 /**

   Unlock the volume.

 **/
 VOID
 FatReleaseLock (
   VOID
   )
 {
   EfiReleaseLock (&FatFsLock);
 }

 /**

   Free directory entry.

   @param  DirEnt                - The directory entry to be freed.

 **/
 VOID
 FatFreeDirEnt (
   IN FAT_DIRENT       *DirEnt
   )
 {
   if (DirEnt->FileString != NULL) {
     FreePool (DirEnt->FileString);
   }

   FreePool (DirEnt);
 }

 /**

   Free volume structure (including the contents of directory cache and disk cache).

   @param  Volume                - The volume structure to be freed.

 **/
 VOID
 FatFreeVolume (
   IN FAT_VOLUME       *Volume
   )
 {
   //
   // Free disk cache
   //
   if (Volume->CacheBuffer != NULL) {
     FreePool (Volume->CacheBuffer);
   }
   //
   // Free directory cache
   //
   FatCleanupODirCache (Volume);
   FreePool (Volume);
 }

 /**

   Translate EFI time to FAT time.

   @param  ETime                 - The time of EFI_TIME.
   @param  FTime                 - The time of FAT_DATE_TIME.

 **/
 VOID
 FatEfiTimeToFatTime (
   IN  EFI_TIME        *ETime,
   OUT FAT_DATE_TIME   *FTime
   )
 {
   //
   // ignores timezone info in source ETime
   //
   if (ETime->Year > 1980) {
     FTime->Date.Year = (UINT16) (ETime->Year - 1980);
   }

   if (ETime->Year >= 1980 + FAT_MAX_YEAR_FROM_1980) {
     FTime->Date.Year = FAT_MAX_YEAR_FROM_1980;
   }

   FTime->Date.Month         = ETime->Month;
   FTime->Date.Day           = ETime->Day;
   FTime->Time.Hour          = ETime->Hour;
   FTime->Time.Minute        = ETime->Minute;
   FTime->Time.DoubleSecond  = (UINT16) (ETime->Second / 2);
 }

 /**

   Translate Fat time to EFI time.

   @param  FTime                 - The time of FAT_DATE_TIME.
   @param  ETime                 - The time of EFI_TIME..

 **/
 VOID
 FatFatTimeToEfiTime (
   IN  FAT_DATE_TIME     *FTime,
   OUT EFI_TIME          *ETime
   )
 {
   ETime->Year       = (UINT16) (FTime->Date.Year + 1980);
   ETime->Month      = (UINT8) FTime->Date.Month;
   ETime->Day        = (UINT8) FTime->Date.Day;
   ETime->Hour       = (UINT8) FTime->Time.Hour;
   ETime->Minute     = (UINT8) FTime->Time.Minute;
   ETime->Second     = (UINT8) (FTime->Time.DoubleSecond * 2);
   ETime->Nanosecond = 0;
   ETime->TimeZone   = EFI_UNSPECIFIED_TIMEZONE;
   ETime->Daylight   = 0;
 }

 /**

   Get Current FAT time.

   @param  FatNow                - Current FAT time.

 **/
 VOID
 FatGetCurrentFatTime (
   OUT FAT_DATE_TIME   *FatNow
   )
 {
   EFI_STATUS Status;
   EFI_TIME   Now;

   Status = gRT->GetTime (&Now, NULL);
   if (!EFI_ERROR (Status)) {
     FatEfiTimeToFatTime (&Now, FatNow);
   } else {
     ZeroMem (&Now, sizeof (EFI_TIME));
     Now.Year = 1980;
     Now.Month = 1;
     Now.Day = 1;
     FatEfiTimeToFatTime (&Now, FatNow);
   }
 }

 /**

   Check whether a time is valid.

   @param  Time                  - The time of EFI_TIME.

   @retval TRUE                  - The time is valid.
   @retval FALSE                 - The time is not valid.

 **/
 BOOLEAN
 FatIsValidTime (
   IN EFI_TIME         *Time
   )
 {
   UINTN         Day;
   BOOLEAN       ValidTime;

   ValidTime = TRUE;

   //
   // Check the fields for range problems
   // Fat can only support from 1980
   //
   if (Time->Year < 1980 ||
       Time->Month < 1 ||
       Time->Month > 12 ||
       Time->Day < 1 ||
       Time->Day > 31 ||
       Time->Hour > 23 ||
       Time->Minute > 59 ||
       Time->Second > 59 ||
       Time->Nanosecond > 999999999
       ) {

     ValidTime = FALSE;

   } else {
     //
     // Perform a more specific check of the day of the month
     //
     Day = mMonthDays[Time->Month - 1];
     if (Time->Month == 2 && IS_LEAP_YEAR (Time->Year)) {
       Day += 1;
       //
       // 1 extra day this month
       //
     }
     if (Time->Day > Day) {
       ValidTime = FALSE;
     }
   }

   return ValidTime;
 }
	/** @file
	Miscellaneous functions.

	Copyright (c) 2005 - 2018, Intel Corporation. All rights reserved.<BR>
	SPDX-License-Identifier: BSD-2-Clause-Patent


	**/

	#include "Fat.h"
	UINT8 mMonthDays[] = { 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 };

	/**

	Create the task

	@param IFile - The instance of the open file.
	@param Token - A pointer to the token associated with the transaction.

	@return FAT_TASK * - Return the task instance.

	**/
	FAT_TASK *
	FatCreateTask (
	FAT_IFILE *IFile,
	EFI_FILE_IO_TOKEN *Token
	)
	{
	FAT_TASK *Task;

	Task = AllocateZeroPool (sizeof (*Task));
	if (Task != NULL) {
	Task->Signature = FAT_TASK_SIGNATURE;
	Task->IFile = IFile;
	Task->FileIoToken = Token;
	InitializeListHead (&Task->Subtasks);
	InitializeListHead (&Task->Link);
	}
	return Task;
	}

	/**

	Destroy the task.

	@param Task - The task to be destroyed.

	**/
	VOID
	FatDestroyTask (
	FAT_TASK *Task
	)
	{
	LIST_ENTRY *Link;
	FAT_SUBTASK *Subtask;

	Link = GetFirstNode (&Task->Subtasks);
	while (!IsNull (&Task->Subtasks, Link)) {
	Subtask = CR (Link, FAT_SUBTASK, Link, FAT_SUBTASK_SIGNATURE);
	Link = FatDestroySubtask (Subtask);
	}
	FreePool (Task);
	}

	/**

	Wait all non-blocking requests complete.

	@param IFile - The instance of the open file.

	**/
	VOID
	FatWaitNonblockingTask (
	FAT_IFILE *IFile
	)
	{
	BOOLEAN TaskQueueEmpty;

	do {
	EfiAcquireLock (&FatTaskLock);
	TaskQueueEmpty = IsListEmpty (&IFile->Tasks);
	EfiReleaseLock (&FatTaskLock);
	} while (!TaskQueueEmpty);
	}

	/**

	Remove the subtask from subtask list.

	@param Subtask - The subtask to be removed.

	@return LIST_ENTRY * - The next node in the list.

	**/
	LIST_ENTRY *
	FatDestroySubtask (
	FAT_SUBTASK *Subtask
	)
	{
	LIST_ENTRY *Link;

	gBS->CloseEvent (Subtask->DiskIo2Token.Event);

	Link = RemoveEntryList (&Subtask->Link);
	FreePool (Subtask);

	return Link;
	}

	/**

	Execute the task.

	@param IFile - The instance of the open file.
	@param Task - The task to be executed.

	@retval EFI_SUCCESS - The task was executed successfully.
	@return other - An error occurred when executing the task.

	**/
	EFI_STATUS
	FatQueueTask (
	IN FAT_IFILE *IFile,
	IN FAT_TASK *Task
	)
	{
	EFI_STATUS Status;
	LIST_ENTRY *Link;
	LIST_ENTRY *NextLink;
	FAT_SUBTASK *Subtask;

	//
	// Sometimes the Task doesn't contain any subtasks, signal the event directly.
	//
	if (IsListEmpty (&Task->Subtasks)) {
	Task->FileIoToken->Status = EFI_SUCCESS;
	gBS->SignalEvent (Task->FileIoToken->Event);
	FreePool (Task);
	return EFI_SUCCESS;
	}

	EfiAcquireLock (&FatTaskLock);
	InsertTailList (&IFile->Tasks, &Task->Link);
	EfiReleaseLock (&FatTaskLock);

	Status = EFI_SUCCESS;
	//
	// Use NextLink to store the next link of the list, because Link might be remove from the
	// doubly-linked list and get freed in the end of current loop.
	//
	// Also, list operation APIs like IsNull() and GetNextNode() are avoided during the loop, since
	// they may check the validity of doubly-linked lists by traversing them. These APIs cannot
	// handle list elements being removed during the traverse.
	//
	for ( Link = GetFirstNode (&Task->Subtasks), NextLink = GetNextNode (&Task->Subtasks, Link)
	; Link != &Task->Subtasks
	; Link = NextLink, NextLink = Link->ForwardLink
	) {
	Subtask = CR (Link, FAT_SUBTASK, Link, FAT_SUBTASK_SIGNATURE);
	if (Subtask->Write) {

	Status = IFile->OFile->Volume->DiskIo2->WriteDiskEx (
	IFile->OFile->Volume->DiskIo2,
	IFile->OFile->Volume->MediaId,
	Subtask->Offset,
	&Subtask->DiskIo2Token,
	Subtask->BufferSize,
	Subtask->Buffer
	);
	} else {
	Status = IFile->OFile->Volume->DiskIo2->ReadDiskEx (
	IFile->OFile->Volume->DiskIo2,
	IFile->OFile->Volume->MediaId,
	Subtask->Offset,
	&Subtask->DiskIo2Token,
	Subtask->BufferSize,
	Subtask->Buffer
	);
	}
	if (EFI_ERROR (Status)) {
	break;
	}
	}

	if (EFI_ERROR (Status)) {
	EfiAcquireLock (&FatTaskLock);
	//
	// Remove all the remaining subtasks when failure.
	// We shouldn't remove all the tasks because the non-blocking requests have
	// been submitted and cannot be canceled.
	//
	while (!IsNull (&Task->Subtasks, Link)) {
	Subtask = CR (Link, FAT_SUBTASK, Link, FAT_SUBTASK_SIGNATURE);
	Link = FatDestroySubtask (Subtask);
	}

	if (IsListEmpty (&Task->Subtasks)) {
	RemoveEntryList (&Task->Link);
	FreePool (Task);
	} else {
	//
	// If one or more subtasks have been already submitted, set FileIoToken
	// to NULL so that the callback won't signal the event.
	//
	Task->FileIoToken = NULL;
	}

	EfiReleaseLock (&FatTaskLock);
	}

	return Status;
	}

	/**

	Set the volume as dirty or not.

	@param Volume - FAT file system volume.
	@param IoMode - The access mode.
	@param DirtyValue - Set the volume as dirty or not.

	@retval EFI_SUCCESS - Set the new FAT entry value successfully.
	@return other - An error occurred when operation the FAT entries.

	**/
	EFI_STATUS
	FatAccessVolumeDirty (
	IN FAT_VOLUME *Volume,
	IN IO_MODE IoMode,
	IN VOID *DirtyValue
	)
	{
	UINTN WriteCount;

	WriteCount = Volume->FatEntrySize;
	return FatDiskIo (Volume, IoMode, Volume->FatPos + WriteCount, WriteCount, DirtyValue, NULL);
	}

	/**
	Invoke a notification event.

	@param Event Event whose notification function is being invoked.
	@param Context The pointer to the notification function's context,
	which is implementation-dependent.

	**/
	VOID
	EFIAPI
	FatOnAccessComplete (
	IN EFI_EVENT Event,
	IN VOID *Context
	)
	{
	EFI_STATUS Status;
	FAT_SUBTASK *Subtask;
	FAT_TASK *Task;

	//
	// Avoid someone in future breaks the below assumption.
	//
	ASSERT (EfiGetCurrentTpl () == FatTaskLock.Tpl);

	Subtask = (FAT_SUBTASK *) Context;
	Task = Subtask->Task;
	Status = Subtask->DiskIo2Token.TransactionStatus;

	ASSERT (Task->Signature == FAT_TASK_SIGNATURE);
	ASSERT (Subtask->Signature == FAT_SUBTASK_SIGNATURE);

	//
	// Remove the task unconditionally
	//
	FatDestroySubtask (Subtask);

	//
	// Task->FileIoToken is NULL which means the task will be ignored (just recycle the subtask and task memory).
	//
	if (Task->FileIoToken != NULL) {
	if (IsListEmpty (&Task->Subtasks) \|\| EFI_ERROR (Status)) {
	Task->FileIoToken->Status = Status;
	gBS->SignalEvent (Task->FileIoToken->Event);
	//
	// Mark Task->FileIoToken to NULL so that the subtasks belonging to the task will be ignored.
	//
	Task->FileIoToken = NULL;
	}
	}

	if (IsListEmpty (&Task->Subtasks)) {
	RemoveEntryList (&Task->Link);
	FreePool (Task);
	}
	}

	/**

	General disk access function.

	@param Volume - FAT file system volume.
	@param IoMode - The access mode (disk read/write or cache access).
	@param Offset - The starting byte offset to read from.
	@param BufferSize - Size of Buffer.
	@param Buffer - Buffer containing read data.
	@param Task point to task instance.

	@retval EFI_SUCCESS - The operation is performed successfully.
	@retval EFI_VOLUME_CORRUPTED - The access is
	@return Others - The status of read/write the disk

	**/
	EFI_STATUS
	FatDiskIo (
	IN FAT_VOLUME *Volume,
	IN IO_MODE IoMode,
	IN UINT64 Offset,
	IN UINTN BufferSize,
	IN OUT VOID *Buffer,
	IN FAT_TASK *Task
	)
	{
	EFI_STATUS Status;
	EFI_DISK_IO_PROTOCOL *DiskIo;
	EFI_DISK_READ IoFunction;
	FAT_SUBTASK *Subtask;

	//
	// Verify the IO is in devices range
	//
	Status = EFI_VOLUME_CORRUPTED;
	if (Offset + BufferSize <= Volume->VolumeSize) {
	if (CACHE_ENABLED (IoMode)) {
	//
	// Access cache
	//
	Status = FatAccessCache (Volume, CACHE_TYPE (IoMode), RAW_ACCESS (IoMode), Offset, BufferSize, Buffer, Task);
	} else {
	//
	// Access disk directly
	//
	if (Task == NULL) {
	//
	// Blocking access
	//
	DiskIo = Volume->DiskIo;
	IoFunction = (IoMode == ReadDisk) ? DiskIo->ReadDisk : DiskIo->WriteDisk;
	Status = IoFunction (DiskIo, Volume->MediaId, Offset, BufferSize, Buffer);
	} else {
	//
	// Non-blocking access
	//
	Subtask = AllocateZeroPool (sizeof (*Subtask));
	if (Subtask == NULL) {
	Status = EFI_OUT_OF_RESOURCES;
	} else {
	Subtask->Signature = FAT_SUBTASK_SIGNATURE;
	Subtask->Task = Task;
	Subtask->Write = (BOOLEAN) (IoMode == WriteDisk);
	Subtask->Offset = Offset;
	Subtask->Buffer = Buffer;
	Subtask->BufferSize = BufferSize;
	Status = gBS->CreateEvent (
	EVT_NOTIFY_SIGNAL,
	TPL_NOTIFY,
	FatOnAccessComplete,
	Subtask,
	&Subtask->DiskIo2Token.Event
	);
	if (!EFI_ERROR (Status)) {
	InsertTailList (&Task->Subtasks, &Subtask->Link);
	} else {
	FreePool (Subtask);
	}
	}
	}
	}
	}

	if (EFI_ERROR (Status)) {
	Volume->DiskError = TRUE;
	DEBUG ((EFI_D_ERROR, "FatDiskIo: error %r\n", Status));
	}

	return Status;
	}

	/**

	Lock the volume.

	**/
	VOID
	FatAcquireLock (
	VOID
	)
	{
	EfiAcquireLock (&FatFsLock);
	}

	/**

	Lock the volume.
	If the lock is already in the acquired state, then EFI_ACCESS_DENIED is returned.
	Otherwise, EFI_SUCCESS is returned.

	@retval EFI_SUCCESS - The volume is locked.
	@retval EFI_ACCESS_DENIED - The volume could not be locked because it is already locked.

	**/
	EFI_STATUS
	FatAcquireLockOrFail (
	VOID
	)
	{
	return EfiAcquireLockOrFail (&FatFsLock);
	}

	/**

	Unlock the volume.

	**/
	VOID
	FatReleaseLock (
	VOID
	)
	{
	EfiReleaseLock (&FatFsLock);
	}

	/**

	Free directory entry.

	@param DirEnt - The directory entry to be freed.

	**/
	VOID
	FatFreeDirEnt (
	IN FAT_DIRENT *DirEnt
	)
	{
	if (DirEnt->FileString != NULL) {
	FreePool (DirEnt->FileString);
	}

	FreePool (DirEnt);
	}

	/**

	Free volume structure (including the contents of directory cache and disk cache).

	@param Volume - The volume structure to be freed.

	**/
	VOID
	FatFreeVolume (
	IN FAT_VOLUME *Volume
	)
	{
	//
	// Free disk cache
	//
	if (Volume->CacheBuffer != NULL) {
	FreePool (Volume->CacheBuffer);
	}
	//
	// Free directory cache
	//
	FatCleanupODirCache (Volume);
	FreePool (Volume);
	}

	/**

	Translate EFI time to FAT time.

	@param ETime - The time of EFI_TIME.
	@param FTime - The time of FAT_DATE_TIME.

	**/
	VOID
	FatEfiTimeToFatTime (
	IN EFI_TIME *ETime,
	OUT FAT_DATE_TIME *FTime
	)
	{
	//
	// ignores timezone info in source ETime
	//
	if (ETime->Year > 1980) {
	FTime->Date.Year = (UINT16) (ETime->Year - 1980);
	}

	if (ETime->Year >= 1980 + FAT_MAX_YEAR_FROM_1980) {
	FTime->Date.Year = FAT_MAX_YEAR_FROM_1980;
	}

	FTime->Date.Month = ETime->Month;
	FTime->Date.Day = ETime->Day;
	FTime->Time.Hour = ETime->Hour;
	FTime->Time.Minute = ETime->Minute;
	FTime->Time.DoubleSecond = (UINT16) (ETime->Second / 2);
	}

	/**

	Translate Fat time to EFI time.

	@param FTime - The time of FAT_DATE_TIME.
	@param ETime - The time of EFI_TIME..

	**/
	VOID
	FatFatTimeToEfiTime (
	IN FAT_DATE_TIME *FTime,
	OUT EFI_TIME *ETime
	)
	{
	ETime->Year = (UINT16) (FTime->Date.Year + 1980);
	ETime->Month = (UINT8) FTime->Date.Month;
	ETime->Day = (UINT8) FTime->Date.Day;
	ETime->Hour = (UINT8) FTime->Time.Hour;
	ETime->Minute = (UINT8) FTime->Time.Minute;
	ETime->Second = (UINT8) (FTime->Time.DoubleSecond * 2);
	ETime->Nanosecond = 0;
	ETime->TimeZone = EFI_UNSPECIFIED_TIMEZONE;
	ETime->Daylight = 0;
	}

	/**

	Get Current FAT time.

	@param FatNow - Current FAT time.

	**/
	VOID
	FatGetCurrentFatTime (
	OUT FAT_DATE_TIME *FatNow
	)
	{
	EFI_STATUS Status;
	EFI_TIME Now;

	Status = gRT->GetTime (&Now, NULL);
	if (!EFI_ERROR (Status)) {
	FatEfiTimeToFatTime (&Now, FatNow);
	} else {
	ZeroMem (&Now, sizeof (EFI_TIME));
	Now.Year = 1980;
	Now.Month = 1;
	Now.Day = 1;
	FatEfiTimeToFatTime (&Now, FatNow);
	}
	}

	/**

	Check whether a time is valid.

	@param Time - The time of EFI_TIME.

	@retval TRUE - The time is valid.
	@retval FALSE - The time is not valid.

	**/
	BOOLEAN
	FatIsValidTime (
	IN EFI_TIME *Time
	)
	{
	UINTN Day;
	BOOLEAN ValidTime;

	ValidTime = TRUE;

	//
	// Check the fields for range problems
	// Fat can only support from 1980
	//
	if (Time->Year < 1980 \|\|
	Time->Month < 1 \|\|
	Time->Month > 12 \|\|
	Time->Day < 1 \|\|
	Time->Day > 31 \|\|
	Time->Hour > 23 \|\|
	Time->Minute > 59 \|\|
	Time->Second > 59 \|\|
	Time->Nanosecond > 999999999
	) {

	ValidTime = FALSE;

	} else {
	//
	// Perform a more specific check of the day of the month
	//
	Day = mMonthDays[Time->Month - 1];
	if (Time->Month == 2 && IS_LEAP_YEAR (Time->Year)) {
	Day += 1;
	//
	// 1 extra day this month
	//
	}
	if (Time->Day > Day) {
	ValidTime = FALSE;
	}
	}

	return ValidTime;
	}