UefiCpuPkg/Library/CpuPageTableLib/UnitTest/TestHelper.c - edk2 - Git at Google

 /** @file
   helper file for Unit tests of the CpuPageTableLib instance of the CpuPageTableLib class

   Copyright (c) 2022 - 2023, Intel Corporation. All rights reserved.<BR>
   SPDX-License-Identifier: BSD-2-Clause-Patent

 **/

 #include "CpuPageTableLibUnitTest.h"
 #include "../CpuPageTable.h"

 #define IA32_PAE_RESERVED_MASK  0x7FF0000000000000ull
 //
 // Global Data to validate if the page table is legal
 // mValidMaskNoLeaf[0] is not used
 // mValidMaskNoLeaf[1] ... mValidMaskNoLeaf [5] represent PTE ... PML5E
 // mValidMaskNoLeaf[Index] means if it is a valid no leaf entry, entry should equal to (entry & mValidMaskNoLeaf[Index])
 // mValidMaskLeaf[Index] means if it is a valid leaf entry, entry should equal to (entry & mValidMaskLeaf[Index])
 // mValidMaskLeafFlag[Index] means if it is a leaf entry, if and only if ((entry & mValidMaskLeafFlag[Index]) == mValidMaskLeafFlag[Index])
 //
 IA32_PAGING_ENTRY  mValidMaskNoLeaf[6];
 IA32_PAGING_ENTRY  mValidMaskLeaf[6];
 IA32_PAGING_ENTRY  mValidMaskLeafFlag[6];

 /**
   Init global data.

   @param[in]   MemorySpace    Memory space
 **/
 VOID
 InitGlobalData (
   UINTN  MemorySpace
   )
 {
   UINTN  Index;

   ASSERT (MemorySpace <= 52);
   mValidMaskNoLeaf[0].Uint64   = 0;
   mValidMaskLeaf[0].Uint64     = 0;
   mValidMaskLeafFlag[0].Uint64 = 0;

   //
   // Set common part for all kinds of entrys.
   //
   for (Index = 1; Index < 6; Index++) {
     mValidMaskNoLeaf[Index].Uint64 = MAX_UINT64;
     mValidMaskLeaf[Index].Uint64   = MAX_UINT64;

     //
     // bit 51:M is reserved, and should be zero
     //
     if (MemorySpace - 1 < 51) {
       mValidMaskNoLeaf[Index].Uint64 = BitFieldWrite64 (mValidMaskNoLeaf[Index].Uint64, MemorySpace - 1, 51, 0);
       mValidMaskLeaf[Index].Uint64   = BitFieldWrite64 (mValidMaskLeaf[Index].Uint64, MemorySpace - 1, 51, 0);
     }
   }

   //
   // Handle mask for no leaf entry.
   //
   mValidMaskNoLeaf[1].Uint64               = 0; // PTE can't map to page structure.
   mValidMaskNoLeaf[2].Pnle.Bits.MustBeZero = 0; // for PML4E, bit 7 must be zero.
   mValidMaskNoLeaf[3].Pnle.Bits.MustBeZero = 0; // for PML5E, bit 7 must be zero.
   mValidMaskNoLeaf[4].Pml4.Bits.MustBeZero = 0; // for PML4E, bit 7 must be zero.
   mValidMaskNoLeaf[5].Pml4.Bits.MustBeZero = 0; // for PML5E, bit 7 must be zero.

   //
   // Handle mask for leaf entry.
   // No need to modification for PTE, since it doesn't have extra reserved bit
   //
   mValidMaskLeaf[2].Uint64 = BitFieldWrite64 (mValidMaskLeaf[2].Uint64, 13, 20, 0); // bit 13-20 is reserved for PDE
   mValidMaskLeaf[3].Uint64 = BitFieldWrite64 (mValidMaskLeaf[2].Uint64, 13, 29, 0); // bit 13-29 is reserved for PDPTE
   mValidMaskLeaf[4].Uint64 = 0;                                                     // for PML4E, no possible to map to page.
   mValidMaskLeaf[5].Uint64 = 0;                                                     // for PML5E, no possible to map to page.

   //
   // Handle Flags to indicate it is a leaf entry.
   // for PML4E and PML5E, no possible to map to page, so the flag should be MAX_UINT64.
   //
   mValidMaskLeafFlag[1].Pce.Present = 1; // For PTE, as long as it is present, it maps to page
   //
   // For PDE and PDPTE, the bit 7 should be set to map to pages
   //
   mValidMaskLeafFlag[2].Pde2M.Bits.MustBeOne = 1;
   mValidMaskLeafFlag[2].Pde2M.Bits.Present   = 1;
   mValidMaskLeafFlag[3].Pde2M.Bits.MustBeOne = 1;
   mValidMaskLeafFlag[3].Pde2M.Bits.Present   = 1;
   mValidMaskLeafFlag[4].Uint64               = MAX_UINT64;
   mValidMaskLeafFlag[5].Uint64               = MAX_UINT64;
 }

 /**
   Check if the Page table entry is valid

   @param[in]   PagingEntry    The entry in page table to verify
   @param[in]   Level          the level of PagingEntry.
   @param[in]   MaxLeafLevel   Max leaf entry level.
   @param[in]   LinearAddress  The linear address verified.
   @param[in]   PagingMode     The paging mode.

   @retval  Leaf entry.
 **/
 UNIT_TEST_STATUS
 IsPageTableEntryValid (
   IN IA32_PAGING_ENTRY  *PagingEntry,
   IN UINTN              Level,
   IN UINTN              MaxLeafLevel,
   IN UINT64             Address,
   IN PAGING_MODE        PagingMode
   )
 {
   UINT64             Index;
   IA32_PAGING_ENTRY  *ChildPageEntry;
   UNIT_TEST_STATUS   Status;

   if (PagingMode == PagingPae) {
     UT_ASSERT_EQUAL (PagingEntry->Uint64 & IA32_PAE_RESERVED_MASK, 0);
   }

   if (PagingEntry->Pce.Present == 0) {
     return UNIT_TEST_PASSED;
   }

   if ((PagingEntry->Uint64 & mValidMaskLeafFlag[Level].Uint64) == mValidMaskLeafFlag[Level].Uint64) {
     //
     // It is a Leaf
     //
     if (Level > MaxLeafLevel) {
       DEBUG ((DEBUG_ERROR, "ERROR: Level %d entry 0x%lx is a leaf entry, but max leaf level is %d \n", Level, PagingEntry->Uint64, MaxLeafLevel));
       UT_ASSERT_TRUE (Level <= MaxLeafLevel);
     }

     if ((PagingEntry->Uint64 & mValidMaskLeaf[Level].Uint64) != PagingEntry->Uint64) {
       DEBUG ((DEBUG_ERROR, "ERROR: Level %d Leaf entry is 0x%lx, which reserved bit is set \n", Level, PagingEntry->Uint64));
       UT_ASSERT_EQUAL ((PagingEntry->Uint64 & mValidMaskLeaf[Level].Uint64), PagingEntry->Uint64);
     }

     return UNIT_TEST_PASSED;
   }

   //
   // Not a leaf
   //
   UT_ASSERT_NOT_EQUAL (Level, 1);
   if ((PagingEntry->Uint64 & mValidMaskNoLeaf[Level].Uint64) != PagingEntry->Uint64) {
     DEBUG ((DEBUG_ERROR, "ERROR: Level %d no Leaf entry is 0x%lx, which reserved bit is set \n", Level, PagingEntry->Uint64));
     UT_ASSERT_EQUAL ((PagingEntry->Uint64 & mValidMaskNoLeaf[Level].Uint64), PagingEntry->Uint64);
   }

   ChildPageEntry = (IA32_PAGING_ENTRY  *)(UINTN)(IA32_PNLE_PAGE_TABLE_BASE_ADDRESS (&PagingEntry->Pnle));
   for (Index = 0; Index < 512; Index++) {
     Status = IsPageTableEntryValid (&ChildPageEntry[Index], Level-1, MaxLeafLevel, Address + (Index<<(9*(Level-1) + 3)), PagingMode);
     if (Status != UNIT_TEST_PASSED) {
       return Status;
     }
   }

   return UNIT_TEST_PASSED;
 }

 /**
   Check if the Page table is valid

   @param[in]   PageTable      The pointer to the page table.
   @param[in]   PagingMode     The paging mode.

   @retval  UNIT_TEST_PASSED   It is a valid Page Table
 **/
 UNIT_TEST_STATUS
 IsPageTableValid (
   IN     UINTN        PageTable,
   IN     PAGING_MODE  PagingMode
   )
 {
   UINTN              MaxLevel;
   UINTN              MaxLeafLevel;
   UINT64             Index;
   UNIT_TEST_STATUS   Status;
   IA32_PAGING_ENTRY  *PagingEntry;

   if (PageTable == 0) {
     return UNIT_TEST_PASSED;
   }

   if ((PagingMode == Paging32bit) || (PagingMode >= PagingModeMax)) {
     //
     // 32bit paging is never supported.
     //
     return UNIT_TEST_ERROR_TEST_FAILED;
   }

   MaxLeafLevel = (UINT8)PagingMode;
   MaxLevel     = (UINT8)(PagingMode >> 8);

   PagingEntry = (IA32_PAGING_ENTRY *)(UINTN)PageTable;
   for (Index = 0; Index < ((PagingMode == PagingPae) ? 4 : 512); Index++) {
     if (PagingMode == PagingPae) {
       UT_ASSERT_EQUAL (PagingEntry[Index].PdptePae.Bits.MustBeZero, 0);
       UT_ASSERT_EQUAL (PagingEntry[Index].PdptePae.Bits.MustBeZero2, 0);
       UT_ASSERT_EQUAL (PagingEntry[Index].PdptePae.Bits.MustBeZero3, 0);
     }

     Status = IsPageTableEntryValid (&PagingEntry[Index], MaxLevel, MaxLeafLevel, Index << (9 * MaxLevel + 3), PagingMode);
     if (Status != UNIT_TEST_PASSED) {
       return Status;
     }
   }

   return Status;
 }

 /**
   Get the leaf entry for a given linear address from one entry in page table

   @param[in]       PagingEntry    The entry in page table which covers the linear address
   @param[in, out]  Level          On input, is the level of PagingEntry.
                                   On outout, is the level of the leaf entry
   @param[in]       MaxLeafLevel   Max leaf entry level.
   @param[in]       LinearAddress  The linear address.

   @retval  Leaf entry.
 **/
 UINT64
 GetEntryFromSubPageTable (
   IN     IA32_PAGING_ENTRY  *PagingEntry,
   IN OUT UINTN              *Level,
   IN     UINTN              MaxLeafLevel,
   IN     UINT64             Address
   )
 {
   UINT64             Index;
   IA32_PAGING_ENTRY  *ChildPageEntry;

   if (PagingEntry->Pce.Present == 0) {
     return 0;
   }

   if ((PagingEntry->Uint64 & mValidMaskLeafFlag[*Level].Uint64) == mValidMaskLeafFlag[*Level].Uint64) {
     //
     // It is a Leaf
     //
     return PagingEntry->Uint64;
   }

   //
   // Not a leaf
   //
   ChildPageEntry = (IA32_PAGING_ENTRY  *)(UINTN)(IA32_PNLE_PAGE_TABLE_BASE_ADDRESS (&PagingEntry->Pnle));
   *Level         = *Level -1;
   Index          = Address >> (*Level * 9 + 3);
   ASSERT (Index == (Index & ((1<< 9) - 1)));

   return GetEntryFromSubPageTable (&ChildPageEntry[Index], Level, MaxLeafLevel, Address - (Index << (9 * *Level + 3)));
 }

 /**
   Get the leaf entry for a given linear address from a page table

   @param[in]   PageTable      The pointer to the page table.
   @param[in]   PagingMode     The paging mode.
   @param[in]   LinearAddress  The linear address.
   @param[out]  Level          leaf entry's level.

   @retval  Leaf entry.
 **/
 UINT64
 GetEntryFromPageTable (
   IN     UINTN        PageTable,
   IN     PAGING_MODE  PagingMode,
   IN     UINT64       Address,
   OUT    UINTN        *Level
   )
 {
   UINTN              MaxLevel;
   UINTN              MaxLeafLevel;
   UINT64             Index;
   IA32_PAGING_ENTRY  *PagingEntry;

   if ((PagingMode == Paging32bit) || (PagingMode >= PagingModeMax)) {
     //
     // 32bit paging is never supported.
     // PAE paging will be supported later.
     //
     return 0;
   }

   MaxLeafLevel = (UINT8)PagingMode;
   MaxLevel     = (UINT8)(PagingMode >> 8);

   Index = Address >> (MaxLevel * 9 + 3);
   ASSERT (Index == (Index & ((1<< 9) - 1)));
   PagingEntry = (IA32_PAGING_ENTRY *)(UINTN)PageTable;
   *Level      = MaxLevel;

   return GetEntryFromSubPageTable (&PagingEntry[Index], Level, MaxLeafLevel, Address - (Index << (9 * MaxLevel + 3)));
 }

 /**
   Get max physical adrress supported by specific page mode

   @param[in]  Mode           The paging mode.

   @retval  max address.
 **/
 UINT64
 GetMaxAddress (
   IN PAGING_MODE  Mode
   )
 {
   switch (Mode) {
     case Paging32bit:
     case PagingPae:
       return SIZE_4GB;

     case Paging4Level:
     case Paging4Level1GB:
     case Paging5Level:
     case Paging5Level1GB:
       return 1ull << MIN (12 + (Mode >> 8) * 9, 52);

     default:
       ASSERT (0);
       return 0;
   }
 }
	/** @file
	helper file for Unit tests of the CpuPageTableLib instance of the CpuPageTableLib class

	Copyright (c) 2022 - 2023, Intel Corporation. All rights reserved.<BR>
	SPDX-License-Identifier: BSD-2-Clause-Patent

	**/

	#include "CpuPageTableLibUnitTest.h"
	#include "../CpuPageTable.h"

	#define IA32_PAE_RESERVED_MASK 0x7FF0000000000000ull
	//
	// Global Data to validate if the page table is legal
	// mValidMaskNoLeaf[0] is not used
	// mValidMaskNoLeaf[1] ... mValidMaskNoLeaf [5] represent PTE ... PML5E
	// mValidMaskNoLeaf[Index] means if it is a valid no leaf entry, entry should equal to (entry & mValidMaskNoLeaf[Index])
	// mValidMaskLeaf[Index] means if it is a valid leaf entry, entry should equal to (entry & mValidMaskLeaf[Index])
	// mValidMaskLeafFlag[Index] means if it is a leaf entry, if and only if ((entry & mValidMaskLeafFlag[Index]) == mValidMaskLeafFlag[Index])
	//
	IA32_PAGING_ENTRY mValidMaskNoLeaf[6];
	IA32_PAGING_ENTRY mValidMaskLeaf[6];
	IA32_PAGING_ENTRY mValidMaskLeafFlag[6];

	/**
	Init global data.

	@param[in] MemorySpace Memory space
	**/
	VOID
	InitGlobalData (
	UINTN MemorySpace
	)
	{
	UINTN Index;

	ASSERT (MemorySpace <= 52);
	mValidMaskNoLeaf[0].Uint64 = 0;
	mValidMaskLeaf[0].Uint64 = 0;
	mValidMaskLeafFlag[0].Uint64 = 0;

	//
	// Set common part for all kinds of entrys.
	//
	for (Index = 1; Index < 6; Index++) {
	mValidMaskNoLeaf[Index].Uint64 = MAX_UINT64;
	mValidMaskLeaf[Index].Uint64 = MAX_UINT64;

	//
	// bit 51:M is reserved, and should be zero
	//
	if (MemorySpace - 1 < 51) {
	mValidMaskNoLeaf[Index].Uint64 = BitFieldWrite64 (mValidMaskNoLeaf[Index].Uint64, MemorySpace - 1, 51, 0);
	mValidMaskLeaf[Index].Uint64 = BitFieldWrite64 (mValidMaskLeaf[Index].Uint64, MemorySpace - 1, 51, 0);
	}
	}

	//
	// Handle mask for no leaf entry.
	//
	mValidMaskNoLeaf[1].Uint64 = 0; // PTE can't map to page structure.
	mValidMaskNoLeaf[2].Pnle.Bits.MustBeZero = 0; // for PML4E, bit 7 must be zero.
	mValidMaskNoLeaf[3].Pnle.Bits.MustBeZero = 0; // for PML5E, bit 7 must be zero.
	mValidMaskNoLeaf[4].Pml4.Bits.MustBeZero = 0; // for PML4E, bit 7 must be zero.
	mValidMaskNoLeaf[5].Pml4.Bits.MustBeZero = 0; // for PML5E, bit 7 must be zero.

	//
	// Handle mask for leaf entry.
	// No need to modification for PTE, since it doesn't have extra reserved bit
	//
	mValidMaskLeaf[2].Uint64 = BitFieldWrite64 (mValidMaskLeaf[2].Uint64, 13, 20, 0); // bit 13-20 is reserved for PDE
	mValidMaskLeaf[3].Uint64 = BitFieldWrite64 (mValidMaskLeaf[2].Uint64, 13, 29, 0); // bit 13-29 is reserved for PDPTE
	mValidMaskLeaf[4].Uint64 = 0; // for PML4E, no possible to map to page.
	mValidMaskLeaf[5].Uint64 = 0; // for PML5E, no possible to map to page.

	//
	// Handle Flags to indicate it is a leaf entry.
	// for PML4E and PML5E, no possible to map to page, so the flag should be MAX_UINT64.
	//
	mValidMaskLeafFlag[1].Pce.Present = 1; // For PTE, as long as it is present, it maps to page
	//
	// For PDE and PDPTE, the bit 7 should be set to map to pages
	//
	mValidMaskLeafFlag[2].Pde2M.Bits.MustBeOne = 1;
	mValidMaskLeafFlag[2].Pde2M.Bits.Present = 1;
	mValidMaskLeafFlag[3].Pde2M.Bits.MustBeOne = 1;
	mValidMaskLeafFlag[3].Pde2M.Bits.Present = 1;
	mValidMaskLeafFlag[4].Uint64 = MAX_UINT64;
	mValidMaskLeafFlag[5].Uint64 = MAX_UINT64;
	}

	/**
	Check if the Page table entry is valid

	@param[in] PagingEntry The entry in page table to verify
	@param[in] Level the level of PagingEntry.
	@param[in] MaxLeafLevel Max leaf entry level.
	@param[in] LinearAddress The linear address verified.
	@param[in] PagingMode The paging mode.

	@retval Leaf entry.
	**/
	UNIT_TEST_STATUS
	IsPageTableEntryValid (
	IN IA32_PAGING_ENTRY *PagingEntry,
	IN UINTN Level,
	IN UINTN MaxLeafLevel,
	IN UINT64 Address,
	IN PAGING_MODE PagingMode
	)
	{
	UINT64 Index;
	IA32_PAGING_ENTRY *ChildPageEntry;
	UNIT_TEST_STATUS Status;

	if (PagingMode == PagingPae) {
	UT_ASSERT_EQUAL (PagingEntry->Uint64 & IA32_PAE_RESERVED_MASK, 0);
	}

	if (PagingEntry->Pce.Present == 0) {
	return UNIT_TEST_PASSED;
	}

	if ((PagingEntry->Uint64 & mValidMaskLeafFlag[Level].Uint64) == mValidMaskLeafFlag[Level].Uint64) {
	//
	// It is a Leaf
	//
	if (Level > MaxLeafLevel) {
	DEBUG ((DEBUG_ERROR, "ERROR: Level %d entry 0x%lx is a leaf entry, but max leaf level is %d \n", Level, PagingEntry->Uint64, MaxLeafLevel));
	UT_ASSERT_TRUE (Level <= MaxLeafLevel);
	}

	if ((PagingEntry->Uint64 & mValidMaskLeaf[Level].Uint64) != PagingEntry->Uint64) {
	DEBUG ((DEBUG_ERROR, "ERROR: Level %d Leaf entry is 0x%lx, which reserved bit is set \n", Level, PagingEntry->Uint64));
	UT_ASSERT_EQUAL ((PagingEntry->Uint64 & mValidMaskLeaf[Level].Uint64), PagingEntry->Uint64);
	}

	return UNIT_TEST_PASSED;
	}

	//
	// Not a leaf
	//
	UT_ASSERT_NOT_EQUAL (Level, 1);
	if ((PagingEntry->Uint64 & mValidMaskNoLeaf[Level].Uint64) != PagingEntry->Uint64) {
	DEBUG ((DEBUG_ERROR, "ERROR: Level %d no Leaf entry is 0x%lx, which reserved bit is set \n", Level, PagingEntry->Uint64));
	UT_ASSERT_EQUAL ((PagingEntry->Uint64 & mValidMaskNoLeaf[Level].Uint64), PagingEntry->Uint64);
	}

	ChildPageEntry = (IA32_PAGING_ENTRY *)(UINTN)(IA32_PNLE_PAGE_TABLE_BASE_ADDRESS (&PagingEntry->Pnle));
	for (Index = 0; Index < 512; Index++) {
	Status = IsPageTableEntryValid (&ChildPageEntry[Index], Level-1, MaxLeafLevel, Address + (Index<<(9*(Level-1) + 3)), PagingMode);
	if (Status != UNIT_TEST_PASSED) {
	return Status;
	}
	}

	return UNIT_TEST_PASSED;
	}

	/**
	Check if the Page table is valid

	@param[in] PageTable The pointer to the page table.
	@param[in] PagingMode The paging mode.

	@retval UNIT_TEST_PASSED It is a valid Page Table
	**/
	UNIT_TEST_STATUS
	IsPageTableValid (
	IN UINTN PageTable,
	IN PAGING_MODE PagingMode
	)
	{
	UINTN MaxLevel;
	UINTN MaxLeafLevel;
	UINT64 Index;
	UNIT_TEST_STATUS Status;
	IA32_PAGING_ENTRY *PagingEntry;

	if (PageTable == 0) {
	return UNIT_TEST_PASSED;
	}

	if ((PagingMode == Paging32bit) \|\| (PagingMode >= PagingModeMax)) {
	//
	// 32bit paging is never supported.
	//
	return UNIT_TEST_ERROR_TEST_FAILED;
	}

	MaxLeafLevel = (UINT8)PagingMode;
	MaxLevel = (UINT8)(PagingMode >> 8);

	PagingEntry = (IA32_PAGING_ENTRY *)(UINTN)PageTable;
	for (Index = 0; Index < ((PagingMode == PagingPae) ? 4 : 512); Index++) {
	if (PagingMode == PagingPae) {
	UT_ASSERT_EQUAL (PagingEntry[Index].PdptePae.Bits.MustBeZero, 0);
	UT_ASSERT_EQUAL (PagingEntry[Index].PdptePae.Bits.MustBeZero2, 0);
	UT_ASSERT_EQUAL (PagingEntry[Index].PdptePae.Bits.MustBeZero3, 0);
	}

	Status = IsPageTableEntryValid (&PagingEntry[Index], MaxLevel, MaxLeafLevel, Index << (9 * MaxLevel + 3), PagingMode);
	if (Status != UNIT_TEST_PASSED) {
	return Status;
	}
	}

	return Status;
	}

	/**
	Get the leaf entry for a given linear address from one entry in page table

	@param[in] PagingEntry The entry in page table which covers the linear address
	@param[in, out] Level On input, is the level of PagingEntry.
	On outout, is the level of the leaf entry
	@param[in] MaxLeafLevel Max leaf entry level.
	@param[in] LinearAddress The linear address.

	@retval Leaf entry.
	**/
	UINT64
	GetEntryFromSubPageTable (
	IN IA32_PAGING_ENTRY *PagingEntry,
	IN OUT UINTN *Level,
	IN UINTN MaxLeafLevel,
	IN UINT64 Address
	)
	{
	UINT64 Index;
	IA32_PAGING_ENTRY *ChildPageEntry;

	if (PagingEntry->Pce.Present == 0) {
	return 0;
	}

	if ((PagingEntry->Uint64 & mValidMaskLeafFlag[Level].Uint64) == mValidMaskLeafFlag[Level].Uint64) {
	//
	// It is a Leaf
	//
	return PagingEntry->Uint64;
	}

	//
	// Not a leaf
	//
	ChildPageEntry = (IA32_PAGING_ENTRY *)(UINTN)(IA32_PNLE_PAGE_TABLE_BASE_ADDRESS (&PagingEntry->Pnle));
	Level = Level -1;
	Index = Address >> (Level 9 + 3);
	ASSERT (Index == (Index & ((1<< 9) - 1)));

	return GetEntryFromSubPageTable (&ChildPageEntry[Index], Level, MaxLeafLevel, Address - (Index << (9 * *Level + 3)));
	}

	/**
	Get the leaf entry for a given linear address from a page table

	@param[in] PageTable The pointer to the page table.
	@param[in] PagingMode The paging mode.
	@param[in] LinearAddress The linear address.
	@param[out] Level leaf entry's level.

	@retval Leaf entry.
	**/
	UINT64
	GetEntryFromPageTable (
	IN UINTN PageTable,
	IN PAGING_MODE PagingMode,
	IN UINT64 Address,
	OUT UINTN *Level
	)
	{
	UINTN MaxLevel;
	UINTN MaxLeafLevel;
	UINT64 Index;
	IA32_PAGING_ENTRY *PagingEntry;

	if ((PagingMode == Paging32bit) \|\| (PagingMode >= PagingModeMax)) {
	//
	// 32bit paging is never supported.
	// PAE paging will be supported later.
	//
	return 0;
	}

	MaxLeafLevel = (UINT8)PagingMode;
	MaxLevel = (UINT8)(PagingMode >> 8);

	Index = Address >> (MaxLevel * 9 + 3);
	ASSERT (Index == (Index & ((1<< 9) - 1)));
	PagingEntry = (IA32_PAGING_ENTRY *)(UINTN)PageTable;
	*Level = MaxLevel;

	return GetEntryFromSubPageTable (&PagingEntry[Index], Level, MaxLeafLevel, Address - (Index << (9 * MaxLevel + 3)));
	}

	/**
	Get max physical adrress supported by specific page mode

	@param[in] Mode The paging mode.

	@retval max address.
	**/
	UINT64
	GetMaxAddress (
	IN PAGING_MODE Mode
	)
	{
	switch (Mode) {
	case Paging32bit:
	case PagingPae:
	return SIZE_4GB;

	case Paging4Level:
	case Paging4Level1GB:
	case Paging5Level:
	case Paging5Level1GB:
	return 1ull << MIN (12 + (Mode >> 8) * 9, 52);

	default:
	ASSERT (0);
	return 0;
	}
	}