OvmfPkg/Library/SmmCpuFeaturesLib/SmmCpuFeaturesLib.c - edk2 - Git at Google

 /** @file
   The CPU specific programming for PiSmmCpuDxeSmm module.

   Copyright (c) 2010 - 2023, Intel Corporation. All rights reserved.<BR>

   SPDX-License-Identifier: BSD-2-Clause-Patent
 **/

 #include <IndustryStandard/Q35MchIch9.h>
 #include <Library/BaseLib.h>
 #include <Library/BaseMemoryLib.h>
 #include <Library/DebugLib.h>
 #include <Library/MemEncryptSevLib.h>
 #include <Library/MemoryAllocationLib.h>
 #include <Library/PcdLib.h>
 #include <Library/SafeIntLib.h>
 #include <Library/SmmCpuFeaturesLib.h>
 #include <Library/SmmServicesTableLib.h>
 #include <Library/UefiBootServicesTableLib.h>
 #include <Library/HobLib.h>
 #include <Pcd/CpuHotEjectData.h>
 #include <PiSmm.h>
 #include <Register/Amd/SmramSaveStateMap.h>
 #include <Guid/SmmBaseHob.h>

 //
 // EFER register LMA bit
 //
 #define LMA  BIT10

 //
 // Indicate SmBase for each Processors has been relocated or not. If TRUE,
 // means no need to do the relocation in SmmCpuFeaturesInitializeProcessor().
 //
 BOOLEAN  mSmmCpuFeaturesSmmRelocated;

 /**
   The constructor function

   @param[in]  ImageHandle  The firmware allocated handle for the EFI image.
   @param[in]  SystemTable  A pointer to the EFI System Table.

   @retval EFI_SUCCESS      The constructor always returns EFI_SUCCESS.

 **/
 EFI_STATUS
 EFIAPI
 SmmCpuFeaturesLibConstructor (
   IN EFI_HANDLE        ImageHandle,
   IN EFI_SYSTEM_TABLE  *SystemTable
   )
 {
   //
   // If gSmmBaseHobGuid found, means SmBase info has been relocated and recorded
   // in the SmBase array.
   //
   mSmmCpuFeaturesSmmRelocated = (BOOLEAN)(GetFirstGuidHob (&gSmmBaseHobGuid) != NULL);

   //
   // No need to program SMRRs on our virtual platform.
   //
   return EFI_SUCCESS;
 }

 /**
   Called during the very first SMI into System Management Mode to initialize
   CPU features, including SMBASE, for the currently executing CPU.  Since this
   is the first SMI, the SMRAM Save State Map is at the default address of
   SMM_DEFAULT_SMBASE + SMRAM_SAVE_STATE_MAP_OFFSET.  The currently executing
   CPU is specified by CpuIndex and CpuIndex can be used to access information
   about the currently executing CPU in the ProcessorInfo array and the
   HotPlugCpuData data structure.

   @param[in] CpuIndex        The index of the CPU to initialize.  The value
                              must be between 0 and the NumberOfCpus field in
                              the System Management System Table (SMST).
   @param[in] IsMonarch       TRUE if the CpuIndex is the index of the CPU that
                              was elected as monarch during System Management
                              Mode initialization.
                              FALSE if the CpuIndex is not the index of the CPU
                              that was elected as monarch during System
                              Management Mode initialization.
   @param[in] ProcessorInfo   Pointer to an array of EFI_PROCESSOR_INFORMATION
                              structures.  ProcessorInfo[CpuIndex] contains the
                              information for the currently executing CPU.
   @param[in] CpuHotPlugData  Pointer to the CPU_HOT_PLUG_DATA structure that
                              contains the ApidId and SmBase arrays.
 **/
 VOID
 EFIAPI
 SmmCpuFeaturesInitializeProcessor (
   IN UINTN                      CpuIndex,
   IN BOOLEAN                    IsMonarch,
   IN EFI_PROCESSOR_INFORMATION  *ProcessorInfo,
   IN CPU_HOT_PLUG_DATA          *CpuHotPlugData
   )
 {
   AMD_SMRAM_SAVE_STATE_MAP  *CpuState;

   //
   // No need to configure SMBASE if SmBase relocation has been done.
   //
   if (!mSmmCpuFeaturesSmmRelocated) {
     //
     // Configure SMBASE.
     //
     CpuState = (AMD_SMRAM_SAVE_STATE_MAP *)(UINTN)(
                                                    SMM_DEFAULT_SMBASE +
                                                    SMRAM_SAVE_STATE_MAP_OFFSET
                                                    );
     if ((CpuState->x86.SMMRevId & 0xFFFF) == 0) {
       CpuState->x86.SMBASE = (UINT32)CpuHotPlugData->SmBase[CpuIndex];
     } else {
       CpuState->x64.SMBASE = (UINT32)CpuHotPlugData->SmBase[CpuIndex];
     }
   }

   //
   // No need to program SMRRs on our virtual platform.
   //
 }

 /**
   This function updates the SMRAM save state on the currently executing CPU
   to resume execution at a specific address after an RSM instruction.  This
   function must evaluate the SMRAM save state to determine the execution mode
   the RSM instruction resumes and update the resume execution address with
   either NewInstructionPointer32 or NewInstructionPoint.  The auto HALT restart
   flag in the SMRAM save state must always be cleared.  This function returns
   the value of the instruction pointer from the SMRAM save state that was
   replaced.  If this function returns 0, then the SMRAM save state was not
   modified.

   This function is called during the very first SMI on each CPU after
   SmmCpuFeaturesInitializeProcessor() to set a flag in normal execution mode
   to signal that the SMBASE of each CPU has been updated before the default
   SMBASE address is used for the first SMI to the next CPU.

   @param[in] CpuIndex                 The index of the CPU to hook.  The value
                                       must be between 0 and the NumberOfCpus
                                       field in the System Management System
                                       Table (SMST).
   @param[in] CpuState                 Pointer to SMRAM Save State Map for the
                                       currently executing CPU.
   @param[in] NewInstructionPointer32  Instruction pointer to use if resuming to
                                       32-bit execution mode from 64-bit SMM.
   @param[in] NewInstructionPointer    Instruction pointer to use if resuming to
                                       same execution mode as SMM.

   @retval 0    This function did modify the SMRAM save state.
   @retval > 0  The original instruction pointer value from the SMRAM save state
                before it was replaced.
 **/
 UINT64
 EFIAPI
 SmmCpuFeaturesHookReturnFromSmm (
   IN UINTN                 CpuIndex,
   IN SMRAM_SAVE_STATE_MAP  *CpuState,
   IN UINT64                NewInstructionPointer32,
   IN UINT64                NewInstructionPointer
   )
 {
   UINT64                    OriginalInstructionPointer;
   AMD_SMRAM_SAVE_STATE_MAP  *CpuSaveState;

   CpuSaveState = (AMD_SMRAM_SAVE_STATE_MAP *)CpuState;
   if ((CpuSaveState->x86.SMMRevId & 0xFFFF) == 0) {
     OriginalInstructionPointer = (UINT64)CpuSaveState->x86._EIP;
     CpuSaveState->x86._EIP     = (UINT32)NewInstructionPointer;
     //
     // Clear the auto HALT restart flag so the RSM instruction returns
     // program control to the instruction following the HLT instruction.
     //
     if ((CpuSaveState->x86.AutoHALTRestart & BIT0) != 0) {
       CpuSaveState->x86.AutoHALTRestart &= ~BIT0;
     }
   } else {
     OriginalInstructionPointer = CpuSaveState->x64._RIP;
     if ((CpuSaveState->x64.EFER & LMA) == 0) {
       CpuSaveState->x64._RIP = (UINT32)NewInstructionPointer32;
     } else {
       CpuSaveState->x64._RIP = (UINT32)NewInstructionPointer;
     }

     //
     // Clear the auto HALT restart flag so the RSM instruction returns
     // program control to the instruction following the HLT instruction.
     //
     if ((CpuSaveState->x64.AutoHALTRestart & BIT0) != 0) {
       CpuSaveState->x64.AutoHALTRestart &= ~BIT0;
     }
   }

   return OriginalInstructionPointer;
 }

 STATIC CPU_HOT_EJECT_DATA  *mCpuHotEjectData = NULL;

 /**
   Initialize mCpuHotEjectData if PcdCpuMaxLogicalProcessorNumber > 1.

   Also setup the corresponding PcdCpuHotEjectDataAddress.
 **/
 STATIC
 VOID
 InitCpuHotEjectData (
   VOID
   )
 {
   UINTN          Size;
   UINT32         Idx;
   UINT32         MaxNumberOfCpus;
   RETURN_STATUS  PcdStatus;

   MaxNumberOfCpus = PcdGet32 (PcdCpuMaxLogicalProcessorNumber);
   if (MaxNumberOfCpus == 1) {
     return;
   }

   //
   // We allocate CPU_HOT_EJECT_DATA and CPU_HOT_EJECT_DATA->QemuSelectorMap[]
   // in a single allocation, and explicitly align the QemuSelectorMap[] (which
   // is a UINT64 array) at its natural boundary.
   // Accordingly, allocate:
   //   sizeof(*mCpuHotEjectData) + (MaxNumberOfCpus * sizeof(UINT64))
   // and, add sizeof(UINT64) - 1 to use as padding if needed.
   //

   if (RETURN_ERROR (SafeUintnMult (MaxNumberOfCpus, sizeof (UINT64), &Size)) ||
       RETURN_ERROR (SafeUintnAdd (Size, sizeof (*mCpuHotEjectData), &Size)) ||
       RETURN_ERROR (SafeUintnAdd (Size, sizeof (UINT64) - 1, &Size)))
   {
     DEBUG ((DEBUG_ERROR, "%a: invalid CPU_HOT_EJECT_DATA\n", __func__));
     goto Fatal;
   }

   mCpuHotEjectData = AllocatePool (Size);
   if (mCpuHotEjectData == NULL) {
     ASSERT (mCpuHotEjectData != NULL);
     goto Fatal;
   }

   mCpuHotEjectData->Handler     = NULL;
   mCpuHotEjectData->ArrayLength = MaxNumberOfCpus;

   mCpuHotEjectData->QemuSelectorMap = ALIGN_POINTER (
                                         mCpuHotEjectData + 1,
                                         sizeof (UINT64)
                                         );
   //
   // We use mCpuHotEjectData->QemuSelectorMap to map
   // ProcessorNum -> QemuSelector. Initialize to invalid values.
   //
   for (Idx = 0; Idx < mCpuHotEjectData->ArrayLength; Idx++) {
     mCpuHotEjectData->QemuSelectorMap[Idx] = CPU_EJECT_QEMU_SELECTOR_INVALID;
   }

   //
   // Expose address of CPU Hot eject Data structure
   //
   PcdStatus = PcdSet64S (
                 PcdCpuHotEjectDataAddress,
                 (UINTN)(VOID *)mCpuHotEjectData
                 );
   ASSERT_RETURN_ERROR (PcdStatus);

   return;

 Fatal:
   CpuDeadLoop ();
 }

 /**
   Hook point in normal execution mode that allows the one CPU that was elected
   as monarch during System Management Mode initialization to perform additional
   initialization actions immediately after all of the CPUs have processed their
   first SMI and called SmmCpuFeaturesInitializeProcessor() relocating SMBASE
   into a buffer in SMRAM and called SmmCpuFeaturesHookReturnFromSmm().
 **/
 VOID
 EFIAPI
 SmmCpuFeaturesSmmRelocationComplete (
   VOID
   )
 {
   EFI_STATUS  Status;
   UINTN       MapPagesBase;
   UINTN       MapPagesCount;

   InitCpuHotEjectData ();

   if (!MemEncryptSevIsEnabled ()) {
     return;
   }

   //
   // Now that SMBASE relocation is complete, re-encrypt the original SMRAM save
   // state map's container pages, and release the pages to DXE. (The pages were
   // allocated in PlatformPei.)
   //
   Status = MemEncryptSevLocateInitialSmramSaveStateMapPages (
              &MapPagesBase,
              &MapPagesCount
              );
   ASSERT_EFI_ERROR (Status);

   Status = MemEncryptSevSetPageEncMask (
              0,             // Cr3BaseAddress -- use current CR3
              MapPagesBase,  // BaseAddress
              MapPagesCount  // NumPages
              );
   if (EFI_ERROR (Status)) {
     DEBUG ((
       DEBUG_ERROR,
       "%a: MemEncryptSevSetPageEncMask(): %r\n",
       __func__,
       Status
       ));
     ASSERT (FALSE);
     CpuDeadLoop ();
   }

   ZeroMem ((VOID *)MapPagesBase, EFI_PAGES_TO_SIZE (MapPagesCount));

   if (PcdGetBool (PcdQ35SmramAtDefaultSmbase)) {
     //
     // The initial SMRAM Save State Map has been covered as part of a larger
     // reserved memory allocation in PlatformPei's InitializeRamRegions(). That
     // allocation is supposed to survive into OS runtime; we must not release
     // any part of it. Only re-assert the containment here.
     //
     ASSERT (SMM_DEFAULT_SMBASE <= MapPagesBase);
     ASSERT (
       (MapPagesBase + EFI_PAGES_TO_SIZE (MapPagesCount) <=
        SMM_DEFAULT_SMBASE + MCH_DEFAULT_SMBASE_SIZE)
       );
   } else {
     Status = gBS->FreePages (MapPagesBase, MapPagesCount);
     ASSERT_EFI_ERROR (Status);
   }
 }

 /**
   Return the size, in bytes, of a custom SMI Handler in bytes.  If 0 is
   returned, then a custom SMI handler is not provided by this library,
   and the default SMI handler must be used.

   @retval 0    Use the default SMI handler.
   @retval > 0  Use the SMI handler installed by
                SmmCpuFeaturesInstallSmiHandler(). The caller is required to
                allocate enough SMRAM for each CPU to support the size of the
                custom SMI handler.
 **/
 UINTN
 EFIAPI
 SmmCpuFeaturesGetSmiHandlerSize (
   VOID
   )
 {
   return 0;
 }

 /**
   Install a custom SMI handler for the CPU specified by CpuIndex.  This
   function is only called if SmmCpuFeaturesGetSmiHandlerSize() returns a size
   is greater than zero and is called by the CPU that was elected as monarch
   during System Management Mode initialization.

   @param[in] CpuIndex   The index of the CPU to install the custom SMI handler.
                         The value must be between 0 and the NumberOfCpus field
                         in the System Management System Table (SMST).
   @param[in] SmBase     The SMBASE address for the CPU specified by CpuIndex.
   @param[in] SmiStack   The stack to use when an SMI is processed by the
                         the CPU specified by CpuIndex.
   @param[in] StackSize  The size, in bytes, if the stack used when an SMI is
                         processed by the CPU specified by CpuIndex.
   @param[in] GdtBase    The base address of the GDT to use when an SMI is
                         processed by the CPU specified by CpuIndex.
   @param[in] GdtSize    The size, in bytes, of the GDT used when an SMI is
                         processed by the CPU specified by CpuIndex.
   @param[in] IdtBase    The base address of the IDT to use when an SMI is
                         processed by the CPU specified by CpuIndex.
   @param[in] IdtSize    The size, in bytes, of the IDT used when an SMI is
                         processed by the CPU specified by CpuIndex.
   @param[in] Cr3        The base address of the page tables to use when an SMI
                         is processed by the CPU specified by CpuIndex.
 **/
 VOID
 EFIAPI
 SmmCpuFeaturesInstallSmiHandler (
   IN UINTN   CpuIndex,
   IN UINT32  SmBase,
   IN VOID    *SmiStack,
   IN UINTN   StackSize,
   IN UINTN   GdtBase,
   IN UINTN   GdtSize,
   IN UINTN   IdtBase,
   IN UINTN   IdtSize,
   IN UINT32  Cr3
   )
 {
 }

 /**
   Determines if MTRR registers must be configured to set SMRAM cache-ability
   when executing in System Management Mode.

   @retval TRUE   MTRR registers must be configured to set SMRAM cache-ability.
   @retval FALSE  MTRR registers do not need to be configured to set SMRAM
                  cache-ability.
 **/
 BOOLEAN
 EFIAPI
 SmmCpuFeaturesNeedConfigureMtrrs (
   VOID
   )
 {
   return FALSE;
 }

 /**
   Disable SMRR register if SMRR is supported and
   SmmCpuFeaturesNeedConfigureMtrrs() returns TRUE.
 **/
 VOID
 EFIAPI
 SmmCpuFeaturesDisableSmrr (
   VOID
   )
 {
   //
   // No SMRR support, nothing to do
   //
 }

 /**
   Enable SMRR register if SMRR is supported and
   SmmCpuFeaturesNeedConfigureMtrrs() returns TRUE.
 **/
 VOID
 EFIAPI
 SmmCpuFeaturesReenableSmrr (
   VOID
   )
 {
   //
   // No SMRR support, nothing to do
   //
 }

 /**
   Processor specific hook point each time a CPU enters System Management Mode.

   @param[in] CpuIndex  The index of the CPU that has entered SMM.  The value
                        must be between 0 and the NumberOfCpus field in the
                        System Management System Table (SMST).
 **/
 VOID
 EFIAPI
 SmmCpuFeaturesRendezvousEntry (
   IN UINTN  CpuIndex
   )
 {
   //
   // No SMRR support, nothing to do
   //
 }

 /**
   Processor specific hook point each time a CPU exits System Management Mode.

   @param[in] CpuIndex  The index of the CPU that is exiting SMM.  The value
                        must be between 0 and the NumberOfCpus field in the
                        System Management System Table (SMST).
 **/
 VOID
 EFIAPI
 SmmCpuFeaturesRendezvousExit (
   IN UINTN  CpuIndex
   )
 {
   //
   // We only call the Handler if CPU hot-eject is enabled
   // (PcdCpuMaxLogicalProcessorNumber > 1), and hot-eject is needed
   // in this SMI exit (otherwise mCpuHotEjectData->Handler is not armed.)
   //

   if (mCpuHotEjectData != NULL) {
     CPU_HOT_EJECT_HANDLER  Handler;

     //
     // As the comment above mentions, mCpuHotEjectData->Handler might be
     // written to on the BSP as part of handling of the CPU-ejection.
     //
     // We know that any initial assignment to mCpuHotEjectData->Handler
     // (on the BSP, in the CpuHotplugMmi() context) is ordered-before the
     // load below, since it is guaranteed to happen before the
     // control-dependency of the BSP's SMI exit signal -- by way of a store
     // to AllCpusInSync (on the BSP, in BspHandler()) and the corresponding
     // AllCpusInSync loop (on the APs, in SmiRendezvous()) which depends on
     // that store.
     //
     // This guarantees that these pieces of code can never execute
     // simultaneously. In addition, we ensure that the following load is
     // ordered-after the AllCpusInSync loop by using a MemoryFence() with
     // acquire semantics.
     //
     MemoryFence ();

     Handler = mCpuHotEjectData->Handler;

     if (Handler != NULL) {
       Handler (CpuIndex);
     }
   }
 }

 /**
   Check to see if an SMM register is supported by a specified CPU.

   @param[in] CpuIndex  The index of the CPU to check for SMM register support.
                        The value must be between 0 and the NumberOfCpus field
                        in the System Management System Table (SMST).
   @param[in] RegName   Identifies the SMM register to check for support.

   @retval TRUE   The SMM register specified by RegName is supported by the CPU
                  specified by CpuIndex.
   @retval FALSE  The SMM register specified by RegName is not supported by the
                  CPU specified by CpuIndex.
 **/
 BOOLEAN
 EFIAPI
 SmmCpuFeaturesIsSmmRegisterSupported (
   IN UINTN         CpuIndex,
   IN SMM_REG_NAME  RegName
   )
 {
   ASSERT (RegName == SmmRegFeatureControl);
   return FALSE;
 }

 /**
   Returns the current value of the SMM register for the specified CPU.
   If the SMM register is not supported, then 0 is returned.

   @param[in] CpuIndex  The index of the CPU to read the SMM register.  The
                        value must be between 0 and the NumberOfCpus field in
                        the System Management System Table (SMST).
   @param[in] RegName   Identifies the SMM register to read.

   @return  The value of the SMM register specified by RegName from the CPU
            specified by CpuIndex.
 **/
 UINT64
 EFIAPI
 SmmCpuFeaturesGetSmmRegister (
   IN UINTN         CpuIndex,
   IN SMM_REG_NAME  RegName
   )
 {
   //
   // This is called for SmmRegSmmDelayed, SmmRegSmmBlocked, SmmRegSmmEnable.
   // The last of these should actually be SmmRegSmmDisable, so we can just
   // return FALSE.
   //
   return 0;
 }

 /**
   Sets the value of an SMM register on a specified CPU.
   If the SMM register is not supported, then no action is performed.

   @param[in] CpuIndex  The index of the CPU to write the SMM register.  The
                        value must be between 0 and the NumberOfCpus field in
                        the System Management System Table (SMST).
   @param[in] RegName   Identifies the SMM register to write.
                        registers are read-only.
   @param[in] Value     The value to write to the SMM register.
 **/
 VOID
 EFIAPI
 SmmCpuFeaturesSetSmmRegister (
   IN UINTN         CpuIndex,
   IN SMM_REG_NAME  RegName,
   IN UINT64        Value
   )
 {
   ASSERT (FALSE);
 }

 /**
   This function is hook point called after the gEfiSmmReadyToLockProtocolGuid
   notification is completely processed.
 **/
 VOID
 EFIAPI
 SmmCpuFeaturesCompleteSmmReadyToLock (
   VOID
   )
 {
 }
	/** @file
	The CPU specific programming for PiSmmCpuDxeSmm module.

	Copyright (c) 2010 - 2023, Intel Corporation. All rights reserved.<BR>

	SPDX-License-Identifier: BSD-2-Clause-Patent
	**/

	#include <IndustryStandard/Q35MchIch9.h>
	#include <Library/BaseLib.h>
	#include <Library/BaseMemoryLib.h>
	#include <Library/DebugLib.h>
	#include <Library/MemEncryptSevLib.h>
	#include <Library/MemoryAllocationLib.h>
	#include <Library/PcdLib.h>
	#include <Library/SafeIntLib.h>
	#include <Library/SmmCpuFeaturesLib.h>
	#include <Library/SmmServicesTableLib.h>
	#include <Library/UefiBootServicesTableLib.h>
	#include <Library/HobLib.h>
	#include <Pcd/CpuHotEjectData.h>
	#include <PiSmm.h>
	#include <Register/Amd/SmramSaveStateMap.h>
	#include <Guid/SmmBaseHob.h>

	//
	// EFER register LMA bit
	//
	#define LMA BIT10

	//
	// Indicate SmBase for each Processors has been relocated or not. If TRUE,
	// means no need to do the relocation in SmmCpuFeaturesInitializeProcessor().
	//
	BOOLEAN mSmmCpuFeaturesSmmRelocated;

	/**
	The constructor function

	@param[in] ImageHandle The firmware allocated handle for the EFI image.
	@param[in] SystemTable A pointer to the EFI System Table.

	@retval EFI_SUCCESS The constructor always returns EFI_SUCCESS.

	**/
	EFI_STATUS
	EFIAPI
	SmmCpuFeaturesLibConstructor (
	IN EFI_HANDLE ImageHandle,
	IN EFI_SYSTEM_TABLE *SystemTable
	)
	{
	//
	// If gSmmBaseHobGuid found, means SmBase info has been relocated and recorded
	// in the SmBase array.
	//
	mSmmCpuFeaturesSmmRelocated = (BOOLEAN)(GetFirstGuidHob (&gSmmBaseHobGuid) != NULL);

	//
	// No need to program SMRRs on our virtual platform.
	//
	return EFI_SUCCESS;
	}

	/**
	Called during the very first SMI into System Management Mode to initialize
	CPU features, including SMBASE, for the currently executing CPU. Since this
	is the first SMI, the SMRAM Save State Map is at the default address of
	SMM_DEFAULT_SMBASE + SMRAM_SAVE_STATE_MAP_OFFSET. The currently executing
	CPU is specified by CpuIndex and CpuIndex can be used to access information
	about the currently executing CPU in the ProcessorInfo array and the
	HotPlugCpuData data structure.

	@param[in] CpuIndex The index of the CPU to initialize. The value
	must be between 0 and the NumberOfCpus field in
	the System Management System Table (SMST).
	@param[in] IsMonarch TRUE if the CpuIndex is the index of the CPU that
	was elected as monarch during System Management
	Mode initialization.
	FALSE if the CpuIndex is not the index of the CPU
	that was elected as monarch during System
	Management Mode initialization.
	@param[in] ProcessorInfo Pointer to an array of EFI_PROCESSOR_INFORMATION
	structures. ProcessorInfo[CpuIndex] contains the
	information for the currently executing CPU.
	@param[in] CpuHotPlugData Pointer to the CPU_HOT_PLUG_DATA structure that
	contains the ApidId and SmBase arrays.
	**/
	VOID
	EFIAPI
	SmmCpuFeaturesInitializeProcessor (
	IN UINTN CpuIndex,
	IN BOOLEAN IsMonarch,
	IN EFI_PROCESSOR_INFORMATION *ProcessorInfo,
	IN CPU_HOT_PLUG_DATA *CpuHotPlugData
	)
	{
	AMD_SMRAM_SAVE_STATE_MAP *CpuState;

	//
	// No need to configure SMBASE if SmBase relocation has been done.
	//
	if (!mSmmCpuFeaturesSmmRelocated) {
	//
	// Configure SMBASE.
	//
	CpuState = (AMD_SMRAM_SAVE_STATE_MAP *)(UINTN)(
	SMM_DEFAULT_SMBASE +
	SMRAM_SAVE_STATE_MAP_OFFSET
	);
	if ((CpuState->x86.SMMRevId & 0xFFFF) == 0) {
	CpuState->x86.SMBASE = (UINT32)CpuHotPlugData->SmBase[CpuIndex];
	} else {
	CpuState->x64.SMBASE = (UINT32)CpuHotPlugData->SmBase[CpuIndex];
	}
	}

	//
	// No need to program SMRRs on our virtual platform.
	//
	}

	/**
	This function updates the SMRAM save state on the currently executing CPU
	to resume execution at a specific address after an RSM instruction. This
	function must evaluate the SMRAM save state to determine the execution mode
	the RSM instruction resumes and update the resume execution address with
	either NewInstructionPointer32 or NewInstructionPoint. The auto HALT restart
	flag in the SMRAM save state must always be cleared. This function returns
	the value of the instruction pointer from the SMRAM save state that was
	replaced. If this function returns 0, then the SMRAM save state was not
	modified.

	This function is called during the very first SMI on each CPU after
	SmmCpuFeaturesInitializeProcessor() to set a flag in normal execution mode
	to signal that the SMBASE of each CPU has been updated before the default
	SMBASE address is used for the first SMI to the next CPU.

	@param[in] CpuIndex The index of the CPU to hook. The value
	must be between 0 and the NumberOfCpus
	field in the System Management System
	Table (SMST).
	@param[in] CpuState Pointer to SMRAM Save State Map for the
	currently executing CPU.
	@param[in] NewInstructionPointer32 Instruction pointer to use if resuming to
	32-bit execution mode from 64-bit SMM.
	@param[in] NewInstructionPointer Instruction pointer to use if resuming to
	same execution mode as SMM.

	@retval 0 This function did modify the SMRAM save state.
	@retval > 0 The original instruction pointer value from the SMRAM save state
	before it was replaced.
	**/
	UINT64
	EFIAPI
	SmmCpuFeaturesHookReturnFromSmm (
	IN UINTN CpuIndex,
	IN SMRAM_SAVE_STATE_MAP *CpuState,
	IN UINT64 NewInstructionPointer32,
	IN UINT64 NewInstructionPointer
	)
	{
	UINT64 OriginalInstructionPointer;
	AMD_SMRAM_SAVE_STATE_MAP *CpuSaveState;

	CpuSaveState = (AMD_SMRAM_SAVE_STATE_MAP *)CpuState;
	if ((CpuSaveState->x86.SMMRevId & 0xFFFF) == 0) {
	OriginalInstructionPointer = (UINT64)CpuSaveState->x86._EIP;
	CpuSaveState->x86._EIP = (UINT32)NewInstructionPointer;
	//
	// Clear the auto HALT restart flag so the RSM instruction returns
	// program control to the instruction following the HLT instruction.
	//
	if ((CpuSaveState->x86.AutoHALTRestart & BIT0) != 0) {
	CpuSaveState->x86.AutoHALTRestart &= ~BIT0;
	}
	} else {
	OriginalInstructionPointer = CpuSaveState->x64._RIP;
	if ((CpuSaveState->x64.EFER & LMA) == 0) {
	CpuSaveState->x64._RIP = (UINT32)NewInstructionPointer32;
	} else {
	CpuSaveState->x64._RIP = (UINT32)NewInstructionPointer;
	}

	//
	// Clear the auto HALT restart flag so the RSM instruction returns
	// program control to the instruction following the HLT instruction.
	//
	if ((CpuSaveState->x64.AutoHALTRestart & BIT0) != 0) {
	CpuSaveState->x64.AutoHALTRestart &= ~BIT0;
	}
	}

	return OriginalInstructionPointer;
	}

	STATIC CPU_HOT_EJECT_DATA *mCpuHotEjectData = NULL;

	/**
	Initialize mCpuHotEjectData if PcdCpuMaxLogicalProcessorNumber > 1.

	Also setup the corresponding PcdCpuHotEjectDataAddress.
	**/
	STATIC
	VOID
	InitCpuHotEjectData (
	VOID
	)
	{
	UINTN Size;
	UINT32 Idx;
	UINT32 MaxNumberOfCpus;
	RETURN_STATUS PcdStatus;

	MaxNumberOfCpus = PcdGet32 (PcdCpuMaxLogicalProcessorNumber);
	if (MaxNumberOfCpus == 1) {
	return;
	}

	//
	// We allocate CPU_HOT_EJECT_DATA and CPU_HOT_EJECT_DATA->QemuSelectorMap[]
	// in a single allocation, and explicitly align the QemuSelectorMap[] (which
	// is a UINT64 array) at its natural boundary.
	// Accordingly, allocate:
	// sizeof(mCpuHotEjectData) + (MaxNumberOfCpus sizeof(UINT64))
	// and, add sizeof(UINT64) - 1 to use as padding if needed.
	//

	if (RETURN_ERROR (SafeUintnMult (MaxNumberOfCpus, sizeof (UINT64), &Size)) \|\|
	RETURN_ERROR (SafeUintnAdd (Size, sizeof (*mCpuHotEjectData), &Size)) \|\|
	RETURN_ERROR (SafeUintnAdd (Size, sizeof (UINT64) - 1, &Size)))
	{
	DEBUG ((DEBUG_ERROR, "%a: invalid CPU_HOT_EJECT_DATA\n", __func__));
	goto Fatal;
	}

	mCpuHotEjectData = AllocatePool (Size);
	if (mCpuHotEjectData == NULL) {
	ASSERT (mCpuHotEjectData != NULL);
	goto Fatal;
	}

	mCpuHotEjectData->Handler = NULL;
	mCpuHotEjectData->ArrayLength = MaxNumberOfCpus;

	mCpuHotEjectData->QemuSelectorMap = ALIGN_POINTER (
	mCpuHotEjectData + 1,
	sizeof (UINT64)
	);
	//
	// We use mCpuHotEjectData->QemuSelectorMap to map
	// ProcessorNum -> QemuSelector. Initialize to invalid values.
	//
	for (Idx = 0; Idx < mCpuHotEjectData->ArrayLength; Idx++) {
	mCpuHotEjectData->QemuSelectorMap[Idx] = CPU_EJECT_QEMU_SELECTOR_INVALID;
	}

	//
	// Expose address of CPU Hot eject Data structure
	//
	PcdStatus = PcdSet64S (
	PcdCpuHotEjectDataAddress,
	(UINTN)(VOID *)mCpuHotEjectData
	);
	ASSERT_RETURN_ERROR (PcdStatus);

	return;

	Fatal:
	CpuDeadLoop ();
	}

	/**
	Hook point in normal execution mode that allows the one CPU that was elected
	as monarch during System Management Mode initialization to perform additional
	initialization actions immediately after all of the CPUs have processed their
	first SMI and called SmmCpuFeaturesInitializeProcessor() relocating SMBASE
	into a buffer in SMRAM and called SmmCpuFeaturesHookReturnFromSmm().
	**/
	VOID
	EFIAPI
	SmmCpuFeaturesSmmRelocationComplete (
	VOID
	)
	{
	EFI_STATUS Status;
	UINTN MapPagesBase;
	UINTN MapPagesCount;

	InitCpuHotEjectData ();

	if (!MemEncryptSevIsEnabled ()) {
	return;
	}

	//
	// Now that SMBASE relocation is complete, re-encrypt the original SMRAM save
	// state map's container pages, and release the pages to DXE. (The pages were
	// allocated in PlatformPei.)
	//
	Status = MemEncryptSevLocateInitialSmramSaveStateMapPages (
	&MapPagesBase,
	&MapPagesCount
	);
	ASSERT_EFI_ERROR (Status);

	Status = MemEncryptSevSetPageEncMask (
	0, // Cr3BaseAddress -- use current CR3
	MapPagesBase, // BaseAddress
	MapPagesCount // NumPages
	);
	if (EFI_ERROR (Status)) {
	DEBUG ((
	DEBUG_ERROR,
	"%a: MemEncryptSevSetPageEncMask(): %r\n",
	__func__,
	Status
	));
	ASSERT (FALSE);
	CpuDeadLoop ();
	}

	ZeroMem ((VOID *)MapPagesBase, EFI_PAGES_TO_SIZE (MapPagesCount));

	if (PcdGetBool (PcdQ35SmramAtDefaultSmbase)) {
	//
	// The initial SMRAM Save State Map has been covered as part of a larger
	// reserved memory allocation in PlatformPei's InitializeRamRegions(). That
	// allocation is supposed to survive into OS runtime; we must not release
	// any part of it. Only re-assert the containment here.
	//
	ASSERT (SMM_DEFAULT_SMBASE <= MapPagesBase);
	ASSERT (
	(MapPagesBase + EFI_PAGES_TO_SIZE (MapPagesCount) <=
	SMM_DEFAULT_SMBASE + MCH_DEFAULT_SMBASE_SIZE)
	);
	} else {
	Status = gBS->FreePages (MapPagesBase, MapPagesCount);
	ASSERT_EFI_ERROR (Status);
	}
	}

	/**
	Return the size, in bytes, of a custom SMI Handler in bytes. If 0 is
	returned, then a custom SMI handler is not provided by this library,
	and the default SMI handler must be used.

	@retval 0 Use the default SMI handler.
	@retval > 0 Use the SMI handler installed by
	SmmCpuFeaturesInstallSmiHandler(). The caller is required to
	allocate enough SMRAM for each CPU to support the size of the
	custom SMI handler.
	**/
	UINTN
	EFIAPI
	SmmCpuFeaturesGetSmiHandlerSize (
	VOID
	)
	{
	return 0;
	}

	/**
	Install a custom SMI handler for the CPU specified by CpuIndex. This
	function is only called if SmmCpuFeaturesGetSmiHandlerSize() returns a size
	is greater than zero and is called by the CPU that was elected as monarch
	during System Management Mode initialization.

	@param[in] CpuIndex The index of the CPU to install the custom SMI handler.
	The value must be between 0 and the NumberOfCpus field
	in the System Management System Table (SMST).
	@param[in] SmBase The SMBASE address for the CPU specified by CpuIndex.
	@param[in] SmiStack The stack to use when an SMI is processed by the
	the CPU specified by CpuIndex.
	@param[in] StackSize The size, in bytes, if the stack used when an SMI is
	processed by the CPU specified by CpuIndex.
	@param[in] GdtBase The base address of the GDT to use when an SMI is
	processed by the CPU specified by CpuIndex.
	@param[in] GdtSize The size, in bytes, of the GDT used when an SMI is
	processed by the CPU specified by CpuIndex.
	@param[in] IdtBase The base address of the IDT to use when an SMI is
	processed by the CPU specified by CpuIndex.
	@param[in] IdtSize The size, in bytes, of the IDT used when an SMI is
	processed by the CPU specified by CpuIndex.
	@param[in] Cr3 The base address of the page tables to use when an SMI
	is processed by the CPU specified by CpuIndex.
	**/
	VOID
	EFIAPI
	SmmCpuFeaturesInstallSmiHandler (
	IN UINTN CpuIndex,
	IN UINT32 SmBase,
	IN VOID *SmiStack,
	IN UINTN StackSize,
	IN UINTN GdtBase,
	IN UINTN GdtSize,
	IN UINTN IdtBase,
	IN UINTN IdtSize,
	IN UINT32 Cr3
	)
	{
	}

	/**
	Determines if MTRR registers must be configured to set SMRAM cache-ability
	when executing in System Management Mode.

	@retval TRUE MTRR registers must be configured to set SMRAM cache-ability.
	@retval FALSE MTRR registers do not need to be configured to set SMRAM
	cache-ability.
	**/
	BOOLEAN
	EFIAPI
	SmmCpuFeaturesNeedConfigureMtrrs (
	VOID
	)
	{
	return FALSE;
	}

	/**
	Disable SMRR register if SMRR is supported and
	SmmCpuFeaturesNeedConfigureMtrrs() returns TRUE.
	**/
	VOID
	EFIAPI
	SmmCpuFeaturesDisableSmrr (
	VOID
	)
	{
	//
	// No SMRR support, nothing to do
	//
	}

	/**
	Enable SMRR register if SMRR is supported and
	SmmCpuFeaturesNeedConfigureMtrrs() returns TRUE.
	**/
	VOID
	EFIAPI
	SmmCpuFeaturesReenableSmrr (
	VOID
	)
	{
	//
	// No SMRR support, nothing to do
	//
	}

	/**
	Processor specific hook point each time a CPU enters System Management Mode.

	@param[in] CpuIndex The index of the CPU that has entered SMM. The value
	must be between 0 and the NumberOfCpus field in the
	System Management System Table (SMST).
	**/
	VOID
	EFIAPI
	SmmCpuFeaturesRendezvousEntry (
	IN UINTN CpuIndex
	)
	{
	//
	// No SMRR support, nothing to do
	//
	}

	/**
	Processor specific hook point each time a CPU exits System Management Mode.

	@param[in] CpuIndex The index of the CPU that is exiting SMM. The value
	must be between 0 and the NumberOfCpus field in the
	System Management System Table (SMST).
	**/
	VOID
	EFIAPI
	SmmCpuFeaturesRendezvousExit (
	IN UINTN CpuIndex
	)
	{
	//
	// We only call the Handler if CPU hot-eject is enabled
	// (PcdCpuMaxLogicalProcessorNumber > 1), and hot-eject is needed
	// in this SMI exit (otherwise mCpuHotEjectData->Handler is not armed.)
	//

	if (mCpuHotEjectData != NULL) {
	CPU_HOT_EJECT_HANDLER Handler;

	//
	// As the comment above mentions, mCpuHotEjectData->Handler might be
	// written to on the BSP as part of handling of the CPU-ejection.
	//
	// We know that any initial assignment to mCpuHotEjectData->Handler
	// (on the BSP, in the CpuHotplugMmi() context) is ordered-before the
	// load below, since it is guaranteed to happen before the
	// control-dependency of the BSP's SMI exit signal -- by way of a store
	// to AllCpusInSync (on the BSP, in BspHandler()) and the corresponding
	// AllCpusInSync loop (on the APs, in SmiRendezvous()) which depends on
	// that store.
	//
	// This guarantees that these pieces of code can never execute
	// simultaneously. In addition, we ensure that the following load is
	// ordered-after the AllCpusInSync loop by using a MemoryFence() with
	// acquire semantics.
	//
	MemoryFence ();

	Handler = mCpuHotEjectData->Handler;

	if (Handler != NULL) {
	Handler (CpuIndex);
	}
	}
	}

	/**
	Check to see if an SMM register is supported by a specified CPU.

	@param[in] CpuIndex The index of the CPU to check for SMM register support.
	The value must be between 0 and the NumberOfCpus field
	in the System Management System Table (SMST).
	@param[in] RegName Identifies the SMM register to check for support.

	@retval TRUE The SMM register specified by RegName is supported by the CPU
	specified by CpuIndex.
	@retval FALSE The SMM register specified by RegName is not supported by the
	CPU specified by CpuIndex.
	**/
	BOOLEAN
	EFIAPI
	SmmCpuFeaturesIsSmmRegisterSupported (
	IN UINTN CpuIndex,
	IN SMM_REG_NAME RegName
	)
	{
	ASSERT (RegName == SmmRegFeatureControl);
	return FALSE;
	}

	/**
	Returns the current value of the SMM register for the specified CPU.
	If the SMM register is not supported, then 0 is returned.

	@param[in] CpuIndex The index of the CPU to read the SMM register. The
	value must be between 0 and the NumberOfCpus field in
	the System Management System Table (SMST).
	@param[in] RegName Identifies the SMM register to read.

	@return The value of the SMM register specified by RegName from the CPU
	specified by CpuIndex.
	**/
	UINT64
	EFIAPI
	SmmCpuFeaturesGetSmmRegister (
	IN UINTN CpuIndex,
	IN SMM_REG_NAME RegName
	)
	{
	//
	// This is called for SmmRegSmmDelayed, SmmRegSmmBlocked, SmmRegSmmEnable.
	// The last of these should actually be SmmRegSmmDisable, so we can just
	// return FALSE.
	//
	return 0;
	}

	/**
	Sets the value of an SMM register on a specified CPU.
	If the SMM register is not supported, then no action is performed.

	@param[in] CpuIndex The index of the CPU to write the SMM register. The
	value must be between 0 and the NumberOfCpus field in
	the System Management System Table (SMST).
	@param[in] RegName Identifies the SMM register to write.
	registers are read-only.
	@param[in] Value The value to write to the SMM register.
	**/
	VOID
	EFIAPI
	SmmCpuFeaturesSetSmmRegister (
	IN UINTN CpuIndex,
	IN SMM_REG_NAME RegName,
	IN UINT64 Value
	)
	{
	ASSERT (FALSE);
	}

	/**
	This function is hook point called after the gEfiSmmReadyToLockProtocolGuid
	notification is completely processed.
	**/
	VOID
	EFIAPI
	SmmCpuFeaturesCompleteSmmReadyToLock (
	VOID
	)
	{
	}