OvmfPkg/CpuHotplugSmm/CpuHotplug.c - third_party/edk2 - Git at Google

 /** @file
   Root SMI handler for VCPU hotplug SMIs.

   Copyright (c) 2020, Red Hat, Inc.

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

 #include <CpuHotPlugData.h>                  // CPU_HOT_PLUG_DATA
 #include <IndustryStandard/Q35MchIch9.h>     // ICH9_APM_CNT
 #include <IndustryStandard/QemuCpuHotplug.h> // QEMU_CPUHP_CMD_GET_PENDING
 #include <Library/BaseLib.h>                 // CpuDeadLoop()
 #include <Library/DebugLib.h>                // ASSERT()
 #include <Library/MmServicesTableLib.h>      // gMmst
 #include <Library/PcdLib.h>                  // PcdGetBool()
 #include <Library/SafeIntLib.h>              // SafeUintnSub()
 #include <Protocol/MmCpuIo.h>                // EFI_MM_CPU_IO_PROTOCOL
 #include <Protocol/SmmCpuService.h>          // EFI_SMM_CPU_SERVICE_PROTOCOL
 #include <Uefi/UefiBaseType.h>               // EFI_STATUS

 #include "ApicId.h"                          // APIC_ID
 #include "QemuCpuhp.h"                       // QemuCpuhpWriteCpuSelector()
 #include "Smbase.h"                          // SmbaseAllocatePostSmmPen()

 //
 // We use this protocol for accessing IO Ports.
 //
 STATIC EFI_MM_CPU_IO_PROTOCOL *mMmCpuIo;
 //
 // The following protocol is used to report the addition or removal of a CPU to
 // the SMM CPU driver (PiSmmCpuDxeSmm).
 //
 STATIC EFI_SMM_CPU_SERVICE_PROTOCOL *mMmCpuService;
 //
 // This structure is a communication side-channel between the
 // EFI_SMM_CPU_SERVICE_PROTOCOL consumer (i.e., this driver) and provider
 // (i.e., PiSmmCpuDxeSmm).
 //
 STATIC CPU_HOT_PLUG_DATA *mCpuHotPlugData;
 //
 // SMRAM arrays for fetching the APIC IDs of processors with pending events (of
 // known event types), for the time of just one MMI.
 //
 // The lifetimes of these arrays match that of this driver only because we
 // don't want to allocate SMRAM at OS runtime, and potentially fail (or
 // fragment the SMRAM map).
 //
 // These arrays provide room for ("possible CPU count" minus one) APIC IDs
 // each, as we don't expect every possible CPU to appear, or disappear, in a
 // single MMI. The numbers of used (populated) elements in the arrays are
 // determined on every MMI separately.
 //
 STATIC APIC_ID *mPluggedApicIds;
 STATIC APIC_ID *mToUnplugApicIds;
 //
 // Address of the non-SMRAM reserved memory page that contains the Post-SMM Pen
 // for hot-added CPUs.
 //
 STATIC UINT32 mPostSmmPenAddress;
 //
 // Represents the registration of the CPU Hotplug MMI handler.
 //
 STATIC EFI_HANDLE mDispatchHandle;


 /**
   CPU Hotplug MMI handler function.

   This is a root MMI handler.

   @param[in] DispatchHandle      The unique handle assigned to this handler by
                                  EFI_MM_SYSTEM_TABLE.MmiHandlerRegister().

   @param[in] Context             Context passed in by
                                  EFI_MM_SYSTEM_TABLE.MmiManage(). Due to
                                  CpuHotplugMmi() being a root MMI handler,
                                  Context is ASSERT()ed to be NULL.

   @param[in,out] CommBuffer      Ignored, due to CpuHotplugMmi() being a root
                                  MMI handler.

   @param[in,out] CommBufferSize  Ignored, due to CpuHotplugMmi() being a root
                                  MMI handler.

   @retval EFI_SUCCESS                       The MMI was handled and the MMI
                                             source was quiesced. When returned
                                             by a non-root MMI handler,
                                             EFI_SUCCESS terminates the
                                             processing of MMI handlers in
                                             EFI_MM_SYSTEM_TABLE.MmiManage().
                                             For a root MMI handler (i.e., for
                                             the present function too),
                                             EFI_SUCCESS behaves identically to
                                             EFI_WARN_INTERRUPT_SOURCE_QUIESCED,
                                             as further root MMI handlers are
                                             going to be called by
                                             EFI_MM_SYSTEM_TABLE.MmiManage()
                                             anyway.

   @retval EFI_WARN_INTERRUPT_SOURCE_QUIESCED  The MMI source has been quiesced,
                                               but other handlers should still
                                               be called.

   @retval EFI_WARN_INTERRUPT_SOURCE_PENDING   The MMI source is still pending,
                                               and other handlers should still
                                               be called.

   @retval EFI_INTERRUPT_PENDING               The MMI source could not be
                                               quiesced.
 **/
 STATIC
 EFI_STATUS
 EFIAPI
 CpuHotplugMmi (
   IN EFI_HANDLE DispatchHandle,
   IN CONST VOID *Context        OPTIONAL,
   IN OUT VOID   *CommBuffer     OPTIONAL,
   IN OUT UINTN  *CommBufferSize OPTIONAL
   )
 {
   EFI_STATUS Status;
   UINT8      ApmControl;
   UINT32     PluggedCount;
   UINT32     ToUnplugCount;
   UINT32     PluggedIdx;
   UINT32     NewSlot;

   //
   // Assert that we are entering this function due to our root MMI handler
   // registration.
   //
   ASSERT (DispatchHandle == mDispatchHandle);
   //
   // When MmiManage() is invoked to process root MMI handlers, the caller (the
   // MM Core) is expected to pass in a NULL Context. MmiManage() then passes
   // the same NULL Context to individual handlers.
   //
   ASSERT (Context == NULL);
   //
   // Read the MMI command value from the APM Control Port, to see if this is an
   // MMI we should care about.
   //
   Status = mMmCpuIo->Io.Read (mMmCpuIo, MM_IO_UINT8, ICH9_APM_CNT, 1,
                           &ApmControl);
   if (EFI_ERROR (Status)) {
     DEBUG ((DEBUG_ERROR, "%a: failed to read ICH9_APM_CNT: %r\n", __FUNCTION__,
       Status));
     //
     // We couldn't even determine if the MMI was for us or not.
     //
     goto Fatal;
   }

   if (ApmControl != ICH9_APM_CNT_CPU_HOTPLUG) {
     //
     // The MMI is not for us.
     //
     return EFI_WARN_INTERRUPT_SOURCE_QUIESCED;
   }

   //
   // Collect the CPUs with pending events.
   //
   Status = QemuCpuhpCollectApicIds (
              mMmCpuIo,
              mCpuHotPlugData->ArrayLength,     // PossibleCpuCount
              mCpuHotPlugData->ArrayLength - 1, // ApicIdCount
              mPluggedApicIds,
              &PluggedCount,
              mToUnplugApicIds,
              &ToUnplugCount
              );
   if (EFI_ERROR (Status)) {
     goto Fatal;
   }
   if (ToUnplugCount > 0) {
     DEBUG ((DEBUG_ERROR, "%a: hot-unplug is not supported yet\n",
       __FUNCTION__));
     goto Fatal;
   }

   //
   // Process hot-added CPUs.
   //
   // The Post-SMM Pen need not be reinstalled multiple times within a single
   // root MMI handling. Even reinstalling once per root MMI is only prudence;
   // in theory installing the pen in the driver's entry point function should
   // suffice.
   //
   SmbaseReinstallPostSmmPen (mPostSmmPenAddress);

   PluggedIdx = 0;
   NewSlot = 0;
   while (PluggedIdx < PluggedCount) {
     APIC_ID NewApicId;
     UINT32  CheckSlot;
     UINTN   NewProcessorNumberByProtocol;

     NewApicId = mPluggedApicIds[PluggedIdx];

     //
     // Check if the supposedly hot-added CPU is already known to us.
     //
     for (CheckSlot = 0;
          CheckSlot < mCpuHotPlugData->ArrayLength;
          CheckSlot++) {
       if (mCpuHotPlugData->ApicId[CheckSlot] == NewApicId) {
         break;
       }
     }
     if (CheckSlot < mCpuHotPlugData->ArrayLength) {
       DEBUG ((DEBUG_VERBOSE, "%a: APIC ID " FMT_APIC_ID " was hot-plugged "
         "before; ignoring it\n", __FUNCTION__, NewApicId));
       PluggedIdx++;
       continue;
     }

     //
     // Find the first empty slot in CPU_HOT_PLUG_DATA.
     //
     while (NewSlot < mCpuHotPlugData->ArrayLength &&
            mCpuHotPlugData->ApicId[NewSlot] != MAX_UINT64) {
       NewSlot++;
     }
     if (NewSlot == mCpuHotPlugData->ArrayLength) {
       DEBUG ((DEBUG_ERROR, "%a: no room for APIC ID " FMT_APIC_ID "\n",
         __FUNCTION__, NewApicId));
       goto Fatal;
     }

     //
     // Store the APIC ID of the new processor to the slot.
     //
     mCpuHotPlugData->ApicId[NewSlot] = NewApicId;

     //
     // Relocate the SMBASE of the new CPU.
     //
     Status = SmbaseRelocate (NewApicId, mCpuHotPlugData->SmBase[NewSlot],
                mPostSmmPenAddress);
     if (EFI_ERROR (Status)) {
       goto RevokeNewSlot;
     }

     //
     // Add the new CPU with EFI_SMM_CPU_SERVICE_PROTOCOL.
     //
     Status = mMmCpuService->AddProcessor (mMmCpuService, NewApicId,
                               &NewProcessorNumberByProtocol);
     if (EFI_ERROR (Status)) {
       DEBUG ((DEBUG_ERROR, "%a: AddProcessor(" FMT_APIC_ID "): %r\n",
         __FUNCTION__, NewApicId, Status));
       goto RevokeNewSlot;
     }

     DEBUG ((DEBUG_INFO, "%a: hot-added APIC ID " FMT_APIC_ID ", SMBASE 0x%Lx, "
       "EFI_SMM_CPU_SERVICE_PROTOCOL assigned number %Lu\n", __FUNCTION__,
       NewApicId, (UINT64)mCpuHotPlugData->SmBase[NewSlot],
       (UINT64)NewProcessorNumberByProtocol));

     NewSlot++;
     PluggedIdx++;
   }

   //
   // We've handled this MMI.
   //
   return EFI_SUCCESS;

 RevokeNewSlot:
   mCpuHotPlugData->ApicId[NewSlot] = MAX_UINT64;

 Fatal:
   ASSERT (FALSE);
   CpuDeadLoop ();
   //
   // We couldn't handle this MMI.
   //
   return EFI_INTERRUPT_PENDING;
 }


 //
 // Entry point function of this driver.
 //
 EFI_STATUS
 EFIAPI
 CpuHotplugEntry (
   IN EFI_HANDLE       ImageHandle,
   IN EFI_SYSTEM_TABLE *SystemTable
   )
 {
   EFI_STATUS Status;
   UINTN      Size;

   //
   // This module should only be included when SMM support is required.
   //
   ASSERT (FeaturePcdGet (PcdSmmSmramRequire));
   //
   // This driver depends on the dynamically detected "SMRAM at default SMBASE"
   // feature.
   //
   if (!PcdGetBool (PcdQ35SmramAtDefaultSmbase)) {
     return EFI_UNSUPPORTED;
   }

   //
   // Errors from here on are fatal; we cannot allow the boot to proceed if we
   // can't set up this driver to handle CPU hotplug.
   //
   // First, collect the protocols needed later. All of these protocols are
   // listed in our module DEPEX.
   //
   Status = gMmst->MmLocateProtocol (&gEfiMmCpuIoProtocolGuid,
                     NULL /* Registration */, (VOID **)&mMmCpuIo);
   if (EFI_ERROR (Status)) {
     DEBUG ((DEBUG_ERROR, "%a: locate MmCpuIo: %r\n", __FUNCTION__, Status));
     goto Fatal;
   }
   Status = gMmst->MmLocateProtocol (&gEfiSmmCpuServiceProtocolGuid,
                     NULL /* Registration */, (VOID **)&mMmCpuService);
   if (EFI_ERROR (Status)) {
     DEBUG ((DEBUG_ERROR, "%a: locate MmCpuService: %r\n", __FUNCTION__,
       Status));
     goto Fatal;
   }

   //
   // Our DEPEX on EFI_SMM_CPU_SERVICE_PROTOCOL guarantees that PiSmmCpuDxeSmm
   // has pointed PcdCpuHotPlugDataAddress to CPU_HOT_PLUG_DATA in SMRAM.
   //
   mCpuHotPlugData = (VOID *)(UINTN)PcdGet64 (PcdCpuHotPlugDataAddress);
   if (mCpuHotPlugData == NULL) {
     Status = EFI_NOT_FOUND;
     DEBUG ((DEBUG_ERROR, "%a: CPU_HOT_PLUG_DATA: %r\n", __FUNCTION__, Status));
     goto Fatal;
   }
   //
   // If the possible CPU count is 1, there's nothing for this driver to do.
   //
   if (mCpuHotPlugData->ArrayLength == 1) {
     return EFI_UNSUPPORTED;
   }
   //
   // Allocate the data structures that depend on the possible CPU count.
   //
   if (RETURN_ERROR (SafeUintnSub (mCpuHotPlugData->ArrayLength, 1, &Size)) ||
       RETURN_ERROR (SafeUintnMult (sizeof (APIC_ID), Size, &Size))) {
     Status = EFI_ABORTED;
     DEBUG ((DEBUG_ERROR, "%a: invalid CPU_HOT_PLUG_DATA\n", __FUNCTION__));
     goto Fatal;
   }
   Status = gMmst->MmAllocatePool (EfiRuntimeServicesData, Size,
                     (VOID **)&mPluggedApicIds);
   if (EFI_ERROR (Status)) {
     DEBUG ((DEBUG_ERROR, "%a: MmAllocatePool(): %r\n", __FUNCTION__, Status));
     goto Fatal;
   }
   Status = gMmst->MmAllocatePool (EfiRuntimeServicesData, Size,
                     (VOID **)&mToUnplugApicIds);
   if (EFI_ERROR (Status)) {
     DEBUG ((DEBUG_ERROR, "%a: MmAllocatePool(): %r\n", __FUNCTION__, Status));
     goto ReleasePluggedApicIds;
   }

   //
   // Allocate the Post-SMM Pen for hot-added CPUs.
   //
   Status = SmbaseAllocatePostSmmPen (&mPostSmmPenAddress,
              SystemTable->BootServices);
   if (EFI_ERROR (Status)) {
     goto ReleaseToUnplugApicIds;
   }

   //
   // Sanity-check the CPU hotplug interface.
   //
   // Both of the following features are part of QEMU 5.0, introduced primarily
   // in commit range 3e08b2b9cb64..3a61c8db9d25:
   //
   // (a) the QEMU_CPUHP_CMD_GET_ARCH_ID command of the modern CPU hotplug
   //     interface,
   //
   // (b) the "SMRAM at default SMBASE" feature.
   //
   // From these, (b) is restricted to 5.0+ machine type versions, while (a)
   // does not depend on machine type version. Because we ensured the stricter
   // condition (b) through PcdQ35SmramAtDefaultSmbase above, the (a)
   // QEMU_CPUHP_CMD_GET_ARCH_ID command must now be available too. While we
   // can't verify the presence of precisely that command, we can still verify
   // (sanity-check) that the modern interface is active, at least.
   //
   // Consult the "Typical usecases | Detecting and enabling modern CPU hotplug
   // interface" section in QEMU's "docs/specs/acpi_cpu_hotplug.txt", on the
   // following.
   //
   QemuCpuhpWriteCpuSelector (mMmCpuIo, 0);
   QemuCpuhpWriteCpuSelector (mMmCpuIo, 0);
   QemuCpuhpWriteCommand (mMmCpuIo, QEMU_CPUHP_CMD_GET_PENDING);
   if (QemuCpuhpReadCommandData2 (mMmCpuIo) != 0) {
     Status = EFI_NOT_FOUND;
     DEBUG ((DEBUG_ERROR, "%a: modern CPU hotplug interface: %r\n",
       __FUNCTION__, Status));
     goto ReleasePostSmmPen;
   }

   //
   // Register the handler for the CPU Hotplug MMI.
   //
   Status = gMmst->MmiHandlerRegister (
                     CpuHotplugMmi,
                     NULL,            // HandlerType: root MMI handler
                     &mDispatchHandle
                     );
   if (EFI_ERROR (Status)) {
     DEBUG ((DEBUG_ERROR, "%a: MmiHandlerRegister(): %r\n", __FUNCTION__,
       Status));
     goto ReleasePostSmmPen;
   }

   //
   // Install the handler for the hot-added CPUs' first SMI.
   //
   SmbaseInstallFirstSmiHandler ();

   return EFI_SUCCESS;

 ReleasePostSmmPen:
   SmbaseReleasePostSmmPen (mPostSmmPenAddress, SystemTable->BootServices);
   mPostSmmPenAddress = 0;

 ReleaseToUnplugApicIds:
   gMmst->MmFreePool (mToUnplugApicIds);
   mToUnplugApicIds = NULL;

 ReleasePluggedApicIds:
   gMmst->MmFreePool (mPluggedApicIds);
   mPluggedApicIds = NULL;

 Fatal:
   ASSERT (FALSE);
   CpuDeadLoop ();
   return Status;
 }
	/** @file
	Root SMI handler for VCPU hotplug SMIs.

	Copyright (c) 2020, Red Hat, Inc.

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

	#include <CpuHotPlugData.h> // CPU_HOT_PLUG_DATA
	#include <IndustryStandard/Q35MchIch9.h> // ICH9_APM_CNT
	#include <IndustryStandard/QemuCpuHotplug.h> // QEMU_CPUHP_CMD_GET_PENDING
	#include <Library/BaseLib.h> // CpuDeadLoop()
	#include <Library/DebugLib.h> // ASSERT()
	#include <Library/MmServicesTableLib.h> // gMmst
	#include <Library/PcdLib.h> // PcdGetBool()
	#include <Library/SafeIntLib.h> // SafeUintnSub()
	#include <Protocol/MmCpuIo.h> // EFI_MM_CPU_IO_PROTOCOL
	#include <Protocol/SmmCpuService.h> // EFI_SMM_CPU_SERVICE_PROTOCOL
	#include <Uefi/UefiBaseType.h> // EFI_STATUS

	#include "ApicId.h" // APIC_ID
	#include "QemuCpuhp.h" // QemuCpuhpWriteCpuSelector()
	#include "Smbase.h" // SmbaseAllocatePostSmmPen()

	//
	// We use this protocol for accessing IO Ports.
	//
	STATIC EFI_MM_CPU_IO_PROTOCOL *mMmCpuIo;
	//
	// The following protocol is used to report the addition or removal of a CPU to
	// the SMM CPU driver (PiSmmCpuDxeSmm).
	//
	STATIC EFI_SMM_CPU_SERVICE_PROTOCOL *mMmCpuService;
	//
	// This structure is a communication side-channel between the
	// EFI_SMM_CPU_SERVICE_PROTOCOL consumer (i.e., this driver) and provider
	// (i.e., PiSmmCpuDxeSmm).
	//
	STATIC CPU_HOT_PLUG_DATA *mCpuHotPlugData;
	//
	// SMRAM arrays for fetching the APIC IDs of processors with pending events (of
	// known event types), for the time of just one MMI.
	//
	// The lifetimes of these arrays match that of this driver only because we
	// don't want to allocate SMRAM at OS runtime, and potentially fail (or
	// fragment the SMRAM map).
	//
	// These arrays provide room for ("possible CPU count" minus one) APIC IDs
	// each, as we don't expect every possible CPU to appear, or disappear, in a
	// single MMI. The numbers of used (populated) elements in the arrays are
	// determined on every MMI separately.
	//
	STATIC APIC_ID *mPluggedApicIds;
	STATIC APIC_ID *mToUnplugApicIds;
	//
	// Address of the non-SMRAM reserved memory page that contains the Post-SMM Pen
	// for hot-added CPUs.
	//
	STATIC UINT32 mPostSmmPenAddress;
	//
	// Represents the registration of the CPU Hotplug MMI handler.
	//
	STATIC EFI_HANDLE mDispatchHandle;


	/**
	CPU Hotplug MMI handler function.

	This is a root MMI handler.

	@param[in] DispatchHandle The unique handle assigned to this handler by
	EFI_MM_SYSTEM_TABLE.MmiHandlerRegister().

	@param[in] Context Context passed in by
	EFI_MM_SYSTEM_TABLE.MmiManage(). Due to
	CpuHotplugMmi() being a root MMI handler,
	Context is ASSERT()ed to be NULL.

	@param[in,out] CommBuffer Ignored, due to CpuHotplugMmi() being a root
	MMI handler.

	@param[in,out] CommBufferSize Ignored, due to CpuHotplugMmi() being a root
	MMI handler.

	@retval EFI_SUCCESS The MMI was handled and the MMI
	source was quiesced. When returned
	by a non-root MMI handler,
	EFI_SUCCESS terminates the
	processing of MMI handlers in
	EFI_MM_SYSTEM_TABLE.MmiManage().
	For a root MMI handler (i.e., for
	the present function too),
	EFI_SUCCESS behaves identically to
	EFI_WARN_INTERRUPT_SOURCE_QUIESCED,
	as further root MMI handlers are
	going to be called by
	EFI_MM_SYSTEM_TABLE.MmiManage()
	anyway.

	@retval EFI_WARN_INTERRUPT_SOURCE_QUIESCED The MMI source has been quiesced,
	but other handlers should still
	be called.

	@retval EFI_WARN_INTERRUPT_SOURCE_PENDING The MMI source is still pending,
	and other handlers should still
	be called.

	@retval EFI_INTERRUPT_PENDING The MMI source could not be
	quiesced.
	**/
	STATIC
	EFI_STATUS
	EFIAPI
	CpuHotplugMmi (
	IN EFI_HANDLE DispatchHandle,
	IN CONST VOID *Context OPTIONAL,
	IN OUT VOID *CommBuffer OPTIONAL,
	IN OUT UINTN *CommBufferSize OPTIONAL
	)
	{
	EFI_STATUS Status;
	UINT8 ApmControl;
	UINT32 PluggedCount;
	UINT32 ToUnplugCount;
	UINT32 PluggedIdx;
	UINT32 NewSlot;

	//
	// Assert that we are entering this function due to our root MMI handler
	// registration.
	//
	ASSERT (DispatchHandle == mDispatchHandle);
	//
	// When MmiManage() is invoked to process root MMI handlers, the caller (the
	// MM Core) is expected to pass in a NULL Context. MmiManage() then passes
	// the same NULL Context to individual handlers.
	//
	ASSERT (Context == NULL);
	//
	// Read the MMI command value from the APM Control Port, to see if this is an
	// MMI we should care about.
	//
	Status = mMmCpuIo->Io.Read (mMmCpuIo, MM_IO_UINT8, ICH9_APM_CNT, 1,
	&ApmControl);
	if (EFI_ERROR (Status)) {
	DEBUG ((DEBUG_ERROR, "%a: failed to read ICH9_APM_CNT: %r\n", __FUNCTION__,
	Status));
	//
	// We couldn't even determine if the MMI was for us or not.
	//
	goto Fatal;
	}

	if (ApmControl != ICH9_APM_CNT_CPU_HOTPLUG) {
	//
	// The MMI is not for us.
	//
	return EFI_WARN_INTERRUPT_SOURCE_QUIESCED;
	}

	//
	// Collect the CPUs with pending events.
	//
	Status = QemuCpuhpCollectApicIds (
	mMmCpuIo,
	mCpuHotPlugData->ArrayLength, // PossibleCpuCount
	mCpuHotPlugData->ArrayLength - 1, // ApicIdCount
	mPluggedApicIds,
	&PluggedCount,
	mToUnplugApicIds,
	&ToUnplugCount
	);
	if (EFI_ERROR (Status)) {
	goto Fatal;
	}
	if (ToUnplugCount > 0) {
	DEBUG ((DEBUG_ERROR, "%a: hot-unplug is not supported yet\n",
	__FUNCTION__));
	goto Fatal;
	}

	//
	// Process hot-added CPUs.
	//
	// The Post-SMM Pen need not be reinstalled multiple times within a single
	// root MMI handling. Even reinstalling once per root MMI is only prudence;
	// in theory installing the pen in the driver's entry point function should
	// suffice.
	//
	SmbaseReinstallPostSmmPen (mPostSmmPenAddress);

	PluggedIdx = 0;
	NewSlot = 0;
	while (PluggedIdx < PluggedCount) {
	APIC_ID NewApicId;
	UINT32 CheckSlot;
	UINTN NewProcessorNumberByProtocol;

	NewApicId = mPluggedApicIds[PluggedIdx];

	//
	// Check if the supposedly hot-added CPU is already known to us.
	//
	for (CheckSlot = 0;
	CheckSlot < mCpuHotPlugData->ArrayLength;
	CheckSlot++) {
	if (mCpuHotPlugData->ApicId[CheckSlot] == NewApicId) {
	break;
	}
	}
	if (CheckSlot < mCpuHotPlugData->ArrayLength) {
	DEBUG ((DEBUG_VERBOSE, "%a: APIC ID " FMT_APIC_ID " was hot-plugged "
	"before; ignoring it\n", __FUNCTION__, NewApicId));
	PluggedIdx++;
	continue;
	}

	//
	// Find the first empty slot in CPU_HOT_PLUG_DATA.
	//
	while (NewSlot < mCpuHotPlugData->ArrayLength &&
	mCpuHotPlugData->ApicId[NewSlot] != MAX_UINT64) {
	NewSlot++;
	}
	if (NewSlot == mCpuHotPlugData->ArrayLength) {
	DEBUG ((DEBUG_ERROR, "%a: no room for APIC ID " FMT_APIC_ID "\n",
	__FUNCTION__, NewApicId));
	goto Fatal;
	}

	//
	// Store the APIC ID of the new processor to the slot.
	//
	mCpuHotPlugData->ApicId[NewSlot] = NewApicId;

	//
	// Relocate the SMBASE of the new CPU.
	//
	Status = SmbaseRelocate (NewApicId, mCpuHotPlugData->SmBase[NewSlot],
	mPostSmmPenAddress);
	if (EFI_ERROR (Status)) {
	goto RevokeNewSlot;
	}

	//
	// Add the new CPU with EFI_SMM_CPU_SERVICE_PROTOCOL.
	//
	Status = mMmCpuService->AddProcessor (mMmCpuService, NewApicId,
	&NewProcessorNumberByProtocol);
	if (EFI_ERROR (Status)) {
	DEBUG ((DEBUG_ERROR, "%a: AddProcessor(" FMT_APIC_ID "): %r\n",
	__FUNCTION__, NewApicId, Status));
	goto RevokeNewSlot;
	}

	DEBUG ((DEBUG_INFO, "%a: hot-added APIC ID " FMT_APIC_ID ", SMBASE 0x%Lx, "
	"EFI_SMM_CPU_SERVICE_PROTOCOL assigned number %Lu\n", __FUNCTION__,
	NewApicId, (UINT64)mCpuHotPlugData->SmBase[NewSlot],
	(UINT64)NewProcessorNumberByProtocol));

	NewSlot++;
	PluggedIdx++;
	}

	//
	// We've handled this MMI.
	//
	return EFI_SUCCESS;

	RevokeNewSlot:
	mCpuHotPlugData->ApicId[NewSlot] = MAX_UINT64;

	Fatal:
	ASSERT (FALSE);
	CpuDeadLoop ();
	//
	// We couldn't handle this MMI.
	//
	return EFI_INTERRUPT_PENDING;
	}


	//
	// Entry point function of this driver.
	//
	EFI_STATUS
	EFIAPI
	CpuHotplugEntry (
	IN EFI_HANDLE ImageHandle,
	IN EFI_SYSTEM_TABLE *SystemTable
	)
	{
	EFI_STATUS Status;
	UINTN Size;

	//
	// This module should only be included when SMM support is required.
	//
	ASSERT (FeaturePcdGet (PcdSmmSmramRequire));
	//
	// This driver depends on the dynamically detected "SMRAM at default SMBASE"
	// feature.
	//
	if (!PcdGetBool (PcdQ35SmramAtDefaultSmbase)) {
	return EFI_UNSUPPORTED;
	}

	//
	// Errors from here on are fatal; we cannot allow the boot to proceed if we
	// can't set up this driver to handle CPU hotplug.
	//
	// First, collect the protocols needed later. All of these protocols are
	// listed in our module DEPEX.
	//
	Status = gMmst->MmLocateProtocol (&gEfiMmCpuIoProtocolGuid,
	NULL /* Registration /, (VOID *)&mMmCpuIo);
	if (EFI_ERROR (Status)) {
	DEBUG ((DEBUG_ERROR, "%a: locate MmCpuIo: %r\n", __FUNCTION__, Status));
	goto Fatal;
	}
	Status = gMmst->MmLocateProtocol (&gEfiSmmCpuServiceProtocolGuid,
	NULL /* Registration /, (VOID *)&mMmCpuService);
	if (EFI_ERROR (Status)) {
	DEBUG ((DEBUG_ERROR, "%a: locate MmCpuService: %r\n", __FUNCTION__,
	Status));
	goto Fatal;
	}

	//
	// Our DEPEX on EFI_SMM_CPU_SERVICE_PROTOCOL guarantees that PiSmmCpuDxeSmm
	// has pointed PcdCpuHotPlugDataAddress to CPU_HOT_PLUG_DATA in SMRAM.
	//
	mCpuHotPlugData = (VOID *)(UINTN)PcdGet64 (PcdCpuHotPlugDataAddress);
	if (mCpuHotPlugData == NULL) {
	Status = EFI_NOT_FOUND;
	DEBUG ((DEBUG_ERROR, "%a: CPU_HOT_PLUG_DATA: %r\n", __FUNCTION__, Status));
	goto Fatal;
	}
	//
	// If the possible CPU count is 1, there's nothing for this driver to do.
	//
	if (mCpuHotPlugData->ArrayLength == 1) {
	return EFI_UNSUPPORTED;
	}
	//
	// Allocate the data structures that depend on the possible CPU count.
	//
	if (RETURN_ERROR (SafeUintnSub (mCpuHotPlugData->ArrayLength, 1, &Size)) \|\|
	RETURN_ERROR (SafeUintnMult (sizeof (APIC_ID), Size, &Size))) {
	Status = EFI_ABORTED;
	DEBUG ((DEBUG_ERROR, "%a: invalid CPU_HOT_PLUG_DATA\n", __FUNCTION__));
	goto Fatal;
	}
	Status = gMmst->MmAllocatePool (EfiRuntimeServicesData, Size,
	(VOID **)&mPluggedApicIds);
	if (EFI_ERROR (Status)) {
	DEBUG ((DEBUG_ERROR, "%a: MmAllocatePool(): %r\n", __FUNCTION__, Status));
	goto Fatal;
	}
	Status = gMmst->MmAllocatePool (EfiRuntimeServicesData, Size,
	(VOID **)&mToUnplugApicIds);
	if (EFI_ERROR (Status)) {
	DEBUG ((DEBUG_ERROR, "%a: MmAllocatePool(): %r\n", __FUNCTION__, Status));
	goto ReleasePluggedApicIds;
	}

	//
	// Allocate the Post-SMM Pen for hot-added CPUs.
	//
	Status = SmbaseAllocatePostSmmPen (&mPostSmmPenAddress,
	SystemTable->BootServices);
	if (EFI_ERROR (Status)) {
	goto ReleaseToUnplugApicIds;
	}

	//
	// Sanity-check the CPU hotplug interface.
	//
	// Both of the following features are part of QEMU 5.0, introduced primarily
	// in commit range 3e08b2b9cb64..3a61c8db9d25:
	//
	// (a) the QEMU_CPUHP_CMD_GET_ARCH_ID command of the modern CPU hotplug
	// interface,
	//
	// (b) the "SMRAM at default SMBASE" feature.
	//
	// From these, (b) is restricted to 5.0+ machine type versions, while (a)
	// does not depend on machine type version. Because we ensured the stricter
	// condition (b) through PcdQ35SmramAtDefaultSmbase above, the (a)
	// QEMU_CPUHP_CMD_GET_ARCH_ID command must now be available too. While we
	// can't verify the presence of precisely that command, we can still verify
	// (sanity-check) that the modern interface is active, at least.
	//
	// Consult the "Typical usecases \| Detecting and enabling modern CPU hotplug
	// interface" section in QEMU's "docs/specs/acpi_cpu_hotplug.txt", on the
	// following.
	//
	QemuCpuhpWriteCpuSelector (mMmCpuIo, 0);
	QemuCpuhpWriteCpuSelector (mMmCpuIo, 0);
	QemuCpuhpWriteCommand (mMmCpuIo, QEMU_CPUHP_CMD_GET_PENDING);
	if (QemuCpuhpReadCommandData2 (mMmCpuIo) != 0) {
	Status = EFI_NOT_FOUND;
	DEBUG ((DEBUG_ERROR, "%a: modern CPU hotplug interface: %r\n",
	__FUNCTION__, Status));
	goto ReleasePostSmmPen;
	}

	//
	// Register the handler for the CPU Hotplug MMI.
	//
	Status = gMmst->MmiHandlerRegister (
	CpuHotplugMmi,
	NULL, // HandlerType: root MMI handler
	&mDispatchHandle
	);
	if (EFI_ERROR (Status)) {
	DEBUG ((DEBUG_ERROR, "%a: MmiHandlerRegister(): %r\n", __FUNCTION__,
	Status));
	goto ReleasePostSmmPen;
	}

	//
	// Install the handler for the hot-added CPUs' first SMI.
	//
	SmbaseInstallFirstSmiHandler ();

	return EFI_SUCCESS;

	ReleasePostSmmPen:
	SmbaseReleasePostSmmPen (mPostSmmPenAddress, SystemTable->BootServices);
	mPostSmmPenAddress = 0;

	ReleaseToUnplugApicIds:
	gMmst->MmFreePool (mToUnplugApicIds);
	mToUnplugApicIds = NULL;

	ReleasePluggedApicIds:
	gMmst->MmFreePool (mPluggedApicIds);
	mPluggedApicIds = NULL;

	Fatal:
	ASSERT (FALSE);
	CpuDeadLoop ();
	return Status;
	}