OvmfPkg/XenPlatformPei/MemDetect.c - third_party/edk2 - Git at Google

 /**@file
   Memory Detection for Virtual Machines.

   Copyright (c) 2006 - 2016, Intel Corporation. All rights reserved.<BR>
   Copyright (c) 2019, Citrix Systems, Inc.

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

 Module Name:

   MemDetect.c

 **/

 //
 // The package level header files this module uses
 //
 #include <IndustryStandard/Q35MchIch9.h>
 #include <PiPei.h>

 //
 // The Library classes this module consumes
 //
 #include <Library/BaseLib.h>
 #include <Library/BaseMemoryLib.h>
 #include <Library/DebugLib.h>
 #include <Library/HobLib.h>
 #include <Library/IoLib.h>
 #include <Library/PcdLib.h>
 #include <Library/PciLib.h>
 #include <Library/PeimEntryPoint.h>
 #include <Library/ResourcePublicationLib.h>

 #include "Platform.h"
 #include "Cmos.h"

 UINT8 mPhysMemAddressWidth;

 STATIC UINT32 mS3AcpiReservedMemoryBase;
 STATIC UINT32 mS3AcpiReservedMemorySize;

 STATIC UINT16 mQ35TsegMbytes;

 VOID
 Q35TsegMbytesInitialization (
   VOID
   )
 {
   UINT16        ExtendedTsegMbytes;
   RETURN_STATUS PcdStatus;

   if (mHostBridgeDevId != INTEL_Q35_MCH_DEVICE_ID) {
     DEBUG ((
       DEBUG_ERROR,
       "%a: no TSEG (SMRAM) on host bridge DID=0x%04x; "
       "only DID=0x%04x (Q35) is supported\n",
       __FUNCTION__,
       mHostBridgeDevId,
       INTEL_Q35_MCH_DEVICE_ID
       ));
     ASSERT (FALSE);
     CpuDeadLoop ();
   }

   //
   // Check if QEMU offers an extended TSEG.
   //
   // This can be seen from writing MCH_EXT_TSEG_MB_QUERY to the MCH_EXT_TSEG_MB
   // register, and reading back the register.
   //
   // On a QEMU machine type that does not offer an extended TSEG, the initial
   // write overwrites whatever value a malicious guest OS may have placed in
   // the (unimplemented) register, before entering S3 or rebooting.
   // Subsequently, the read returns MCH_EXT_TSEG_MB_QUERY unchanged.
   //
   // On a QEMU machine type that offers an extended TSEG, the initial write
   // triggers an update to the register. Subsequently, the value read back
   // (which is guaranteed to differ from MCH_EXT_TSEG_MB_QUERY) tells us the
   // number of megabytes.
   //
   PciWrite16 (DRAMC_REGISTER_Q35 (MCH_EXT_TSEG_MB), MCH_EXT_TSEG_MB_QUERY);
   ExtendedTsegMbytes = PciRead16 (DRAMC_REGISTER_Q35 (MCH_EXT_TSEG_MB));
   if (ExtendedTsegMbytes == MCH_EXT_TSEG_MB_QUERY) {
     mQ35TsegMbytes = PcdGet16 (PcdQ35TsegMbytes);
     return;
   }

   DEBUG ((
     DEBUG_INFO,
     "%a: QEMU offers an extended TSEG (%d MB)\n",
     __FUNCTION__,
     ExtendedTsegMbytes
     ));
   PcdStatus = PcdSet16S (PcdQ35TsegMbytes, ExtendedTsegMbytes);
   ASSERT_RETURN_ERROR (PcdStatus);
   mQ35TsegMbytes = ExtendedTsegMbytes;
 }

 STATIC
 UINT64
 GetHighestSystemMemoryAddress (
   BOOLEAN       Below4gb
   )
 {
   EFI_E820_ENTRY64    *E820Map;
   UINT32              E820EntriesCount;
   EFI_E820_ENTRY64    *Entry;
   EFI_STATUS          Status;
   UINT32              Loop;
   UINT64              HighestAddress;
   UINT64              EntryEnd;

   HighestAddress = 0;

   Status = XenGetE820Map (&E820Map, &E820EntriesCount);
   ASSERT_EFI_ERROR (Status);

   for (Loop = 0; Loop < E820EntriesCount; Loop++) {
     Entry = E820Map + Loop;
     EntryEnd = Entry->BaseAddr + Entry->Length;

     if (Entry->Type == EfiAcpiAddressRangeMemory &&
         EntryEnd > HighestAddress) {

       if (Below4gb && (EntryEnd <= BASE_4GB)) {
         HighestAddress = EntryEnd;
       } else if (!Below4gb && (EntryEnd >= BASE_4GB)) {
         HighestAddress = EntryEnd;
       }
     }
   }

   //
   // Round down the end address.
   //
   return HighestAddress & ~(UINT64)EFI_PAGE_MASK;
 }

 UINT32
 GetSystemMemorySizeBelow4gb (
   VOID
   )
 {
   UINT8 Cmos0x34;
   UINT8 Cmos0x35;

   //
   // In PVH case, there is no CMOS, we have to calculate the memory size
   // from parsing the E820
   //
   if (XenPvhDetected ()) {
     UINT64  HighestAddress;

     HighestAddress = GetHighestSystemMemoryAddress (TRUE);
     ASSERT (HighestAddress > 0 && HighestAddress <= BASE_4GB);

     return HighestAddress;
   }

   //
   // CMOS 0x34/0x35 specifies the system memory above 16 MB.
   // * CMOS(0x35) is the high byte
   // * CMOS(0x34) is the low byte
   // * The size is specified in 64kb chunks
   // * Since this is memory above 16MB, the 16MB must be added
   //   into the calculation to get the total memory size.
   //

   Cmos0x34 = (UINT8) CmosRead8 (0x34);
   Cmos0x35 = (UINT8) CmosRead8 (0x35);

   return (UINT32) (((UINTN)((Cmos0x35 << 8) + Cmos0x34) << 16) + SIZE_16MB);
 }


 STATIC
 UINT64
 GetSystemMemorySizeAbove4gb (
   )
 {
   UINT32 Size;
   UINTN  CmosIndex;

   //
   // In PVH case, there is no CMOS, we have to calculate the memory size
   // from parsing the E820
   //
   if (XenPvhDetected ()) {
     UINT64  HighestAddress;

     HighestAddress = GetHighestSystemMemoryAddress (FALSE);
     ASSERT (HighestAddress == 0 || HighestAddress >= BASE_4GB);

     if (HighestAddress >= BASE_4GB) {
       HighestAddress -= BASE_4GB;
     }

     return HighestAddress;
   }

   //
   // CMOS 0x5b-0x5d specifies the system memory above 4GB MB.
   // * CMOS(0x5d) is the most significant size byte
   // * CMOS(0x5c) is the middle size byte
   // * CMOS(0x5b) is the least significant size byte
   // * The size is specified in 64kb chunks
   //

   Size = 0;
   for (CmosIndex = 0x5d; CmosIndex >= 0x5b; CmosIndex--) {
     Size = (UINT32) (Size << 8) + (UINT32) CmosRead8 (CmosIndex);
   }

   return LShiftU64 (Size, 16);
 }


 /**
   Return the highest address that DXE could possibly use, plus one.
 **/
 STATIC
 UINT64
 GetFirstNonAddress (
   VOID
   )
 {
   UINT64               FirstNonAddress;
   UINT64               Pci64Base, Pci64Size;
   RETURN_STATUS        PcdStatus;

   FirstNonAddress = BASE_4GB + GetSystemMemorySizeAbove4gb ();

   //
   // If DXE is 32-bit, then we're done; PciBusDxe will degrade 64-bit MMIO
   // resources to 32-bit anyway. See DegradeResource() in
   // "PciResourceSupport.c".
   //
 #ifdef MDE_CPU_IA32
   if (!FeaturePcdGet (PcdDxeIplSwitchToLongMode)) {
     return FirstNonAddress;
   }
 #endif

   //
   // Otherwise, in order to calculate the highest address plus one, we must
   // consider the 64-bit PCI host aperture too. Fetch the default size.
   //
   Pci64Size = PcdGet64 (PcdPciMmio64Size);

   if (Pci64Size == 0) {
     if (mBootMode != BOOT_ON_S3_RESUME) {
       DEBUG ((DEBUG_INFO, "%a: disabling 64-bit PCI host aperture\n",
         __FUNCTION__));
       PcdStatus = PcdSet64S (PcdPciMmio64Size, 0);
       ASSERT_RETURN_ERROR (PcdStatus);
     }

     //
     // There's nothing more to do; the amount of memory above 4GB fully
     // determines the highest address plus one. The memory hotplug area (see
     // below) plays no role for the firmware in this case.
     //
     return FirstNonAddress;
   }

   //
   // SeaBIOS aligns both boundaries of the 64-bit PCI host aperture to 1GB, so
   // that the host can map it with 1GB hugepages. Follow suit.
   //
   Pci64Base = ALIGN_VALUE (FirstNonAddress, (UINT64)SIZE_1GB);
   Pci64Size = ALIGN_VALUE (Pci64Size, (UINT64)SIZE_1GB);

   //
   // The 64-bit PCI host aperture should also be "naturally" aligned. The
   // alignment is determined by rounding the size of the aperture down to the
   // next smaller or equal power of two. That is, align the aperture by the
   // largest BAR size that can fit into it.
   //
   Pci64Base = ALIGN_VALUE (Pci64Base, GetPowerOfTwo64 (Pci64Size));

   if (mBootMode != BOOT_ON_S3_RESUME) {
     //
     // The core PciHostBridgeDxe driver will automatically add this range to
     // the GCD memory space map through our PciHostBridgeLib instance; here we
     // only need to set the PCDs.
     //
     PcdStatus = PcdSet64S (PcdPciMmio64Base, Pci64Base);
     ASSERT_RETURN_ERROR (PcdStatus);
     PcdStatus = PcdSet64S (PcdPciMmio64Size, Pci64Size);
     ASSERT_RETURN_ERROR (PcdStatus);

     DEBUG ((DEBUG_INFO, "%a: Pci64Base=0x%Lx Pci64Size=0x%Lx\n",
       __FUNCTION__, Pci64Base, Pci64Size));
   }

   //
   // The useful address space ends with the 64-bit PCI host aperture.
   //
   FirstNonAddress = Pci64Base + Pci64Size;
   return FirstNonAddress;
 }


 /**
   Initialize the mPhysMemAddressWidth variable, based on guest RAM size.
 **/
 VOID
 AddressWidthInitialization (
   VOID
   )
 {
   UINT64 FirstNonAddress;

   //
   // As guest-physical memory size grows, the permanent PEI RAM requirements
   // are dominated by the identity-mapping page tables built by the DXE IPL.
   // The DXL IPL keys off of the physical address bits advertized in the CPU
   // HOB. To conserve memory, we calculate the minimum address width here.
   //
   FirstNonAddress      = GetFirstNonAddress ();
   mPhysMemAddressWidth = (UINT8)HighBitSet64 (FirstNonAddress);

   //
   // If FirstNonAddress is not an integral power of two, then we need an
   // additional bit.
   //
   if ((FirstNonAddress & (FirstNonAddress - 1)) != 0) {
     ++mPhysMemAddressWidth;
   }

   //
   // The minimum address width is 36 (covers up to and excluding 64 GB, which
   // is the maximum for Ia32 + PAE). The theoretical architecture maximum for
   // X64 long mode is 52 bits, but the DXE IPL clamps that down to 48 bits. We
   // can simply assert that here, since 48 bits are good enough for 256 TB.
   //
   if (mPhysMemAddressWidth <= 36) {
     mPhysMemAddressWidth = 36;
   }
   ASSERT (mPhysMemAddressWidth <= 48);
 }


 /**
   Calculate the cap for the permanent PEI memory.
 **/
 STATIC
 UINT32
 GetPeiMemoryCap (
   VOID
   )
 {
   BOOLEAN Page1GSupport;
   UINT32  RegEax;
   UINT32  RegEdx;
   UINT32  Pml4Entries;
   UINT32  PdpEntries;
   UINTN   TotalPages;

   //
   // If DXE is 32-bit, then just return the traditional 64 MB cap.
   //
 #ifdef MDE_CPU_IA32
   if (!FeaturePcdGet (PcdDxeIplSwitchToLongMode)) {
     return SIZE_64MB;
   }
 #endif

   //
   // Dependent on physical address width, PEI memory allocations can be
   // dominated by the page tables built for 64-bit DXE. So we key the cap off
   // of those. The code below is based on CreateIdentityMappingPageTables() in
   // "MdeModulePkg/Core/DxeIplPeim/X64/VirtualMemory.c".
   //
   Page1GSupport = FALSE;
   if (PcdGetBool (PcdUse1GPageTable)) {
     AsmCpuid (0x80000000, &RegEax, NULL, NULL, NULL);
     if (RegEax >= 0x80000001) {
       AsmCpuid (0x80000001, NULL, NULL, NULL, &RegEdx);
       if ((RegEdx & BIT26) != 0) {
         Page1GSupport = TRUE;
       }
     }
   }

   if (mPhysMemAddressWidth <= 39) {
     Pml4Entries = 1;
     PdpEntries = 1 << (mPhysMemAddressWidth - 30);
     ASSERT (PdpEntries <= 0x200);
   } else {
     Pml4Entries = 1 << (mPhysMemAddressWidth - 39);
     ASSERT (Pml4Entries <= 0x200);
     PdpEntries = 512;
   }

   TotalPages = Page1GSupport ? Pml4Entries + 1 :
                                (PdpEntries + 1) * Pml4Entries + 1;
   ASSERT (TotalPages <= 0x40201);

   //
   // Add 64 MB for miscellaneous allocations. Note that for
   // mPhysMemAddressWidth values close to 36, the cap will actually be
   // dominated by this increment.
   //
   return (UINT32)(EFI_PAGES_TO_SIZE (TotalPages) + SIZE_64MB);
 }


 /**
   Publish PEI core memory

   @return EFI_SUCCESS     The PEIM initialized successfully.

 **/
 EFI_STATUS
 PublishPeiMemory (
   VOID
   )
 {
   EFI_STATUS                  Status;
   EFI_PHYSICAL_ADDRESS        MemoryBase;
   UINT64                      MemorySize;
   UINT32                      LowerMemorySize;
   UINT32                      PeiMemoryCap;

   LowerMemorySize = GetSystemMemorySizeBelow4gb ();

   if (mBootMode == BOOT_ON_S3_RESUME) {
     MemoryBase = mS3AcpiReservedMemoryBase;
     MemorySize = mS3AcpiReservedMemorySize;
   } else {
     PeiMemoryCap = GetPeiMemoryCap ();
     DEBUG ((DEBUG_INFO, "%a: mPhysMemAddressWidth=%d PeiMemoryCap=%u KB\n",
       __FUNCTION__, mPhysMemAddressWidth, PeiMemoryCap >> 10));

     //
     // Determine the range of memory to use during PEI
     //
     MemoryBase =
       PcdGet32 (PcdOvmfDxeMemFvBase) + PcdGet32 (PcdOvmfDxeMemFvSize);
     MemorySize = LowerMemorySize - MemoryBase;
     if (MemorySize > PeiMemoryCap) {
       MemoryBase = LowerMemorySize - PeiMemoryCap;
       MemorySize = PeiMemoryCap;
     }
   }

   //
   // Publish this memory to the PEI Core
   //
   Status = PublishSystemMemory(MemoryBase, MemorySize);
   ASSERT_EFI_ERROR (Status);

   return Status;
 }


 /**
   Publish system RAM and reserve memory regions

 **/
 VOID
 InitializeRamRegions (
   VOID
   )
 {
   XenPublishRamRegions ();

   if (mBootMode != BOOT_ON_S3_RESUME) {
     //
     // Reserve the lock box storage area
     //
     // Since this memory range will be used on S3 resume, it must be
     // reserved as ACPI NVS.
     //
     // If S3 is unsupported, then various drivers might still write to the
     // LockBox area. We ought to prevent DXE from serving allocation requests
     // such that they would overlap the LockBox storage.
     //
     ZeroMem (
       (VOID*)(UINTN) PcdGet32 (PcdOvmfLockBoxStorageBase),
       (UINTN) PcdGet32 (PcdOvmfLockBoxStorageSize)
       );
     BuildMemoryAllocationHob (
       (EFI_PHYSICAL_ADDRESS)(UINTN) PcdGet32 (PcdOvmfLockBoxStorageBase),
       (UINT64)(UINTN) PcdGet32 (PcdOvmfLockBoxStorageSize),
       EfiBootServicesData
       );
   }
 }
	/**@file
	Memory Detection for Virtual Machines.

	Copyright (c) 2006 - 2016, Intel Corporation. All rights reserved.<BR>
	Copyright (c) 2019, Citrix Systems, Inc.

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

	Module Name:

	MemDetect.c

	**/

	//
	// The package level header files this module uses
	//
	#include <IndustryStandard/Q35MchIch9.h>
	#include <PiPei.h>

	//
	// The Library classes this module consumes
	//
	#include <Library/BaseLib.h>
	#include <Library/BaseMemoryLib.h>
	#include <Library/DebugLib.h>
	#include <Library/HobLib.h>
	#include <Library/IoLib.h>
	#include <Library/PcdLib.h>
	#include <Library/PciLib.h>
	#include <Library/PeimEntryPoint.h>
	#include <Library/ResourcePublicationLib.h>

	#include "Platform.h"
	#include "Cmos.h"

	UINT8 mPhysMemAddressWidth;

	STATIC UINT32 mS3AcpiReservedMemoryBase;
	STATIC UINT32 mS3AcpiReservedMemorySize;

	STATIC UINT16 mQ35TsegMbytes;

	VOID
	Q35TsegMbytesInitialization (
	VOID
	)
	{
	UINT16 ExtendedTsegMbytes;
	RETURN_STATUS PcdStatus;

	if (mHostBridgeDevId != INTEL_Q35_MCH_DEVICE_ID) {
	DEBUG ((
	DEBUG_ERROR,
	"%a: no TSEG (SMRAM) on host bridge DID=0x%04x; "
	"only DID=0x%04x (Q35) is supported\n",
	__FUNCTION__,
	mHostBridgeDevId,
	INTEL_Q35_MCH_DEVICE_ID
	));
	ASSERT (FALSE);
	CpuDeadLoop ();
	}

	//
	// Check if QEMU offers an extended TSEG.
	//
	// This can be seen from writing MCH_EXT_TSEG_MB_QUERY to the MCH_EXT_TSEG_MB
	// register, and reading back the register.
	//
	// On a QEMU machine type that does not offer an extended TSEG, the initial
	// write overwrites whatever value a malicious guest OS may have placed in
	// the (unimplemented) register, before entering S3 or rebooting.
	// Subsequently, the read returns MCH_EXT_TSEG_MB_QUERY unchanged.
	//
	// On a QEMU machine type that offers an extended TSEG, the initial write
	// triggers an update to the register. Subsequently, the value read back
	// (which is guaranteed to differ from MCH_EXT_TSEG_MB_QUERY) tells us the
	// number of megabytes.
	//
	PciWrite16 (DRAMC_REGISTER_Q35 (MCH_EXT_TSEG_MB), MCH_EXT_TSEG_MB_QUERY);
	ExtendedTsegMbytes = PciRead16 (DRAMC_REGISTER_Q35 (MCH_EXT_TSEG_MB));
	if (ExtendedTsegMbytes == MCH_EXT_TSEG_MB_QUERY) {
	mQ35TsegMbytes = PcdGet16 (PcdQ35TsegMbytes);
	return;
	}

	DEBUG ((
	DEBUG_INFO,
	"%a: QEMU offers an extended TSEG (%d MB)\n",
	__FUNCTION__,
	ExtendedTsegMbytes
	));
	PcdStatus = PcdSet16S (PcdQ35TsegMbytes, ExtendedTsegMbytes);
	ASSERT_RETURN_ERROR (PcdStatus);
	mQ35TsegMbytes = ExtendedTsegMbytes;
	}

	STATIC
	UINT64
	GetHighestSystemMemoryAddress (
	BOOLEAN Below4gb
	)
	{
	EFI_E820_ENTRY64 *E820Map;
	UINT32 E820EntriesCount;
	EFI_E820_ENTRY64 *Entry;
	EFI_STATUS Status;
	UINT32 Loop;
	UINT64 HighestAddress;
	UINT64 EntryEnd;

	HighestAddress = 0;

	Status = XenGetE820Map (&E820Map, &E820EntriesCount);
	ASSERT_EFI_ERROR (Status);

	for (Loop = 0; Loop < E820EntriesCount; Loop++) {
	Entry = E820Map + Loop;
	EntryEnd = Entry->BaseAddr + Entry->Length;

	if (Entry->Type == EfiAcpiAddressRangeMemory &&
	EntryEnd > HighestAddress) {

	if (Below4gb && (EntryEnd <= BASE_4GB)) {
	HighestAddress = EntryEnd;
	} else if (!Below4gb && (EntryEnd >= BASE_4GB)) {
	HighestAddress = EntryEnd;
	}
	}
	}

	//
	// Round down the end address.
	//
	return HighestAddress & ~(UINT64)EFI_PAGE_MASK;
	}

	UINT32
	GetSystemMemorySizeBelow4gb (
	VOID
	)
	{
	UINT8 Cmos0x34;
	UINT8 Cmos0x35;

	//
	// In PVH case, there is no CMOS, we have to calculate the memory size
	// from parsing the E820
	//
	if (XenPvhDetected ()) {
	UINT64 HighestAddress;

	HighestAddress = GetHighestSystemMemoryAddress (TRUE);
	ASSERT (HighestAddress > 0 && HighestAddress <= BASE_4GB);

	return HighestAddress;
	}

	//
	// CMOS 0x34/0x35 specifies the system memory above 16 MB.
	// * CMOS(0x35) is the high byte
	// * CMOS(0x34) is the low byte
	// * The size is specified in 64kb chunks
	// * Since this is memory above 16MB, the 16MB must be added
	// into the calculation to get the total memory size.
	//

	Cmos0x34 = (UINT8) CmosRead8 (0x34);
	Cmos0x35 = (UINT8) CmosRead8 (0x35);

	return (UINT32) (((UINTN)((Cmos0x35 << 8) + Cmos0x34) << 16) + SIZE_16MB);
	}


	STATIC
	UINT64
	GetSystemMemorySizeAbove4gb (
	)
	{
	UINT32 Size;
	UINTN CmosIndex;

	//
	// In PVH case, there is no CMOS, we have to calculate the memory size
	// from parsing the E820
	//
	if (XenPvhDetected ()) {
	UINT64 HighestAddress;

	HighestAddress = GetHighestSystemMemoryAddress (FALSE);
	ASSERT (HighestAddress == 0 \|\| HighestAddress >= BASE_4GB);

	if (HighestAddress >= BASE_4GB) {
	HighestAddress -= BASE_4GB;
	}

	return HighestAddress;
	}

	//
	// CMOS 0x5b-0x5d specifies the system memory above 4GB MB.
	// * CMOS(0x5d) is the most significant size byte
	// * CMOS(0x5c) is the middle size byte
	// * CMOS(0x5b) is the least significant size byte
	// * The size is specified in 64kb chunks
	//

	Size = 0;
	for (CmosIndex = 0x5d; CmosIndex >= 0x5b; CmosIndex--) {
	Size = (UINT32) (Size << 8) + (UINT32) CmosRead8 (CmosIndex);
	}

	return LShiftU64 (Size, 16);
	}


	/**
	Return the highest address that DXE could possibly use, plus one.
	**/
	STATIC
	UINT64
	GetFirstNonAddress (
	VOID
	)
	{
	UINT64 FirstNonAddress;
	UINT64 Pci64Base, Pci64Size;
	RETURN_STATUS PcdStatus;

	FirstNonAddress = BASE_4GB + GetSystemMemorySizeAbove4gb ();

	//
	// If DXE is 32-bit, then we're done; PciBusDxe will degrade 64-bit MMIO
	// resources to 32-bit anyway. See DegradeResource() in
	// "PciResourceSupport.c".
	//
	#ifdef MDE_CPU_IA32
	if (!FeaturePcdGet (PcdDxeIplSwitchToLongMode)) {
	return FirstNonAddress;
	}
	#endif

	//
	// Otherwise, in order to calculate the highest address plus one, we must
	// consider the 64-bit PCI host aperture too. Fetch the default size.
	//
	Pci64Size = PcdGet64 (PcdPciMmio64Size);

	if (Pci64Size == 0) {
	if (mBootMode != BOOT_ON_S3_RESUME) {
	DEBUG ((DEBUG_INFO, "%a: disabling 64-bit PCI host aperture\n",
	__FUNCTION__));
	PcdStatus = PcdSet64S (PcdPciMmio64Size, 0);
	ASSERT_RETURN_ERROR (PcdStatus);
	}

	//
	// There's nothing more to do; the amount of memory above 4GB fully
	// determines the highest address plus one. The memory hotplug area (see
	// below) plays no role for the firmware in this case.
	//
	return FirstNonAddress;
	}

	//
	// SeaBIOS aligns both boundaries of the 64-bit PCI host aperture to 1GB, so
	// that the host can map it with 1GB hugepages. Follow suit.
	//
	Pci64Base = ALIGN_VALUE (FirstNonAddress, (UINT64)SIZE_1GB);
	Pci64Size = ALIGN_VALUE (Pci64Size, (UINT64)SIZE_1GB);

	//
	// The 64-bit PCI host aperture should also be "naturally" aligned. The
	// alignment is determined by rounding the size of the aperture down to the
	// next smaller or equal power of two. That is, align the aperture by the
	// largest BAR size that can fit into it.
	//
	Pci64Base = ALIGN_VALUE (Pci64Base, GetPowerOfTwo64 (Pci64Size));

	if (mBootMode != BOOT_ON_S3_RESUME) {
	//
	// The core PciHostBridgeDxe driver will automatically add this range to
	// the GCD memory space map through our PciHostBridgeLib instance; here we
	// only need to set the PCDs.
	//
	PcdStatus = PcdSet64S (PcdPciMmio64Base, Pci64Base);
	ASSERT_RETURN_ERROR (PcdStatus);
	PcdStatus = PcdSet64S (PcdPciMmio64Size, Pci64Size);
	ASSERT_RETURN_ERROR (PcdStatus);

	DEBUG ((DEBUG_INFO, "%a: Pci64Base=0x%Lx Pci64Size=0x%Lx\n",
	__FUNCTION__, Pci64Base, Pci64Size));
	}

	//
	// The useful address space ends with the 64-bit PCI host aperture.
	//
	FirstNonAddress = Pci64Base + Pci64Size;
	return FirstNonAddress;
	}


	/**
	Initialize the mPhysMemAddressWidth variable, based on guest RAM size.
	**/
	VOID
	AddressWidthInitialization (
	VOID
	)
	{
	UINT64 FirstNonAddress;

	//
	// As guest-physical memory size grows, the permanent PEI RAM requirements
	// are dominated by the identity-mapping page tables built by the DXE IPL.
	// The DXL IPL keys off of the physical address bits advertized in the CPU
	// HOB. To conserve memory, we calculate the minimum address width here.
	//
	FirstNonAddress = GetFirstNonAddress ();
	mPhysMemAddressWidth = (UINT8)HighBitSet64 (FirstNonAddress);

	//
	// If FirstNonAddress is not an integral power of two, then we need an
	// additional bit.
	//
	if ((FirstNonAddress & (FirstNonAddress - 1)) != 0) {
	++mPhysMemAddressWidth;
	}

	//
	// The minimum address width is 36 (covers up to and excluding 64 GB, which
	// is the maximum for Ia32 + PAE). The theoretical architecture maximum for
	// X64 long mode is 52 bits, but the DXE IPL clamps that down to 48 bits. We
	// can simply assert that here, since 48 bits are good enough for 256 TB.
	//
	if (mPhysMemAddressWidth <= 36) {
	mPhysMemAddressWidth = 36;
	}
	ASSERT (mPhysMemAddressWidth <= 48);
	}


	/**
	Calculate the cap for the permanent PEI memory.
	**/
	STATIC
	UINT32
	GetPeiMemoryCap (
	VOID
	)
	{
	BOOLEAN Page1GSupport;
	UINT32 RegEax;
	UINT32 RegEdx;
	UINT32 Pml4Entries;
	UINT32 PdpEntries;
	UINTN TotalPages;

	//
	// If DXE is 32-bit, then just return the traditional 64 MB cap.
	//
	#ifdef MDE_CPU_IA32
	if (!FeaturePcdGet (PcdDxeIplSwitchToLongMode)) {
	return SIZE_64MB;
	}
	#endif

	//
	// Dependent on physical address width, PEI memory allocations can be
	// dominated by the page tables built for 64-bit DXE. So we key the cap off
	// of those. The code below is based on CreateIdentityMappingPageTables() in
	// "MdeModulePkg/Core/DxeIplPeim/X64/VirtualMemory.c".
	//
	Page1GSupport = FALSE;
	if (PcdGetBool (PcdUse1GPageTable)) {
	AsmCpuid (0x80000000, &RegEax, NULL, NULL, NULL);
	if (RegEax >= 0x80000001) {
	AsmCpuid (0x80000001, NULL, NULL, NULL, &RegEdx);
	if ((RegEdx & BIT26) != 0) {
	Page1GSupport = TRUE;
	}
	}
	}

	if (mPhysMemAddressWidth <= 39) {
	Pml4Entries = 1;
	PdpEntries = 1 << (mPhysMemAddressWidth - 30);
	ASSERT (PdpEntries <= 0x200);
	} else {
	Pml4Entries = 1 << (mPhysMemAddressWidth - 39);
	ASSERT (Pml4Entries <= 0x200);
	PdpEntries = 512;
	}

	TotalPages = Page1GSupport ? Pml4Entries + 1 :
	(PdpEntries + 1) * Pml4Entries + 1;
	ASSERT (TotalPages <= 0x40201);

	//
	// Add 64 MB for miscellaneous allocations. Note that for
	// mPhysMemAddressWidth values close to 36, the cap will actually be
	// dominated by this increment.
	//
	return (UINT32)(EFI_PAGES_TO_SIZE (TotalPages) + SIZE_64MB);
	}


	/**
	Publish PEI core memory

	@return EFI_SUCCESS The PEIM initialized successfully.

	**/
	EFI_STATUS
	PublishPeiMemory (
	VOID
	)
	{
	EFI_STATUS Status;
	EFI_PHYSICAL_ADDRESS MemoryBase;
	UINT64 MemorySize;
	UINT32 LowerMemorySize;
	UINT32 PeiMemoryCap;

	LowerMemorySize = GetSystemMemorySizeBelow4gb ();

	if (mBootMode == BOOT_ON_S3_RESUME) {
	MemoryBase = mS3AcpiReservedMemoryBase;
	MemorySize = mS3AcpiReservedMemorySize;
	} else {
	PeiMemoryCap = GetPeiMemoryCap ();
	DEBUG ((DEBUG_INFO, "%a: mPhysMemAddressWidth=%d PeiMemoryCap=%u KB\n",
	__FUNCTION__, mPhysMemAddressWidth, PeiMemoryCap >> 10));

	//
	// Determine the range of memory to use during PEI
	//
	MemoryBase =
	PcdGet32 (PcdOvmfDxeMemFvBase) + PcdGet32 (PcdOvmfDxeMemFvSize);
	MemorySize = LowerMemorySize - MemoryBase;
	if (MemorySize > PeiMemoryCap) {
	MemoryBase = LowerMemorySize - PeiMemoryCap;
	MemorySize = PeiMemoryCap;
	}
	}

	//
	// Publish this memory to the PEI Core
	//
	Status = PublishSystemMemory(MemoryBase, MemorySize);
	ASSERT_EFI_ERROR (Status);

	return Status;
	}


	/**
	Publish system RAM and reserve memory regions

	**/
	VOID
	InitializeRamRegions (
	VOID
	)
	{
	XenPublishRamRegions ();

	if (mBootMode != BOOT_ON_S3_RESUME) {
	//
	// Reserve the lock box storage area
	//
	// Since this memory range will be used on S3 resume, it must be
	// reserved as ACPI NVS.
	//
	// If S3 is unsupported, then various drivers might still write to the
	// LockBox area. We ought to prevent DXE from serving allocation requests
	// such that they would overlap the LockBox storage.
	//
	ZeroMem (
	(VOID*)(UINTN) PcdGet32 (PcdOvmfLockBoxStorageBase),
	(UINTN) PcdGet32 (PcdOvmfLockBoxStorageSize)
	);
	BuildMemoryAllocationHob (
	(EFI_PHYSICAL_ADDRESS)(UINTN) PcdGet32 (PcdOvmfLockBoxStorageBase),
	(UINT64)(UINTN) PcdGet32 (PcdOvmfLockBoxStorageSize),
	EfiBootServicesData
	);
	}
	}