reactos/boot/environ/lib/misc/util.c
Hermès Bélusca-Maïto 9393fc320e
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2021-09-13 03:52:22 +02:00

983 lines
23 KiB
C

/*
* COPYRIGHT: See COPYING.ARM in the top level directory
* PROJECT: ReactOS UEFI Boot Library
* FILE: boot/environ/lib/misc/util.c
* PURPOSE: Boot Library Utility Functions
* PROGRAMMER: Alex Ionescu (alex.ionescu@reactos.org)
*/
/* INCLUDES ******************************************************************/
#include "bl.h"
/* DATA VARIABLES ************************************************************/
PRSDT UtlRsdt;
PXSDT UtlXsdt;
PVOID UtlMcContext;
PVOID UtlMcDisplayMessageRoutine;
PVOID UtlMcUpdateMessageRoutine;
PVOID UtlProgressRoutine;
PVOID UtlProgressContext;
PVOID UtlProgressInfoRoutine;
ULONG UtlProgressGranularity;
ULONG UtlCurrentPercentComplete;
ULONG UtlNextUpdatePercentage;
BOOLEAN UtlProgressNeedsInfoUpdate;
PVOID UtlProgressInfo;
/* FUNCTIONS *****************************************************************/
NTSTATUS
BlUtlGetAcpiTable (
_Out_ PVOID* TableAddress,
_In_ ULONG Signature
)
{
ULONG i, TableCount, HeaderLength;
NTSTATUS Status;
PRSDT Rsdt;
PXSDT Xsdt;
PHYSICAL_ADDRESS PhysicalAddress;
PDESCRIPTION_HEADER Header;
Header = 0;
/* Make sure there's an output parameter */
if (!TableAddress)
{
return STATUS_INVALID_PARAMETER;
}
/* Get the currently known RSDT and XSDT */
Rsdt = (PRSDT)UtlRsdt;
Xsdt = (PXSDT)UtlXsdt;
/* Is there an RSDT? */
if (!Rsdt)
{
/* No -- is there an XSDT? */
if (!Xsdt)
{
/* No. Look up the RSDT */
Status = EfipGetRsdt(&PhysicalAddress);
if (!NT_SUCCESS(Status))
{
EfiPrintf(L"no rsdp found\r\n");
return Status;
}
/* Map the header */
Status = BlMmMapPhysicalAddressEx((PVOID)&Header,
0,
sizeof(*Header),
PhysicalAddress);
if (!NT_SUCCESS(Status))
{
return Status;
}
/* Unmap the header */
BlMmUnmapVirtualAddressEx(Header, sizeof(*Header));
/* Map the whole table */
Status = BlMmMapPhysicalAddressEx((PVOID)&Header,
0,
Header->Length,
PhysicalAddress);
if (!NT_SUCCESS(Status))
{
return Status;
}
/* Check if its an XSDT or an RSDT */
if (Header->Signature == XSDT_SIGNATURE)
{
/* It's an XSDT */
Xsdt = (PXSDT)Header;
UtlXsdt = Xsdt;
}
else
{
/* It's an RSDT */
Rsdt = (PRSDT)Header;
UtlRsdt = Rsdt;
}
}
}
/* OK, so do we have an XSDT after all? */
if (Xsdt)
{
/* Yes... how big is it? */
HeaderLength = Xsdt->Header.Length;
if (HeaderLength >= sizeof(*Header))
{
HeaderLength = sizeof(*Header);
}
/* Based on that, how many tables are there? */
TableCount = (Xsdt->Header.Length - HeaderLength) / sizeof(PHYSICAL_ADDRESS);
}
else
{
/* Nope, we have an RSDT. How big is it? */
HeaderLength = Rsdt->Header.Length;
if (HeaderLength >= sizeof(*Header))
{
HeaderLength = sizeof(*Header);
}
/* Based on that, how many tables are there? */
TableCount = (Rsdt->Header.Length - HeaderLength) / sizeof(ULONG);
}
/* Loop through the ACPI tables */
for (i = 0; i < TableCount; i++)
{
/* For an XSDT, read the 64-bit address directly */
if (Xsdt)
{
PhysicalAddress = Xsdt->Tables[i];
}
else
{
/* For RSDT, cast it */
PhysicalAddress.QuadPart = Rsdt->Tables[i];
}
/* Map the header */
Status = BlMmMapPhysicalAddressEx((PVOID)&Header,
0,
sizeof(*Header),
PhysicalAddress);
if (!NT_SUCCESS(Status))
{
return Status;
}
/* Is it the right one? */
if (Header->Signature == Signature)
{
/* Unmap the header */
BlMmUnmapVirtualAddressEx(Header, sizeof(*Header));
/* Map the whole table */
return BlMmMapPhysicalAddressEx(TableAddress,
0,
Header->Length,
PhysicalAddress);
}
}
/* Requested table does not exist */
return STATUS_NOT_FOUND;
}
VOID
BlUtlUpdateProgress (
_In_ ULONG Percentage,
_Out_opt_ PBOOLEAN Completed
)
{
if (UtlProgressRoutine)
{
EfiPrintf(L"Unimplemented\r\n");
}
else if (*Completed)
{
*Completed = TRUE;
}
}
NTSTATUS
BlUtlInitialize (
VOID
)
{
UtlRsdt = 0;
UtlXsdt = 0;
UtlMcContext = 0;
UtlMcDisplayMessageRoutine = 0;
UtlMcUpdateMessageRoutine = 0;
UtlProgressRoutine = 0;
UtlProgressContext = 0;
UtlProgressInfoRoutine = 0;
UtlProgressGranularity = 0;
UtlCurrentPercentComplete = 0;
UtlNextUpdatePercentage = 0;
UtlProgressNeedsInfoUpdate = 0;
UtlProgressInfo = 0;
return STATUS_SUCCESS;
}
VOID
BmUpdateProgressInfo (
_In_ PVOID Unknown,
_In_ PWCHAR ProgressInfo
)
{
EfiPrintf(L"Progress Info: %s\r\n", ProgressInfo);
}
VOID
BmUpdateProgress (
_In_ PVOID Unknown,
_In_ ULONG Percent,
_Out_ PBOOLEAN Completed
)
{
EfiPrintf(L"Progress: %d\r\n", Percent);
if (Completed)
{
*Completed = TRUE;
}
}
NTSTATUS
BlUtlRegisterProgressRoutine (
VOID
)
{
/* One shouldn't already exist */
if (UtlProgressRoutine)
{
return STATUS_UNSUCCESSFUL;
}
/* Set the routine, and no context */
UtlProgressRoutine = BmUpdateProgress;
UtlProgressContext = NULL;
/* Progress increases by one */
UtlProgressGranularity = 1;
/* Set progress to zero for now */
UtlCurrentPercentComplete = 0;
UtlNextUpdatePercentage = 0;
/* Set the info routine if there is one */
UtlProgressInfoRoutine = BmUpdateProgressInfo;
/* All good */
return STATUS_SUCCESS;
}
PVOID
BlTblFindEntry (
_In_ PVOID *Table,
_In_ ULONG Count,
_Out_ PULONG EntryIndex,
_In_ PBL_TBL_LOOKUP_ROUTINE Callback,
_In_ PVOID Argument1,
_In_ PVOID Argument2,
_In_ PVOID Argument3,
_In_ PVOID Argument4
)
{
PVOID Entry = NULL;
ULONG Index;
BOOLEAN Result;
/* Check for invalid parameters */
if (!(Table) || !(EntryIndex))
{
return Entry;
}
/* Loop each entry in the table */
for (Index = 0; Index < Count; Index++)
{
/* Check if this entry is filled out */
if (Table[Index])
{
/* Call the comparison function */
Result = Callback(Table[Index],
Argument1,
Argument2,
Argument3,
Argument4);
if (Result)
{
/* Entry found return it */
*EntryIndex = Index;
Entry = Table[Index];
break;
}
}
}
/* Return the entry that was (or wasn't) found */
return Entry;
}
NTSTATUS
BlTblSetEntry (
_Inout_ PVOID** Table,
_Inout_ PULONG Count,
_In_ PVOID Entry,
_Out_ PULONG EntryIndex,
_In_ PBL_TBL_SET_ROUTINE Callback
)
{
ULONG NewCount;
NTSTATUS Status = STATUS_SUCCESS;
ULONG Index = 0;
PVOID* NewTable;
/* Make sure all the parameters were specified */
if (!(Table) || !(*Table) || !(Count) || !(Callback))
{
return STATUS_INVALID_PARAMETER;
}
/* Read the current table */
NewTable = *Table;
NewCount = *Count;
/* Iterate over it */
while (Index < NewCount)
{
/* Look for a free index */
if (!NewTable[Index])
{
goto SetIndex;
}
/* No free index yet, keep going */
++Index;
}
/* No free index was found, try to purge some entries */
Index = 0;
while (Index < NewCount)
{
/* Call each purge callback, trying to make space */
Status = Callback(NewTable[Index]);
if (NT_SUCCESS(Status))
{
/* We should have this slot available now */
goto SetIndex;
}
/* Keep trying to purge more */
++Index;
}
/* Double the table */
NewTable = BlMmAllocateHeap(2 * sizeof(PVOID) * NewCount);
if (!NewTable)
{
return STATUS_NO_MEMORY;
}
/* Clear the new table, and copy the old entries */
RtlZeroMemory(&NewTable[NewCount], sizeof(PVOID) * NewCount);
RtlCopyMemory(NewTable, *Table, sizeof(PVOID) * NewCount);
/* Free the old table */
BlMmFreeHeap(*Table);
/* Return the new table and count */
*Count = 2 * NewCount;
*Table = NewTable;
SetIndex:
/* Set the index and return */
NewTable[Index] = Entry;
*EntryIndex = Index;
return Status;
}
NTSTATUS
BlTblMap (
_In_ PVOID *Table,
_In_ ULONG Count,
_In_ PBL_TBL_MAP_ROUTINE MapCallback
)
{
NTSTATUS Status, LocalStatus;
PVOID Entry;
ULONG Index;
/* Bail out if there's no table */
if (!Table)
{
return STATUS_INVALID_PARAMETER;
}
/* Assume success and loop each index */
Status = STATUS_SUCCESS;
for (Index = 0; Index < Count; Index++)
{
/* See if an entry exists at this index */
Entry = Table[Index];
if (Entry)
{
/* Call the map routine for this entry */
LocalStatus = MapCallback(Entry, Index);
if (!NT_SUCCESS(LocalStatus))
{
/* Propagate failure only */
Status = LocalStatus;
}
}
}
/* Return status to caller */
return Status;
}
ULONG HtTableSize;
PBL_HASH_TABLE* HtTableArray;
ULONG HtTableEntries;
ULONG
DefaultHashFunction (
_In_ PBL_HASH_ENTRY Entry,
_In_ ULONG TableSize
)
{
PUCHAR Value;
ULONG KeyHash, i;
/* Check if the value is a pointer, or embedded inline */
Value = (Entry->Flags & BL_HT_VALUE_IS_INLINE) ? Entry->Value : (PUCHAR)&Entry->Value;
/* Iterate over each byte, and sum it */
for (i = 0, KeyHash = 0; i < Entry->Size; i++)
{
KeyHash += Value[i++];
}
/* Modulo the number of buckets */
return KeyHash % TableSize;
}
BOOLEAN
HtpCompareKeys (
_In_ PBL_HASH_ENTRY Entry1,
_In_ PBL_HASH_ENTRY Entry2
)
{
ULONG Flags;
BOOLEAN ValueMatch;
/* Check if the flags or sizes are not matching */
Flags = Entry1->Flags;
if ((Entry1->Size != Entry2->Size) || (Flags != Entry2->Flags))
{
ValueMatch = FALSE;
}
else if (Flags & BL_HT_VALUE_IS_INLINE)
{
/* Check if this is an in-line value, compare it */
ValueMatch = Entry1->Value == Entry2->Value;
}
else
{
/* This is a pointer value, compare it */
ValueMatch = (RtlCompareMemory(Entry1->Value, Entry2->Value, Entry1->Size) ==
Entry1->Size);
}
/* Return if it matched */
return ValueMatch;
}
NTSTATUS
TblDoNotPurgeEntry (
_In_ PVOID Entry
)
{
/* Never purge this entry */
return STATUS_UNSUCCESSFUL;
}
NTSTATUS
BlHtCreate (
_In_ ULONG Size,
_In_ PBL_HASH_TABLE_HASH_FUNCTION HashFunction,
_In_ PBL_HASH_TABLE_COMPARE_FUNCTION CompareFunction,
_Out_ PULONG Id
)
{
NTSTATUS Status;
PBL_HASH_TABLE HashTable;
ULONG i;
/* Assume failure */
HashTable = NULL;
/* Can't create a table with no ID */
if (!Id)
{
return STATUS_INVALID_PARAMETER;
}
/* Check if we don't already have a hash table table */
if (!HtTableSize)
{
/* Allocate it and zero it out */
HtTableSize = 4;
HtTableArray = BlMmAllocateHeap(HtTableSize * sizeof(PVOID));
if (!HtTableArray)
{
Status = STATUS_NO_MEMORY;
goto Quickie;
}
RtlZeroMemory(HtTableArray, HtTableSize * sizeof(PVOID));
HtTableEntries = 0;
}
/* Allocate the hash table */
HashTable = BlMmAllocateHeap(sizeof(*HashTable));
if (!HashTable)
{
Status = STATUS_NO_MEMORY;
goto Quickie;
}
/* Fill it out */
HashTable->HashFunction = HashFunction ? HashFunction : DefaultHashFunction;
HashTable->CompareFunction = CompareFunction ? CompareFunction : HtpCompareKeys;
HashTable->Size = Size ? Size : 13;
/* Allocate the hash links, one for each bucket */
HashTable->HashLinks = BlMmAllocateHeap(sizeof(LIST_ENTRY) * HashTable->Size);
if (!HashTable->HashLinks)
{
Status = STATUS_NO_MEMORY;
goto Quickie;
}
/* Initialize the hash links */
for (i = 0; i < HashTable->Size; i++)
{
InitializeListHead(&HashTable->HashLinks[i]);
}
/* Save us in the table of hash tables */
Status = BlTblSetEntry((PVOID**)&HtTableArray,
&Size,
HashTable,
Id,
TblDoNotPurgeEntry);
if (NT_SUCCESS(Status))
{
/* One more -- we're done */
++HtTableEntries;
return Status;
}
Quickie:
/* Check if we just allocated the table array now */
if (!(HtTableEntries) && (HtTableArray))
{
/* Free it */
BlMmFreeHeap(HtTableArray);
HtTableArray = NULL;
HtTableSize = 0;
}
/* Check if we allocated a hash table*/
if (HashTable)
{
/* With links? */
if (HashTable->HashLinks)
{
/* Free them */
BlMmFreeHeap(HashTable->HashLinks);
}
/* Free the table*/
BlMmFreeHeap(HashTable);
}
/* We're done */
return Status;
}
NTSTATUS
BlHtLookup (
_In_ ULONG TableId,
_In_ PBL_HASH_ENTRY Entry,
_Out_opt_ PBL_HASH_VALUE *Value
)
{
PBL_HASH_TABLE HashTable;
ULONG HashValue;
NTSTATUS Status;
PLIST_ENTRY HashLinkHead, HashLink;
PBL_HASH_NODE HashNode;
/* Check if the table ID is invalid, or we have no entry, or it's malformed */
if ((HtTableSize <= TableId) ||
!(Entry) ||
((Entry->Flags & BL_HT_VALUE_IS_INLINE) && (Entry->Size != sizeof(ULONG))))
{
/* Fail */
Status = STATUS_INVALID_PARAMETER;
}
else
{
/* Otherwise, get the hash table for this index */
HashTable = HtTableArray[TableId];
/* Get the hash bucket */
HashValue = HashTable->HashFunction(Entry, HashTable->Size);
/* Start iterating each entry in the bucket, assuming failure */
Status = STATUS_NOT_FOUND;
HashLinkHead = &HashTable->HashLinks[HashValue];
HashLink = HashLinkHead->Flink;
while (HashLink != HashLinkHead)
{
/* Get a node in this bucket, and compare the value */
HashNode = CONTAINING_RECORD(HashLink, BL_HASH_NODE, ListEntry);
if (HashTable->CompareFunction(&HashNode->Entry, Entry))
{
/* Does the caller want the value? */
if (Value)
{
/* Return it */
*Value = &HashNode->Value;
}
/* Return success and stop scanning */
Status = STATUS_SUCCESS;
break;
}
/* Try the next node */
HashLink = HashLink->Flink;
}
}
/* Return back to the caller */
return Status;
}
NTSTATUS
BlHtStore (
_In_ ULONG TableId,
_In_ PBL_HASH_ENTRY Entry,
_In_ PVOID Data,
_In_ ULONG DataSize
)
{
PBL_HASH_NODE HashNode;
NTSTATUS Status;
PLIST_ENTRY HashLinkHead;
PBL_HASH_TABLE HashTable;
/* Check for invalid table ID, missing arguments, or malformed entry */
if ((HtTableSize <= TableId) ||
!(Entry) ||
!(Data) ||
!(Entry->Size) ||
!(Entry->Value) ||
!(DataSize) ||
((Entry->Flags & BL_HT_VALUE_IS_INLINE) && (Entry->Size != sizeof(ULONG))))
{
/* Fail the call */
Status = STATUS_INVALID_PARAMETER;
goto Quickie;
}
/* Get the hash table for this ID */
HashTable = HtTableArray[TableId];
/* Allocate a hash node */
HashNode = BlMmAllocateHeap(sizeof(*HashNode));
if (!HashNode)
{
Status = STATUS_NO_MEMORY;
goto Quickie;
}
/* Capture all the data*/
HashNode->Entry.Size = Entry->Size;
HashNode->Entry.Flags = Entry->Flags;
HashNode->Entry.Value = Entry->Value;
HashNode->Value.DataSize = DataSize;
HashNode->Value.Data = Data;
/* Insert it into the bucket list and return success */
HashLinkHead = &HashTable->HashLinks[HashTable->HashFunction(Entry, HashTable->Size)];
InsertTailList(HashLinkHead, &HashNode->ListEntry);
Status = STATUS_SUCCESS;
Quickie:
return Status;
}
NTSTATUS
BlHtDelete (
_In_ ULONG TableId,
_In_ PBL_HASH_ENTRY Entry
)
{
PBL_HASH_TABLE HashTable;
ULONG HashValue;
NTSTATUS Status;
PLIST_ENTRY HashLinkHead, HashLink;
PBL_HASH_NODE HashNode;
/* Check if the table ID is invalid, or we have no entry, or it's malformed */
if ((HtTableSize <= TableId) ||
!(Entry) ||
!(Entry->Size) ||
!(Entry->Value) ||
((Entry->Flags & BL_HT_VALUE_IS_INLINE) && (Entry->Size != sizeof(ULONG))))
{
/* Fail */
Status = STATUS_INVALID_PARAMETER;
}
else
{
/* Otherwise, get the hash table for this index */
HashTable = HtTableArray[TableId];
/* Get the hash bucket */
HashValue = HashTable->HashFunction(Entry, HashTable->Size);
/* Start iterating each entry in the bucket, assuming failure */
Status = STATUS_NOT_FOUND;
HashLinkHead = &HashTable->HashLinks[HashValue];
HashLink = HashLinkHead->Flink;
while (HashLink != HashLinkHead)
{
/* Get a node in this bucket, and compare the value */
HashNode = CONTAINING_RECORD(HashLink, BL_HASH_NODE, ListEntry);
if (HashTable->CompareFunction(&HashNode->Entry, Entry))
{
/* Remove it from the list and free it */
RemoveEntryList(&HashNode->ListEntry);
BlMmFreeHeap(HashNode);
return STATUS_SUCCESS;
}
/* Try the next node */
HashLink = HashLink->Flink;
}
}
/* Return back to the caller */
return Status;
}
ULONG
BlUtlCheckSum (
_In_ ULONG PartialSum,
_In_ PUCHAR Buffer,
_In_ ULONG Length,
_In_ ULONG Flags
)
{
ULONG i;
if (Flags & BL_UTL_CHECKSUM_UCHAR_BUFFER)
{
EfiPrintf(L"Not supported\r\n");
return 0;
}
else if (Flags & BL_UTL_CHECKSUM_USHORT_BUFFER)
{
PartialSum = (unsigned __int16)PartialSum;
Length &= ~1;
for (i = 0; i < Length; i += 2)
{
PartialSum += *(unsigned __int16 *)&Buffer[i];
if (Flags & BL_UTL_CHECKSUM_COMPLEMENT)
{
PartialSum = (unsigned __int16)((PartialSum >> 16) + PartialSum);
}
}
if (i != Length)
{
PartialSum += (unsigned __int8)Buffer[Length];
if (Flags & BL_UTL_CHECKSUM_COMPLEMENT)
{
PartialSum = (unsigned __int16)((PartialSum >> 16) + PartialSum);
}
}
if (Flags & BL_UTL_CHECKSUM_NEGATE)
{
return ~PartialSum;
}
PartialSum = (unsigned __int16)PartialSum;
}
else
{
/* Invalid mode */
return 0;
}
if (Flags & BL_UTL_CHECKSUM_NEGATE)
{
return ~PartialSum;
}
return PartialSum;
}
#if defined(_M_IX86) || defined(_M_X64)
BOOLEAN
Archx86IsCpuidSupported (
VOID
)
{
ULONG CallerFlags, Flags;
/* Read the original flags, and add the CPUID bit */
CallerFlags = __readeflags() ^ 0x200000;
__writeeflags(CallerFlags);
/* Read our flags now */
Flags = __readeflags();
/* Check if the bit stuck */
return (((CallerFlags ^ Flags) >> 21) & 1) ^ 1;
}
#endif
BOOLEAN
BlArchIsCpuIdFunctionSupported (
_In_ ULONG Function
)
{
#if defined(_M_IX86) || defined(_M_X64)
BOOLEAN Supported;
INT CpuInfo[4];
/* Check if the CPU supports this instruction */
Supported = Archx86IsCpuidSupported();
if (!Supported)
{
return FALSE;
}
/* Check if it's the extended function */
if (Function >= 0x80000000)
{
/* Check if extended functions are supported */
__cpuid(CpuInfo, 0x80000000);
if ((CpuInfo[0] & 0xFFFFFF00) != 0x80000000)
{
/* Nope */
return FALSE;
}
}
else
{
/* It's a regular function, get the maximum one supported */
__cpuid(CpuInfo, 0);
}
/* Check if our function is within bounds */
if (Function <= CpuInfo[0])
{
return TRUE;
}
#else
EfiPrintf(L"BlArchIsCpuIdFunctionSupported not implemented for this platform.\r\n");
#endif
/* Nope */
return FALSE;
}
ULONGLONG
BlArchGetPerformanceCounter (
VOID
)
{
#if defined(_M_IX86) || defined(_M_X64)
CPU_INFO CpuInfo;
/* Serialize with CPUID, if it exists */
if (Archx86IsCpuidSupported())
{
BlArchCpuId(0, 0, &CpuInfo);
}
/* Read the TSC */
return __rdtsc();
#else
EfiPrintf(L"BlArchGetPerformanceCounter not implemented for this platform.\r\n");
return 0;
#endif
}
VOID
BlArchCpuId (
_In_ ULONG Function,
_In_ ULONG SubFunction,
_Out_ PCPU_INFO Result
)
{
#if defined(_M_IX86) || defined(_M_X64)
/* Use the intrinsic */
__cpuidex((INT*)Result->AsUINT32, Function, SubFunction);
#endif
}
CPU_VENDORS
BlArchGetCpuVendor (
VOID
)
{
CPU_INFO CpuInfo;
INT Temp;
/* Get the CPU Vendor */
BlArchCpuId(0, 0, &CpuInfo);
#if defined(_M_IX86) || defined(_M_X64)
Temp = CpuInfo.Ecx;
CpuInfo.Ecx = CpuInfo.Edx;
CpuInfo.Edx = Temp;
/* Check against supported values */
if (!strncmp((PCHAR)&CpuInfo.Ebx, "GenuineIntel", 12))
{
return CPU_INTEL;
}
if (!strncmp((PCHAR)&CpuInfo.Ebx, "AuthenticAMD", 12))
{
return CPU_AMD;
}
if (!strncmp((PCHAR)&CpuInfo.Ebx, "CentaurHauls", 12))
{
return CPU_VIA;
}
#ifdef _M_IX86
if (!strncmp((PCHAR)&CpuInfo.Ebx, "CyrixInstead", 12))
{
return CPU_CYRIX;
}
if (!strncmp((PCHAR)&CpuInfo.Ebx, "GenuineTMx86", 12))
{
return CPU_TRANSMETA;
}
if (!strncmp((PCHAR)&CpuInfo.Ebx, "RiseRiseRise", 12))
{
return CPU_RISE;
}
#endif // _M_IX86
#else // defined(_M_IX86) || defined(_M_X64)
EfiPrintf(L"BlArchGetCpuVendor not implemented for this platform.\r\n");
#endif
/* Other */
return CPU_UNKNOWN;
}