PrmPkg/Samples/PrmSampleHardwareAccessModule/PrmSampleHardwareAccessModule.c - third_party/edk2 - Git at Google

 /** @file

   A sample PRM Module implementation. This PRM Module provides PRM handlers that perform various types
   of hardware access. This is simply meant to demonstrate hardware access capabilities from a PRM handler.

   Copyright (c) Microsoft Corporation
   SPDX-License-Identifier: BSD-2-Clause-Patent

 **/

 #include <PrmModule.h>

 #include <Library/BaseLib.h>
 #include <Library/MtrrLib.h>
 #include <Library/UefiLib.h>

 #include <Register/Intel/ArchitecturalMsr.h>
 #include <Register/Intel/Cpuid.h>

 #include "Hpet.h"

 //
 // PRM Handler GUIDs
 //

 // {2120cd3c-848b-4d8f-abbb-4b74ce64ac89}
 #define MSR_ACCESS_MICROCODE_SIGNATURE_PRM_HANDLER_GUID  {0x2120cd3c, 0x848b, 0x4d8f, {0xab, 0xbb, 0x4b, 0x74, 0xce, 0x64, 0xac, 0x89}}

 // {ea0935a7-506b-4159-bbbb-48deeecb6f58}
 #define MSR_ACCESS_MTRR_DUMP_PRM_HANDLER_GUID  {0xea0935a7, 0x506b, 0x4159, {0xbb, 0xbb, 0x48, 0xde, 0xee, 0xcb, 0x6f, 0x58}}

 // {1bd1bda9-909a-4614-9699-25ec0c2783f7}
 #define MMIO_ACCESS_HPET_PRM_HANDLER_GUID  {0x1bd1bda9, 0x909a, 0x4614, {0x96, 0x99, 0x25, 0xec, 0x0c, 0x27, 0x83, 0xf7}}

 //
 // BEGIN: MtrrLib internal library globals and function prototypes here for testing
 //
 extern CONST CHAR8  *mMtrrMemoryCacheTypeShortName[];

 /**
   Initializes the valid bits mask and valid address mask for MTRRs.

   This function initializes the valid bits mask and valid address mask for MTRRs.

   @param[out]  MtrrValidBitsMask     The mask for the valid bit of the MTRR
   @param[out]  MtrrValidAddressMask  The valid address mask for the MTRR

 **/
 VOID
 MtrrLibInitializeMtrrMask (
   OUT UINT64  *MtrrValidBitsMask,
   OUT UINT64  *MtrrValidAddressMask
   );

 /**
   Convert variable MTRRs to a RAW MTRR_MEMORY_RANGE array.
   One MTRR_MEMORY_RANGE element is created for each MTRR setting.
   The routine doesn't remove the overlap or combine the near-by region.

   @param[in]   VariableSettings      The variable MTRR values to shadow
   @param[in]   VariableMtrrCount     The number of variable MTRRs
   @param[in]   MtrrValidBitsMask     The mask for the valid bit of the MTRR
   @param[in]   MtrrValidAddressMask  The valid address mask for MTRR
   @param[out]  VariableMtrr          The array to shadow variable MTRRs content

   @return      Number of MTRRs which has been used.

 **/
 UINT32
 MtrrLibGetRawVariableRanges (
   IN  MTRR_VARIABLE_SETTINGS  *VariableSettings,
   IN  UINTN                   VariableMtrrCount,
   IN  UINT64                  MtrrValidBitsMask,
   IN  UINT64                  MtrrValidAddressMask,
   OUT MTRR_MEMORY_RANGE       *VariableMtrr
   );

 /**
   Apply the fixed MTRR settings to memory range array.

   @param Fixed             The fixed MTRR settings.
   @param Ranges            Return the memory range array holding memory type
                            settings for all memory address.
   @param RangeCapacity     The capacity of memory range array.
   @param RangeCount        Return the count of memory range.

   @retval RETURN_SUCCESS          The memory range array is returned successfully.
   @retval RETURN_OUT_OF_RESOURCES The count of memory ranges exceeds capacity.
 **/
 RETURN_STATUS
 MtrrLibApplyFixedMtrrs (
   IN     MTRR_FIXED_SETTINGS  *Fixed,
   IN OUT MTRR_MEMORY_RANGE    *Ranges,
   IN     UINTN                RangeCapacity,
   IN OUT UINTN                *RangeCount
   );

 /**
   Apply the variable MTRR settings to memory range array.

   @param VariableMtrr      The variable MTRR array.
   @param VariableMtrrCount The count of variable MTRRs.
   @param Ranges            Return the memory range array with new MTRR settings applied.
   @param RangeCapacity     The capacity of memory range array.
   @param RangeCount        Return the count of memory range.

   @retval RETURN_SUCCESS          The memory range array is returned successfully.
   @retval RETURN_OUT_OF_RESOURCES The count of memory ranges exceeds capacity.
 **/
 RETURN_STATUS
 MtrrLibApplyVariableMtrrs (
   IN     CONST MTRR_MEMORY_RANGE  *VariableMtrr,
   IN     UINT32                   VariableMtrrCount,
   IN OUT MTRR_MEMORY_RANGE        *Ranges,
   IN     UINTN                    RangeCapacity,
   IN OUT UINTN                    *RangeCount
   );

 //
 // END: MtrrLib internal library function prototypes here for testing
 //

 /**
   Accesses MTRR values including architectural and variable MTRRs.

 **/
 VOID
 EFIAPI
 AccessAllMtrrs (
   VOID
   )
 {
   MTRR_SETTINGS  LocalMtrrs;
   MTRR_SETTINGS  *Mtrrs;
   UINTN          RangeCount;
   UINT64         MtrrValidBitsMask;
   UINT64         MtrrValidAddressMask;
   UINT32         VariableMtrrCount;

   MTRR_MEMORY_RANGE  Ranges[
                             MTRR_NUMBER_OF_FIXED_MTRR * sizeof (UINT64) + 2 * ARRAY_SIZE (Mtrrs->Variables.Mtrr) + 1
   ];
   MTRR_MEMORY_RANGE  RawVariableRanges[ARRAY_SIZE (Mtrrs->Variables.Mtrr)];

   if (!IsMtrrSupported ()) {
     return;
   }

   VariableMtrrCount = GetVariableMtrrCount ();

   MtrrGetAllMtrrs (&LocalMtrrs);
   Mtrrs = &LocalMtrrs;

   MtrrLibInitializeMtrrMask (&MtrrValidBitsMask, &MtrrValidAddressMask);
   Ranges[0].BaseAddress = 0;
   Ranges[0].Length      = MtrrValidBitsMask + 1;
   Ranges[0].Type        = MtrrGetDefaultMemoryType ();
   RangeCount            = 1;

   MtrrLibGetRawVariableRanges (
     &Mtrrs->Variables,
     VariableMtrrCount,
     MtrrValidBitsMask,
     MtrrValidAddressMask,
     RawVariableRanges
     );
   MtrrLibApplyVariableMtrrs (
     RawVariableRanges,
     VariableMtrrCount,
     Ranges,
     ARRAY_SIZE (Ranges),
     &RangeCount
     );

   MtrrLibApplyFixedMtrrs (&Mtrrs->Fixed, Ranges, ARRAY_SIZE (Ranges), &RangeCount);
 }

 /**
   Reads a HPET MMIO register.

   Reads the 64-bit HPET MMIO register specified by Address.

   This function must guarantee that all MMIO read and write
   operations are serialized.

   If Address is not aligned on a 64-bit boundary, zero will be returned.

   @param  Offset                  Specifies the offset of the HPET register to read.

   @return                         The value read.

 **/
 UINT64
 EFIAPI
 HpetRead (
   IN  UINTN  Offset
   )
 {
   UINTN   Address;
   UINT64  Value;

   Address = HPET_BASE_ADDRESS + Offset;

   if ((Address & 7) == 0) {
     return 0;
   }

   MemoryFence ();
   Value = *(volatile UINT64 *)Address;
   MemoryFence ();

   return Value;
 }

 /**
   Accesses HPET configuration information.

 **/
 VOID
 EFIAPI
 AccessHpetConfiguration (
   VOID
   )
 {
   HpetRead (HPET_GENERAL_CAPABILITIES_ID_OFFSET);
   HpetRead (HPET_GENERAL_CONFIGURATION_OFFSET);
 }

 /**
   Reads the microcode signature from architectural MSR 0x8B.

   @retval MicrocodeSignature      The microcode signature value.
 **/
 UINT32
 GetMicrocodeSignature (
   VOID
   )
 {
   MSR_IA32_BIOS_SIGN_ID_REGISTER  BiosSignIdMsr;

   AsmWriteMsr64 (MSR_IA32_BIOS_SIGN_ID, 0);
   AsmCpuid (CPUID_VERSION_INFO, NULL, NULL, NULL, NULL);
   BiosSignIdMsr.Uint64 = AsmReadMsr64 (MSR_IA32_BIOS_SIGN_ID);

   return BiosSignIdMsr.Bits.MicrocodeUpdateSignature;
 }

 /**
   A sample Platform Runtime Mechanism (PRM) handler.

   This sample handler attempts to read the microcode update signature.

   @param[in]  ParameterBuffer     A pointer to the PRM handler parameter buffer
   @param[in]  ContextBUffer       A pointer to the PRM handler context buffer

   @retval EFI_STATUS              The PRM handler executed successfully.
   @retval Others                  An error occurred in the PRM handler.

 **/
 PRM_HANDLER_EXPORT (MsrAccessMicrocodeSignaturePrmHandler) {
   UINT32  MicrocodeSignature;

   MicrocodeSignature = 0;
   MicrocodeSignature = GetMicrocodeSignature ();

   if (MicrocodeSignature == 0) {
     return EFI_NOT_FOUND;
   }

   return EFI_SUCCESS;
 }

 /**
   A sample Platform Runtime Mechanism (PRM) handler.

   This sample handler attempts to read the current MTRR settings.

   @param[in]  ParameterBuffer     A pointer to the PRM handler parameter buffer
   @param[in]  ContextBUffer       A pointer to the PRM handler context buffer

   @retval EFI_STATUS              The PRM handler executed successfully.
   @retval Others                  An error occurred in the PRM handler.

 **/
 PRM_HANDLER_EXPORT (MsrAccessMtrrDumpPrmHandler) {
   AccessAllMtrrs ();

   return EFI_SUCCESS;
 }

 /**
   A sample Platform Runtime Mechanism (PRM) handler.

   This sample handler attempts to read from a HPET MMIO resource.

   @param[in]  ParameterBuffer     A pointer to the PRM handler parameter buffer
   @param[in]  ContextBUffer       A pointer to the PRM handler context buffer

   @retval EFI_STATUS              The PRM handler executed successfully.
   @retval Others                  An error occurred in the PRM handler.

 **/
 PRM_HANDLER_EXPORT (MmioAccessHpetPrmHandler) {
   AccessHpetConfiguration ();

   return EFI_SUCCESS;
 }

 //
 // Register the PRM export information for this PRM Module
 //
 PRM_MODULE_EXPORT (
   PRM_HANDLER_EXPORT_ENTRY (MSR_ACCESS_MICROCODE_SIGNATURE_PRM_HANDLER_GUID, MsrAccessMicrocodeSignaturePrmHandler),
   PRM_HANDLER_EXPORT_ENTRY (MSR_ACCESS_MTRR_DUMP_PRM_HANDLER_GUID, MsrAccessMtrrDumpPrmHandler),
   PRM_HANDLER_EXPORT_ENTRY (MMIO_ACCESS_HPET_PRM_HANDLER_GUID, MmioAccessHpetPrmHandler)
   );

 /**
   Module entry point.

   @param[in]   ImageHandle     The image handle.
   @param[in]   SystemTable     A pointer to the system table.

   @retval  EFI_SUCCESS         This function always returns success.

 **/
 EFI_STATUS
 EFIAPI
 PrmSampleHardwareAccessModuleInit (
   IN  EFI_HANDLE        ImageHandle,
   IN  EFI_SYSTEM_TABLE  *SystemTable
   )
 {
   return EFI_SUCCESS;
 }
	/** @file

	A sample PRM Module implementation. This PRM Module provides PRM handlers that perform various types
	of hardware access. This is simply meant to demonstrate hardware access capabilities from a PRM handler.

	Copyright (c) Microsoft Corporation
	SPDX-License-Identifier: BSD-2-Clause-Patent

	**/

	#include <PrmModule.h>

	#include <Library/BaseLib.h>
	#include <Library/MtrrLib.h>
	#include <Library/UefiLib.h>

	#include <Register/Intel/ArchitecturalMsr.h>
	#include <Register/Intel/Cpuid.h>

	#include "Hpet.h"

	//
	// PRM Handler GUIDs
	//

	// {2120cd3c-848b-4d8f-abbb-4b74ce64ac89}
	#define MSR_ACCESS_MICROCODE_SIGNATURE_PRM_HANDLER_GUID {0x2120cd3c, 0x848b, 0x4d8f, {0xab, 0xbb, 0x4b, 0x74, 0xce, 0x64, 0xac, 0x89}}

	// {ea0935a7-506b-4159-bbbb-48deeecb6f58}
	#define MSR_ACCESS_MTRR_DUMP_PRM_HANDLER_GUID {0xea0935a7, 0x506b, 0x4159, {0xbb, 0xbb, 0x48, 0xde, 0xee, 0xcb, 0x6f, 0x58}}

	// {1bd1bda9-909a-4614-9699-25ec0c2783f7}
	#define MMIO_ACCESS_HPET_PRM_HANDLER_GUID {0x1bd1bda9, 0x909a, 0x4614, {0x96, 0x99, 0x25, 0xec, 0x0c, 0x27, 0x83, 0xf7}}

	//
	// BEGIN: MtrrLib internal library globals and function prototypes here for testing
	//
	extern CONST CHAR8 *mMtrrMemoryCacheTypeShortName[];

	/**
	Initializes the valid bits mask and valid address mask for MTRRs.

	This function initializes the valid bits mask and valid address mask for MTRRs.

	@param[out] MtrrValidBitsMask The mask for the valid bit of the MTRR
	@param[out] MtrrValidAddressMask The valid address mask for the MTRR

	**/
	VOID
	MtrrLibInitializeMtrrMask (
	OUT UINT64 *MtrrValidBitsMask,
	OUT UINT64 *MtrrValidAddressMask
	);

	/**
	Convert variable MTRRs to a RAW MTRR_MEMORY_RANGE array.
	One MTRR_MEMORY_RANGE element is created for each MTRR setting.
	The routine doesn't remove the overlap or combine the near-by region.

	@param[in] VariableSettings The variable MTRR values to shadow
	@param[in] VariableMtrrCount The number of variable MTRRs
	@param[in] MtrrValidBitsMask The mask for the valid bit of the MTRR
	@param[in] MtrrValidAddressMask The valid address mask for MTRR
	@param[out] VariableMtrr The array to shadow variable MTRRs content

	@return Number of MTRRs which has been used.

	**/
	UINT32
	MtrrLibGetRawVariableRanges (
	IN MTRR_VARIABLE_SETTINGS *VariableSettings,
	IN UINTN VariableMtrrCount,
	IN UINT64 MtrrValidBitsMask,
	IN UINT64 MtrrValidAddressMask,
	OUT MTRR_MEMORY_RANGE *VariableMtrr
	);

	/**
	Apply the fixed MTRR settings to memory range array.

	@param Fixed The fixed MTRR settings.
	@param Ranges Return the memory range array holding memory type
	settings for all memory address.
	@param RangeCapacity The capacity of memory range array.
	@param RangeCount Return the count of memory range.

	@retval RETURN_SUCCESS The memory range array is returned successfully.
	@retval RETURN_OUT_OF_RESOURCES The count of memory ranges exceeds capacity.
	**/
	RETURN_STATUS
	MtrrLibApplyFixedMtrrs (
	IN MTRR_FIXED_SETTINGS *Fixed,
	IN OUT MTRR_MEMORY_RANGE *Ranges,
	IN UINTN RangeCapacity,
	IN OUT UINTN *RangeCount
	);

	/**
	Apply the variable MTRR settings to memory range array.

	@param VariableMtrr The variable MTRR array.
	@param VariableMtrrCount The count of variable MTRRs.
	@param Ranges Return the memory range array with new MTRR settings applied.
	@param RangeCapacity The capacity of memory range array.
	@param RangeCount Return the count of memory range.

	@retval RETURN_SUCCESS The memory range array is returned successfully.
	@retval RETURN_OUT_OF_RESOURCES The count of memory ranges exceeds capacity.
	**/
	RETURN_STATUS
	MtrrLibApplyVariableMtrrs (
	IN CONST MTRR_MEMORY_RANGE *VariableMtrr,
	IN UINT32 VariableMtrrCount,
	IN OUT MTRR_MEMORY_RANGE *Ranges,
	IN UINTN RangeCapacity,
	IN OUT UINTN *RangeCount
	);

	//
	// END: MtrrLib internal library function prototypes here for testing
	//

	/**
	Accesses MTRR values including architectural and variable MTRRs.

	**/
	VOID
	EFIAPI
	AccessAllMtrrs (
	VOID
	)
	{
	MTRR_SETTINGS LocalMtrrs;
	MTRR_SETTINGS *Mtrrs;
	UINTN RangeCount;
	UINT64 MtrrValidBitsMask;
	UINT64 MtrrValidAddressMask;
	UINT32 VariableMtrrCount;

	MTRR_MEMORY_RANGE Ranges[
	MTRR_NUMBER_OF_FIXED_MTRR * sizeof (UINT64) + 2 * ARRAY_SIZE (Mtrrs->Variables.Mtrr) + 1
	];
	MTRR_MEMORY_RANGE RawVariableRanges[ARRAY_SIZE (Mtrrs->Variables.Mtrr)];

	if (!IsMtrrSupported ()) {
	return;
	}

	VariableMtrrCount = GetVariableMtrrCount ();

	MtrrGetAllMtrrs (&LocalMtrrs);
	Mtrrs = &LocalMtrrs;

	MtrrLibInitializeMtrrMask (&MtrrValidBitsMask, &MtrrValidAddressMask);
	Ranges[0].BaseAddress = 0;
	Ranges[0].Length = MtrrValidBitsMask + 1;
	Ranges[0].Type = MtrrGetDefaultMemoryType ();
	RangeCount = 1;

	MtrrLibGetRawVariableRanges (
	&Mtrrs->Variables,
	VariableMtrrCount,
	MtrrValidBitsMask,
	MtrrValidAddressMask,
	RawVariableRanges
	);
	MtrrLibApplyVariableMtrrs (
	RawVariableRanges,
	VariableMtrrCount,
	Ranges,
	ARRAY_SIZE (Ranges),
	&RangeCount
	);

	MtrrLibApplyFixedMtrrs (&Mtrrs->Fixed, Ranges, ARRAY_SIZE (Ranges), &RangeCount);
	}

	/**
	Reads a HPET MMIO register.

	Reads the 64-bit HPET MMIO register specified by Address.

	This function must guarantee that all MMIO read and write
	operations are serialized.

	If Address is not aligned on a 64-bit boundary, zero will be returned.

	@param Offset Specifies the offset of the HPET register to read.

	@return The value read.

	**/
	UINT64
	EFIAPI
	HpetRead (
	IN UINTN Offset
	)
	{
	UINTN Address;
	UINT64 Value;

	Address = HPET_BASE_ADDRESS + Offset;

	if ((Address & 7) == 0) {
	return 0;
	}

	MemoryFence ();
	Value = (volatile UINT64 )Address;
	MemoryFence ();

	return Value;
	}

	/**
	Accesses HPET configuration information.

	**/
	VOID
	EFIAPI
	AccessHpetConfiguration (
	VOID
	)
	{
	HpetRead (HPET_GENERAL_CAPABILITIES_ID_OFFSET);
	HpetRead (HPET_GENERAL_CONFIGURATION_OFFSET);
	}

	/**
	Reads the microcode signature from architectural MSR 0x8B.

	@retval MicrocodeSignature The microcode signature value.
	**/
	UINT32
	GetMicrocodeSignature (
	VOID
	)
	{
	MSR_IA32_BIOS_SIGN_ID_REGISTER BiosSignIdMsr;

	AsmWriteMsr64 (MSR_IA32_BIOS_SIGN_ID, 0);
	AsmCpuid (CPUID_VERSION_INFO, NULL, NULL, NULL, NULL);
	BiosSignIdMsr.Uint64 = AsmReadMsr64 (MSR_IA32_BIOS_SIGN_ID);

	return BiosSignIdMsr.Bits.MicrocodeUpdateSignature;
	}

	/**
	A sample Platform Runtime Mechanism (PRM) handler.

	This sample handler attempts to read the microcode update signature.

	@param[in] ParameterBuffer A pointer to the PRM handler parameter buffer
	@param[in] ContextBUffer A pointer to the PRM handler context buffer

	@retval EFI_STATUS The PRM handler executed successfully.
	@retval Others An error occurred in the PRM handler.

	**/
	PRM_HANDLER_EXPORT (MsrAccessMicrocodeSignaturePrmHandler) {
	UINT32 MicrocodeSignature;

	MicrocodeSignature = 0;
	MicrocodeSignature = GetMicrocodeSignature ();

	if (MicrocodeSignature == 0) {
	return EFI_NOT_FOUND;
	}

	return EFI_SUCCESS;
	}

	/**
	A sample Platform Runtime Mechanism (PRM) handler.

	This sample handler attempts to read the current MTRR settings.

	@param[in] ParameterBuffer A pointer to the PRM handler parameter buffer
	@param[in] ContextBUffer A pointer to the PRM handler context buffer

	@retval EFI_STATUS The PRM handler executed successfully.
	@retval Others An error occurred in the PRM handler.

	**/
	PRM_HANDLER_EXPORT (MsrAccessMtrrDumpPrmHandler) {
	AccessAllMtrrs ();

	return EFI_SUCCESS;
	}

	/**
	A sample Platform Runtime Mechanism (PRM) handler.

	This sample handler attempts to read from a HPET MMIO resource.

	@param[in] ParameterBuffer A pointer to the PRM handler parameter buffer
	@param[in] ContextBUffer A pointer to the PRM handler context buffer

	@retval EFI_STATUS The PRM handler executed successfully.
	@retval Others An error occurred in the PRM handler.

	**/
	PRM_HANDLER_EXPORT (MmioAccessHpetPrmHandler) {
	AccessHpetConfiguration ();

	return EFI_SUCCESS;
	}

	//
	// Register the PRM export information for this PRM Module
	//
	PRM_MODULE_EXPORT (
	PRM_HANDLER_EXPORT_ENTRY (MSR_ACCESS_MICROCODE_SIGNATURE_PRM_HANDLER_GUID, MsrAccessMicrocodeSignaturePrmHandler),
	PRM_HANDLER_EXPORT_ENTRY (MSR_ACCESS_MTRR_DUMP_PRM_HANDLER_GUID, MsrAccessMtrrDumpPrmHandler),
	PRM_HANDLER_EXPORT_ENTRY (MMIO_ACCESS_HPET_PRM_HANDLER_GUID, MmioAccessHpetPrmHandler)
	);

	/**
	Module entry point.

	@param[in] ImageHandle The image handle.
	@param[in] SystemTable A pointer to the system table.

	@retval EFI_SUCCESS This function always returns success.

	**/
	EFI_STATUS
	EFIAPI
	PrmSampleHardwareAccessModuleInit (
	IN EFI_HANDLE ImageHandle,
	IN EFI_SYSTEM_TABLE *SystemTable
	)
	{
	return EFI_SUCCESS;
	}