StandaloneMmPkg/Include/Guid/MmCoreData.h - third_party/edk2 - Git at Google

 /** @file
   MM Core data.

 Copyright (c) 2015, Intel Corporation. All rights reserved.<BR>
 Copyright (c) 2018 - 2021, Arm Limited. All rights reserved.<BR>
 SPDX-License-Identifier: BSD-2-Clause-Patent

 **/

 #ifndef __MM_CORE_DATA_H__
 #define __MM_CORE_DATA_H__

 #define MM_CORE_DATA_HOB_GUID \
   { 0xa160bf99, 0x2aa4, 0x4d7d, { 0x99, 0x93, 0x89, 0x9c, 0xb1, 0x2d, 0xf3, 0x76 }}

 extern EFI_GUID  gMmCoreDataHobGuid;

 typedef struct {
   //
   // Address pointer to MM_CORE_PRIVATE_DATA
   //
   EFI_PHYSICAL_ADDRESS    Address;
 } MM_CORE_DATA_HOB_DATA;

 ///
 /// Define values for the communications buffer used when gEfiEventDxeDispatchGuid is
 /// event signaled.  This event is signaled by the DXE Core each time the DXE Core
 /// dispatcher has completed its work.  When this event is signaled, the MM Core
 /// if notified, so the MM Core can dispatch MM drivers.  If COMM_BUFFER_MM_DISPATCH_ERROR
 /// is returned in the communication buffer, then an error occurred dispatching MM
 /// Drivers.  If COMM_BUFFER_MM_DISPATCH_SUCCESS is returned, then the MM Core
 /// dispatched all the drivers it could.  If COMM_BUFFER_MM_DISPATCH_RESTART is
 /// returned, then the MM Core just dispatched the MM Driver that registered
 /// the MM Entry Point enabling the use of MM Mode.  In this case, the MM Core
 /// should be notified again to dispatch more MM Drivers using MM Mode.
 ///
 #define COMM_BUFFER_MM_DISPATCH_ERROR    0x00
 #define COMM_BUFFER_MM_DISPATCH_SUCCESS  0x01
 #define COMM_BUFFER_MM_DISPATCH_RESTART  0x02

 ///
 /// Signature for the private structure shared between the MM IPL and the MM Core
 ///
 #define MM_CORE_PRIVATE_DATA_SIGNATURE  SIGNATURE_32 ('m', 'm', 'i', 'c')

 ///
 /// Private structure that is used to share information between the MM IPL and
 /// the MM Core.  This structure is allocated from memory of type EfiRuntimeServicesData.
 /// Since runtime memory types are converted to available memory when a legacy boot
 /// is performed, the MM Core must not access any fields of this structure if a legacy
 /// boot is performed.  As a result, the MM IPL must create an event notification
 /// for the Legacy Boot event and notify the MM Core that a legacy boot is being
 /// performed.  The MM Core can then use this information to filter accesses to
 /// thos structure.
 ///
 typedef struct {
   UINT64                  Signature;

   ///
   /// The number of MMRAM ranges passed from the MM IPL to the MM Core.  The MM
   /// Core uses these ranges of MMRAM to initialize the MM Core memory manager.
   ///
   UINT64                  MmramRangeCount;

   ///
   /// A table of MMRAM ranges passed from the MM IPL to the MM Core.  The MM
   /// Core uses these ranges of MMRAM to initialize the MM Core memory manager.
   ///
   EFI_PHYSICAL_ADDRESS    MmramRanges;

   ///
   /// The MM Foundation Entry Point.  The MM Core fills in this field when the
   /// MM Core is initialized.  The MM IPL is responsbile for registering this entry
   /// point with the MM Configuration Protocol.  The MM Configuration Protocol may
   /// not be available at the time the MM IPL and MM Core are started, so the MM IPL
   /// sets up a protocol notification on the MM Configuration Protocol and registers
   /// the MM Foundation Entry Point as soon as the MM Configuration Protocol is
   /// available.
   ///
   EFI_PHYSICAL_ADDRESS    MmEntryPoint;

   ///
   /// Boolean flag set to TRUE while an MMI is being processed by the MM Core.
   ///
   BOOLEAN                 MmEntryPointRegistered;

   ///
   /// Boolean flag set to TRUE while an MMI is being processed by the MM Core.
   ///
   BOOLEAN                 InMm;

   ///
   /// This field is set by the MM Core then the MM Core is initialized.  This field is
   /// used by the MM Base 2 Protocol and MM Communication Protocol implementations in
   /// the MM IPL.
   ///
   EFI_PHYSICAL_ADDRESS    Mmst;

   ///
   /// This field is used by the MM Communication Protocol to pass a buffer into
   /// a software MMI handler and for the software MMI handler to pass a buffer back to
   /// the caller of the MM Communication Protocol.
   ///
   EFI_PHYSICAL_ADDRESS    CommunicationBuffer;

   ///
   /// This field is used by the MM Communication Protocol to pass the size of a buffer,
   /// in bytes, into a software MMI handler and for the software MMI handler to pass the
   /// size, in bytes, of a buffer back to the caller of the MM Communication Protocol.
   ///
   UINT64                  BufferSize;

   ///
   /// This field is used by the MM Communication Protocol to pass the return status from
   /// a software MMI handler back to the caller of the MM Communication Protocol.
   ///
   UINT64                  ReturnStatus;

   EFI_PHYSICAL_ADDRESS    MmCoreImageBase;
   UINT64                  MmCoreImageSize;
   EFI_PHYSICAL_ADDRESS    MmCoreEntryPoint;

   EFI_PHYSICAL_ADDRESS    StandaloneBfvAddress;
 } MM_CORE_PRIVATE_DATA;

 #endif
	/** @file
	MM Core data.

	Copyright (c) 2015, Intel Corporation. All rights reserved.<BR>
	Copyright (c) 2018 - 2021, Arm Limited. All rights reserved.<BR>
	SPDX-License-Identifier: BSD-2-Clause-Patent

	**/

	#ifndef __MM_CORE_DATA_H__
	#define __MM_CORE_DATA_H__

	#define MM_CORE_DATA_HOB_GUID \
	{ 0xa160bf99, 0x2aa4, 0x4d7d, { 0x99, 0x93, 0x89, 0x9c, 0xb1, 0x2d, 0xf3, 0x76 }}

	extern EFI_GUID gMmCoreDataHobGuid;

	typedef struct {
	//
	// Address pointer to MM_CORE_PRIVATE_DATA
	//
	EFI_PHYSICAL_ADDRESS Address;
	} MM_CORE_DATA_HOB_DATA;

	///
	/// Define values for the communications buffer used when gEfiEventDxeDispatchGuid is
	/// event signaled. This event is signaled by the DXE Core each time the DXE Core
	/// dispatcher has completed its work. When this event is signaled, the MM Core
	/// if notified, so the MM Core can dispatch MM drivers. If COMM_BUFFER_MM_DISPATCH_ERROR
	/// is returned in the communication buffer, then an error occurred dispatching MM
	/// Drivers. If COMM_BUFFER_MM_DISPATCH_SUCCESS is returned, then the MM Core
	/// dispatched all the drivers it could. If COMM_BUFFER_MM_DISPATCH_RESTART is
	/// returned, then the MM Core just dispatched the MM Driver that registered
	/// the MM Entry Point enabling the use of MM Mode. In this case, the MM Core
	/// should be notified again to dispatch more MM Drivers using MM Mode.
	///
	#define COMM_BUFFER_MM_DISPATCH_ERROR 0x00
	#define COMM_BUFFER_MM_DISPATCH_SUCCESS 0x01
	#define COMM_BUFFER_MM_DISPATCH_RESTART 0x02

	///
	/// Signature for the private structure shared between the MM IPL and the MM Core
	///
	#define MM_CORE_PRIVATE_DATA_SIGNATURE SIGNATURE_32 ('m', 'm', 'i', 'c')

	///
	/// Private structure that is used to share information between the MM IPL and
	/// the MM Core. This structure is allocated from memory of type EfiRuntimeServicesData.
	/// Since runtime memory types are converted to available memory when a legacy boot
	/// is performed, the MM Core must not access any fields of this structure if a legacy
	/// boot is performed. As a result, the MM IPL must create an event notification
	/// for the Legacy Boot event and notify the MM Core that a legacy boot is being
	/// performed. The MM Core can then use this information to filter accesses to
	/// thos structure.
	///
	typedef struct {
	UINT64 Signature;

	///
	/// The number of MMRAM ranges passed from the MM IPL to the MM Core. The MM
	/// Core uses these ranges of MMRAM to initialize the MM Core memory manager.
	///
	UINT64 MmramRangeCount;

	///
	/// A table of MMRAM ranges passed from the MM IPL to the MM Core. The MM
	/// Core uses these ranges of MMRAM to initialize the MM Core memory manager.
	///
	EFI_PHYSICAL_ADDRESS MmramRanges;

	///
	/// The MM Foundation Entry Point. The MM Core fills in this field when the
	/// MM Core is initialized. The MM IPL is responsbile for registering this entry
	/// point with the MM Configuration Protocol. The MM Configuration Protocol may
	/// not be available at the time the MM IPL and MM Core are started, so the MM IPL
	/// sets up a protocol notification on the MM Configuration Protocol and registers
	/// the MM Foundation Entry Point as soon as the MM Configuration Protocol is
	/// available.
	///
	EFI_PHYSICAL_ADDRESS MmEntryPoint;

	///
	/// Boolean flag set to TRUE while an MMI is being processed by the MM Core.
	///
	BOOLEAN MmEntryPointRegistered;

	///
	/// Boolean flag set to TRUE while an MMI is being processed by the MM Core.
	///
	BOOLEAN InMm;

	///
	/// This field is set by the MM Core then the MM Core is initialized. This field is
	/// used by the MM Base 2 Protocol and MM Communication Protocol implementations in
	/// the MM IPL.
	///
	EFI_PHYSICAL_ADDRESS Mmst;

	///
	/// This field is used by the MM Communication Protocol to pass a buffer into
	/// a software MMI handler and for the software MMI handler to pass a buffer back to
	/// the caller of the MM Communication Protocol.
	///
	EFI_PHYSICAL_ADDRESS CommunicationBuffer;

	///
	/// This field is used by the MM Communication Protocol to pass the size of a buffer,
	/// in bytes, into a software MMI handler and for the software MMI handler to pass the
	/// size, in bytes, of a buffer back to the caller of the MM Communication Protocol.
	///
	UINT64 BufferSize;

	///
	/// This field is used by the MM Communication Protocol to pass the return status from
	/// a software MMI handler back to the caller of the MM Communication Protocol.
	///
	UINT64 ReturnStatus;

	EFI_PHYSICAL_ADDRESS MmCoreImageBase;
	UINT64 MmCoreImageSize;
	EFI_PHYSICAL_ADDRESS MmCoreEntryPoint;

	EFI_PHYSICAL_ADDRESS StandaloneBfvAddress;
	} MM_CORE_PRIVATE_DATA;

	#endif