audk/StandaloneMmPkg/Core/Pool.c

/** @file
  SMM Memory pool management functions.

  Copyright (c) 2009 - 2014, Intel Corporation. All rights reserved.<BR>
  Copyright (c) 2016 - 2018, ARM Limited. All rights reserved.<BR>
  SPDX-License-Identifier: BSD-2-Clause-Patent

**/

#include "StandaloneMmCore.h"

LIST_ENTRY  mMmPoolLists[MAX_POOL_INDEX];
//
// To cache the MMRAM base since when Loading modules At fixed address feature is enabled,
// all module is assigned an offset relative the MMRAM base in build time.
//
GLOBAL_REMOVE_IF_UNREFERENCED  EFI_PHYSICAL_ADDRESS       gLoadModuleAtFixAddressMmramBase = 0;

/**
  Called to initialize the memory service.

  @param   MmramRangeCount       Number of MMRAM Regions
  @param   MmramRanges           Pointer to MMRAM Descriptors

**/
VOID
MmInitializeMemoryServices (
  IN UINTN                 MmramRangeCount,
  IN EFI_MMRAM_DESCRIPTOR  *MmramRanges
  )
{
  UINTN                  Index;

  //
  // Initialize Pool list
  //
  for (Index = sizeof (mMmPoolLists) / sizeof (*mMmPoolLists); Index > 0;) {
    InitializeListHead (&mMmPoolLists[--Index]);
  }


  //
  // Initialize free MMRAM regions
  //
  for (Index = 0; Index < MmramRangeCount; Index++) {
    //
    // BUGBUG: Add legacy MMRAM region is buggy.
    //
    if (MmramRanges[Index].CpuStart < BASE_1MB) {
      continue;
    }
    DEBUG ((DEBUG_INFO, "MmAddMemoryRegion %d : 0x%016lx - 0x%016lx\n",
	    Index, MmramRanges[Index].CpuStart, MmramRanges[Index].PhysicalSize));
    MmAddMemoryRegion (
      MmramRanges[Index].CpuStart,
      MmramRanges[Index].PhysicalSize,
      EfiConventionalMemory,
      MmramRanges[Index].RegionState
      );
  }

}

/**
  Internal Function. Allocate a pool by specified PoolIndex.

  @param  PoolIndex             Index which indicate the Pool size.
  @param  FreePoolHdr           The returned Free pool.

  @retval EFI_OUT_OF_RESOURCES   Allocation failed.
  @retval EFI_SUCCESS            Pool successfully allocated.

**/
EFI_STATUS
InternalAllocPoolByIndex (
  IN  UINTN             PoolIndex,
  OUT FREE_POOL_HEADER  **FreePoolHdr
  )
{
  EFI_STATUS            Status;
  FREE_POOL_HEADER      *Hdr;
  EFI_PHYSICAL_ADDRESS  Address;

  ASSERT (PoolIndex <= MAX_POOL_INDEX);
  Status = EFI_SUCCESS;
  Hdr = NULL;
  if (PoolIndex == MAX_POOL_INDEX) {
    Status = MmInternalAllocatePages (
	             AllocateAnyPages,
               EfiRuntimeServicesData,
               EFI_SIZE_TO_PAGES (MAX_POOL_SIZE << 1),
               &Address
               );
    if (EFI_ERROR (Status)) {
      return EFI_OUT_OF_RESOURCES;
    }
    Hdr = (FREE_POOL_HEADER *) (UINTN) Address;
  } else if (!IsListEmpty (&mMmPoolLists[PoolIndex])) {
    Hdr = BASE_CR (GetFirstNode (&mMmPoolLists[PoolIndex]), FREE_POOL_HEADER, Link);
    RemoveEntryList (&Hdr->Link);
  } else {
    Status = InternalAllocPoolByIndex (PoolIndex + 1, &Hdr);
    if (!EFI_ERROR (Status)) {
      Hdr->Header.Size >>= 1;
      Hdr->Header.Available = TRUE;
      InsertHeadList (&mMmPoolLists[PoolIndex], &Hdr->Link);
      Hdr = (FREE_POOL_HEADER*)((UINT8*)Hdr + Hdr->Header.Size);
    }
  }

  if (!EFI_ERROR (Status)) {
    Hdr->Header.Size = MIN_POOL_SIZE << PoolIndex;
    Hdr->Header.Available = FALSE;
  }

  *FreePoolHdr = Hdr;
  return Status;
}

/**
  Internal Function. Free a pool by specified PoolIndex.

  @param  FreePoolHdr           The pool to free.

  @retval EFI_SUCCESS           Pool successfully freed.

**/
EFI_STATUS
InternalFreePoolByIndex (
  IN FREE_POOL_HEADER  *FreePoolHdr
  )
{
  UINTN  PoolIndex;

  ASSERT ((FreePoolHdr->Header.Size & (FreePoolHdr->Header.Size - 1)) == 0);
  ASSERT (((UINTN)FreePoolHdr & (FreePoolHdr->Header.Size - 1)) == 0);
  ASSERT (FreePoolHdr->Header.Size >= MIN_POOL_SIZE);

  PoolIndex = (UINTN) (HighBitSet32 ((UINT32)FreePoolHdr->Header.Size) - MIN_POOL_SHIFT);
  FreePoolHdr->Header.Available = TRUE;
  ASSERT (PoolIndex < MAX_POOL_INDEX);
  InsertHeadList (&mMmPoolLists[PoolIndex], &FreePoolHdr->Link);
  return EFI_SUCCESS;
}

/**
  Allocate pool of a particular type.

  @param  PoolType               Type of pool to allocate.
  @param  Size                   The amount of pool to allocate.
  @param  Buffer                 The address to return a pointer to the allocated
                                 pool.

  @retval EFI_INVALID_PARAMETER  PoolType not valid.
  @retval EFI_OUT_OF_RESOURCES   Size exceeds max pool size or allocation failed.
  @retval EFI_SUCCESS            Pool successfully allocated.

**/
EFI_STATUS
EFIAPI
MmInternalAllocatePool (
  IN   EFI_MEMORY_TYPE  PoolType,
  IN   UINTN            Size,
  OUT  VOID             **Buffer
  )
{
  POOL_HEADER           *PoolHdr;
  FREE_POOL_HEADER      *FreePoolHdr;
  EFI_STATUS            Status;
  EFI_PHYSICAL_ADDRESS  Address;
  UINTN                 PoolIndex;

  if (PoolType != EfiRuntimeServicesCode &&
      PoolType != EfiRuntimeServicesData) {
    return EFI_INVALID_PARAMETER;
  }

  Size += sizeof (*PoolHdr);
  if (Size > MAX_POOL_SIZE) {
    Size = EFI_SIZE_TO_PAGES (Size);
    Status = MmInternalAllocatePages (AllocateAnyPages, PoolType, Size, &Address);
    if (EFI_ERROR (Status)) {
      return Status;
    }

    PoolHdr = (POOL_HEADER*)(UINTN)Address;
    PoolHdr->Size = EFI_PAGES_TO_SIZE (Size);
    PoolHdr->Available = FALSE;
    *Buffer = PoolHdr + 1;
    return Status;
  }

  Size = (Size + MIN_POOL_SIZE - 1) >> MIN_POOL_SHIFT;
  PoolIndex = (UINTN) HighBitSet32 ((UINT32)Size);
  if ((Size & (Size - 1)) != 0) {
    PoolIndex++;
  }

  Status = InternalAllocPoolByIndex (PoolIndex, &FreePoolHdr);
  if (!EFI_ERROR (Status)) {
    *Buffer = &FreePoolHdr->Header + 1;
  }
  return Status;
}

/**
  Allocate pool of a particular type.

  @param  PoolType               Type of pool to allocate.
  @param  Size                   The amount of pool to allocate.
  @param  Buffer                 The address to return a pointer to the allocated
                                 pool.

  @retval EFI_INVALID_PARAMETER  PoolType not valid.
  @retval EFI_OUT_OF_RESOURCES   Size exceeds max pool size or allocation failed.
  @retval EFI_SUCCESS            Pool successfully allocated.

**/
EFI_STATUS
EFIAPI
MmAllocatePool (
  IN   EFI_MEMORY_TYPE  PoolType,
  IN   UINTN            Size,
  OUT  VOID             **Buffer
  )
{
  EFI_STATUS  Status;

  Status = MmInternalAllocatePool (PoolType, Size, Buffer);
  return Status;
}

/**
  Frees pool.

  @param  Buffer                 The allocated pool entry to free.

  @retval EFI_INVALID_PARAMETER  Buffer is not a valid value.
  @retval EFI_SUCCESS            Pool successfully freed.

**/
EFI_STATUS
EFIAPI
MmInternalFreePool (
  IN VOID  *Buffer
  )
{
  FREE_POOL_HEADER  *FreePoolHdr;

  if (Buffer == NULL) {
    return EFI_INVALID_PARAMETER;
  }

  FreePoolHdr = (FREE_POOL_HEADER*)((POOL_HEADER*)Buffer - 1);
  ASSERT (!FreePoolHdr->Header.Available);

  if (FreePoolHdr->Header.Size > MAX_POOL_SIZE) {
    ASSERT (((UINTN)FreePoolHdr & EFI_PAGE_MASK) == 0);
    ASSERT ((FreePoolHdr->Header.Size & EFI_PAGE_MASK) == 0);
    return MmInternalFreePages (
             (EFI_PHYSICAL_ADDRESS)(UINTN)FreePoolHdr,
             EFI_SIZE_TO_PAGES (FreePoolHdr->Header.Size)
             );
  }
  return InternalFreePoolByIndex (FreePoolHdr);
}

/**
  Frees pool.

  @param  Buffer                 The allocated pool entry to free.

  @retval EFI_INVALID_PARAMETER  Buffer is not a valid value.
  @retval EFI_SUCCESS            Pool successfully freed.

**/
EFI_STATUS
EFIAPI
MmFreePool (
  IN VOID  *Buffer
  )
{
  EFI_STATUS  Status;

  Status = MmInternalFreePool (Buffer);
  return Status;
}
StandaloneMmPkg/Core: Implementation of Standalone MM Core Module. Management Mode (MM) is a generic term used to describe a secure execution environment provided by the CPU and related silicon that is entered when the CPU detects a MMI. For x86 systems, this can be implemented with System Management Mode (SMM). For ARM systems, this can be implemented with TrustZone (TZ). A MMI can be a CPU instruction or interrupt. Upon detection of a MMI, a CPU will jump to the MM Entry Point and save some portion of its state (the "save state") such that execution can be resumed. The MMI can be generated synchronously by software or asynchronously by a hardware event. Each MMI source can be detected, cleared and disabled. Some systems provide for special memory (Management Mode RAM or MMRAM) which is set aside for software running in MM. Usually the MMRAM is hidden during normal CPU execution, but this is not required. Usually, after MMRAM is hidden it cannot be exposed until the next system reset. The MM Core Interface Specification describes three pieces of the PI Management Mode architecture: 1. MM Dispatch During DXE, the DXE Foundation works with the MM Foundation to schedule MM drivers for execution in the discovered firmware volumes. 2. MM Initialization MM related code opens MMRAM, creates the MMRAM memory map, and launches the MM Foundation, which provides the necessary services to launch MM-related drivers. Then, sometime before boot, MMRAM is closed and locked. This piece may be completed during the SEC, PEI or DXE phases. 3. MMI Management When an MMI generated, the MM environment is created and then the MMI sources are detected and MMI handlers called. This patch implements the MM Core. Contributed-under: TianoCore Contribution Agreement 1.1 Signed-off-by: Sughosh Ganu <sughosh.ganu@arm.com> Signed-off-by: Supreeth Venkatesh <supreeth.venkatesh@arm.com> Reviewed-by: Jiewen Yao <jiewen.yao@intel.com> 2018-07-13 17:05:27 +02:00			`/** @file`
			`SMM Memory pool management functions.`

			`Copyright (c) 2009 - 2014, Intel Corporation. All rights reserved.<BR>`
			`Copyright (c) 2016 - 2018, ARM Limited. All rights reserved.<BR>`
StandaloneMmPkg: Replace BSD License with BSD+Patent License https://bugzilla.tianocore.org/show_bug.cgi?id=1373 Replace BSD 2-Clause License with BSD+Patent License. This change is based on the following emails: https://lists.01.org/pipermail/edk2-devel/2019-February/036260.html https://lists.01.org/pipermail/edk2-devel/2018-October/030385.html RFCs with detailed process for the license change: V3: https://lists.01.org/pipermail/edk2-devel/2019-March/038116.html V2: https://lists.01.org/pipermail/edk2-devel/2019-March/037669.html V1: https://lists.01.org/pipermail/edk2-devel/2019-March/037500.html Contributed-under: TianoCore Contribution Agreement 1.1 Signed-off-by: Michael D Kinney <michael.d.kinney@intel.com> Reviewed-by: Jiewen Yao <Jiewen.yao@intel.com> 2019-04-04 01:07:12 +02:00			`SPDX-License-Identifier: BSD-2-Clause-Patent`
StandaloneMmPkg/Core: Implementation of Standalone MM Core Module. Management Mode (MM) is a generic term used to describe a secure execution environment provided by the CPU and related silicon that is entered when the CPU detects a MMI. For x86 systems, this can be implemented with System Management Mode (SMM). For ARM systems, this can be implemented with TrustZone (TZ). A MMI can be a CPU instruction or interrupt. Upon detection of a MMI, a CPU will jump to the MM Entry Point and save some portion of its state (the "save state") such that execution can be resumed. The MMI can be generated synchronously by software or asynchronously by a hardware event. Each MMI source can be detected, cleared and disabled. Some systems provide for special memory (Management Mode RAM or MMRAM) which is set aside for software running in MM. Usually the MMRAM is hidden during normal CPU execution, but this is not required. Usually, after MMRAM is hidden it cannot be exposed until the next system reset. The MM Core Interface Specification describes three pieces of the PI Management Mode architecture: 1. MM Dispatch During DXE, the DXE Foundation works with the MM Foundation to schedule MM drivers for execution in the discovered firmware volumes. 2. MM Initialization MM related code opens MMRAM, creates the MMRAM memory map, and launches the MM Foundation, which provides the necessary services to launch MM-related drivers. Then, sometime before boot, MMRAM is closed and locked. This piece may be completed during the SEC, PEI or DXE phases. 3. MMI Management When an MMI generated, the MM environment is created and then the MMI sources are detected and MMI handlers called. This patch implements the MM Core. Contributed-under: TianoCore Contribution Agreement 1.1 Signed-off-by: Sughosh Ganu <sughosh.ganu@arm.com> Signed-off-by: Supreeth Venkatesh <supreeth.venkatesh@arm.com> Reviewed-by: Jiewen Yao <jiewen.yao@intel.com> 2018-07-13 17:05:27 +02:00
			`**/`

			`#include "StandaloneMmCore.h"`

			`LIST_ENTRY mMmPoolLists[MAX_POOL_INDEX];`
			`//`
			`// To cache the MMRAM base since when Loading modules At fixed address feature is enabled,`
			`// all module is assigned an offset relative the MMRAM base in build time.`
			`//`
			`GLOBAL_REMOVE_IF_UNREFERENCED EFI_PHYSICAL_ADDRESS gLoadModuleAtFixAddressMmramBase = 0;`

			`/**`
			`Called to initialize the memory service.`

			`@param MmramRangeCount Number of MMRAM Regions`
			`@param MmramRanges Pointer to MMRAM Descriptors`

			`**/`
			`VOID`
			`MmInitializeMemoryServices (`
			`IN UINTN MmramRangeCount,`
			`IN EFI_MMRAM_DESCRIPTOR *MmramRanges`
			`)`
			`{`
			`UINTN Index;`

			`//`
			`// Initialize Pool list`
			`//`
			`for (Index = sizeof (mMmPoolLists) / sizeof (*mMmPoolLists); Index > 0;) {`
			`InitializeListHead (&mMmPoolLists[--Index]);`
			`}`


			`//`
			`// Initialize free MMRAM regions`
			`//`
			`for (Index = 0; Index < MmramRangeCount; Index++) {`
			`//`
			`// BUGBUG: Add legacy MMRAM region is buggy.`
			`//`
			`if (MmramRanges[Index].CpuStart < BASE_1MB) {`
			`continue;`
			`}`
			`DEBUG ((DEBUG_INFO, "MmAddMemoryRegion %d : 0x%016lx - 0x%016lx\n",`
			`Index, MmramRanges[Index].CpuStart, MmramRanges[Index].PhysicalSize));`
			`MmAddMemoryRegion (`
			`MmramRanges[Index].CpuStart,`
			`MmramRanges[Index].PhysicalSize,`
			`EfiConventionalMemory,`
			`MmramRanges[Index].RegionState`
			`);`
			`}`

			`}`

			`/**`
			`Internal Function. Allocate a pool by specified PoolIndex.`

			`@param PoolIndex Index which indicate the Pool size.`
			`@param FreePoolHdr The returned Free pool.`

			`@retval EFI_OUT_OF_RESOURCES Allocation failed.`
			`@retval EFI_SUCCESS Pool successfully allocated.`

			`**/`
			`EFI_STATUS`
			`InternalAllocPoolByIndex (`
			`IN UINTN PoolIndex,`
			`OUT FREE_POOL_HEADER **FreePoolHdr`
			`)`
			`{`
			`EFI_STATUS Status;`
			`FREE_POOL_HEADER *Hdr;`
			`EFI_PHYSICAL_ADDRESS Address;`

			`ASSERT (PoolIndex <= MAX_POOL_INDEX);`
			`Status = EFI_SUCCESS;`
			`Hdr = NULL;`
			`if (PoolIndex == MAX_POOL_INDEX) {`
			`Status = MmInternalAllocatePages (`
			`AllocateAnyPages,`
			`EfiRuntimeServicesData,`
			`EFI_SIZE_TO_PAGES (MAX_POOL_SIZE << 1),`
			`&Address`
			`);`
			`if (EFI_ERROR (Status)) {`
			`return EFI_OUT_OF_RESOURCES;`
			`}`
			`Hdr = (FREE_POOL_HEADER *) (UINTN) Address;`
			`} else if (!IsListEmpty (&mMmPoolLists[PoolIndex])) {`
			`Hdr = BASE_CR (GetFirstNode (&mMmPoolLists[PoolIndex]), FREE_POOL_HEADER, Link);`
			`RemoveEntryList (&Hdr->Link);`
			`} else {`
			`Status = InternalAllocPoolByIndex (PoolIndex + 1, &Hdr);`
			`if (!EFI_ERROR (Status)) {`
			`Hdr->Header.Size >>= 1;`
			`Hdr->Header.Available = TRUE;`
			`InsertHeadList (&mMmPoolLists[PoolIndex], &Hdr->Link);`
			`Hdr = (FREE_POOL_HEADER)((UINT8)Hdr + Hdr->Header.Size);`
			`}`
			`}`

			`if (!EFI_ERROR (Status)) {`
			`Hdr->Header.Size = MIN_POOL_SIZE << PoolIndex;`
			`Hdr->Header.Available = FALSE;`
			`}`

			`*FreePoolHdr = Hdr;`
			`return Status;`
			`}`

			`/**`
			`Internal Function. Free a pool by specified PoolIndex.`

			`@param FreePoolHdr The pool to free.`

			`@retval EFI_SUCCESS Pool successfully freed.`

			`**/`
			`EFI_STATUS`
			`InternalFreePoolByIndex (`
			`IN FREE_POOL_HEADER *FreePoolHdr`
			`)`
			`{`
			`UINTN PoolIndex;`

			`ASSERT ((FreePoolHdr->Header.Size & (FreePoolHdr->Header.Size - 1)) == 0);`
			`ASSERT (((UINTN)FreePoolHdr & (FreePoolHdr->Header.Size - 1)) == 0);`
			`ASSERT (FreePoolHdr->Header.Size >= MIN_POOL_SIZE);`

			`PoolIndex = (UINTN) (HighBitSet32 ((UINT32)FreePoolHdr->Header.Size) - MIN_POOL_SHIFT);`
			`FreePoolHdr->Header.Available = TRUE;`
			`ASSERT (PoolIndex < MAX_POOL_INDEX);`
			`InsertHeadList (&mMmPoolLists[PoolIndex], &FreePoolHdr->Link);`
			`return EFI_SUCCESS;`
			`}`

			`/**`
			`Allocate pool of a particular type.`

			`@param PoolType Type of pool to allocate.`
			`@param Size The amount of pool to allocate.`
			`@param Buffer The address to return a pointer to the allocated`
			`pool.`

			`@retval EFI_INVALID_PARAMETER PoolType not valid.`
			`@retval EFI_OUT_OF_RESOURCES Size exceeds max pool size or allocation failed.`
			`@retval EFI_SUCCESS Pool successfully allocated.`

			`**/`
			`EFI_STATUS`
			`EFIAPI`
			`MmInternalAllocatePool (`
			`IN EFI_MEMORY_TYPE PoolType,`
			`IN UINTN Size,`
			`OUT VOID **Buffer`
			`)`
			`{`
			`POOL_HEADER *PoolHdr;`
			`FREE_POOL_HEADER *FreePoolHdr;`
			`EFI_STATUS Status;`
			`EFI_PHYSICAL_ADDRESS Address;`
			`UINTN PoolIndex;`

			`if (PoolType != EfiRuntimeServicesCode &&`
			`PoolType != EfiRuntimeServicesData) {`
			`return EFI_INVALID_PARAMETER;`
			`}`

			`Size += sizeof (*PoolHdr);`
			`if (Size > MAX_POOL_SIZE) {`
			`Size = EFI_SIZE_TO_PAGES (Size);`
			`Status = MmInternalAllocatePages (AllocateAnyPages, PoolType, Size, &Address);`
			`if (EFI_ERROR (Status)) {`
			`return Status;`
			`}`

			`PoolHdr = (POOL_HEADER*)(UINTN)Address;`
			`PoolHdr->Size = EFI_PAGES_TO_SIZE (Size);`
			`PoolHdr->Available = FALSE;`
			`*Buffer = PoolHdr + 1;`
			`return Status;`
			`}`

			`Size = (Size + MIN_POOL_SIZE - 1) >> MIN_POOL_SHIFT;`
			`PoolIndex = (UINTN) HighBitSet32 ((UINT32)Size);`
			`if ((Size & (Size - 1)) != 0) {`
			`PoolIndex++;`
			`}`

			`Status = InternalAllocPoolByIndex (PoolIndex, &FreePoolHdr);`
			`if (!EFI_ERROR (Status)) {`
			`*Buffer = &FreePoolHdr->Header + 1;`
			`}`
			`return Status;`
			`}`

			`/**`
			`Allocate pool of a particular type.`

			`@param PoolType Type of pool to allocate.`
			`@param Size The amount of pool to allocate.`
			`@param Buffer The address to return a pointer to the allocated`
			`pool.`

			`@retval EFI_INVALID_PARAMETER PoolType not valid.`
			`@retval EFI_OUT_OF_RESOURCES Size exceeds max pool size or allocation failed.`
			`@retval EFI_SUCCESS Pool successfully allocated.`

			`**/`
			`EFI_STATUS`
			`EFIAPI`
			`MmAllocatePool (`
			`IN EFI_MEMORY_TYPE PoolType,`
			`IN UINTN Size,`
			`OUT VOID **Buffer`
			`)`
			`{`
			`EFI_STATUS Status;`

			`Status = MmInternalAllocatePool (PoolType, Size, Buffer);`
			`return Status;`
			`}`

			`/**`
			`Frees pool.`

			`@param Buffer The allocated pool entry to free.`

			`@retval EFI_INVALID_PARAMETER Buffer is not a valid value.`
			`@retval EFI_SUCCESS Pool successfully freed.`

			`**/`
			`EFI_STATUS`
			`EFIAPI`
			`MmInternalFreePool (`
			`IN VOID *Buffer`
			`)`
			`{`
			`FREE_POOL_HEADER *FreePoolHdr;`

			`if (Buffer == NULL) {`
			`return EFI_INVALID_PARAMETER;`
			`}`

			`FreePoolHdr = (FREE_POOL_HEADER)((POOL_HEADER)Buffer - 1);`
			`ASSERT (!FreePoolHdr->Header.Available);`

			`if (FreePoolHdr->Header.Size > MAX_POOL_SIZE) {`
			`ASSERT (((UINTN)FreePoolHdr & EFI_PAGE_MASK) == 0);`
			`ASSERT ((FreePoolHdr->Header.Size & EFI_PAGE_MASK) == 0);`
			`return MmInternalFreePages (`
			`(EFI_PHYSICAL_ADDRESS)(UINTN)FreePoolHdr,`
			`EFI_SIZE_TO_PAGES (FreePoolHdr->Header.Size)`
			`);`
			`}`
			`return InternalFreePoolByIndex (FreePoolHdr);`
			`}`

			`/**`
			`Frees pool.`

			`@param Buffer The allocated pool entry to free.`

			`@retval EFI_INVALID_PARAMETER Buffer is not a valid value.`
			`@retval EFI_SUCCESS Pool successfully freed.`

			`**/`
			`EFI_STATUS`
			`EFIAPI`
			`MmFreePool (`
			`IN VOID *Buffer`
			`)`
			`{`
			`EFI_STATUS Status;`

			`Status = MmInternalFreePool (Buffer);`
			`return Status;`
			`}`