audk/ArmPkg/Drivers/CpuDxe/Arm/Mmu.c

/*++

Copyright (c) 2009, Hewlett-Packard Company. All rights reserved.<BR>
Portions copyright (c) 2010, Apple Inc. All rights reserved.<BR>
Portions copyright (c) 2013, ARM Ltd. All rights reserved.<BR>
Copyright (c) 2017, Intel Corporation. All rights reserved.<BR>

This program and the accompanying materials
are licensed and made available under the terms and conditions of the BSD License
which accompanies this distribution.  The full text of the license may be found at
http://opensource.org/licenses/bsd-license.php

THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,
WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.


--*/

#include <Library/MemoryAllocationLib.h>
#include "CpuDxe.h"

EFI_STATUS
SectionToGcdAttributes (
  IN  UINT32  SectionAttributes,
  OUT UINT64  *GcdAttributes
  )
{
  *GcdAttributes = 0;

  // determine cacheability attributes
  switch(SectionAttributes & TT_DESCRIPTOR_SECTION_CACHE_POLICY_MASK) {
    case TT_DESCRIPTOR_SECTION_CACHE_POLICY_STRONGLY_ORDERED:
      *GcdAttributes |= EFI_MEMORY_UC;
      break;
    case TT_DESCRIPTOR_SECTION_CACHE_POLICY_SHAREABLE_DEVICE:
      *GcdAttributes |= EFI_MEMORY_UC;
      break;
    case TT_DESCRIPTOR_SECTION_CACHE_POLICY_WRITE_THROUGH_NO_ALLOC:
      *GcdAttributes |= EFI_MEMORY_WT;
      break;
    case TT_DESCRIPTOR_SECTION_CACHE_POLICY_WRITE_BACK_NO_ALLOC:
      *GcdAttributes |= EFI_MEMORY_WB;
      break;
    case TT_DESCRIPTOR_SECTION_CACHE_POLICY_NON_CACHEABLE:
      *GcdAttributes |= EFI_MEMORY_WC;
      break;
    case TT_DESCRIPTOR_SECTION_CACHE_POLICY_WRITE_BACK_ALLOC:
      *GcdAttributes |= EFI_MEMORY_WB;
      break;
    case TT_DESCRIPTOR_SECTION_CACHE_POLICY_NON_SHAREABLE_DEVICE:
      *GcdAttributes |= EFI_MEMORY_UC;
      break;
    default:
      return EFI_UNSUPPORTED;
  }

  // determine protection attributes
  switch(SectionAttributes & TT_DESCRIPTOR_SECTION_AP_MASK) {
    case TT_DESCRIPTOR_SECTION_AP_NO_NO: // no read, no write
      //*GcdAttributes |= EFI_MEMORY_RO | EFI_MEMORY_RP;
      break;

    case TT_DESCRIPTOR_SECTION_AP_RW_NO:
    case TT_DESCRIPTOR_SECTION_AP_RW_RW:
      // normal read/write access, do not add additional attributes
      break;

    // read only cases map to write-protect
    case TT_DESCRIPTOR_SECTION_AP_RO_NO:
    case TT_DESCRIPTOR_SECTION_AP_RO_RO:
      *GcdAttributes |= EFI_MEMORY_RO;
      break;

    default:
      return EFI_UNSUPPORTED;
  }

  // now process eXectue Never attribute
  if ((SectionAttributes & TT_DESCRIPTOR_SECTION_XN_MASK) != 0 ) {
    *GcdAttributes |= EFI_MEMORY_XP;
  }

  return EFI_SUCCESS;
}

EFI_STATUS
PageToGcdAttributes (
  IN  UINT32  PageAttributes,
  OUT UINT64  *GcdAttributes
  )
{
  *GcdAttributes = 0;

  // determine cacheability attributes
  switch(PageAttributes & TT_DESCRIPTOR_PAGE_CACHE_POLICY_MASK) {
    case TT_DESCRIPTOR_PAGE_CACHE_POLICY_STRONGLY_ORDERED:
      *GcdAttributes |= EFI_MEMORY_UC;
      break;
    case TT_DESCRIPTOR_PAGE_CACHE_POLICY_SHAREABLE_DEVICE:
      *GcdAttributes |= EFI_MEMORY_UC;
      break;
    case TT_DESCRIPTOR_PAGE_CACHE_POLICY_WRITE_THROUGH_NO_ALLOC:
      *GcdAttributes |= EFI_MEMORY_WT;
      break;
    case TT_DESCRIPTOR_PAGE_CACHE_POLICY_WRITE_BACK_NO_ALLOC:
      *GcdAttributes |= EFI_MEMORY_WB;
      break;
    case TT_DESCRIPTOR_PAGE_CACHE_POLICY_NON_CACHEABLE:
      *GcdAttributes |= EFI_MEMORY_WC;
      break;
    case TT_DESCRIPTOR_PAGE_CACHE_POLICY_WRITE_BACK_ALLOC:
      *GcdAttributes |= EFI_MEMORY_WB;
      break;
    case TT_DESCRIPTOR_PAGE_CACHE_POLICY_NON_SHAREABLE_DEVICE:
      *GcdAttributes |= EFI_MEMORY_UC;
      break;
    default:
      return EFI_UNSUPPORTED;
  }

  // determine protection attributes
  switch(PageAttributes & TT_DESCRIPTOR_PAGE_AP_MASK) {
    case TT_DESCRIPTOR_PAGE_AP_NO_NO: // no read, no write
      //*GcdAttributes |= EFI_MEMORY_RO | EFI_MEMORY_RP;
      break;

    case TT_DESCRIPTOR_PAGE_AP_RW_NO:
    case TT_DESCRIPTOR_PAGE_AP_RW_RW:
      // normal read/write access, do not add additional attributes
      break;

    // read only cases map to write-protect
    case TT_DESCRIPTOR_PAGE_AP_RO_NO:
    case TT_DESCRIPTOR_PAGE_AP_RO_RO:
      *GcdAttributes |= EFI_MEMORY_RO;
      break;

    default:
      return EFI_UNSUPPORTED;
  }

  // now process eXectue Never attribute
  if ((PageAttributes & TT_DESCRIPTOR_PAGE_XN_MASK) != 0 ) {
    *GcdAttributes |= EFI_MEMORY_XP;
  }

  return EFI_SUCCESS;
}

EFI_STATUS
SyncCacheConfigPage (
  IN     UINT32                             SectionIndex,
  IN     UINT32                             FirstLevelDescriptor,
  IN     UINTN                              NumberOfDescriptors,
  IN     EFI_GCD_MEMORY_SPACE_DESCRIPTOR    *MemorySpaceMap,
  IN OUT EFI_PHYSICAL_ADDRESS               *NextRegionBase,
  IN OUT UINT64                             *NextRegionLength,
  IN OUT UINT32                             *NextSectionAttributes
  )
{
  EFI_STATUS                          Status;
  UINT32                              i;
  volatile ARM_PAGE_TABLE_ENTRY       *SecondLevelTable;
  UINT32                              NextPageAttributes = 0;
  UINT32                              PageAttributes = 0;
  UINT32                              BaseAddress;
  UINT64                              GcdAttributes;

  // Get the Base Address from FirstLevelDescriptor;
  BaseAddress = TT_DESCRIPTOR_PAGE_BASE_ADDRESS(SectionIndex << TT_DESCRIPTOR_SECTION_BASE_SHIFT);

  // Convert SectionAttributes into PageAttributes
  NextPageAttributes =
      TT_DESCRIPTOR_CONVERT_TO_PAGE_CACHE_POLICY(*NextSectionAttributes,0) |
      TT_DESCRIPTOR_CONVERT_TO_PAGE_AP(*NextSectionAttributes);

  // obtain page table base
  SecondLevelTable = (ARM_PAGE_TABLE_ENTRY *)(FirstLevelDescriptor & TT_DESCRIPTOR_SECTION_PAGETABLE_ADDRESS_MASK);

  for (i=0; i < TRANSLATION_TABLE_PAGE_COUNT; i++) {
    if ((SecondLevelTable[i] & TT_DESCRIPTOR_PAGE_TYPE_MASK) == TT_DESCRIPTOR_PAGE_TYPE_PAGE) {
      // extract attributes (cacheability and permissions)
      PageAttributes = SecondLevelTable[i] & (TT_DESCRIPTOR_PAGE_CACHE_POLICY_MASK | TT_DESCRIPTOR_PAGE_AP_MASK);

      if (NextPageAttributes == 0) {
        // start on a new region
        *NextRegionLength = 0;
        *NextRegionBase = BaseAddress | (i << TT_DESCRIPTOR_PAGE_BASE_SHIFT);
        NextPageAttributes = PageAttributes;
      } else if (PageAttributes != NextPageAttributes) {
        // Convert Section Attributes into GCD Attributes
        Status = PageToGcdAttributes (NextPageAttributes, &GcdAttributes);
        ASSERT_EFI_ERROR (Status);

        // update GCD with these changes (this will recurse into our own CpuSetMemoryAttributes below which is OK)
        SetGcdMemorySpaceAttributes (MemorySpaceMap, NumberOfDescriptors, *NextRegionBase, *NextRegionLength, GcdAttributes);

        // start on a new region
        *NextRegionLength = 0;
        *NextRegionBase = BaseAddress | (i << TT_DESCRIPTOR_PAGE_BASE_SHIFT);
        NextPageAttributes = PageAttributes;
      }
    } else if (NextPageAttributes != 0) {
      // Convert Page Attributes into GCD Attributes
      Status = PageToGcdAttributes (NextPageAttributes, &GcdAttributes);
      ASSERT_EFI_ERROR (Status);

      // update GCD with these changes (this will recurse into our own CpuSetMemoryAttributes below which is OK)
      SetGcdMemorySpaceAttributes (MemorySpaceMap, NumberOfDescriptors, *NextRegionBase, *NextRegionLength, GcdAttributes);

      *NextRegionLength = 0;
      *NextRegionBase = BaseAddress | (i << TT_DESCRIPTOR_PAGE_BASE_SHIFT);
      NextPageAttributes = 0;
    }
    *NextRegionLength += TT_DESCRIPTOR_PAGE_SIZE;
  }

  // Convert back PageAttributes into SectionAttributes
  *NextSectionAttributes =
      TT_DESCRIPTOR_CONVERT_TO_SECTION_CACHE_POLICY(NextPageAttributes,0) |
      TT_DESCRIPTOR_CONVERT_TO_SECTION_AP(NextPageAttributes);

  return EFI_SUCCESS;
}

EFI_STATUS
SyncCacheConfig (
  IN  EFI_CPU_ARCH_PROTOCOL *CpuProtocol
  )
{
  EFI_STATUS                          Status;
  UINT32                              i;
  EFI_PHYSICAL_ADDRESS                NextRegionBase;
  UINT64                              NextRegionLength;
  UINT32                              NextSectionAttributes = 0;
  UINT32                              SectionAttributes = 0;
  UINT64                              GcdAttributes;
  volatile ARM_FIRST_LEVEL_DESCRIPTOR   *FirstLevelTable;
  UINTN                               NumberOfDescriptors;
  EFI_GCD_MEMORY_SPACE_DESCRIPTOR     *MemorySpaceMap;


  DEBUG ((EFI_D_PAGE, "SyncCacheConfig()\n"));

  // This code assumes MMU is enabled and filed with section translations
  ASSERT (ArmMmuEnabled ());

  //
  // Get the memory space map from GCD
  //
  MemorySpaceMap = NULL;
  Status = gDS->GetMemorySpaceMap (&NumberOfDescriptors, &MemorySpaceMap);
  ASSERT_EFI_ERROR (Status);


  // The GCD implementation maintains its own copy of the state of memory space attributes.  GCD needs
  // to know what the initial memory space attributes are.  The CPU Arch. Protocol does not provide a
  // GetMemoryAttributes function for GCD to get this so we must resort to calling GCD (as if we were
  // a client) to update its copy of the attributes.  This is bad architecture and should be replaced
  // with a way for GCD to query the CPU Arch. driver of the existing memory space attributes instead.

  // obtain page table base
  FirstLevelTable = (ARM_FIRST_LEVEL_DESCRIPTOR *)(ArmGetTTBR0BaseAddress ());

  // Get the first region
  NextSectionAttributes = FirstLevelTable[0] & (TT_DESCRIPTOR_SECTION_CACHE_POLICY_MASK | TT_DESCRIPTOR_SECTION_AP_MASK);

  // iterate through each 1MB descriptor
  NextRegionBase = NextRegionLength = 0;
  for (i=0; i < TRANSLATION_TABLE_SECTION_COUNT; i++) {
    if ((FirstLevelTable[i] & TT_DESCRIPTOR_SECTION_TYPE_MASK) == TT_DESCRIPTOR_SECTION_TYPE_SECTION) {
      // extract attributes (cacheability and permissions)
      SectionAttributes = FirstLevelTable[i] & (TT_DESCRIPTOR_SECTION_CACHE_POLICY_MASK | TT_DESCRIPTOR_SECTION_AP_MASK);

      if (NextSectionAttributes == 0) {
        // start on a new region
        NextRegionLength = 0;
        NextRegionBase = TT_DESCRIPTOR_SECTION_BASE_ADDRESS(i << TT_DESCRIPTOR_SECTION_BASE_SHIFT);
        NextSectionAttributes = SectionAttributes;
      } else if (SectionAttributes != NextSectionAttributes) {
        // Convert Section Attributes into GCD Attributes
        Status = SectionToGcdAttributes (NextSectionAttributes, &GcdAttributes);
        ASSERT_EFI_ERROR (Status);

        // update GCD with these changes (this will recurse into our own CpuSetMemoryAttributes below which is OK)
        SetGcdMemorySpaceAttributes (MemorySpaceMap, NumberOfDescriptors, NextRegionBase, NextRegionLength, GcdAttributes);

        // start on a new region
        NextRegionLength = 0;
        NextRegionBase = TT_DESCRIPTOR_SECTION_BASE_ADDRESS(i << TT_DESCRIPTOR_SECTION_BASE_SHIFT);
        NextSectionAttributes = SectionAttributes;
      }
      NextRegionLength += TT_DESCRIPTOR_SECTION_SIZE;
    } else if (TT_DESCRIPTOR_SECTION_TYPE_IS_PAGE_TABLE(FirstLevelTable[i])) {
      // In this case any bits set in the 'NextSectionAttributes' are garbage and were set from
      // bits that are actually part of the pagetable address.  We clear it out to zero so that
      // the SyncCacheConfigPage will use the page attributes instead of trying to convert the
      // section attributes into page attributes
      NextSectionAttributes = 0;
      Status = SyncCacheConfigPage (
          i,FirstLevelTable[i],
          NumberOfDescriptors, MemorySpaceMap,
          &NextRegionBase,&NextRegionLength,&NextSectionAttributes);
      ASSERT_EFI_ERROR (Status);
    } else {
      // We do not support yet 16MB sections
      ASSERT ((FirstLevelTable[i] & TT_DESCRIPTOR_SECTION_TYPE_MASK) != TT_DESCRIPTOR_SECTION_TYPE_SUPERSECTION);

      // start on a new region
      if (NextSectionAttributes != 0) {
        // Convert Section Attributes into GCD Attributes
        Status = SectionToGcdAttributes (NextSectionAttributes, &GcdAttributes);
        ASSERT_EFI_ERROR (Status);

        // update GCD with these changes (this will recurse into our own CpuSetMemoryAttributes below which is OK)
        SetGcdMemorySpaceAttributes (MemorySpaceMap, NumberOfDescriptors, NextRegionBase, NextRegionLength, GcdAttributes);

        NextRegionLength = 0;
        NextRegionBase = TT_DESCRIPTOR_SECTION_BASE_ADDRESS(i << TT_DESCRIPTOR_SECTION_BASE_SHIFT);
        NextSectionAttributes = 0;
      }
      NextRegionLength += TT_DESCRIPTOR_SECTION_SIZE;
    }
  } // section entry loop

  if (NextSectionAttributes != 0) {
    // Convert Section Attributes into GCD Attributes
    Status = SectionToGcdAttributes (NextSectionAttributes, &GcdAttributes);
    ASSERT_EFI_ERROR (Status);

    // update GCD with these changes (this will recurse into our own CpuSetMemoryAttributes below which is OK)
    SetGcdMemorySpaceAttributes (MemorySpaceMap, NumberOfDescriptors, NextRegionBase, NextRegionLength, GcdAttributes);
  }

  FreePool (MemorySpaceMap);

  return EFI_SUCCESS;
}

UINT64
EfiAttributeToArmAttribute (
  IN UINT64                    EfiAttributes
  )
{
  UINT64 ArmAttributes;

  switch (EfiAttributes & EFI_MEMORY_CACHETYPE_MASK) {
    case EFI_MEMORY_UC:
      // Map to strongly ordered
      ArmAttributes = TT_DESCRIPTOR_SECTION_CACHE_POLICY_STRONGLY_ORDERED; // TEX[2:0] = 0, C=0, B=0
      break;

    case EFI_MEMORY_WC:
      // Map to normal non-cachable
      ArmAttributes = TT_DESCRIPTOR_SECTION_CACHE_POLICY_NON_CACHEABLE; // TEX [2:0]= 001 = 0x2, B=0, C=0
      break;

    case EFI_MEMORY_WT:
      // Write through with no-allocate
      ArmAttributes = TT_DESCRIPTOR_SECTION_CACHE_POLICY_WRITE_THROUGH_NO_ALLOC; // TEX [2:0] = 0, C=1, B=0
      break;

    case EFI_MEMORY_WB:
      // Write back (with allocate)
      ArmAttributes = TT_DESCRIPTOR_SECTION_CACHE_POLICY_WRITE_BACK_ALLOC; // TEX [2:0] = 001, C=1, B=1
      break;

    case EFI_MEMORY_UCE:
    default:
      ArmAttributes = TT_DESCRIPTOR_SECTION_TYPE_FAULT;
      break;
  }

  // Determine protection attributes
  if (EfiAttributes & EFI_MEMORY_RO) {
    ArmAttributes |= TT_DESCRIPTOR_SECTION_AP_RO_RO;
  } else {
    ArmAttributes |= TT_DESCRIPTOR_SECTION_AP_RW_RW;
  }

  // Determine eXecute Never attribute
  if (EfiAttributes & EFI_MEMORY_XP) {
    ArmAttributes |= TT_DESCRIPTOR_SECTION_XN_MASK;
  }

  return ArmAttributes;
}

EFI_STATUS
GetMemoryRegionPage (
  IN     UINT32                  *PageTable,
  IN OUT UINTN                   *BaseAddress,
  OUT    UINTN                   *RegionLength,
  OUT    UINTN                   *RegionAttributes
  )
{
  UINT32      PageAttributes;
  UINT32      TableIndex;
  UINT32      PageDescriptor;

  // Convert the section attributes into page attributes
  PageAttributes = ConvertSectionAttributesToPageAttributes (*RegionAttributes, 0);

  // Calculate index into first level translation table for start of modification
  TableIndex = ((*BaseAddress) & TT_DESCRIPTOR_PAGE_INDEX_MASK)  >> TT_DESCRIPTOR_PAGE_BASE_SHIFT;
  ASSERT (TableIndex < TRANSLATION_TABLE_PAGE_COUNT);

  // Go through the page table to find the end of the section
  for (; TableIndex < TRANSLATION_TABLE_PAGE_COUNT; TableIndex++) {
    // Get the section at the given index
    PageDescriptor = PageTable[TableIndex];

    if ((PageDescriptor & TT_DESCRIPTOR_PAGE_TYPE_MASK) == TT_DESCRIPTOR_PAGE_TYPE_FAULT) {
      // Case: End of the boundary of the region
      return EFI_SUCCESS;
    } else if ((PageDescriptor & TT_DESCRIPTOR_PAGE_TYPE_PAGE) == TT_DESCRIPTOR_PAGE_TYPE_PAGE) {
      if ((PageDescriptor & TT_DESCRIPTOR_PAGE_ATTRIBUTE_MASK) == PageAttributes) {
        *RegionLength = *RegionLength + TT_DESCRIPTOR_PAGE_SIZE;
      } else {
        // Case: End of the boundary of the region
        return EFI_SUCCESS;
      }
    } else {
      // We do not support Large Page yet. We return EFI_SUCCESS that means end of the region.
      ASSERT(0);
      return EFI_SUCCESS;
    }
  }

  return EFI_NOT_FOUND;
}

EFI_STATUS
GetMemoryRegion (
  IN OUT UINTN                   *BaseAddress,
  OUT    UINTN                   *RegionLength,
  OUT    UINTN                   *RegionAttributes
  )
{
  EFI_STATUS                  Status;
  UINT32                      TableIndex;
  UINT32                      PageAttributes;
  UINT32                      PageTableIndex;
  UINT32                      SectionDescriptor;
  ARM_FIRST_LEVEL_DESCRIPTOR *FirstLevelTable;
  UINT32                     *PageTable;

  // Initialize the arguments
  *RegionLength = 0;

  // Obtain page table base
  FirstLevelTable = (ARM_FIRST_LEVEL_DESCRIPTOR *)ArmGetTTBR0BaseAddress ();

  // Calculate index into first level translation table for start of modification
  TableIndex = TT_DESCRIPTOR_SECTION_BASE_ADDRESS (*BaseAddress) >> TT_DESCRIPTOR_SECTION_BASE_SHIFT;
  ASSERT (TableIndex < TRANSLATION_TABLE_SECTION_COUNT);

  // Get the section at the given index
  SectionDescriptor = FirstLevelTable[TableIndex];

  // If 'BaseAddress' belongs to the section then round it to the section boundary
  if (((SectionDescriptor & TT_DESCRIPTOR_SECTION_TYPE_MASK) == TT_DESCRIPTOR_SECTION_TYPE_SECTION) ||
      ((SectionDescriptor & TT_DESCRIPTOR_SECTION_TYPE_MASK) == TT_DESCRIPTOR_SECTION_TYPE_SUPERSECTION))
  {
    *BaseAddress = (*BaseAddress) & TT_DESCRIPTOR_SECTION_BASE_ADDRESS_MASK;
    *RegionAttributes = SectionDescriptor & TT_DESCRIPTOR_SECTION_ATTRIBUTE_MASK;
  } else {
    // Otherwise, we round it to the page boundary
    *BaseAddress = (*BaseAddress) & TT_DESCRIPTOR_PAGE_BASE_ADDRESS_MASK;

    // Get the attribute at the page table level (Level 2)
    PageTable = (UINT32*)(SectionDescriptor & TT_DESCRIPTOR_SECTION_PAGETABLE_ADDRESS_MASK);

    // Calculate index into first level translation table for start of modification
    PageTableIndex = ((*BaseAddress) & TT_DESCRIPTOR_PAGE_INDEX_MASK)  >> TT_DESCRIPTOR_PAGE_BASE_SHIFT;
    ASSERT (PageTableIndex < TRANSLATION_TABLE_PAGE_COUNT);

    PageAttributes = PageTable[PageTableIndex] & TT_DESCRIPTOR_PAGE_ATTRIBUTE_MASK;
    *RegionAttributes = TT_DESCRIPTOR_CONVERT_TO_SECTION_CACHE_POLICY (PageAttributes, 0) |
                        TT_DESCRIPTOR_CONVERT_TO_SECTION_AP (PageAttributes);
  }

  for (;TableIndex < TRANSLATION_TABLE_SECTION_COUNT; TableIndex++) {
    // Get the section at the given index
    SectionDescriptor = FirstLevelTable[TableIndex];

    // If the entry is a level-2 page table then we scan it to find the end of the region
    if (TT_DESCRIPTOR_SECTION_TYPE_IS_PAGE_TABLE (SectionDescriptor)) {
      // Extract the page table location from the descriptor
      PageTable = (UINT32*)(SectionDescriptor & TT_DESCRIPTOR_SECTION_PAGETABLE_ADDRESS_MASK);

      // Scan the page table to find the end of the region.
      Status = GetMemoryRegionPage (PageTable, BaseAddress, RegionLength, RegionAttributes);

      // If we have found the end of the region (Status == EFI_SUCCESS) then we exit the for-loop
      if (Status == EFI_SUCCESS) {
        break;
      }
    } else if (((SectionDescriptor & TT_DESCRIPTOR_SECTION_TYPE_MASK) == TT_DESCRIPTOR_SECTION_TYPE_SECTION) ||
               ((SectionDescriptor & TT_DESCRIPTOR_SECTION_TYPE_MASK) == TT_DESCRIPTOR_SECTION_TYPE_SUPERSECTION)) {
      if ((SectionDescriptor & TT_DESCRIPTOR_SECTION_ATTRIBUTE_MASK) != *RegionAttributes) {
        // If the attributes of the section differ from the one targeted then we exit the loop
        break;
      } else {
        *RegionLength = *RegionLength + TT_DESCRIPTOR_SECTION_SIZE;
      }
    } else {
      // If we are on an invalid section then it means it is the end of our section.
      break;
    }
  }

  return EFI_SUCCESS;
}