mirror of
https://github.com/CloverHackyColor/CloverBootloader.git
synced 2024-12-01 12:53:27 +01:00
434 lines
14 KiB
C
434 lines
14 KiB
C
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/*++
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Copyright (c) 2009, Hewlett-Packard Company. All rights reserved.<BR>
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Portions copyright (c) 2010, Apple Inc. All rights reserved.<BR>
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Portions copyright (c) 2011-2021, Arm Limited. All rights reserved.<BR>
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Copyright (c) 2017, Intel Corporation. All rights reserved.<BR>
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SPDX-License-Identifier: BSD-2-Clause-Patent
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--*/
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#include <Library/MemoryAllocationLib.h>
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#include "CpuDxe.h"
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#define INVALID_ENTRY ((UINT32)~0)
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#define MIN_T0SZ 16
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#define BITS_PER_LEVEL 9
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STATIC
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VOID
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GetRootTranslationTableInfo (
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IN UINTN T0SZ,
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OUT UINTN *RootTableLevel,
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OUT UINTN *RootTableEntryCount
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)
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{
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*RootTableLevel = (T0SZ - MIN_T0SZ) / BITS_PER_LEVEL;
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*RootTableEntryCount = TT_ENTRY_COUNT >> (T0SZ - MIN_T0SZ) % BITS_PER_LEVEL;
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}
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STATIC
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UINT64
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PageAttributeToGcdAttribute (
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IN UINT64 PageAttributes
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)
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{
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UINT64 GcdAttributes;
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switch (PageAttributes & TT_ATTR_INDX_MASK) {
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case TT_ATTR_INDX_DEVICE_MEMORY:
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GcdAttributes = EFI_MEMORY_UC;
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break;
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case TT_ATTR_INDX_MEMORY_NON_CACHEABLE:
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GcdAttributes = EFI_MEMORY_WC;
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break;
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case TT_ATTR_INDX_MEMORY_WRITE_THROUGH:
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GcdAttributes = EFI_MEMORY_WT;
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break;
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case TT_ATTR_INDX_MEMORY_WRITE_BACK:
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GcdAttributes = EFI_MEMORY_WB;
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break;
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default:
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DEBUG ((
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DEBUG_ERROR,
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"PageAttributeToGcdAttribute: PageAttributes:0x%lX not supported.\n",
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PageAttributes
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));
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ASSERT (0);
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// The Global Coherency Domain (GCD) value is defined as a bit set.
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// Returning 0 means no attribute has been set.
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GcdAttributes = 0;
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}
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// Determine protection attributes
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if (((PageAttributes & TT_AP_MASK) == TT_AP_NO_RO) ||
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((PageAttributes & TT_AP_MASK) == TT_AP_RO_RO))
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{
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// Read only cases map to write-protect
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GcdAttributes |= EFI_MEMORY_RO;
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}
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// Process eXecute Never attribute
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if ((PageAttributes & (TT_PXN_MASK | TT_UXN_MASK)) != 0) {
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GcdAttributes |= EFI_MEMORY_XP;
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}
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return GcdAttributes;
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}
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STATIC
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UINT64
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GetFirstPageAttribute (
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IN UINT64 *FirstLevelTableAddress,
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IN UINTN TableLevel
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)
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{
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UINT64 FirstEntry;
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// Get the first entry of the table
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FirstEntry = *FirstLevelTableAddress;
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if ((TableLevel != 3) && ((FirstEntry & TT_TYPE_MASK) == TT_TYPE_TABLE_ENTRY)) {
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// Only valid for Levels 0, 1 and 2
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// Get the attribute of the subsequent table
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return GetFirstPageAttribute ((UINT64 *)(FirstEntry & TT_ADDRESS_MASK_DESCRIPTION_TABLE), TableLevel + 1);
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} else if (((FirstEntry & TT_TYPE_MASK) == TT_TYPE_BLOCK_ENTRY) ||
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((TableLevel == 3) && ((FirstEntry & TT_TYPE_MASK) == TT_TYPE_BLOCK_ENTRY_LEVEL3)))
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{
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return FirstEntry & TT_ATTR_INDX_MASK;
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} else {
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return INVALID_ENTRY;
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}
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}
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STATIC
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UINT64
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GetNextEntryAttribute (
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IN UINT64 *TableAddress,
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IN UINTN EntryCount,
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IN UINTN TableLevel,
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IN UINT64 BaseAddress,
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IN OUT UINT32 *PrevEntryAttribute,
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IN OUT UINT64 *StartGcdRegion
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)
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{
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UINTN Index;
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UINT64 Entry;
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UINT32 EntryAttribute;
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UINT32 EntryType;
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EFI_STATUS Status;
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UINTN NumberOfDescriptors;
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EFI_GCD_MEMORY_SPACE_DESCRIPTOR *MemorySpaceMap;
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// Get the memory space map from GCD
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MemorySpaceMap = NULL;
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Status = gDS->GetMemorySpaceMap (&NumberOfDescriptors, &MemorySpaceMap);
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ASSERT_EFI_ERROR (Status);
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// We cannot get more than 3-level page table
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ASSERT (TableLevel <= 3);
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// While the top level table might not contain TT_ENTRY_COUNT entries;
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// the subsequent ones should be filled up
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for (Index = 0; Index < EntryCount; Index++) {
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Entry = TableAddress[Index];
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EntryType = Entry & TT_TYPE_MASK;
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EntryAttribute = Entry & TT_ATTR_INDX_MASK;
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// If Entry is a Table Descriptor type entry then go through the sub-level table
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if ((EntryType == TT_TYPE_BLOCK_ENTRY) ||
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((TableLevel == 3) && (EntryType == TT_TYPE_BLOCK_ENTRY_LEVEL3)))
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{
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if ((*PrevEntryAttribute == INVALID_ENTRY) || (EntryAttribute != *PrevEntryAttribute)) {
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if (*PrevEntryAttribute != INVALID_ENTRY) {
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// Update GCD with the last region
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SetGcdMemorySpaceAttributes (
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MemorySpaceMap,
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NumberOfDescriptors,
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*StartGcdRegion,
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(BaseAddress + (Index * TT_ADDRESS_AT_LEVEL (TableLevel))) - *StartGcdRegion,
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PageAttributeToGcdAttribute (*PrevEntryAttribute)
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);
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}
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// Start of the new region
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*StartGcdRegion = BaseAddress + (Index * TT_ADDRESS_AT_LEVEL (TableLevel));
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*PrevEntryAttribute = EntryAttribute;
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} else {
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continue;
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}
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} else if (EntryType == TT_TYPE_TABLE_ENTRY) {
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// Table Entry type is only valid for Level 0, 1, 2
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ASSERT (TableLevel < 3);
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// Increase the level number and scan the sub-level table
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GetNextEntryAttribute (
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(UINT64 *)(Entry & TT_ADDRESS_MASK_DESCRIPTION_TABLE),
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TT_ENTRY_COUNT,
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TableLevel + 1,
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(BaseAddress + (Index * TT_ADDRESS_AT_LEVEL (TableLevel))),
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PrevEntryAttribute,
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StartGcdRegion
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);
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} else {
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if (*PrevEntryAttribute != INVALID_ENTRY) {
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// Update GCD with the last region
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SetGcdMemorySpaceAttributes (
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MemorySpaceMap,
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NumberOfDescriptors,
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*StartGcdRegion,
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(BaseAddress + (Index * TT_ADDRESS_AT_LEVEL (TableLevel))) - *StartGcdRegion,
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PageAttributeToGcdAttribute (*PrevEntryAttribute)
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);
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// Start of the new region
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*StartGcdRegion = BaseAddress + (Index * TT_ADDRESS_AT_LEVEL (TableLevel));
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*PrevEntryAttribute = INVALID_ENTRY;
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}
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}
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}
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FreePool (MemorySpaceMap);
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return BaseAddress + (EntryCount * TT_ADDRESS_AT_LEVEL (TableLevel));
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}
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EFI_STATUS
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SyncCacheConfig (
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IN EFI_CPU_ARCH_PROTOCOL *CpuProtocol
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)
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{
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EFI_STATUS Status;
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UINT32 PageAttribute;
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UINT64 *FirstLevelTableAddress;
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UINTN TableLevel;
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UINTN TableCount;
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UINTN NumberOfDescriptors;
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EFI_GCD_MEMORY_SPACE_DESCRIPTOR *MemorySpaceMap;
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UINTN Tcr;
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UINTN T0SZ;
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UINT64 BaseAddressGcdRegion;
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UINT64 EndAddressGcdRegion;
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// This code assumes MMU is enabled and filed with section translations
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ASSERT (ArmMmuEnabled ());
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//
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// Get the memory space map from GCD
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//
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MemorySpaceMap = NULL;
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Status = gDS->GetMemorySpaceMap (&NumberOfDescriptors, &MemorySpaceMap);
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ASSERT_EFI_ERROR (Status);
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// The GCD implementation maintains its own copy of the state of memory space attributes. GCD needs
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// to know what the initial memory space attributes are. The CPU Arch. Protocol does not provide a
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// GetMemoryAttributes function for GCD to get this so we must resort to calling GCD (as if we were
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// a client) to update its copy of the attributes. This is bad architecture and should be replaced
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// with a way for GCD to query the CPU Arch. driver of the existing memory space attributes instead.
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// Obtain page table base
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FirstLevelTableAddress = (UINT64 *)(ArmGetTTBR0BaseAddress ());
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// Get Translation Control Register value
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Tcr = ArmGetTCR ();
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// Get Address Region Size
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T0SZ = Tcr & TCR_T0SZ_MASK;
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// Get the level of the first table for the indicated Address Region Size
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GetRootTranslationTableInfo (T0SZ, &TableLevel, &TableCount);
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// First Attribute of the Page Tables
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PageAttribute = GetFirstPageAttribute (FirstLevelTableAddress, TableLevel);
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// We scan from the start of the memory map (ie: at the address 0x0)
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BaseAddressGcdRegion = 0x0;
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EndAddressGcdRegion = GetNextEntryAttribute (
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FirstLevelTableAddress,
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TableCount,
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TableLevel,
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BaseAddressGcdRegion,
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&PageAttribute,
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&BaseAddressGcdRegion
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);
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// Update GCD with the last region if valid
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if (PageAttribute != INVALID_ENTRY) {
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SetGcdMemorySpaceAttributes (
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MemorySpaceMap,
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NumberOfDescriptors,
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BaseAddressGcdRegion,
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EndAddressGcdRegion - BaseAddressGcdRegion,
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PageAttributeToGcdAttribute (PageAttribute)
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);
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}
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FreePool (MemorySpaceMap);
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return EFI_SUCCESS;
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}
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UINT64
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EfiAttributeToArmAttribute (
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IN UINT64 EfiAttributes
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)
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{
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UINT64 ArmAttributes;
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switch (EfiAttributes & EFI_MEMORY_CACHETYPE_MASK) {
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case EFI_MEMORY_UC:
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if (ArmReadCurrentEL () == AARCH64_EL2) {
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ArmAttributes = TT_ATTR_INDX_DEVICE_MEMORY | TT_XN_MASK;
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} else {
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ArmAttributes = TT_ATTR_INDX_DEVICE_MEMORY | TT_UXN_MASK | TT_PXN_MASK;
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}
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break;
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case EFI_MEMORY_WC:
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ArmAttributes = TT_ATTR_INDX_MEMORY_NON_CACHEABLE;
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break;
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case EFI_MEMORY_WT:
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ArmAttributes = TT_ATTR_INDX_MEMORY_WRITE_THROUGH | TT_SH_INNER_SHAREABLE;
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break;
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case EFI_MEMORY_WB:
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ArmAttributes = TT_ATTR_INDX_MEMORY_WRITE_BACK | TT_SH_INNER_SHAREABLE;
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break;
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default:
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ArmAttributes = TT_ATTR_INDX_MASK;
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}
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// Set the access flag to match the block attributes
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ArmAttributes |= TT_AF;
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// Determine protection attributes
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if ((EfiAttributes & EFI_MEMORY_RO) != 0) {
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ArmAttributes |= TT_AP_NO_RO;
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}
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// Process eXecute Never attribute
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if ((EfiAttributes & EFI_MEMORY_XP) != 0) {
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ArmAttributes |= TT_PXN_MASK;
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}
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return ArmAttributes;
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}
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// This function will recursively go down the page table to find the first block address linked to 'BaseAddress'.
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// And then the function will identify the size of the region that has the same page table attribute.
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EFI_STATUS
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GetMemoryRegionRec (
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IN UINT64 *TranslationTable,
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IN UINTN TableLevel,
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IN UINT64 *LastBlockEntry,
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IN OUT UINTN *BaseAddress,
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OUT UINTN *RegionLength,
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OUT UINTN *RegionAttributes
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)
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{
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EFI_STATUS Status;
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UINT64 *NextTranslationTable;
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UINT64 *BlockEntry;
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UINT64 BlockEntryType;
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UINT64 EntryType;
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if (TableLevel != 3) {
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BlockEntryType = TT_TYPE_BLOCK_ENTRY;
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} else {
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BlockEntryType = TT_TYPE_BLOCK_ENTRY_LEVEL3;
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}
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// Find the block entry linked to the Base Address
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BlockEntry = (UINT64 *)TT_GET_ENTRY_FOR_ADDRESS (TranslationTable, TableLevel, *BaseAddress);
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EntryType = *BlockEntry & TT_TYPE_MASK;
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if ((TableLevel < 3) && (EntryType == TT_TYPE_TABLE_ENTRY)) {
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NextTranslationTable = (UINT64 *)(*BlockEntry & TT_ADDRESS_MASK_DESCRIPTION_TABLE);
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// The entry is a page table, so we go to the next level
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Status = GetMemoryRegionRec (
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NextTranslationTable, // Address of the next level page table
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TableLevel + 1, // Next Page Table level
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(UINTN *)TT_LAST_BLOCK_ADDRESS (NextTranslationTable, TT_ENTRY_COUNT),
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BaseAddress,
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RegionLength,
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RegionAttributes
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);
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// In case of 'Success', it means the end of the block region has been found into the upper
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// level translation table
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if (!EFI_ERROR (Status)) {
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return EFI_SUCCESS;
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}
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// Now we processed the table move to the next entry
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BlockEntry++;
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} else if (EntryType == BlockEntryType) {
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// We have found the BlockEntry attached to the address. We save its start address (the start
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// address might be before the 'BaseAddress') and attributes
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*BaseAddress = *BaseAddress & ~(TT_ADDRESS_AT_LEVEL (TableLevel) - 1);
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*RegionLength = 0;
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*RegionAttributes = *BlockEntry & TT_ATTRIBUTES_MASK;
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} else {
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// We have an 'Invalid' entry
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return EFI_UNSUPPORTED;
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}
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while (BlockEntry <= LastBlockEntry) {
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if ((*BlockEntry & TT_ATTRIBUTES_MASK) == *RegionAttributes) {
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*RegionLength = *RegionLength + TT_BLOCK_ENTRY_SIZE_AT_LEVEL (TableLevel);
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} else {
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// In case we have found the end of the region we return success
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return EFI_SUCCESS;
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}
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BlockEntry++;
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}
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// If we have reached the end of the TranslationTable and we have not found the end of the region then
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// we return EFI_NOT_FOUND.
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// The caller will continue to look for the memory region at its level
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return EFI_NOT_FOUND;
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}
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EFI_STATUS
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GetMemoryRegion (
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IN OUT UINTN *BaseAddress,
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OUT UINTN *RegionLength,
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OUT UINTN *RegionAttributes
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)
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{
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EFI_STATUS Status;
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UINT64 *TranslationTable;
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UINTN TableLevel;
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UINTN EntryCount;
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UINTN T0SZ;
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ASSERT ((BaseAddress != NULL) && (RegionLength != NULL) && (RegionAttributes != NULL));
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TranslationTable = ArmGetTTBR0BaseAddress ();
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T0SZ = ArmGetTCR () & TCR_T0SZ_MASK;
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// Get the Table info from T0SZ
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GetRootTranslationTableInfo (T0SZ, &TableLevel, &EntryCount);
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Status = GetMemoryRegionRec (
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TranslationTable,
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TableLevel,
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(UINTN *)TT_LAST_BLOCK_ADDRESS (TranslationTable, EntryCount),
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BaseAddress,
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RegionLength,
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RegionAttributes
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);
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// If the region continues up to the end of the root table then GetMemoryRegionRec()
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// will return EFI_NOT_FOUND
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if (Status == EFI_NOT_FOUND) {
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return EFI_SUCCESS;
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} else {
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return Status;
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}
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}
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