reactos/sdk/lib/cmlib/hiveinit.c
Hermès Bélusca-Maïto 8ccd435eb0
[SDK:CMLIB] HvGetCell is a macro calling the hive's GetCellRoutine callback.
In principle there should be different get-cell routines, depending
on the type of the hive (given by the OperationType parameter of
HvInitialize): for flat hives, memory-mapped hives, etc.
For now in ReactOS we only support a restricted subset of these,
therefore we are still happy with a single get-cell callback...
This may change in the future.
2022-03-27 18:37:16 +02:00

650 lines
18 KiB
C

/*
* PROJECT: Registry manipulation library
* LICENSE: GPL - See COPYING in the top level directory
* COPYRIGHT: Copyright 2005 Filip Navara <navaraf@reactos.org>
* Copyright 2001 - 2005 Eric Kohl
*/
#include "cmlib.h"
#define NDEBUG
#include <debug.h>
/**
* @name HvpVerifyHiveHeader
*
* Internal function to verify that a hive header has valid format.
*/
BOOLEAN CMAPI
HvpVerifyHiveHeader(
IN PHBASE_BLOCK BaseBlock)
{
if (BaseBlock->Signature != HV_HBLOCK_SIGNATURE ||
BaseBlock->Major != HSYS_MAJOR ||
BaseBlock->Minor < HSYS_MINOR ||
BaseBlock->Type != HFILE_TYPE_PRIMARY ||
BaseBlock->Format != HBASE_FORMAT_MEMORY ||
BaseBlock->Cluster != 1 ||
BaseBlock->Sequence1 != BaseBlock->Sequence2 ||
HvpHiveHeaderChecksum(BaseBlock) != BaseBlock->CheckSum)
{
DPRINT1("Verify Hive Header failed:\n");
DPRINT1(" Signature: 0x%x, expected 0x%x; Major: 0x%x, expected 0x%x\n",
BaseBlock->Signature, HV_HBLOCK_SIGNATURE, BaseBlock->Major, HSYS_MAJOR);
DPRINT1(" Minor: 0x%x expected to be >= 0x%x; Type: 0x%x, expected 0x%x\n",
BaseBlock->Minor, HSYS_MINOR, BaseBlock->Type, HFILE_TYPE_PRIMARY);
DPRINT1(" Format: 0x%x, expected 0x%x; Cluster: 0x%x, expected 1\n",
BaseBlock->Format, HBASE_FORMAT_MEMORY, BaseBlock->Cluster);
DPRINT1(" Sequence: 0x%x, expected 0x%x; Checksum: 0x%x, expected 0x%x\n",
BaseBlock->Sequence1, BaseBlock->Sequence2,
HvpHiveHeaderChecksum(BaseBlock), BaseBlock->CheckSum);
return FALSE;
}
return TRUE;
}
/**
* @name HvpFreeHiveBins
*
* Internal function to free all bin storage associated with a hive descriptor.
*/
VOID CMAPI
HvpFreeHiveBins(
PHHIVE Hive)
{
ULONG i;
PHBIN Bin;
ULONG Storage;
for (Storage = 0; Storage < Hive->StorageTypeCount; Storage++)
{
Bin = NULL;
for (i = 0; i < Hive->Storage[Storage].Length; i++)
{
if (Hive->Storage[Storage].BlockList[i].BinAddress == (ULONG_PTR)NULL)
continue;
if (Hive->Storage[Storage].BlockList[i].BinAddress != (ULONG_PTR)Bin)
{
Bin = (PHBIN)Hive->Storage[Storage].BlockList[i].BinAddress;
Hive->Free((PHBIN)Hive->Storage[Storage].BlockList[i].BinAddress, 0);
}
Hive->Storage[Storage].BlockList[i].BinAddress = (ULONG_PTR)NULL;
Hive->Storage[Storage].BlockList[i].BlockAddress = (ULONG_PTR)NULL;
}
if (Hive->Storage[Storage].Length)
Hive->Free(Hive->Storage[Storage].BlockList, 0);
}
}
/**
* @name HvpAllocBaseBlockAligned
*
* Internal helper function to allocate cluster-aligned hive base blocks.
*/
static __inline PHBASE_BLOCK
HvpAllocBaseBlockAligned(
IN PHHIVE Hive,
IN BOOLEAN Paged,
IN ULONG Tag)
{
PHBASE_BLOCK BaseBlock;
ULONG Alignment;
ASSERT(sizeof(HBASE_BLOCK) >= (HSECTOR_SIZE * Hive->Cluster));
/* Allocate the buffer */
BaseBlock = Hive->Allocate(Hive->BaseBlockAlloc, Paged, Tag);
if (!BaseBlock) return NULL;
/* Check for, and enforce, alignment */
Alignment = Hive->Cluster * HSECTOR_SIZE -1;
if ((ULONG_PTR)BaseBlock & Alignment)
{
/* Free the old header and reallocate a new one, always paged */
Hive->Free(BaseBlock, Hive->BaseBlockAlloc);
BaseBlock = Hive->Allocate(PAGE_SIZE, TRUE, Tag);
if (!BaseBlock) return NULL;
Hive->BaseBlockAlloc = PAGE_SIZE;
}
return BaseBlock;
}
/**
* @name HvpInitFileName
*
* Internal function to initialize the UNICODE NULL-terminated hive file name
* member of a hive header by copying the last 31 characters of the file name.
* Mainly used for debugging purposes.
*/
static VOID
HvpInitFileName(
IN OUT PHBASE_BLOCK BaseBlock,
IN PCUNICODE_STRING FileName OPTIONAL)
{
ULONG_PTR Offset;
SIZE_T Length;
/* Always NULL-initialize */
RtlZeroMemory(BaseBlock->FileName, (HIVE_FILENAME_MAXLEN + 1) * sizeof(WCHAR));
/* Copy the 31 last characters of the hive file name if any */
if (!FileName) return;
if (FileName->Length / sizeof(WCHAR) <= HIVE_FILENAME_MAXLEN)
{
Offset = 0;
Length = FileName->Length;
}
else
{
Offset = FileName->Length / sizeof(WCHAR) - HIVE_FILENAME_MAXLEN;
Length = HIVE_FILENAME_MAXLEN * sizeof(WCHAR);
}
RtlCopyMemory(BaseBlock->FileName, FileName->Buffer + Offset, Length);
}
/**
* @name HvpCreateHive
*
* Internal helper function to initialize a hive descriptor structure
* for a newly created hive in memory.
*
* @see HvInitialize
*/
NTSTATUS CMAPI
HvpCreateHive(
IN OUT PHHIVE RegistryHive,
IN PCUNICODE_STRING FileName OPTIONAL)
{
PHBASE_BLOCK BaseBlock;
ULONG Index;
/* Allocate the base block */
BaseBlock = HvpAllocBaseBlockAligned(RegistryHive, FALSE, TAG_CM);
if (BaseBlock == NULL)
return STATUS_NO_MEMORY;
/* Clear it */
RtlZeroMemory(BaseBlock, RegistryHive->BaseBlockAlloc);
BaseBlock->Signature = HV_HBLOCK_SIGNATURE;
BaseBlock->Major = HSYS_MAJOR;
BaseBlock->Minor = HSYS_MINOR;
BaseBlock->Type = HFILE_TYPE_PRIMARY;
BaseBlock->Format = HBASE_FORMAT_MEMORY;
BaseBlock->Cluster = 1;
BaseBlock->RootCell = HCELL_NIL;
BaseBlock->Length = 0;
BaseBlock->Sequence1 = 1;
BaseBlock->Sequence2 = 1;
BaseBlock->TimeStamp.QuadPart = 0ULL;
/*
* No need to compute the checksum since
* the hive resides only in memory so far.
*/
BaseBlock->CheckSum = 0;
/* Set default boot type */
BaseBlock->BootType = 0;
/* Setup hive data */
RegistryHive->BaseBlock = BaseBlock;
RegistryHive->Version = BaseBlock->Minor; // == HSYS_MINOR
for (Index = 0; Index < 24; Index++)
{
RegistryHive->Storage[Stable].FreeDisplay[Index] = HCELL_NIL;
RegistryHive->Storage[Volatile].FreeDisplay[Index] = HCELL_NIL;
}
HvpInitFileName(BaseBlock, FileName);
return STATUS_SUCCESS;
}
/**
* @name HvpInitializeMemoryHive
*
* Internal helper function to initialize hive descriptor structure for
* an existing hive stored in memory. The data of the hive is copied
* and it is prepared for read/write access.
*
* @see HvInitialize
*/
NTSTATUS CMAPI
HvpInitializeMemoryHive(
PHHIVE Hive,
PHBASE_BLOCK ChunkBase,
IN PCUNICODE_STRING FileName OPTIONAL)
{
SIZE_T BlockIndex;
PHBIN Bin, NewBin;
ULONG i;
ULONG BitmapSize;
PULONG BitmapBuffer;
SIZE_T ChunkSize;
ChunkSize = ChunkBase->Length;
DPRINT("ChunkSize: %zx\n", ChunkSize);
if (ChunkSize < sizeof(HBASE_BLOCK) ||
!HvpVerifyHiveHeader(ChunkBase))
{
DPRINT1("Registry is corrupt: ChunkSize 0x%zx < sizeof(HBASE_BLOCK) 0x%zx, "
"or HvpVerifyHiveHeader() failed\n", ChunkSize, sizeof(HBASE_BLOCK));
return STATUS_REGISTRY_CORRUPT;
}
/* Allocate the base block */
Hive->BaseBlock = HvpAllocBaseBlockAligned(Hive, FALSE, TAG_CM);
if (Hive->BaseBlock == NULL)
return STATUS_NO_MEMORY;
RtlCopyMemory(Hive->BaseBlock, ChunkBase, sizeof(HBASE_BLOCK));
/* Setup hive data */
Hive->Version = ChunkBase->Minor;
/*
* Build a block list from the in-memory chunk and copy the data as
* we go.
*/
Hive->Storage[Stable].Length = (ULONG)(ChunkSize / HBLOCK_SIZE);
Hive->Storage[Stable].BlockList =
Hive->Allocate(Hive->Storage[Stable].Length *
sizeof(HMAP_ENTRY), FALSE, TAG_CM);
if (Hive->Storage[Stable].BlockList == NULL)
{
DPRINT1("Allocating block list failed\n");
Hive->Free(Hive->BaseBlock, Hive->BaseBlockAlloc);
return STATUS_NO_MEMORY;
}
for (BlockIndex = 0; BlockIndex < Hive->Storage[Stable].Length; )
{
Bin = (PHBIN)((ULONG_PTR)ChunkBase + (BlockIndex + 1) * HBLOCK_SIZE);
if (Bin->Signature != HV_HBIN_SIGNATURE ||
(Bin->Size % HBLOCK_SIZE) != 0)
{
DPRINT1("Invalid bin at BlockIndex %lu, Signature 0x%x, Size 0x%x\n",
(unsigned long)BlockIndex, (unsigned)Bin->Signature, (unsigned)Bin->Size);
Hive->Free(Hive->Storage[Stable].BlockList, 0);
Hive->Free(Hive->BaseBlock, Hive->BaseBlockAlloc);
return STATUS_REGISTRY_CORRUPT;
}
NewBin = Hive->Allocate(Bin->Size, TRUE, TAG_CM);
if (NewBin == NULL)
{
Hive->Free(Hive->Storage[Stable].BlockList, 0);
Hive->Free(Hive->BaseBlock, Hive->BaseBlockAlloc);
return STATUS_NO_MEMORY;
}
Hive->Storage[Stable].BlockList[BlockIndex].BinAddress = (ULONG_PTR)NewBin;
Hive->Storage[Stable].BlockList[BlockIndex].BlockAddress = (ULONG_PTR)NewBin;
RtlCopyMemory(NewBin, Bin, Bin->Size);
if (Bin->Size > HBLOCK_SIZE)
{
for (i = 1; i < Bin->Size / HBLOCK_SIZE; i++)
{
Hive->Storage[Stable].BlockList[BlockIndex + i].BinAddress = (ULONG_PTR)NewBin;
Hive->Storage[Stable].BlockList[BlockIndex + i].BlockAddress =
((ULONG_PTR)NewBin + (i * HBLOCK_SIZE));
}
}
BlockIndex += Bin->Size / HBLOCK_SIZE;
}
if (HvpCreateHiveFreeCellList(Hive))
{
HvpFreeHiveBins(Hive);
Hive->Free(Hive->BaseBlock, Hive->BaseBlockAlloc);
return STATUS_NO_MEMORY;
}
BitmapSize = ROUND_UP(Hive->Storage[Stable].Length,
sizeof(ULONG) * 8) / 8;
BitmapBuffer = (PULONG)Hive->Allocate(BitmapSize, TRUE, TAG_CM);
if (BitmapBuffer == NULL)
{
HvpFreeHiveBins(Hive);
Hive->Free(Hive->BaseBlock, Hive->BaseBlockAlloc);
return STATUS_NO_MEMORY;
}
RtlInitializeBitMap(&Hive->DirtyVector, BitmapBuffer, BitmapSize * 8);
RtlClearAllBits(&Hive->DirtyVector);
HvpInitFileName(Hive->BaseBlock, FileName);
return STATUS_SUCCESS;
}
/**
* @name HvpInitializeFlatHive
*
* Internal helper function to initialize hive descriptor structure for
* a hive stored in memory. The in-memory data of the hive are directly
* used and it is read-only accessible.
*
* @see HvInitialize
*/
NTSTATUS CMAPI
HvpInitializeFlatHive(
PHHIVE Hive,
PHBASE_BLOCK ChunkBase)
{
if (!HvpVerifyHiveHeader(ChunkBase))
return STATUS_REGISTRY_CORRUPT;
/* Setup hive data */
Hive->BaseBlock = ChunkBase;
Hive->Version = ChunkBase->Minor;
Hive->Flat = TRUE;
Hive->ReadOnly = TRUE;
Hive->StorageTypeCount = 1;
/* Set default boot type */
ChunkBase->BootType = 0;
return STATUS_SUCCESS;
}
typedef enum _RESULT
{
NotHive,
Fail,
NoMemory,
HiveSuccess,
RecoverHeader,
RecoverData,
SelfHeal
} RESULT;
RESULT CMAPI
HvpGetHiveHeader(IN PHHIVE Hive,
IN PHBASE_BLOCK *HiveBaseBlock,
IN PLARGE_INTEGER TimeStamp)
{
PHBASE_BLOCK BaseBlock;
ULONG Result;
ULONG Offset = 0;
ASSERT(sizeof(HBASE_BLOCK) >= (HSECTOR_SIZE * Hive->Cluster));
/* Assume failure and allocate the base block */
*HiveBaseBlock = NULL;
BaseBlock = HvpAllocBaseBlockAligned(Hive, TRUE, TAG_CM);
if (!BaseBlock) return NoMemory;
/* Clear it */
RtlZeroMemory(BaseBlock, sizeof(HBASE_BLOCK));
/* Now read it from disk */
Result = Hive->FileRead(Hive,
HFILE_TYPE_PRIMARY,
&Offset,
BaseBlock,
Hive->Cluster * HSECTOR_SIZE);
/* Couldn't read: assume it's not a hive */
if (!Result) return NotHive;
/* Do validation */
if (!HvpVerifyHiveHeader(BaseBlock)) return NotHive;
/* Return information */
*HiveBaseBlock = BaseBlock;
*TimeStamp = BaseBlock->TimeStamp;
return HiveSuccess;
}
NTSTATUS CMAPI
HvLoadHive(IN PHHIVE Hive,
IN PCUNICODE_STRING FileName OPTIONAL)
{
NTSTATUS Status;
PHBASE_BLOCK BaseBlock = NULL;
ULONG Result;
LARGE_INTEGER TimeStamp;
ULONG Offset = 0;
PVOID HiveData;
ULONG FileSize;
/* Get the hive header */
Result = HvpGetHiveHeader(Hive, &BaseBlock, &TimeStamp);
switch (Result)
{
/* Out of memory */
case NoMemory:
/* Fail */
return STATUS_INSUFFICIENT_RESOURCES;
/* Not a hive */
case NotHive:
/* Fail */
return STATUS_NOT_REGISTRY_FILE;
/* Has recovery data */
case RecoverData:
case RecoverHeader:
/* Fail */
return STATUS_REGISTRY_CORRUPT;
}
/* Set default boot type */
BaseBlock->BootType = 0;
/* Setup hive data */
Hive->BaseBlock = BaseBlock;
Hive->Version = BaseBlock->Minor;
/* Allocate a buffer large enough to hold the hive */
FileSize = HBLOCK_SIZE + BaseBlock->Length; // == sizeof(HBASE_BLOCK) + BaseBlock->Length;
HiveData = Hive->Allocate(FileSize, TRUE, TAG_CM);
if (!HiveData)
{
Hive->Free(BaseBlock, Hive->BaseBlockAlloc);
return STATUS_INSUFFICIENT_RESOURCES;
}
/* Now read the whole hive */
Result = Hive->FileRead(Hive,
HFILE_TYPE_PRIMARY,
&Offset,
HiveData,
FileSize);
if (!Result)
{
Hive->Free(HiveData, FileSize);
Hive->Free(BaseBlock, Hive->BaseBlockAlloc);
return STATUS_NOT_REGISTRY_FILE;
}
// This is a HACK!
/* Free our base block... it's usless in this implementation */
Hive->Free(BaseBlock, Hive->BaseBlockAlloc);
/* Initialize the hive directly from memory */
Status = HvpInitializeMemoryHive(Hive, HiveData, FileName);
if (!NT_SUCCESS(Status))
Hive->Free(HiveData, FileSize);
return Status;
}
/**
* @name HvInitialize
*
* Allocate a new hive descriptor structure and intialize it.
*
* @param RegistryHive
* Output variable to store pointer to the hive descriptor.
* @param OperationType
* - HV_OPERATION_CREATE_HIVE
* Create a new hive for read/write access.
* - HV_OPERATION_MEMORY
* Load and copy in-memory hive for read/write access. The
* pointer to data passed to this routine can be freed after
* the function is executed.
* - HV_OPERATION_MEMORY_INPLACE
* Load an in-memory hive for read-only access. The pointer
* to data passed to this routine MUSTN'T be freed until
* HvFree is called.
* @param ChunkBase
* Pointer to hive data.
* @param ChunkSize
* Size of passed hive data.
*
* @return
* STATUS_NO_MEMORY - A memory allocation failed.
* STATUS_REGISTRY_CORRUPT - Registry corruption was detected.
* STATUS_SUCCESS
*
* @see HvFree
*/
NTSTATUS CMAPI
HvInitialize(
PHHIVE RegistryHive,
ULONG OperationType,
ULONG HiveFlags,
ULONG FileType,
PVOID HiveData OPTIONAL,
PALLOCATE_ROUTINE Allocate,
PFREE_ROUTINE Free,
PFILE_SET_SIZE_ROUTINE FileSetSize,
PFILE_WRITE_ROUTINE FileWrite,
PFILE_READ_ROUTINE FileRead,
PFILE_FLUSH_ROUTINE FileFlush,
ULONG Cluster OPTIONAL,
PCUNICODE_STRING FileName OPTIONAL)
{
NTSTATUS Status;
PHHIVE Hive = RegistryHive;
/*
* Create a new hive structure that will hold all the maintenance data.
*/
RtlZeroMemory(Hive, sizeof(HHIVE));
Hive->Signature = HV_HHIVE_SIGNATURE;
Hive->Allocate = Allocate;
Hive->Free = Free;
Hive->FileSetSize = FileSetSize;
Hive->FileWrite = FileWrite;
Hive->FileRead = FileRead;
Hive->FileFlush = FileFlush;
Hive->RefreshCount = 0;
Hive->StorageTypeCount = HTYPE_COUNT;
Hive->Cluster = Cluster;
Hive->BaseBlockAlloc = sizeof(HBASE_BLOCK); // == HBLOCK_SIZE
Hive->Version = HSYS_MINOR;
#if (NTDDI_VERSION < NTDDI_VISTA)
Hive->Log = (FileType == HFILE_TYPE_LOG);
#endif
Hive->HiveFlags = HiveFlags & ~HIVE_NOLAZYFLUSH;
// TODO: The CellRoutines point to different callbacks
// depending on the OperationType.
Hive->GetCellRoutine = HvpGetCellData;
Hive->ReleaseCellRoutine = NULL;
switch (OperationType)
{
case HINIT_CREATE:
Status = HvpCreateHive(Hive, FileName);
break;
case HINIT_MEMORY:
Status = HvpInitializeMemoryHive(Hive, HiveData, FileName);
break;
case HINIT_FLAT:
Status = HvpInitializeFlatHive(Hive, HiveData);
break;
case HINIT_FILE:
{
Status = HvLoadHive(Hive, FileName);
if ((Status != STATUS_SUCCESS) &&
(Status != STATUS_REGISTRY_RECOVERED))
{
/* Unrecoverable failure */
return Status;
}
/* Check for previous damage */
ASSERT(Status != STATUS_REGISTRY_RECOVERED);
break;
}
case HINIT_MEMORY_INPLACE:
// Status = HvpInitializeMemoryInplaceHive(Hive, HiveData);
// break;
case HINIT_MAPFILE:
default:
/* FIXME: A better return status value is needed */
Status = STATUS_NOT_IMPLEMENTED;
ASSERT(FALSE);
}
if (!NT_SUCCESS(Status)) return Status;
/* HACK: ROS: Init root key cell and prepare the hive */
// r31253
// if (OperationType == HINIT_CREATE) CmCreateRootNode(Hive, L"");
if (OperationType != HINIT_CREATE) CmPrepareHive(Hive);
return Status;
}
/**
* @name HvFree
*
* Free all stroage and handles associated with hive descriptor.
* But do not free the hive descriptor itself.
*/
VOID CMAPI
HvFree(
PHHIVE RegistryHive)
{
if (!RegistryHive->ReadOnly)
{
/* Release hive bitmap */
if (RegistryHive->DirtyVector.Buffer)
{
RegistryHive->Free(RegistryHive->DirtyVector.Buffer, 0);
}
HvpFreeHiveBins(RegistryHive);
/* Free the BaseBlock */
if (RegistryHive->BaseBlock)
{
RegistryHive->Free(RegistryHive->BaseBlock, RegistryHive->BaseBlockAlloc);
RegistryHive->BaseBlock = NULL;
}
}
}
/* EOF */