reactos/sdk/lib/cmlib/hivecell.c
George Bișoc 578f2fc512
[NTOS:CM] Don't lazy flush the registry during unlocking operation
Whenever ReactOS finishes its operations onto the registry and unlocks it, a lazy flush is invoked to do an eventual flushing of the registry to the backing storage of the system. Except that... lazy flushing never comes into place.

This is because whenever CmpLazyFlush is called that sets up a timer which needs to expire in order to trigger the lazy flusher engine worker. However, registry locking/unlocking is a frequent occurrence, mainly when on desktop. Therefore as a matter of fact, CmpLazyFlush keeps removing and inserting the timer and the lazy flusher will never kick in that way.

Ironically the lazy flusher actually does the flushing when on USETUP installation phase because during text-mode setup installation in ReactOS the frequency of registry operations is actually less so the timer has the opportunity to expire and fire up the flusher.

In addition to that, we must queue a lazy flush when marking cells as dirty because such dirty data has to be flushed down to the media storage of the system. Of course, the real place where lazy flushing operation is done should be in a subset helper like HvMarkDirty that marks parts of a hive as dirty but since we do not have that, we'll be lazy flushing the registry during cells dirty marking instead for now.

CORE-18303
2022-12-23 19:45:13 +01:00

679 lines
19 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>
/* DECLARATIONS *************************************************************/
#if !defined(CMLIB_HOST) && !defined(_BLDR_)
VOID
NTAPI
CmpLazyFlush(VOID);
#endif
/* FUNCTIONS *****************************************************************/
static __inline PHCELL CMAPI
HvpGetCellHeader(
PHHIVE RegistryHive,
HCELL_INDEX CellIndex)
{
PVOID Block;
CMLTRACE(CMLIB_HCELL_DEBUG, "%s - Hive %p, CellIndex %08lx\n",
__FUNCTION__, RegistryHive, CellIndex);
ASSERT(CellIndex != HCELL_NIL);
if (!RegistryHive->Flat)
{
ULONG CellType = HvGetCellType(CellIndex);
ULONG CellBlock = HvGetCellBlock(CellIndex);
ULONG CellOffset = (CellIndex & HCELL_OFFSET_MASK) >> HCELL_OFFSET_SHIFT;
ASSERT(CellBlock < RegistryHive->Storage[CellType].Length);
Block = (PVOID)RegistryHive->Storage[CellType].BlockList[CellBlock].BlockAddress;
ASSERT(Block != NULL);
return (PHCELL)((ULONG_PTR)Block + CellOffset);
}
else
{
ASSERT(HvGetCellType(CellIndex) == Stable);
return (PHCELL)((ULONG_PTR)RegistryHive->BaseBlock + HBLOCK_SIZE +
CellIndex);
}
}
BOOLEAN CMAPI
HvIsCellAllocated(IN PHHIVE RegistryHive,
IN HCELL_INDEX CellIndex)
{
ULONG Type, Block;
/* If it's a flat hive, the cell is always allocated */
if (RegistryHive->Flat)
return TRUE;
/* Otherwise, get the type and make sure it's valid */
Type = HvGetCellType(CellIndex);
Block = HvGetCellBlock(CellIndex);
if (Block >= RegistryHive->Storage[Type].Length)
return FALSE;
/* Try to get the cell block */
if (RegistryHive->Storage[Type].BlockList[Block].BlockAddress)
return TRUE;
/* No valid block, fail */
return FALSE;
}
PCELL_DATA CMAPI
HvpGetCellData(
_In_ PHHIVE Hive,
_In_ HCELL_INDEX CellIndex)
{
return (PCELL_DATA)(HvpGetCellHeader(Hive, CellIndex) + 1);
}
static __inline LONG CMAPI
HvpGetCellFullSize(
PHHIVE RegistryHive,
PVOID Cell)
{
UNREFERENCED_PARAMETER(RegistryHive);
return ((PHCELL)Cell - 1)->Size;
}
LONG CMAPI
HvGetCellSize(IN PHHIVE Hive,
IN PVOID Address)
{
PHCELL CellHeader;
LONG Size;
UNREFERENCED_PARAMETER(Hive);
CellHeader = (PHCELL)Address - 1;
Size = CellHeader->Size * -1;
Size -= sizeof(HCELL);
return Size;
}
BOOLEAN CMAPI
HvMarkCellDirty(
PHHIVE RegistryHive,
HCELL_INDEX CellIndex,
BOOLEAN HoldingLock)
{
ULONG CellBlock;
ULONG CellLastBlock;
ASSERT(RegistryHive->ReadOnly == FALSE);
CMLTRACE(CMLIB_HCELL_DEBUG, "%s - Hive %p, CellIndex %08lx, HoldingLock %u\n",
__FUNCTION__, RegistryHive, CellIndex, HoldingLock);
if (HvGetCellType(CellIndex) != Stable)
return TRUE;
CellBlock = HvGetCellBlock(CellIndex);
CellLastBlock = HvGetCellBlock(CellIndex + HBLOCK_SIZE - 1);
RtlSetBits(&RegistryHive->DirtyVector,
CellBlock, CellLastBlock - CellBlock);
RegistryHive->DirtyCount++;
/*
* FIXME: Querying a lazy flush operation is needed to
* ensure that the dirty data is being flushed to disk
* accordingly. However, this operation has to be done
* in a helper like HvMarkDirty that marks specific parts
* of the hive as dirty. Since we do not have such kind
* of helper we have to perform an eventual lazy flush
* when marking cells as dirty here for the moment being,
* so that not only we flush dirty data but also write
* logs.
*/
#if !defined(CMLIB_HOST) && !defined(_BLDR_)
if (!(RegistryHive->HiveFlags & HIVE_NOLAZYFLUSH))
{
CmpLazyFlush();
}
#endif
return TRUE;
}
BOOLEAN CMAPI
HvIsCellDirty(IN PHHIVE Hive,
IN HCELL_INDEX Cell)
{
BOOLEAN IsDirty = FALSE;
/* Sanity checks */
ASSERT(Hive->ReadOnly == FALSE);
/* Volatile cells are always "dirty" */
if (HvGetCellType(Cell) == Volatile)
return TRUE;
/* Check if the dirty bit is set */
if (RtlCheckBit(&Hive->DirtyVector, Cell / HBLOCK_SIZE))
IsDirty = TRUE;
/* Return result as boolean*/
return IsDirty;
}
static __inline ULONG CMAPI
HvpComputeFreeListIndex(
ULONG Size)
{
ULONG Index;
static CCHAR FindFirstSet[128] = {
0, 0, 1, 1, 2, 2, 2, 2, 3, 3, 3, 3, 3, 3, 3, 3,
4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5,
5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5,
6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6,
6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6,
6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6,
6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6};
ASSERT(Size >= (1 << 3));
Index = (Size >> 3) - 1;
if (Index >= 16)
{
if (Index > 127)
Index = 23;
else
Index = FindFirstSet[Index] + 16;
}
return Index;
}
static NTSTATUS CMAPI
HvpAddFree(
PHHIVE RegistryHive,
PHCELL FreeBlock,
HCELL_INDEX FreeIndex)
{
PHCELL_INDEX FreeBlockData;
HSTORAGE_TYPE Storage;
ULONG Index;
ASSERT(RegistryHive != NULL);
ASSERT(FreeBlock != NULL);
Storage = HvGetCellType(FreeIndex);
Index = HvpComputeFreeListIndex((ULONG)FreeBlock->Size);
FreeBlockData = (PHCELL_INDEX)(FreeBlock + 1);
*FreeBlockData = RegistryHive->Storage[Storage].FreeDisplay[Index];
RegistryHive->Storage[Storage].FreeDisplay[Index] = FreeIndex;
/* FIXME: Eventually get rid of free bins. */
return STATUS_SUCCESS;
}
static VOID CMAPI
HvpRemoveFree(
PHHIVE RegistryHive,
PHCELL CellBlock,
HCELL_INDEX CellIndex)
{
PHCELL_INDEX FreeCellData;
PHCELL_INDEX pFreeCellOffset;
HSTORAGE_TYPE Storage;
ULONG Index, FreeListIndex;
ASSERT(RegistryHive->ReadOnly == FALSE);
Storage = HvGetCellType(CellIndex);
Index = HvpComputeFreeListIndex((ULONG)CellBlock->Size);
pFreeCellOffset = &RegistryHive->Storage[Storage].FreeDisplay[Index];
while (*pFreeCellOffset != HCELL_NIL)
{
FreeCellData = (PHCELL_INDEX)HvGetCell(RegistryHive, *pFreeCellOffset);
if (*pFreeCellOffset == CellIndex)
{
*pFreeCellOffset = *FreeCellData;
return;
}
pFreeCellOffset = FreeCellData;
}
/* Something bad happened, print a useful trace info and bugcheck */
CMLTRACE(CMLIB_HCELL_DEBUG, "-- beginning of HvpRemoveFree trace --\n");
CMLTRACE(CMLIB_HCELL_DEBUG, "block we are about to free: %08x\n", CellIndex);
CMLTRACE(CMLIB_HCELL_DEBUG, "chosen free list index: %u\n", Index);
for (FreeListIndex = 0; FreeListIndex < 24; FreeListIndex++)
{
CMLTRACE(CMLIB_HCELL_DEBUG, "free list [%u]: ", FreeListIndex);
pFreeCellOffset = &RegistryHive->Storage[Storage].FreeDisplay[FreeListIndex];
while (*pFreeCellOffset != HCELL_NIL)
{
CMLTRACE(CMLIB_HCELL_DEBUG, "%08x ", *pFreeCellOffset);
FreeCellData = (PHCELL_INDEX)HvGetCell(RegistryHive, *pFreeCellOffset);
pFreeCellOffset = FreeCellData;
}
CMLTRACE(CMLIB_HCELL_DEBUG, "\n");
}
CMLTRACE(CMLIB_HCELL_DEBUG, "-- end of HvpRemoveFree trace --\n");
ASSERT(FALSE);
}
static HCELL_INDEX CMAPI
HvpFindFree(
PHHIVE RegistryHive,
ULONG Size,
HSTORAGE_TYPE Storage)
{
PHCELL_INDEX FreeCellData;
HCELL_INDEX FreeCellOffset;
PHCELL_INDEX pFreeCellOffset;
ULONG Index;
for (Index = HvpComputeFreeListIndex(Size); Index < 24; Index++)
{
pFreeCellOffset = &RegistryHive->Storage[Storage].FreeDisplay[Index];
while (*pFreeCellOffset != HCELL_NIL)
{
FreeCellData = (PHCELL_INDEX)HvGetCell(RegistryHive, *pFreeCellOffset);
if ((ULONG)HvpGetCellFullSize(RegistryHive, FreeCellData) >= Size)
{
FreeCellOffset = *pFreeCellOffset;
*pFreeCellOffset = *FreeCellData;
return FreeCellOffset;
}
pFreeCellOffset = FreeCellData;
}
}
return HCELL_NIL;
}
NTSTATUS CMAPI
HvpCreateHiveFreeCellList(
PHHIVE Hive)
{
HCELL_INDEX BlockOffset;
PHCELL FreeBlock;
ULONG BlockIndex;
ULONG FreeOffset;
PHBIN Bin;
NTSTATUS Status;
ULONG Index;
/* Initialize the free cell list */
for (Index = 0; Index < 24; Index++)
{
Hive->Storage[Stable].FreeDisplay[Index] = HCELL_NIL;
Hive->Storage[Volatile].FreeDisplay[Index] = HCELL_NIL;
}
BlockOffset = 0;
BlockIndex = 0;
while (BlockIndex < Hive->Storage[Stable].Length)
{
Bin = (PHBIN)Hive->Storage[Stable].BlockList[BlockIndex].BinAddress;
/* Search free blocks and add to list */
FreeOffset = sizeof(HBIN);
while (FreeOffset < Bin->Size)
{
FreeBlock = (PHCELL)((ULONG_PTR)Bin + FreeOffset);
if (FreeBlock->Size > 0)
{
Status = HvpAddFree(Hive, FreeBlock, Bin->FileOffset + FreeOffset);
if (!NT_SUCCESS(Status))
return Status;
FreeOffset += FreeBlock->Size;
}
else
{
FreeOffset -= FreeBlock->Size;
}
}
BlockIndex += Bin->Size / HBLOCK_SIZE;
BlockOffset += Bin->Size;
}
return STATUS_SUCCESS;
}
HCELL_INDEX CMAPI
HvAllocateCell(
PHHIVE RegistryHive,
ULONG Size,
HSTORAGE_TYPE Storage,
HCELL_INDEX Vicinity)
{
PHCELL FreeCell;
HCELL_INDEX FreeCellOffset;
PHCELL NewCell;
PHBIN Bin;
ASSERT(RegistryHive->ReadOnly == FALSE);
CMLTRACE(CMLIB_HCELL_DEBUG, "%s - Hive %p, Size %x, %s, Vicinity %08lx\n",
__FUNCTION__, RegistryHive, Size, (Storage == 0) ? "Stable" : "Volatile", Vicinity);
/* Round to 16 bytes multiple. */
Size = ROUND_UP(Size + sizeof(HCELL), 16);
/* First search in free blocks. */
FreeCellOffset = HvpFindFree(RegistryHive, Size, Storage);
/* If no free cell was found we need to extend the hive file. */
if (FreeCellOffset == HCELL_NIL)
{
Bin = HvpAddBin(RegistryHive, Size, Storage);
if (Bin == NULL)
return HCELL_NIL;
FreeCellOffset = Bin->FileOffset + sizeof(HBIN);
FreeCellOffset |= Storage << HCELL_TYPE_SHIFT;
}
FreeCell = HvpGetCellHeader(RegistryHive, FreeCellOffset);
/* Split the block in two parts */
/* The free block that is created has to be at least
sizeof(HCELL) + sizeof(HCELL_INDEX) big, so that free
cell list code can work. Moreover we round cell sizes
to 16 bytes, so creating a smaller block would result in
a cell that would never be allocated. */
if ((ULONG)FreeCell->Size > Size + 16)
{
NewCell = (PHCELL)((ULONG_PTR)FreeCell + Size);
NewCell->Size = FreeCell->Size - Size;
FreeCell->Size = Size;
HvpAddFree(RegistryHive, NewCell, FreeCellOffset + Size);
if (Storage == Stable)
HvMarkCellDirty(RegistryHive, FreeCellOffset + Size, FALSE);
}
if (Storage == Stable)
HvMarkCellDirty(RegistryHive, FreeCellOffset, FALSE);
FreeCell->Size = -FreeCell->Size;
RtlZeroMemory(FreeCell + 1, Size - sizeof(HCELL));
CMLTRACE(CMLIB_HCELL_DEBUG, "%s - CellIndex %08lx\n",
__FUNCTION__, FreeCellOffset);
return FreeCellOffset;
}
HCELL_INDEX CMAPI
HvReallocateCell(
PHHIVE RegistryHive,
HCELL_INDEX CellIndex,
ULONG Size)
{
PVOID OldCell;
PVOID NewCell;
LONG OldCellSize;
HCELL_INDEX NewCellIndex;
HSTORAGE_TYPE Storage;
ASSERT(CellIndex != HCELL_NIL);
CMLTRACE(CMLIB_HCELL_DEBUG, "%s - Hive %p, CellIndex %08lx, Size %x\n",
__FUNCTION__, RegistryHive, CellIndex, Size);
Storage = HvGetCellType(CellIndex);
OldCell = HvGetCell(RegistryHive, CellIndex);
OldCellSize = HvGetCellSize(RegistryHive, OldCell);
ASSERT(OldCellSize > 0);
/*
* If new data size is larger than the current, destroy current
* data block and allocate a new one.
*
* FIXME: Merge with adjacent free cell if possible.
* FIXME: Implement shrinking.
*/
if (Size > (ULONG)OldCellSize)
{
NewCellIndex = HvAllocateCell(RegistryHive, Size, Storage, HCELL_NIL);
if (NewCellIndex == HCELL_NIL)
return HCELL_NIL;
NewCell = HvGetCell(RegistryHive, NewCellIndex);
RtlCopyMemory(NewCell, OldCell, (SIZE_T)OldCellSize);
HvFreeCell(RegistryHive, CellIndex);
return NewCellIndex;
}
return CellIndex;
}
VOID CMAPI
HvFreeCell(
PHHIVE RegistryHive,
HCELL_INDEX CellIndex)
{
PHCELL Free;
PHCELL Neighbor;
PHBIN Bin;
ULONG CellType;
ULONG CellBlock;
ASSERT(RegistryHive->ReadOnly == FALSE);
CMLTRACE(CMLIB_HCELL_DEBUG, "%s - Hive %p, CellIndex %08lx\n",
__FUNCTION__, RegistryHive, CellIndex);
Free = HvpGetCellHeader(RegistryHive, CellIndex);
ASSERT(Free->Size < 0);
Free->Size = -Free->Size;
CellType = HvGetCellType(CellIndex);
CellBlock = HvGetCellBlock(CellIndex);
/* FIXME: Merge free blocks */
Bin = (PHBIN)RegistryHive->Storage[CellType].BlockList[CellBlock].BinAddress;
if ((CellIndex & ~HCELL_TYPE_MASK) + Free->Size <
Bin->FileOffset + Bin->Size)
{
Neighbor = (PHCELL)((ULONG_PTR)Free + Free->Size);
if (Neighbor->Size > 0)
{
HvpRemoveFree(RegistryHive, Neighbor,
((HCELL_INDEX)((ULONG_PTR)Neighbor - (ULONG_PTR)Bin +
Bin->FileOffset)) | (CellIndex & HCELL_TYPE_MASK));
Free->Size += Neighbor->Size;
}
}
Neighbor = (PHCELL)(Bin + 1);
while (Neighbor < Free)
{
if (Neighbor->Size > 0)
{
if ((ULONG_PTR)Neighbor + Neighbor->Size == (ULONG_PTR)Free)
{
HCELL_INDEX NeighborCellIndex =
((HCELL_INDEX)((ULONG_PTR)Neighbor - (ULONG_PTR)Bin +
Bin->FileOffset)) | (CellIndex & HCELL_TYPE_MASK);
if (HvpComputeFreeListIndex(Neighbor->Size) !=
HvpComputeFreeListIndex(Neighbor->Size + Free->Size))
{
HvpRemoveFree(RegistryHive, Neighbor, NeighborCellIndex);
Neighbor->Size += Free->Size;
HvpAddFree(RegistryHive, Neighbor, NeighborCellIndex);
}
else
Neighbor->Size += Free->Size;
if (CellType == Stable)
HvMarkCellDirty(RegistryHive, NeighborCellIndex, FALSE);
return;
}
Neighbor = (PHCELL)((ULONG_PTR)Neighbor + Neighbor->Size);
}
else
{
Neighbor = (PHCELL)((ULONG_PTR)Neighbor - Neighbor->Size);
}
}
/* Add block to the list of free blocks */
HvpAddFree(RegistryHive, Free, CellIndex);
if (CellType == Stable)
HvMarkCellDirty(RegistryHive, CellIndex, FALSE);
}
#define CELL_REF_INCREMENT 10
BOOLEAN
CMAPI
HvTrackCellRef(
IN OUT PHV_TRACK_CELL_REF CellRef,
IN PHHIVE Hive,
IN HCELL_INDEX Cell)
{
PHV_HIVE_CELL_PAIR NewCellArray;
PAGED_CODE();
/* Sanity checks */
ASSERT(CellRef);
ASSERT(Hive);
ASSERT(Cell != HCELL_NIL);
/* NOTE: The hive cell is already referenced! */
/* Less than 4? Use the static array */
if (CellRef->StaticCount < STATIC_CELL_PAIR_COUNT)
{
/* Add the reference */
CellRef->StaticArray[CellRef->StaticCount].Hive = Hive;
CellRef->StaticArray[CellRef->StaticCount].Cell = Cell;
CellRef->StaticCount++;
return TRUE;
}
DPRINT("HvTrackCellRef: Static array full, use dynamic array.\n");
/* Sanity checks */
if (CellRef->Max == 0)
{
/* The dynamic array must not have been allocated already */
ASSERT(CellRef->CellArray == NULL);
ASSERT(CellRef->Count == 0);
}
else
{
/* The dynamic array must be allocated */
ASSERT(CellRef->CellArray);
}
ASSERT(CellRef->Count <= CellRef->Max);
if (CellRef->Count == CellRef->Max)
{
/* Allocate a new reference table */
NewCellArray = CmpAllocate((CellRef->Max + CELL_REF_INCREMENT) * sizeof(HV_HIVE_CELL_PAIR),
TRUE,
TAG_CM);
if (!NewCellArray)
{
DPRINT1("HvTrackCellRef: Cannot reallocate the reference table.\n");
/* We failed, dereference the hive cell */
HvReleaseCell(Hive, Cell);
return FALSE;
}
/* Free the old reference table and use the new one */
if (CellRef->CellArray)
{
/* Copy the handles from the old table to the new one */
RtlCopyMemory(NewCellArray,
CellRef->CellArray,
CellRef->Max * sizeof(HV_HIVE_CELL_PAIR));
CmpFree(CellRef->CellArray, 0); // TAG_CM
}
CellRef->CellArray = NewCellArray;
CellRef->Max += CELL_REF_INCREMENT;
}
// ASSERT(CellRef->Count < CellRef->Max);
/* Add the reference */
CellRef->CellArray[CellRef->Count].Hive = Hive;
CellRef->CellArray[CellRef->Count].Cell = Cell;
CellRef->Count++;
return TRUE;
}
VOID
CMAPI
HvReleaseFreeCellRefArray(
IN OUT PHV_TRACK_CELL_REF CellRef)
{
ULONG i;
PAGED_CODE();
ASSERT(CellRef);
/* Any references in the static array? */
if (CellRef->StaticCount > 0)
{
/* Sanity check */
ASSERT(CellRef->StaticCount <= STATIC_CELL_PAIR_COUNT);
/* Loop over them and release them */
for (i = 0; i < CellRef->StaticCount; i++)
{
HvReleaseCell(CellRef->StaticArray[i].Hive,
CellRef->StaticArray[i].Cell);
}
/* We can reuse the static array */
CellRef->StaticCount = 0;
}
/* Any references in the dynamic array? */
if (CellRef->Count > 0)
{
/* Sanity checks */
ASSERT(CellRef->Count <= CellRef->Max);
ASSERT(CellRef->CellArray);
/* Loop over them and release them */
for (i = 0; i < CellRef->Count; i++)
{
HvReleaseCell(CellRef->CellArray[i].Hive,
CellRef->CellArray[i].Cell);
}
/* We can reuse the dynamic array */
CmpFree(CellRef->CellArray, 0); // TAG_CM
CellRef->CellArray = NULL;
CellRef->Count = CellRef->Max = 0;
}
}