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windows-xp/Source/XPSP1/NT/base/mspatch/api/pestuff.c

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#include <precomp.h>
//
// pestuff.c
//
// Author: Tom McGuire (tommcg) 2/97 - 3/98
//
// Copyright (C) Microsoft, 1997-1999.
//
// MICROSOFT CONFIDENTIAL
//
#define MAX_SYMBOL_NAME_LENGTH 2048
typedef struct _SYMBOL_CONTEXT SYMBOL_CONTEXT, *PSYMBOL_CONTEXT;
struct _SYMBOL_CONTEXT {
SYMBOL_TREE NewDecoratedSymbolTree;
SYMBOL_TREE NewUndecoratedSymbolTree;
SYMBOL_TREE OldUndecoratedSymbolTree;
ULONG_PTR NewImageBase;
ULONG_PTR OldImageBase;
ULONG SymbolOptionFlags;
PRIFT_TABLE RiftTable;
#ifdef TESTCODE
HANDLE OutFile;
#endif
};
typedef struct _RELOC_ARRAY_ENTRY RELOC_ARRAY_ENTRY, *PRELOC_ARRAY_ENTRY;
struct _RELOC_ARRAY_ENTRY {
ULONG RelocRva;
UCHAR RelocType;
USHORT HighAdjValue;
};
#ifndef PATCH_APPLY_CODE_ONLY
#ifdef TESTCODE
ULONG CountDecoratedMatches;
ULONG CountUndecoratedMatches;
#endif
LPCSTR ImagehlpImportNames[] = {
"SymInitialize",
"SymGetOptions",
"SymSetOptions",
"SymLoadModule",
"SymGetModuleInfo",
"SymEnumerateSymbols",
"UnDecorateSymbolName",
"SymUnloadModule",
"SymCleanup"
};
#define COUNT_IMAGEHLP_IMPORTS ( sizeof( ImagehlpImportNames ) / sizeof( ImagehlpImportNames[ 0 ] ))
//
// NOTE: Above names must be in SAME ORDER as the prototypes below.
//
union {
VOID ( __stdcall * Imports[ COUNT_IMAGEHLP_IMPORTS ] )();
struct {
BOOL ( __stdcall * SymInitialize )( HANDLE, LPCSTR, BOOL );
DWORD ( __stdcall * SymGetOptions )( VOID );
DWORD ( __stdcall * SymSetOptions )( DWORD );
DWORD ( __stdcall * SymLoadModule )( HANDLE, HANDLE, LPCSTR, LPCSTR, DWORD_PTR, DWORD );
BOOL ( __stdcall * SymGetModuleInfo )( HANLDE, DWORD, PIMAGEHLP_MODULE );
BOOL ( __stdcall * SymEnumerateSymbols )( HANDLE, DWORD_PTR, PSYM_ENUMSYMBOLS_CALLBACK, PVOID );
BOOL ( __stdcall * UnDecorateSymbolName )( LPCSTR, LPSTR, DWORD, DWORD );
BOOL ( __stdcall * SymUnloadModule )( HANDLE, DWORD_PTR );
BOOL ( __stdcall * SymCleanup )( HANDLE );
};
} Imagehlp;
BOOL ImagehlpCritSectInitialized;
CRITICAL_SECTION ImagehlpCritSect;
HANDLE hLibImagehlp;
HANDLE hProc;
IMAGEHLP_MODULE ImagehlpModuleInfo;
VOID
InitImagehlpCritSect(
VOID
)
{
if ( ! ImagehlpCritSectInitialized ) {
InitializeCriticalSection( &ImagehlpCritSect );
ImagehlpCritSectInitialized = TRUE;
hProc = GetCurrentProcess();
}
}
BOOL
LoadImagehlp(
VOID
)
{
HANDLE hLib;
ULONG i;
if ( Imagehlp.Imports[ COUNT_IMAGEHLP_IMPORTS - 1 ] == NULL ) {
hLib = LoadLibrary( "imagehlp.dll" );
if ( hLib == NULL ) {
return FALSE;
}
for ( i = 0; i < COUNT_IMAGEHLP_IMPORTS; i++ ) {
Imagehlp.Imports[ i ] = GetProcAddress( hLib, ImagehlpImportNames[ i ] );
if ( Imagehlp.Imports[ i ] == NULL ) {
FreeLibrary( hLib );
return FALSE;
}
}
hLibImagehlp = hLib;
}
return TRUE;
}
#ifdef BUILDING_PATCHAPI_DLL
VOID
UnloadImagehlp(
VOID
)
{
if ( hLibImagehlp ) {
FreeLibrary( hLibImagehlp );
hLibImagehlp = NULL;
Imagehlp.Imports[ COUNT_IMAGEHLP_IMPORTS - 1 ] = NULL;
DeleteCriticalSection( &ImagehlpCritSect );
ImagehlpCritSectInitialized = FALSE;
}
}
#endif // BUILDING_PATCHAPI_DLL
#endif // ! PATCH_APPLY_CODE_ONLY
UP_IMAGE_NT_HEADERS32
__fastcall
GetNtHeader(
IN PVOID MappedFile,
IN ULONG MappedFileSize
)
{
UP_IMAGE_DOS_HEADER DosHeader;
UP_IMAGE_NT_HEADERS32 RetHeader;
UP_IMAGE_NT_HEADERS32 NtHeader;
RetHeader = NULL;
__try {
if ( MappedFileSize >= 0x200 ) {
DosHeader = (UP_IMAGE_DOS_HEADER) MappedFile;
if ( DosHeader->e_magic == IMAGE_DOS_SIGNATURE ) {
NtHeader = (UP_IMAGE_NT_HEADERS32)((PUCHAR) MappedFile + DosHeader->e_lfanew );
if (((PUCHAR) NtHeader + sizeof( IMAGE_NT_HEADERS32 )) <= ((PUCHAR) MappedFile + MappedFileSize )) {
if ( NtHeader->Signature == IMAGE_NT_SIGNATURE ) {
if (NtHeader->OptionalHeader.Magic == IMAGE_NT_OPTIONAL_HDR32_MAGIC) {
RetHeader = NtHeader;
}
}
}
}
}
}
__except( EXCEPTION_EXECUTE_HANDLER ) {
}
return RetHeader;
}
BOOL
__fastcall
IsImageRvaInExecutableSection(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN ULONG Rva
)
{
UP_IMAGE_SECTION_HEADER SectionHeader;
ULONG SectionCount;
ULONG i;
SectionHeader = IMAGE_FIRST_SECTION( NtHeader );
SectionCount = NtHeader->FileHeader.NumberOfSections;
for ( i = 0; i < SectionCount; i++ ) {
if (( Rva >= SectionHeader[ i ].VirtualAddress ) &&
( Rva < SectionHeader[ i ].VirtualAddress + SectionHeader[ i ].Misc.VirtualSize )) {
return (( SectionHeader[ i ].Characteristics & IMAGE_SCN_MEM_EXECUTE ) ? TRUE : FALSE );
}
}
return FALSE;
}
ULONG
__fastcall
ImageRvaToFileOffset(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN ULONG Rva
)
{
UP_IMAGE_SECTION_HEADER SectionHeader;
ULONG SectionCount;
ULONG i;
if ( Rva < NtHeader->OptionalHeader.SizeOfHeaders ) {
return Rva;
}
SectionHeader = IMAGE_FIRST_SECTION( NtHeader );
SectionCount = NtHeader->FileHeader.NumberOfSections;
for ( i = 0; i < SectionCount; i++ ) {
if (( Rva >= SectionHeader[ i ].VirtualAddress ) &&
( Rva < SectionHeader[ i ].VirtualAddress + SectionHeader[ i ].SizeOfRawData )) {
return ( SectionHeader[ i ].PointerToRawData + ( Rva - SectionHeader[ i ].VirtualAddress ));
}
}
return 0;
}
PVOID
__fastcall
ImageRvaToMappedAddress(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN ULONG Rva,
IN PVOID MappedBase,
IN ULONG MappedSize
)
{
ULONG MappedOffset = ImageRvaToFileOffset( NtHeader, Rva );
if (( MappedOffset ) && ( MappedOffset < MappedSize )) {
return ((PUCHAR)MappedBase + MappedOffset );
}
return NULL;
}
ULONG
__fastcall
ImageVaToFileOffset(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN ULONG Va
)
{
return ImageRvaToFileOffset( NtHeader, Va - NtHeader->OptionalHeader.ImageBase );
}
PVOID
__fastcall
ImageVaToMappedAddress(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN ULONG Va,
IN PVOID MappedBase,
IN ULONG MappedSize
)
{
return ImageRvaToMappedAddress( NtHeader, Va - NtHeader->OptionalHeader.ImageBase, MappedBase, MappedSize );
}
ULONG
__fastcall
ImageDirectoryRvaAndSize(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN ULONG DirectoryIndex,
OUT PULONG DirectorySize
)
{
if ( DirectoryIndex < NtHeader->OptionalHeader.NumberOfRvaAndSizes ) {
if ( DirectorySize ) {
*DirectorySize = NtHeader->OptionalHeader.DataDirectory[ DirectoryIndex ].Size;
}
return NtHeader->OptionalHeader.DataDirectory[ DirectoryIndex ].VirtualAddress;
}
return 0;
}
ULONG
__fastcall
ImageDirectoryOffsetAndSize(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN ULONG DirectoryIndex,
OUT PULONG DirectorySize
)
{
ULONG Rva = ImageDirectoryRvaAndSize( NtHeader, DirectoryIndex, DirectorySize );
if ( Rva ) {
return ImageRvaToFileOffset( NtHeader, Rva );
}
return 0;
}
PVOID
__fastcall
ImageDirectoryMappedAddress(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN ULONG DirectoryIndex,
OUT PULONG DirectorySize,
IN PUCHAR MappedBase,
IN ULONG MappedSize
)
{
PUCHAR Directory;
ULONG LocalSize;
ULONG Rva;
Rva = ImageDirectoryRvaAndSize( NtHeader, DirectoryIndex, &LocalSize );
Directory = ImageRvaToMappedAddress( NtHeader, Rva, MappedBase, MappedSize );
if (( Directory ) && (( Directory + LocalSize ) <= ( MappedBase + MappedSize ))) {
if ( DirectorySize ) {
*DirectorySize = LocalSize;
}
return Directory;
}
return NULL;
}
ULONG
__fastcall
FileOffsetToImageRva(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN ULONG FileOffset
)
{
UP_IMAGE_SECTION_HEADER SectionHeader;
ULONG SectionCount;
ULONG i;
SectionHeader = IMAGE_FIRST_SECTION( NtHeader );
SectionCount = NtHeader->FileHeader.NumberOfSections;
for ( i = 0; i < SectionCount; i++ ) {
if (( FileOffset >= SectionHeader[ i ].PointerToRawData ) &&
( FileOffset < SectionHeader[ i ].PointerToRawData + SectionHeader[ i ].SizeOfRawData )) {
return ( SectionHeader[ i ].VirtualAddress + ( FileOffset - SectionHeader[ i ].PointerToRawData ));
}
}
return 0;
}
ULONG
MappedAddressToImageRva(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN PVOID MappedAddress,
IN PVOID MappedFile
)
{
LONG FileOffset = (LONG)((PUCHAR)MappedAddress - (PUCHAR)MappedFile);
if ( FileOffset > 0 ) {
return FileOffsetToImageRva( NtHeader, FileOffset );
}
return 0;
}
BOOL
RebaseMappedImage(
IN PUCHAR MappedFile,
IN ULONG FileSize,
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN ULONG NewBase
)
{
UP_IMAGE_BASE_RELOCATION RelocBlock;
LONG RelocAmount;
LONG RelocDirRemaining;
ULONG RelocDirSize;
PUCHAR RelocBlockMa;
PUCHAR RelocFixupMa;
ULONG RelocCount;
USHORT UNALIGNED* RelocEntry;
PUCHAR MappedFileEnd;
BOOL Modified;
//
// Carefully rebase the image, ignoring invalid info as much as possible
// without taking an access violation. We don't want to use try/except
// here because this code needs to be workable without any imports from
// kernel32.dll. This code is not intended to catch errors in invalid
// rebase info -- it is intended to silently do the best it can at
// rebasing the image in memory. If the rebase info is valid, it will
// correctly rebase the image. If the rebase info is not valid, it will
// attempt to avoid causing an access violation.
//
ASSERT( NtHeader->OptionalHeader.ImageBase != NewBase );
ASSERT(( NewBase & 0x0000FFFF ) == 0 );
ASSERT(( NewBase & 0xFFFF0000 ) != 0 );
Modified = FALSE;
MappedFileEnd = MappedFile + FileSize;
RelocAmount = NewBase - NtHeader->OptionalHeader.ImageBase;
RelocBlock = ImageDirectoryMappedAddress( NtHeader, IMAGE_DIRECTORY_ENTRY_BASERELOC, &RelocDirSize, MappedFile, FileSize );
if ( RelocBlock ) {
NtHeader->OptionalHeader.ImageBase = NewBase;
Modified = TRUE;
RelocDirRemaining = (LONG)RelocDirSize;
while ( RelocDirRemaining > 0 ) {
if (( RelocBlock->SizeOfBlock <= (ULONG)RelocDirRemaining ) &&
( RelocBlock->SizeOfBlock > sizeof( IMAGE_BASE_RELOCATION ))) {
//
// ImageRvaToMappedAddress returns NULL if the Rva is zero,
// but that is a valid base address of a reloc block. Use
// ImageRvaToFileOffset instead.
//
RelocBlockMa = MappedFile + ImageRvaToFileOffset( NtHeader, RelocBlock->VirtualAddress );
if ( RelocBlockMa ) {
RelocEntry = (PUSHORT)((PUCHAR)RelocBlock + sizeof( IMAGE_BASE_RELOCATION ));
RelocCount = ( RelocBlock->SizeOfBlock - sizeof( IMAGE_BASE_RELOCATION )) / sizeof( USHORT );
while ( RelocCount-- ) {
RelocFixupMa = RelocBlockMa + ( *RelocEntry & 0x0FFF );
if ( RelocFixupMa < MappedFileEnd ) {
switch ( *RelocEntry >> 12 ) {
case IMAGE_REL_BASED_HIGHLOW:
*(UNALIGNED LONG *)RelocFixupMa += RelocAmount;
break;
case IMAGE_REL_BASED_LOW:
*(UNALIGNED USHORT *)RelocFixupMa = (USHORT)( *(UNALIGNED SHORT *)RelocFixupMa + RelocAmount );
break;
case IMAGE_REL_BASED_HIGH:
*(UNALIGNED USHORT *)RelocFixupMa = (USHORT)((( *(UNALIGNED USHORT *)RelocFixupMa << 16 ) + RelocAmount ) >> 16 );
break;
case IMAGE_REL_BASED_HIGHADJ:
++RelocEntry;
--RelocCount;
*(UNALIGNED USHORT *)RelocFixupMa = (USHORT)((( *(UNALIGNED USHORT *)RelocFixupMa << 16 ) + *(UNALIGNED SHORT *)RelocEntry + RelocAmount + 0x8000 ) >> 16 );
break;
//
// Just skip and continue if we don't
// recognize the reloc type.
//
}
}
++RelocEntry;
}
}
}
RelocDirRemaining -= RelocBlock->SizeOfBlock;
RelocBlock = (UP_IMAGE_BASE_RELOCATION)((PUCHAR)RelocBlock + RelocBlock->SizeOfBlock );
}
}
return Modified;
}
BOOL
UnBindMappedImage(
IN PUCHAR MappedFile,
IN ULONG FileSize,
IN UP_IMAGE_NT_HEADERS32 NtHeader
)
{
UP_IMAGE_SECTION_HEADER SectionHeader;
UP_IMAGE_IMPORT_DESCRIPTOR ImportDesc;
ULONG SectionCount;
DWORDLONG SectionName;
PVOID BoundImportDir;
ULONG BoundImportSize;
ULONG UNALIGNED* OriginalIat;
ULONG UNALIGNED* BoundIat;
PUCHAR MappedFileEnd;
BOOL Modified;
ULONG i;
Modified = FALSE;
MappedFileEnd = MappedFile + FileSize;
BoundImportDir = ImageDirectoryMappedAddress( NtHeader, IMAGE_DIRECTORY_ENTRY_BOUND_IMPORT, &BoundImportSize, MappedFile, FileSize );
if ( BoundImportDir ) {
//
// Zero the bound import directory and pointers to bound
// import directory.
//
ZeroMemory( BoundImportDir, BoundImportSize );
NtHeader->OptionalHeader.DataDirectory[ IMAGE_DIRECTORY_ENTRY_BOUND_IMPORT ].VirtualAddress = 0;
NtHeader->OptionalHeader.DataDirectory[ IMAGE_DIRECTORY_ENTRY_BOUND_IMPORT ].Size = 0;
Modified = TRUE;
}
//
// Now walk imports and zero the TimeDate and
// ForwarderChain fields.
//
ImportDesc = ImageDirectoryMappedAddress( NtHeader, IMAGE_DIRECTORY_ENTRY_IMPORT, NULL, MappedFile, FileSize );
if ( ImportDesc ) {
while (((ULONG_PTR)ImportDesc < ((ULONG_PTR)MappedFileEnd - sizeof( IMAGE_IMPORT_DESCRIPTOR ))) &&
( ImportDesc->Characteristics )) {
if ( ImportDesc->TimeDateStamp ) {
//
// This is a bound import. Copy the unbound
// IAT over the bound IAT to restore.
//
ImportDesc->TimeDateStamp = 0;
Modified = TRUE;
OriginalIat = ImageRvaToMappedAddress( NtHeader, (ULONG)ImportDesc->OriginalFirstThunk, MappedFile, FileSize );
BoundIat = ImageRvaToMappedAddress( NtHeader, (ULONG)ImportDesc->FirstThunk, MappedFile, FileSize );
if (( OriginalIat ) && ( BoundIat )) {
while (((PUCHAR)OriginalIat < MappedFileEnd ) &&
((PUCHAR)BoundIat < MappedFileEnd ) &&
( *OriginalIat )) {
*BoundIat++ = *OriginalIat++;
}
}
}
if ( ImportDesc->ForwarderChain ) {
ImportDesc->ForwarderChain = 0;
Modified = TRUE;
}
++ImportDesc;
}
}
//
// The bind utility marks the .idata section as read-only so we want to
// change it back to read-write.
//
SectionHeader = IMAGE_FIRST_SECTION( NtHeader );
SectionCount = NtHeader->FileHeader.NumberOfSections;
for ( i = 0; i < SectionCount; i++ ) {
SectionName = *(UNALIGNED DWORDLONG*)( &SectionHeader[ i ].Name );
SectionName |= 0x2020202020202020; // fast lower case
if ( SectionName == 0x202061746164692E ) { // ".idata "
if ( ! ( SectionHeader[ i ].Characteristics & IMAGE_SCN_MEM_WRITE )) {
SectionHeader[ i ].Characteristics |= ( IMAGE_SCN_MEM_READ | IMAGE_SCN_MEM_WRITE );
Modified = TRUE;
}
break;
}
}
return Modified;
}
BOOL
SmashLockPrefixesInMappedImage(
IN PUCHAR MappedFile,
IN ULONG FileSize,
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN UCHAR NewOpCode // X86_OPCODE_NOP or X86_OPCODE_LOCK
)
{
UP_IMAGE_LOAD_CONFIG_DIRECTORY32 LoadConfig;
ULONG UNALIGNED* LockPrefixEntry;
PUCHAR LockPrefixInstruction;
BOOL Modified;
Modified = FALSE;
LoadConfig = ImageDirectoryMappedAddress( NtHeader, IMAGE_DIRECTORY_ENTRY_LOAD_CONFIG, NULL, MappedFile, FileSize );
if ( LoadConfig ) {
if ( LoadConfig->LockPrefixTable ) {
//
// The LoadConfig->LockPrefixTable field and
// the lock prefix addresses are stored in the
// image as image VA, not RVA values.
//
LockPrefixEntry = ImageVaToMappedAddress( NtHeader, LoadConfig->LockPrefixTable, MappedFile, FileSize );
if ( LockPrefixEntry ) {
while ( *LockPrefixEntry ) {
LockPrefixInstruction = ImageVaToMappedAddress( NtHeader, *LockPrefixEntry, MappedFile, FileSize );
if ( LockPrefixInstruction ) {
if ( *LockPrefixInstruction != NewOpCode ) {
//
// Lock prefix instruction is not what we want,
// so modify it.
//
*LockPrefixInstruction = NewOpCode;
Modified = TRUE;
}
}
++LockPrefixEntry;
}
}
}
}
return Modified;
}
USHORT
ChkSum(
IN USHORT Initial,
IN PUSHORT Buffer,
IN ULONG Bytes
)
{
USHORT UNALIGNED* p = Buffer;
ULONG WordsRemaining = Bytes / 2;
ULONG WordsInChunk;
ULONG SumChunk;
ULONG SumTotal;
SumTotal = Initial;
while ( WordsRemaining ) {
WordsInChunk = WordsRemaining;
if ( WordsInChunk > 0x10000 ) {
WordsInChunk = 0x10000;
}
WordsRemaining -= WordsInChunk;
SumChunk = 0;
do {
SumChunk += *p++;
}
while ( --WordsInChunk != 0 );
SumTotal += ( SumChunk >> 16 ) + ( SumChunk & 0xFFFF );
}
if ( Bytes % 2 ) {
SumTotal += *((PBYTE) p);
}
return (USHORT)(( SumTotal >> 16 ) + ( SumTotal & 0xFFFF ));
}
BOOL
NormalizeCoffImage(
IN OUT UP_IMAGE_NT_HEADERS32 NtHeader,
IN OUT PUCHAR MappedFile,
IN ULONG FileSize,
IN ULONG OptionFlags,
IN PVOID OptionData,
IN ULONG NewFileCoffBase,
IN ULONG NewFileCoffTime
)
{
BOOL Modified = FALSE;
UNREFERENCED_PARAMETER( OptionData );
if ( ! ( OptionFlags & PATCH_OPTION_NO_REBASE )) {
if (( NewFileCoffTime != 0 ) && ( NtHeader->FileHeader.TimeDateStamp != NewFileCoffTime )) {
NtHeader->FileHeader.TimeDateStamp = NewFileCoffTime;
Modified = TRUE;
}
if (( NewFileCoffBase != 0 ) && ( NtHeader->OptionalHeader.ImageBase != NewFileCoffBase )) {
Modified |= RebaseMappedImage( MappedFile, FileSize, NtHeader, NewFileCoffBase );
}
}
if ( ! ( OptionFlags & PATCH_OPTION_NO_BINDFIX )) {
Modified |= UnBindMappedImage( MappedFile, FileSize, NtHeader );
}
if ( ! ( OptionFlags & PATCH_OPTION_NO_LOCKFIX )) {
Modified |= SmashLockPrefixesInMappedImage( MappedFile, FileSize, NtHeader, X86_OPCODE_LOCK );
}
//
// If the target file has zero checksum (PATCH_OPTION_NO_CHECKSUM),
// set the checksum in this image to zero.
//
// Otherwise, if we either modified the image or if the image has
// a zero checksum, recompute the correct checksum.
//
if ( OptionFlags & PATCH_OPTION_NO_CHECKSUM ) {
if ( NtHeader->OptionalHeader.CheckSum != 0 ) {
NtHeader->OptionalHeader.CheckSum = 0;
Modified = TRUE;
}
}
else {
if ( Modified ) {
(ULONG)( NtHeader->OptionalHeader.CheckSum ) = 0;
NtHeader->OptionalHeader.CheckSum = ChkSum( 0, (PVOID)MappedFile, FileSize ) + FileSize;
}
}
return Modified;
}
//
// For some odd reason, the VC4 compiler says there is unreachable code
// in the GetNewRvaFromRiftTable and FindRiftTableEntryForOldRva functions,
// but I can't find it by inspection, and the VC5 and VC6 compilers don't
// complain about it, so it's probably just a VC4 issue. So, if the compiler
// version is previous to VC5, disable this particular warning.
//
#if ( _MSC_VER < 1100 )
#pragma warning( disable: 4702 ) // unreachable code
#endif
ULONG
__fastcall
GetNewRvaFromRiftTable(
IN PRIFT_TABLE RiftTable,
IN ULONG OldRva
)
{
PRIFT_ENTRY RiftEntryArray;
ULONG NewRva;
ULONG Index;
ULONG MinIndexInclusive;
ULONG MaxIndexExclusive;
LONG Displacement;
BOOL Found;
//
// Rift table is in sorted order by OldRva, so do a binary search for
// matching or nearest preceding OldRva value.
//
RiftEntryArray = RiftTable->RiftEntryArray;
MaxIndexExclusive = RiftTable->RiftEntryCount;
MinIndexInclusive = 0;
Index = 0;
Found = FALSE;
while (( ! Found ) && ( MinIndexInclusive < MaxIndexExclusive )) {
Index = ( MinIndexInclusive + MaxIndexExclusive ) / 2; // won't overflow
if ( RiftEntryArray[ Index ].OldFileRva < OldRva ) {
MinIndexInclusive = Index + 1;
}
else if ( RiftEntryArray[ Index ].OldFileRva > OldRva ) {
MaxIndexExclusive = Index;
}
else {
Found = TRUE;
break;
}
}
if ( ! Found ) {
//
// MinIndex is pointing to next highest entry, which could also be
// the zeroth entry if the search value was lower than anything in
// the table.
//
if ( MinIndexInclusive == 0 ) {
return OldRva; // zero displacement
}
Index = MinIndexInclusive - 1;
}
Displacement = (LONG)( RiftEntryArray[ Index ].NewFileRva - RiftEntryArray[ Index ].OldFileRva );
#ifndef PATCH_APPLY_CODE_ONLY
//
// If we're updating the RiftUsageArray during compression, we want to
// mark the contributing entry as being used.
//
if ( RiftTable->RiftUsageArray != NULL ) {
RiftTable->RiftUsageArray[ Index ] = 1;
}
#endif
NewRva = OldRva + Displacement;
return NewRva;
}
ULONG
__fastcall
FindRiftTableEntryForOldRva(
IN PRIFT_TABLE RiftTable,
IN ULONG OldRva
)
{
PRIFT_ENTRY RiftEntryArray;
ULONG MinIndexInclusive;
ULONG MaxIndexExclusive;
ULONG Index;
BOOL Found;
//
// Rift table is in sorted order by OldRva, so do a binary search for
// matching or nearest preceding OldRva value.
//
RiftEntryArray = RiftTable->RiftEntryArray;
MaxIndexExclusive = RiftTable->RiftEntryCount;
MinIndexInclusive = 0;
Index = 0;
Found = FALSE;
while (( ! Found ) && ( MinIndexInclusive < MaxIndexExclusive )) {
Index = ( MinIndexInclusive + MaxIndexExclusive ) / 2; // won't overflow
if ( RiftEntryArray[ Index ].OldFileRva < OldRva ) {
MinIndexInclusive = Index + 1;
}
else if ( RiftEntryArray[ Index ].OldFileRva > OldRva ) {
MaxIndexExclusive = Index;
}
else {
Found = TRUE;
break;
}
}
if ( ! Found ) {
//
// MinIndex is pointing to next highest entry, which could also be
// the zeroth entry if the search value was lower than anything in
// the table.
//
if ( MinIndexInclusive == 0 ) {
return 0;
}
Index = MinIndexInclusive - 1;
}
return Index;
}
#if ( _MSC_VER < 1100 )
#pragma warning( default: 4702 ) // unreachable code
#endif
VOID
__inline
ChangeOldRvaToNewRva(
IN PRIFT_TABLE RiftTable,
IN OUT PVOID AddressOfRvaToChange
)
{
//
// Assuming all addresses of RVAs in a PE image are aligned.
//
ULONG UNALIGNED* RvaToChange = AddressOfRvaToChange;
*RvaToChange = GetNewRvaFromRiftTable(
RiftTable,
*RvaToChange
);
}
VOID
__inline
SwapRelocs(
PRELOC_ARRAY_ENTRY One,
PRELOC_ARRAY_ENTRY Two
)
{
RELOC_ARRAY_ENTRY Tmp;
Tmp = *One;
*One = *Two;
*Two = Tmp;
}
VOID
__fastcall
RelocQsort(
PRELOC_ARRAY_ENTRY LowerBound,
PRELOC_ARRAY_ENTRY UpperBound
)
{
PRELOC_ARRAY_ENTRY Lower = LowerBound;
PRELOC_ARRAY_ENTRY Upper = UpperBound;
PRELOC_ARRAY_ENTRY Pivot = Lower + (( Upper - Lower ) / 2 );
ULONG PivotRva = Pivot->RelocRva;
do {
while (( Lower <= Upper ) && ( Lower->RelocRva <= PivotRva )) {
++Lower;
}
while (( Upper >= Lower ) && ( Upper->RelocRva >= PivotRva )) {
--Upper;
}
if ( Lower < Upper ) {
SwapRelocs( Lower++, Upper-- );
}
}
while ( Lower <= Upper );
if ( Lower < Pivot ) {
SwapRelocs( Lower, Pivot );
Pivot = Lower;
}
else if ( Upper > Pivot ) {
SwapRelocs( Upper, Pivot );
Pivot = Upper;
}
if ( LowerBound < ( Pivot - 1 )) {
RelocQsort( LowerBound, Pivot - 1 );
}
if (( Pivot + 1 ) < UpperBound ) {
RelocQsort( Pivot + 1, UpperBound );
}
}
VOID
TransformOldFile_PE_Relocations(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN PVOID FileMappedImage,
IN ULONG FileSize,
IN PRIFT_TABLE RiftTable,
IN PUCHAR HintMap
)
{
PUCHAR MappedFile;
PUCHAR MappedFileEnd;
ULONG ImageBaseVa;
ULONG ImageLastVa;
PUCHAR ImageFirstSectionMa; // Mapped address
ULONG ImageFirstSectionVa; // Virtual address
ULONG RelocDirOff;
ULONG RelocDirSize;
LONG RelocDirRemaining;
UP_IMAGE_BASE_RELOCATION RelocBlock;
UP_IMAGE_BASE_RELOCATION RelocBlockBaseMa; // Mapped address
ULONG RelocBlockBaseVa; // Virtual address
ULONG RelocCount;
USHORT UNALIGNED* RelocEntry;
USHORT UNALIGNED* RelocFirst;
UCHAR RelocType;
PUCHAR RelocFixupMa; // Mapped address
ULONG RelocFixupVa; // Virtual address
ULONG RelocFixupRva;
ULONG RelocTargetVa; // Virtual address
ULONG RelocTargetRva;
ULONG NewRva;
ULONG NewVa;
PRELOC_ARRAY_ENTRY RelocArray;
ULONG RelocArrayCount;
ULONG RelocArrayIndex;
UP_IMAGE_SECTION_HEADER SectionHeader;
ULONG SectionCount;
DWORDLONG SectionName;
PUCHAR p;
ULONG i;
#ifdef TESTCODE
ULONG CountRelocChanges = 0;
#endif // TESTCODE
MappedFile = FileMappedImage;
MappedFileEnd = MappedFile + FileSize;
ImageBaseVa = NtHeader->OptionalHeader.ImageBase;
RelocDirOff = ImageDirectoryOffsetAndSize( NtHeader, IMAGE_DIRECTORY_ENTRY_BASERELOC, &RelocDirSize );
if (( RelocDirOff ) && (( RelocDirOff + RelocDirSize ) <= FileSize )) {
memset( HintMap + RelocDirOff, 0x01, RelocDirSize ); // may need to be OR'd if other bits are used
// allocate an array for the new reloc entries, approximating the needed size
RelocArray = MyVirtualAlloc( sizeof( *RelocArray ) * ( RelocDirSize / sizeof(USHORT)));
if ( RelocArray != NULL ) {
RelocArrayCount = 0;
RelocBlock = (UP_IMAGE_BASE_RELOCATION)( MappedFile + RelocDirOff );
RelocDirRemaining = (LONG)RelocDirSize;
while ( RelocDirRemaining > 0 ) {
if (( RelocBlock->SizeOfBlock <= (ULONG)RelocDirRemaining ) &&
( RelocBlock->SizeOfBlock > sizeof( IMAGE_BASE_RELOCATION ))) {
//
// ImageRvaToMappedAddress returns NULL if the Rva is zero,
// but that is a valid base address of a reloc block. Use
// ImageRvaToFileOffset instead.
//
RelocBlockBaseMa = (UP_IMAGE_BASE_RELOCATION)( MappedFile + ImageRvaToFileOffset( NtHeader, RelocBlock->VirtualAddress ));
if ( RelocBlockBaseMa ) {
RelocBlockBaseVa = RelocBlock->VirtualAddress + ImageBaseVa;
RelocEntry = (PUSHORT)((PUCHAR)RelocBlock + sizeof( IMAGE_BASE_RELOCATION ));
RelocCount = ( RelocBlock->SizeOfBlock - sizeof( IMAGE_BASE_RELOCATION )) / sizeof( USHORT );
while ( RelocCount-- ) {
RelocType = (UCHAR)( *RelocEntry >> 12 );
if ( RelocType != IMAGE_REL_BASED_ABSOLUTE ) {
RelocFixupMa = (PUCHAR)RelocBlockBaseMa + ( *RelocEntry & 0x0FFF );
RelocFixupVa = RelocBlockBaseVa + ( *RelocEntry & 0x0FFF );
RelocFixupRva = RelocFixupVa - ImageBaseVa;
RelocArray[ RelocArrayCount ].RelocRva = GetNewRvaFromRiftTable(
RiftTable,
RelocFixupRva
);
RelocArray[ RelocArrayCount ].RelocType = RelocType;
switch ( RelocType ) {
case IMAGE_REL_BASED_HIGHLOW:
if ( RelocFixupMa < MappedFileEnd ) {
*(UNALIGNED ULONG *)( HintMap + ( RelocFixupMa - MappedFile )) |= 0x01010101;
//
// Target is a 32-bit VA that we want to
// change to the corresponding VA in the
// new file.
//
RelocTargetVa = *(UNALIGNED ULONG *) RelocFixupMa;
RelocTargetRva = RelocTargetVa - ImageBaseVa;
NewRva = GetNewRvaFromRiftTable(
RiftTable,
RelocTargetRva
);
if ( NewRva != RelocTargetRva ) {
NewVa = NewRva + ImageBaseVa;
*(UNALIGNED ULONG *) RelocFixupMa = NewVa;
#ifdef TESTCODE
++CountRelocChanges;
#endif // TESTCODE
}
}
break;
case IMAGE_REL_BASED_LOW:
case IMAGE_REL_BASED_HIGH:
if ( RelocFixupMa < MappedFileEnd ) {
*(UNALIGNED USHORT *)( HintMap + ( RelocFixupMa - MappedFile )) |= 0x0101;
}
break;
case IMAGE_REL_BASED_HIGHADJ:
if ( RelocFixupMa < MappedFileEnd ) {
*(UNALIGNED USHORT *)( HintMap + ( RelocFixupMa - MappedFile )) |= 0x0101;
}
++RelocEntry;
--RelocCount;
RelocArray[ RelocArrayCount ].HighAdjValue = *RelocEntry;
break;
}
++RelocArrayCount;
}
++RelocEntry;
}
}
}
RelocDirRemaining -= RelocBlock->SizeOfBlock;
RelocBlock = (UP_IMAGE_BASE_RELOCATION)((PUCHAR)RelocBlock + RelocBlock->SizeOfBlock );
}
#ifdef TESTCODE
printf( "\r%9d modified reloc targets\n", CountRelocChanges );
#endif TESTCODE
//
// Now we want to reconstruct the .reloc table based on the new values
// hoping that it will more closely match the .reloc table in the new
// file.
//
// First we want to sort our RelocArray by Rva.
//
if ( RelocArrayCount > 1 ) {
RelocQsort( &RelocArray[ 0 ], &RelocArray[ RelocArrayCount - 1 ] );
#ifdef TESTCODE
for ( i = 0; i < RelocArrayCount - 1; i++ ) {
if ( RelocArray[ i ].RelocRva > RelocArray[ i + 1 ].RelocRva ) {
printf( "\nReloc sort failed at index %d of %d\n", i, RelocArrayCount );
for ( i = 0; i < RelocArrayCount; i++ ) {
printf( "%08X\n", RelocArray[ i ].RelocRva );
}
exit( 1 );
break;
}
}
#endif // TESTCODE
}
RelocDirRemaining = (LONG)RelocDirSize;
//
// Look for .reloc section to determine max size we can use for new
// .reloc data (may be bigger than old RelocDirSize).
//
SectionHeader = IMAGE_FIRST_SECTION( NtHeader );
SectionCount = NtHeader->FileHeader.NumberOfSections;
for ( i = 0; i < SectionCount; i++ ) {
SectionName = *(UNALIGNED DWORDLONG*)( &SectionHeader[ i ].Name );
SectionName |= 0x2020202020202020; // fast lower case
if ( SectionName == 0x2020636F6C65722E ) { // ".reloc "
if (( RelocDirOff >= SectionHeader[ i ].PointerToRawData ) &&
( RelocDirOff < SectionHeader[ i ].PointerToRawData + SectionHeader[ i ].SizeOfRawData )) {
RelocDirRemaining = ( SectionHeader[ i ].PointerToRawData + SectionHeader[ i ].SizeOfRawData ) - RelocDirOff;
}
}
}
RelocDirRemaining &= ~1; // force to even value
RelocBlock = (UP_IMAGE_BASE_RELOCATION)( MappedFile + RelocDirOff );
RelocArrayIndex = 0;
while (( RelocDirRemaining > sizeof( IMAGE_BASE_RELOCATION )) &&
( RelocArrayIndex < RelocArrayCount )) {
RelocBlock->VirtualAddress = ( RelocArray[ RelocArrayIndex ].RelocRva & 0xFFFFF000 );
RelocFirst = RelocEntry = (PUSHORT)((PUCHAR)RelocBlock + sizeof( IMAGE_BASE_RELOCATION ));
RelocDirRemaining -= sizeof( IMAGE_BASE_RELOCATION );
while (( RelocDirRemaining > 0 ) &&
( RelocArrayIndex < RelocArrayCount ) &&
(( RelocArray[ RelocArrayIndex ].RelocRva & 0xFFFFF000 ) == RelocBlock->VirtualAddress )) {
*RelocEntry++ = (USHORT)(( RelocArray[ RelocArrayIndex ].RelocType << 12 ) | ( RelocArray[ RelocArrayIndex ].RelocRva & 0x00000FFF ));
RelocDirRemaining -= sizeof( USHORT );
if ((( RelocArray[ RelocArrayIndex ].RelocType << 12 ) == IMAGE_REL_BASED_HIGHADJ ) &&
( RelocDirRemaining > 0 )) {
*RelocEntry++ = RelocArray[ RelocArrayIndex ].HighAdjValue;
RelocDirRemaining -= sizeof( USHORT );
}
++RelocArrayIndex;
}
if (( RelocDirRemaining > 0 ) && ((ULONG_PTR)RelocEntry & 2 )) {
*RelocEntry++ = 0;
RelocDirRemaining -= sizeof( USHORT );
}
RelocBlock->SizeOfBlock = (ULONG)((PUCHAR)RelocEntry - (PUCHAR)RelocFirst ) + sizeof( IMAGE_BASE_RELOCATION );
RelocBlock = (UP_IMAGE_BASE_RELOCATION)((PUCHAR)RelocBlock + RelocBlock->SizeOfBlock );
}
MyVirtualFree( RelocArray );
}
}
else {
//
// No relocation table exists for this binary. We can still perform
// this transformation for x86 images by inferring some of the
// relocation targets in the mapped image by scanning the image for
// 4-byte values that are virtual addresses that fall within the
// mapped image range. We start with the address of the first
// section, assuming no relocs occur in the image header.
//
if ( NtHeader->FileHeader.Machine == IMAGE_FILE_MACHINE_I386 ) {
SectionHeader = IMAGE_FIRST_SECTION( NtHeader );
ImageFirstSectionMa = MappedFile + SectionHeader->PointerToRawData;
ImageFirstSectionVa = ImageBaseVa + SectionHeader->VirtualAddress;
ImageLastVa = ImageBaseVa + NtHeader->OptionalHeader.SizeOfImage;
for ( p = ImageFirstSectionMa; p < ( MappedFileEnd - 4 ); p++ ) {
RelocTargetVa = *(UNALIGNED ULONG *) p;
if (( RelocTargetVa >= ImageFirstSectionVa ) && ( RelocTargetVa < ImageLastVa )) {
//
// This looks like a 32-bit VA that points within the image,
// so we'll transform it to the corresponding new address.
//
*(UNALIGNED ULONG *)( HintMap + ( p - MappedFile )) |= 0x01010101;
RelocTargetRva = RelocTargetVa - ImageBaseVa;
NewRva = GetNewRvaFromRiftTable( RiftTable, RelocTargetRva );
if ( NewRva != RelocTargetRva ) {
NewVa = NewRva + ImageBaseVa;
*(UNALIGNED ULONG *) p = NewVa;
#ifdef TESTCODE
++CountRelocChanges;
#endif // TESTCODE
}
p += 3;
}
}
#ifdef TESTCODE
printf( "\r%9d modified inferred reloc targets\n", CountRelocChanges );
#endif // TESTCODE
}
}
}
VOID
TransformOldFile_PE_Exports(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN PVOID FileMappedImage,
IN ULONG FileSize,
IN PRIFT_TABLE RiftTable,
IN PUCHAR HintMap
)
{
UP_IMAGE_EXPORT_DIRECTORY ExportBlock;
ULONG UNALIGNED* Entry;
PUCHAR MappedFile;
PUCHAR MappedFileEnd;
ULONG FileOffset;
ULONG ExportDirOff;
ULONG ExportDirSize;
ULONG EntryCount;
MappedFile = FileMappedImage;
MappedFileEnd = MappedFile + FileSize;
ExportDirOff = ImageDirectoryOffsetAndSize( NtHeader, IMAGE_DIRECTORY_ENTRY_EXPORT, &ExportDirSize );
if (( ExportDirOff ) && (( ExportDirOff + ExportDirSize ) <= FileSize )) {
memset( HintMap + ExportDirOff, 0x01, ExportDirSize ); // may need to be OR'd if other bits are used
ExportBlock = (UP_IMAGE_EXPORT_DIRECTORY)( MappedFile + ExportDirOff );
EntryCount = ExportBlock->NumberOfFunctions;
FileOffset = ImageRvaToFileOffset( NtHeader, (ULONG) ExportBlock->AddressOfFunctions );
memset( HintMap + FileOffset, 0x01, EntryCount * sizeof( ULONG )); // may need to be OR'd if other bits are used
Entry = (PULONG)( MappedFile + FileOffset );
while ( EntryCount-- ) {
ChangeOldRvaToNewRva( RiftTable, Entry++ );
}
EntryCount = ExportBlock->NumberOfNames;
FileOffset = ImageRvaToFileOffset( NtHeader, (ULONG) ExportBlock->AddressOfNames );
memset( HintMap + FileOffset, 0x01, EntryCount * sizeof( ULONG )); // may need to be OR'd if other bits are used
Entry = (PULONG)( MappedFile + FileOffset );
while ( EntryCount-- ) {
ChangeOldRvaToNewRva( RiftTable, Entry++ );
}
EntryCount = ExportBlock->NumberOfNames;
FileOffset = ImageRvaToFileOffset( NtHeader, (ULONG) ExportBlock->AddressOfNameOrdinals );
memset( HintMap + FileOffset, 0x01, EntryCount * sizeof( USHORT )); // may need to be OR'd if other bits are used
ChangeOldRvaToNewRva( RiftTable, &ExportBlock->Name );
ChangeOldRvaToNewRva( RiftTable, &ExportBlock->AddressOfFunctions );
ChangeOldRvaToNewRva( RiftTable, &ExportBlock->AddressOfNames );
ChangeOldRvaToNewRva( RiftTable, &ExportBlock->AddressOfNameOrdinals );
}
return;
}
VOID
TransformOldFile_PE_Imports(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN PVOID FileMappedImage,
IN ULONG FileSize,
IN PRIFT_TABLE RiftTable,
IN PUCHAR HintMap
)
{
UP_IMAGE_IMPORT_BY_NAME ImportByNameData;
UP_IMAGE_IMPORT_DESCRIPTOR ImportBlock;
UP_IMAGE_THUNK_DATA32 ThunkDataStart;
UP_IMAGE_THUNK_DATA32 ThunkData;
PUCHAR MappedFile;
PUCHAR MappedFileEnd;
ULONG FileOffset;
ULONG ImportDirOff;
ULONG ImportDirSize;
ULONG ImportByNameDataOffset;
MappedFile = FileMappedImage;
MappedFileEnd = MappedFile + FileSize;
ImportDirOff = ImageDirectoryOffsetAndSize( NtHeader, IMAGE_DIRECTORY_ENTRY_IMPORT, &ImportDirSize );
if (( ImportDirOff ) && (( ImportDirOff + ImportDirSize ) <= FileSize )) {
memset( HintMap + ImportDirOff, 0x01, ImportDirSize ); // may need to be OR'd if other bits are used
ImportBlock = (UP_IMAGE_IMPORT_DESCRIPTOR)( MappedFile + ImportDirOff );
while ( ImportBlock->OriginalFirstThunk ) {
if ( ! ImportBlock->TimeDateStamp ) {
FileOffset = ImageRvaToFileOffset( NtHeader, (ULONG) ImportBlock->OriginalFirstThunk );
ThunkData = ThunkDataStart = (UP_IMAGE_THUNK_DATA32)( MappedFile + FileOffset );
while ( ThunkData->u1.Ordinal != 0 ) {
if ( ! IMAGE_SNAP_BY_ORDINAL32( ThunkData->u1.Ordinal )) {
ImportByNameDataOffset = ImageRvaToFileOffset( NtHeader, (ULONG) ThunkData->u1.AddressOfData );
ImportByNameData = (UP_IMAGE_IMPORT_BY_NAME)( MappedFile + ImportByNameDataOffset );
memset( HintMap + ImportByNameDataOffset, 0x01, strlen( (LPSTR)ImportByNameData->Name ) + 3 ); // may need to be OR'd if other bits are used
ChangeOldRvaToNewRva( RiftTable, &ThunkData->u1.AddressOfData );
}
ThunkData++;
}
memset( HintMap + FileOffset, 0x01, ((PUCHAR)ThunkData - (PUCHAR)ThunkDataStart )); // may need to be OR'd if other bits are used
FileOffset = ImageRvaToFileOffset( NtHeader, (ULONG) ImportBlock->FirstThunk );
ThunkData = ThunkDataStart = (UP_IMAGE_THUNK_DATA32)( MappedFile + FileOffset );
while ( ThunkData->u1.Ordinal != 0 ) {
if ( ! IMAGE_SNAP_BY_ORDINAL32( ThunkData->u1.Ordinal )) {
ImportByNameDataOffset = ImageRvaToFileOffset( NtHeader, (ULONG) ThunkData->u1.AddressOfData );
ImportByNameData = (UP_IMAGE_IMPORT_BY_NAME)( MappedFile + ImportByNameDataOffset );
memset( HintMap + ImportByNameDataOffset, 0x01, strlen( (LPSTR)ImportByNameData->Name ) + 3 ); // may need to be OR'd if other bits are used
ChangeOldRvaToNewRva( RiftTable, &ThunkData->u1.AddressOfData );
}
ThunkData++;
}
memset( HintMap + FileOffset, 0x01, ((PUCHAR)ThunkData - (PUCHAR)ThunkDataStart )); // may need to be OR'd if other bits are used
}
ChangeOldRvaToNewRva( RiftTable, &ImportBlock->Name );
ChangeOldRvaToNewRva( RiftTable, &ImportBlock->OriginalFirstThunk );
ChangeOldRvaToNewRva( RiftTable, &ImportBlock->FirstThunk );
ImportBlock++;
}
}
//
// Another other big thing that will prevent long matches through
// the IMAGE_IMPORT_BY_NAME entries is the Hint values which
// may change (from implib for dll being imported). The Hint
// values are stored between each of the names. Maybe a separate
// "hint rift table" to fix those, or zero out all the hints in
// both the old and new files, then after the new file is built,
// go fill-in the hint values.
//
// Currently we have no infrastructure for pre-modification of
// the new file before compression and post-modification after
// decompression.
//
return;
}
#ifdef DONTCOMPILE // jmps2 and jmps3 are experimental
VOID
TransformOldFile_PE_RelativeJmps2(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN PUCHAR OldFileMapped,
IN ULONG OldFileSize,
IN PUCHAR NewFileMapped, // OPTIONAL
IN ULONG NewFileSize, // OPTIONAL
IN PRIFT_TABLE RiftTable,
IN PUCHAR HintMap
)
{
UP_IMAGE_NT_HEADERS32 NewNtHeader;
UP_IMAGE_SECTION_HEADER SectionHeader;
ULONG SectionCount;
PUCHAR SectionStart;
PUCHAR SectionExtent;
PUCHAR SearchExtent;
ULONG SectionLength;
ULONG SectionOffset;
ULONG SectionBaseRva;
ULONG SectionLastRva;
ULONG ImageLastRva;
LONG Displacement;
LONG NewDisplacement;
ULONG OffsetInSection;
ULONG OriginRva;
ULONG TargetRva;
ULONG NewOriginRva;
ULONG NewTargetRva;
ULONG i;
PUCHAR p;
//
// For each executable section, scan for opcodes that indicate
// relative call or branch instructions (different opcodes for
// different machine types).
//
#ifdef TESTCODE
ULONG CountRelativeBranchChanges = 0;
ULONG CountRiftModifications = 0;
ULONG CountRiftDeletions = 0;
ULONG CountUnmatchedBranches = 0;
ULONG CountUnmatchedE8 = 0;
ULONG CountUnmatchedE9 = 0;
ULONG CountUnmatched0F = 0;
ULONG CountUnmatchedE8Targets = 0;
ULONG CountUnmatchedE9Targets = 0;
ULONG CountUnmatched0FTargets = 0;
ULONG CountUnmatchedE8Followers = 0;
ULONG CountUnmatchedE9Followers = 0;
ULONG CountUnmatched0FFollowers = 0;
ULONG CountUnmatchedE8Instructions = 0;
ULONG CountUnmatchedE9Instructions = 0;
ULONG CountUnmatched0FInstructions = 0;
ULONG CountBranchInversions = 0;
#endif // TESTCODE
NewNtHeader = NewFileMapped ? GetNtHeader( NewFileMapped, NewFileSize ) : NULL;
ImageLastRva = NtHeader->OptionalHeader.SizeOfImage;
SectionHeader = IMAGE_FIRST_SECTION( NtHeader );
SectionCount = NtHeader->FileHeader.NumberOfSections;
for ( i = 0; i < SectionCount; i++ ) {
if ( SectionHeader[ i ].Characteristics & IMAGE_SCN_MEM_EXECUTE ) {
SectionBaseRva = SectionHeader[ i ].VirtualAddress;
SectionLength = MIN( SectionHeader[ i ].Misc.VirtualSize, SectionHeader[ i ].SizeOfRawData );
SectionOffset = SectionHeader[ i ].PointerToRawData;
SectionStart = OldFileMapped + SectionOffset;
SectionLastRva = SectionBaseRva + SectionLength;
if (( SectionOffset < OldFileSize ) &&
(( SectionOffset + SectionLength ) <= OldFileSize )) {
if ( NtHeader->FileHeader.Machine == IMAGE_FILE_MACHINE_I386 ) {
SearchExtent = SectionStart + SectionLength - 5;
for ( p = SectionStart; p < SearchExtent; p++ ) {
if (( *p == 0xE8 ) || // call relative
( *p == 0xE9 ) || // jmp relative
(( *p == 0x0F ) && // jcc relative (0F 8x)
(( *( p + 1 ) & 0xF0 ) == 0x80 ) &&
( ++p < SearchExtent ))) {
//
// Relative displacement is stored as
// 32-bit signed value following these
// opcodes. The displacement is relative
// to the NEXT instruction, which is at
// (p + 5).
//
Displacement = *(UNALIGNED LONG*)( p + 1 );
//
// We expect a lot of false positives here because
// occurences of <E8>, <E9>, and <0F><8x> will
// likely occur in other parts of the instruction
// stream so now we validate that the TargetRva
// falls within the image and within an executable
// section.
//
// Also, for jmp and jcc instructions, verify that
// the displacement is larger than +/- 127 because
// if it wasn't, the instruction should have been
// encoded as an 8-bit near branch, not a 32-bit
// branch. This prevents us from falsely matching
// data that looks like:
//
// xxE9xxxx 00000000
//
if (( *p == 0xE8 ) ||
( Displacement > 127 ) ||
( Displacement < -128 )) {
OffsetInSection = ( p + 5 ) - SectionStart;
OriginRva = SectionBaseRva + OffsetInSection;
TargetRva = OriginRva + Displacement;
if ((( TargetRva >= SectionBaseRva ) &&
( TargetRva < SectionLastRva )) ||
(( TargetRva < ImageLastRva ) &&
( IsImageRvaInExecutableSection( NtHeader, TargetRva )))) {
//
// Looks like a valid TargetRva.
//
#ifndef PATCH_APPLY_CODE_ONLY
//
// If we're creating the patch, then we need
// to validate the corresponding branch in the
// new file (might want to modify a rift entry).
//
if ( NewFileMapped != NULL ) { // we're compressing
BOOL OriginNext = FALSE;
BOOL OriginFound = FALSE;
BOOL TargetNext = FALSE;
BOOL TargetFound = FALSE;
ULONG RiftIndexOrigin = FindRiftTableEntryForOldRva( RiftTable, OriginRva );
ULONG NewOriginRva = OriginRva + (LONG)( RiftTable->RiftEntryArray[ RiftIndexOrigin ].NewFileRva - RiftTable->RiftEntryArray[ RiftIndexOrigin ].OldFileRva );
PUCHAR NewOriginMa = NewFileMapped + ImageRvaToFileOffset( NewNtHeader, NewOriginRva );
#ifdef TESTCODE
ULONG NewOriginRva1 = NewOriginRva;
ULONG NewOriginMo1 = NewOriginMa - NewFileMapped;
ULONG NewOriginVa1 = NewOriginRva + NewNtHeader->OptionalHeader.ImageBase;
ULONG NewOriginRva2 = 0;
ULONG NewOriginMo2 = 0;
ULONG NewOriginVa2 = 0;
UCHAR OldInstruction = *p;
UCHAR NewInstruction = *( NewOriginMa - 5 );
BOOL InstructionsMatch = ( *p == *( NewOriginMa - 5 ));
BOOL FollowersMatch = ( *( p + 5 ) == *NewOriginMa );
#endif // TESTCODE
if (( *p == *( NewOriginMa - 5 )) && // instructions match, and
(( *p == 0xE9 ) || // jmp instruction, or
( *( p + 5 ) == *NewOriginMa ))) { // followers match
OriginFound = TRUE;
}
else {
if (( RiftIndexOrigin + 1 ) < RiftTable->RiftEntryCount ) {
NewOriginRva = OriginRva + (LONG)( RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].NewFileRva - RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].OldFileRva );
NewOriginMa = NewFileMapped + ImageRvaToFileOffset( NewNtHeader, NewOriginRva );
#ifdef TESTCODE
NewOriginRva2 = NewOriginRva;
NewOriginMo2 = NewOriginMa - NewFileMapped;
NewOriginVa2 = NewOriginRva + NewNtHeader->OptionalHeader.ImageBase;
#endif // TESTCODE
if (( *p == *( NewOriginMa - 5 )) && // instructions match, and
(( *p == 0xE9 ) || // jmp instruction, or
( *( p + 5 ) == *NewOriginMa ))) { // followers match
OriginFound = TRUE;
OriginNext = TRUE;
}
}
}
if ( OriginFound ) {
ULONG RiftIndexTarget = FindRiftTableEntryForOldRva( RiftTable, TargetRva );
ULONG NewTargetRva = TargetRva + (LONG)( RiftTable->RiftEntryArray[ RiftIndexTarget ].NewFileRva - RiftTable->RiftEntryArray[ RiftIndexTarget ].OldFileRva );
PUCHAR NewTargetMa = NewFileMapped + ImageRvaToFileOffset( NewNtHeader, NewTargetRva );
PUCHAR TargetMa = OldFileMapped + ImageRvaToFileOffset( NtHeader, TargetRva );
if ( *NewTargetMa == *TargetMa ) { // target instructions match
TargetFound = TRUE;
}
else {
if (( RiftIndexTarget + 1 ) < RiftTable->RiftEntryCount ) {
NewTargetRva = TargetRva + (LONG)( RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].NewFileRva - RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].OldFileRva );
NewTargetMa = NewFileMapped + ImageRvaToFileOffset( NewNtHeader, NewTargetRva );
if ( *NewTargetMa == *TargetMa ) { // target instructions match
TargetFound = TRUE;
TargetNext = TRUE;
}
}
}
if ( TargetFound ) { // target and origin found
if ( OriginNext ) {
//
// Coast the rift entry at [RiftIndexOrigin+1]
// backwards to the Rva of the instruction.
//
LONG Delta = (LONG)( RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].OldFileRva - OriginRva );
RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].OldFileRva -= Delta;
RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].NewFileRva -= Delta;
#ifdef TESTCODE
++CountRiftModifications;
#endif // TESTCODE
ASSERT( RiftTable->RiftEntryArray[ RiftIndexOrigin ].OldFileRva <= RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].OldFileRva );
if ( RiftTable->RiftEntryArray[ RiftIndexOrigin ].OldFileRva == RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].OldFileRva ) {
RiftTable->RiftEntryArray[ RiftIndexOrigin ].NewFileRva = RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].NewFileRva;
#ifdef TESTCODE
++CountRiftDeletions;
#endif // TESTCODE
}
}
if ( TargetNext ) {
//
// Coast the rift entry at [RiftIndexTarget+1]
// backwards to the Rva of the target.
//
LONG Delta = (LONG)( RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].OldFileRva - TargetRva );
RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].OldFileRva -= Delta;
RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].NewFileRva -= Delta;
#ifdef TESTCODE
++CountRiftModifications;
#endif // TESTCODE
ASSERT( RiftTable->RiftEntryArray[ RiftIndexTarget ].OldFileRva <= RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].OldFileRva );
if ( RiftTable->RiftEntryArray[ RiftIndexTarget ].OldFileRva == RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].OldFileRva ) {
RiftTable->RiftEntryArray[ RiftIndexTarget ].NewFileRva = RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].NewFileRva;
#ifdef TESTCODE
++CountRiftDeletions;
#endif // TESTCODE
}
}
}
}
#ifdef TESTCODE
if ( ! (( OriginFound ) && ( TargetFound ))) {
++CountUnmatchedBranches;
switch ( *p ) {
case 0xE8:
++CountUnmatchedE8;
if ( OriginFound ) {
++CountUnmatchedE8Targets;
}
else if ( InstructionsMatch ) {
ASSERT( ! FollowersMatch );
++CountUnmatchedE8Followers;
}
else {
++CountUnmatchedE8Instructions;
printf( "\rUnmatched E8 at old RVA %08X (VA %08X, FO %08X)\n"
" with either new RVA %08X (VA %08X, FO %08X)\n"
" or backcoasted RVA %08X (VA %08X, FO %08X)\n\n",
OriginRva - 5,
( OriginRva - 5 ) + NtHeader->OptionalHeader.ImageBase,
p - OldFileMapped,
NewOriginRva1,
NewOriginVa1,
NewOriginMo1,
NewOriginRva2,
NewOriginVa2,
NewOriginMo2
);
}
break;
case 0xE9:
++CountUnmatchedE9;
if ( OriginFound ) {
++CountUnmatchedE9Targets;
}
else {
++CountUnmatchedE9Instructions;
}
break;
default:
++CountUnmatched0F;
if ( OriginFound ) {
++CountUnmatched0FTargets;
}
else if ( InstructionsMatch ) {
ASSERT( ! FollowersMatch );
++CountUnmatched0FFollowers;
}
else {
++CountUnmatched0FInstructions;
}
if ( ! InstructionsMatch ) {
if (( OldInstruction & ~1 ) == ( NewInstruction & ~1 )) {
++CountBranchInversions;
}
}
break;
}
}
#endif // TESTCODE
}
#endif // PATCH_APPLY_CODE_ONLY
NewTargetRva = GetNewRvaFromRiftTable( RiftTable, TargetRva );
NewOriginRva = GetNewRvaFromRiftTable( RiftTable, OriginRva );
NewDisplacement = NewTargetRva - NewOriginRva;
if ( NewDisplacement != Displacement ) {
*(UNALIGNED LONG*)( p + 1 ) = NewDisplacement;
#ifdef TESTCODE
++CountRelativeBranchChanges;
#endif // TESTCODE
}
p += 4;
}
}
}
}
}
else if ( NtHeader->FileHeader.Machine == IMAGE_FILE_MACHINE_ALPHA ) {
//
// Need to implement the scan for Alpha platform
// relative call/jmp/jcc opcodes.
//
}
}
}
}
#ifdef TESTCODE
printf( "\r%d modified relative branches\n", CountRelativeBranchChanges );
printf( "%d rift back-coasting modifications due to branch inspection\n", CountRiftModifications );
printf( "%d rift deletions due to branch inspection back-coasting\n", CountRiftDeletions );
printf( "%d total unmatched relative branches, composed of:\n", CountUnmatchedBranches );
printf( "\t%d unmatched E8 (call)\n", CountUnmatchedE8 );
printf( "\t\t%d unmatched E8 (call) instructions\n", CountUnmatchedE8Instructions );
printf( "\t\t%d unmatched E8 (call) followers\n", CountUnmatchedE8Followers );
printf( "\t\t%d unmatched E8 (call) targets\n", CountUnmatchedE8Targets );
printf( "\t%d unmatched E9 (jmp)\n", CountUnmatchedE9 );
printf( "\t\t%d unmatched E9 (jmp) instructions\n", CountUnmatchedE9Instructions );
printf( "\t\t%d unmatched E9 (jmp) targets\n", CountUnmatchedE9Targets );
printf( "\t%d unmatched 0F 8x (jcc)\n", CountUnmatched0F );
printf( "\t\t%d unmatched 0F 8x (jcc) instructions\n", CountUnmatched0FInstructions );
printf( "\t\t\t%d unmatched 0F 8x (jcc) instruction inversions\n", CountBranchInversions );
printf( "\t\t%d unmatched 0F 8x (jcc) followers\n", CountUnmatched0FFollowers );
printf( "\t\t%d unmatched 0F 8x (jcc) targets\n", CountUnmatched0FTargets );
#endif // TESTCODE
}
#ifdef _M_IX86
__inline char * mymemchr( char *buf, int c, unsigned count ) {
__asm {
mov edi, buf
mov ecx, count
mov eax, c
repne scasb
lea eax, [edi-1]
jz RETURNIT
xor eax, eax
RETURNIT:
}
}
#else // ! _M_IX86
#define mymemchr memchr
#endif // ! _M_IX86
VOID
TransformOldFile_PE_RelativeJmps3(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN PUCHAR OldFileMapped,
IN ULONG OldFileSize,
IN PUCHAR NewFileMapped, // OPTIONAL
IN ULONG NewFileSize, // OPTIONAL
IN PRIFT_TABLE RiftTable,
IN PUCHAR HintMap
)
{
UP_IMAGE_NT_HEADERS32 NewNtHeader;
UP_IMAGE_SECTION_HEADER SectionHeader;
ULONG SectionCount;
PUCHAR SectionStart;
PUCHAR SectionExtent;
ULONG SearchExtent;
ULONG SectionLength;
ULONG SectionOffset;
ULONG SectionBaseRva;
ULONG SectionLastRva;
ULONG ImageLastRva;
LONG DisplacementValue;
LONG NewDisplacement;
LONG OffsetToRvaAdjust;
ULONG FileOffset;
ULONG TargetOffset;
UCHAR Instruction;
ULONG InstructionLength;
ULONG DisplacementOrigin;
ULONG DisplacementOffset;
BOOL Skip;
ULONG OffsetInSection;
ULONG OriginRva;
ULONG TargetRva;
ULONG NewOriginRva;
ULONG NewTargetRva;
ULONG i;
ULONG j;
PUCHAR p;
//
// For each executable section, scan for opcodes that indicate
// relative call or branch instructions (different opcodes for
// different machine types).
//
#ifdef TESTCODE
ULONG CountRelativeBranchChanges = 0;
ULONG CountRiftModifications = 0;
ULONG CountRiftDeletions = 0;
ULONG CountUnmatchedBranches = 0;
ULONG CountUnmatchedE8 = 0;
ULONG CountUnmatchedE9 = 0;
ULONG CountUnmatched0F = 0;
ULONG CountUnmatchedE8Targets = 0;
ULONG CountUnmatchedE9Targets = 0;
ULONG CountUnmatched0FTargets = 0;
ULONG CountUnmatchedE8Followers = 0;
ULONG CountUnmatchedE9Followers = 0;
ULONG CountUnmatched0FFollowers = 0;
ULONG CountUnmatchedE8Instructions = 0;
ULONG CountUnmatchedE9Instructions = 0;
ULONG CountUnmatched0FInstructions = 0;
ULONG CountBranchInversions = 0;
#endif // TESTCODE
NewNtHeader = NewFileMapped ? GetNtHeader( NewFileMapped, NewFileSize ) : NULL;
ImageLastRva = NtHeader->OptionalHeader.SizeOfImage - 1;
SectionHeader = IMAGE_FIRST_SECTION( NtHeader );
SectionCount = NtHeader->FileHeader.NumberOfSections;
for ( i = 0; i < SectionCount; i++ ) {
if ( SectionHeader[ i ].Characteristics & IMAGE_SCN_MEM_EXECUTE ) {
SectionBaseRva = SectionHeader[ i ].VirtualAddress;
SectionLength = MIN( SectionHeader[ i ].Misc.VirtualSize, SectionHeader[ i ].SizeOfRawData );
SectionOffset = SectionHeader[ i ].PointerToRawData;
SectionStart = OldFileMapped + SectionOffset;
SectionLastRva = SectionBaseRva + SectionLength;
OffsetToRvaAdjust = SectionHeader[ i ].VirtualAddress - SectionHeader[ i ].PointerToRawData;
if (( SectionOffset < OldFileSize ) &&
(( SectionOffset + SectionLength ) <= OldFileSize )) {
if ( NtHeader->FileHeader.Machine == IMAGE_FILE_MACHINE_I386 ) {
SearchExtent = SectionOffset + SectionLength - 6;
for ( FileOffset = SectionOffset; FileOffset < SearchExtent; FileOffset++ ) {
Instruction = OldFileMapped[ FileOffset ];
switch ( Instruction ) {
case 0xE8:
InstructionLength = 6; // E8 xx xx xx xx yy
DisplacementOrigin = FileOffset + 5;
DisplacementOffset = 1;
break;
case 0xE9:
continue;
InstructionLength = 5; // E9 xx xx xx xx
DisplacementOrigin = FileOffset + 5;
DisplacementOffset = 1;
break;
case 0x0F:
continue;
if (( OldFileMapped[ FileOffset + 1 ] & 0xF0 ) != 0x80 ) {
continue;
}
InstructionLength = 7; // 0F 8x yy yy yy yy zz
DisplacementOrigin = FileOffset + 6;
DisplacementOffset = 2;
break;
default:
continue;
}
Skip = FALSE;
for ( j = 0; j < InstructionLength; j++ ) {
if ( HintMap[ FileOffset + j ] & 0x01 ) {
Skip = TRUE;
break;
}
}
if ( Skip ) {
continue;
}
DisplacementValue = *(UNALIGNED LONG*)( OldFileMapped + FileOffset + DisplacementOffset );
if (( Instruction != 0xE8 ) &&
(( DisplacementValue > 127 ) || ( DisplacementValue < -128 ))) {
continue;
}
OriginRva = DisplacementOrigin + OffsetToRvaAdjust;
TargetRva = OriginRva + DisplacementValue;
if ( TargetRva > ImageLastRva ) {
continue;
}
TargetOffset = ImageRvaToFileOffset( NtHeader, TargetRva );
if ( HintMap[ TargetOffset ] & 0x01 ) {
continue;
}
#ifndef PATCH_APPLY_CODE_ONLY
//
// If we're creating the patch, then we want
// to validate the corresponding branch in the
// new file (might want to modify a rift entry).
//
if ( NewFileMapped != NULL ) { // we're compressing
BOOL OriginNext = FALSE;
BOOL OriginFound = FALSE;
BOOL TargetNext = FALSE;
BOOL TargetFound = FALSE;
ULONG RiftIndexOrigin = FindRiftTableEntryForOldRva( RiftTable, OriginRva );
ULONG NewOriginRva = OriginRva + (LONG)( RiftTable->RiftEntryArray[ RiftIndexOrigin ].NewFileRva - RiftTable->RiftEntryArray[ RiftIndexOrigin ].OldFileRva );
PUCHAR NewOriginMa = NewFileMapped + ImageRvaToFileOffset( NewNtHeader, NewOriginRva );
#ifdef TESTCODE
ULONG NewOriginRva1 = NewOriginRva;
ULONG NewOriginMo1 = NewOriginMa - NewFileMapped;
ULONG NewOriginVa1 = NewOriginRva + NewNtHeader->OptionalHeader.ImageBase;
ULONG NewOriginRva2 = 0;
ULONG NewOriginMo2 = 0;
ULONG NewOriginVa2 = 0;
BOOL InstructionsMatch;
BOOL FollowersMatch;
BOOL BranchInversion;
BranchInversion = FALSE;
if ( Instruction == 0x0F ) {
InstructionsMatch = ( *( NewOriginMa - 6 ) == Instruction ) && ( *( NewOriginMa - 5 ) == OldFileMapped[ FileOffset + 1 ] );
if ( ! InstructionsMatch ) {
BranchInversion = ( *( NewOriginMa - 6 ) == Instruction ) && (( *( NewOriginMa - 5 ) & ~1 ) == ( OldFileMapped[ FileOffset + 1 ] & ~1 ));
}
}
else {
InstructionsMatch = ( *( NewOriginMa - 5 ) == Instruction );
}
FollowersMatch = ( *NewOriginMa == OldFileMapped[ DisplacementOrigin ] );
#endif // TESTCODE
if (( InstructionsMatch ) &&
(( FollowersMatch ) || ( Instruction == 0xE9 ))) {
OriginFound = TRUE;
}
else {
if (( RiftIndexOrigin + 1 ) < RiftTable->RiftEntryCount ) {
NewOriginRva = OriginRva + (LONG)( RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].NewFileRva - RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].OldFileRva );
NewOriginMa = NewFileMapped + ImageRvaToFileOffset( NewNtHeader, NewOriginRva );
#ifdef TESTCODE
NewOriginRva2 = NewOriginRva;
NewOriginMo2 = NewOriginMa - NewFileMapped;
NewOriginVa2 = NewOriginRva + NewNtHeader->OptionalHeader.ImageBase;
#endif // TESTCODE
if ( Instruction == 0x0F ) {
InstructionsMatch = ( *( NewOriginMa - 6 ) == Instruction ) && ( *( NewOriginMa - 5 ) == OldFileMapped[ FileOffset + 1 ] );
}
else {
InstructionsMatch = ( *( NewOriginMa - 5 ) == Instruction );
}
FollowersMatch = ( *NewOriginMa == OldFileMapped[ DisplacementOrigin ] );
if (( InstructionsMatch ) &&
(( FollowersMatch ) || ( Instruction == 0xE9 ))) {
OriginFound = TRUE;
OriginNext = TRUE;
}
}
}
if ( OriginFound ) {
ULONG RiftIndexTarget = FindRiftTableEntryForOldRva( RiftTable, TargetRva );
ULONG NewTargetRva = TargetRva + (LONG)( RiftTable->RiftEntryArray[ RiftIndexTarget ].NewFileRva - RiftTable->RiftEntryArray[ RiftIndexTarget ].OldFileRva );
PUCHAR NewTargetMa = NewFileMapped + ImageRvaToFileOffset( NewNtHeader, NewTargetRva );
PUCHAR TargetMa = OldFileMapped + ImageRvaToFileOffset( NtHeader, TargetRva );
if ( *NewTargetMa == *TargetMa ) { // target instructions match
TargetFound = TRUE;
}
else {
if (( RiftIndexTarget + 1 ) < RiftTable->RiftEntryCount ) {
NewTargetRva = TargetRva + (LONG)( RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].NewFileRva - RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].OldFileRva );
NewTargetMa = NewFileMapped + ImageRvaToFileOffset( NewNtHeader, NewTargetRva );
if ( *NewTargetMa == *TargetMa ) { // target instructions match
TargetFound = TRUE;
TargetNext = TRUE;
}
}
}
if ( TargetFound ) { // target and origin found
if ( OriginNext ) {
//
// Coast the rift entry at [RiftIndexOrigin+1]
// backwards to the Rva of the instruction.
//
LONG Delta = (LONG)( RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].OldFileRva - OriginRva );
RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].OldFileRva -= Delta;
RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].NewFileRva -= Delta;
#ifdef TESTCODE
++CountRiftModifications;
#endif // TESTCODE
ASSERT( RiftTable->RiftEntryArray[ RiftIndexOrigin ].OldFileRva <= RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].OldFileRva );
if ( RiftTable->RiftEntryArray[ RiftIndexOrigin ].OldFileRva == RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].OldFileRva ) {
RiftTable->RiftEntryArray[ RiftIndexOrigin ].NewFileRva = RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].NewFileRva;
#ifdef TESTCODE
++CountRiftDeletions;
#endif // TESTCODE
}
}
if ( TargetNext ) {
//
// Coast the rift entry at [RiftIndexTarget+1]
// backwards to the Rva of the target.
//
LONG Delta = (LONG)( RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].OldFileRva - TargetRva );
RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].OldFileRva -= Delta;
RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].NewFileRva -= Delta;
#ifdef TESTCODE
++CountRiftModifications;
#endif // TESTCODE
ASSERT( RiftTable->RiftEntryArray[ RiftIndexTarget ].OldFileRva <= RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].OldFileRva );
if ( RiftTable->RiftEntryArray[ RiftIndexTarget ].OldFileRva == RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].OldFileRva ) {
RiftTable->RiftEntryArray[ RiftIndexTarget ].NewFileRva = RiftTable->RiftEntryArray[ RiftIndexTarget + 1 ].NewFileRva;
#ifdef TESTCODE
++CountRiftDeletions;
#endif // TESTCODE
}
}
}
}
#ifdef TESTCODE
if ( ! (( OriginFound ) && ( TargetFound ))) {
++CountUnmatchedBranches;
switch ( Instruction ) {
case 0xE8:
++CountUnmatchedE8;
if ( OriginFound ) {
++CountUnmatchedE8Targets;
}
else if ( InstructionsMatch ) {
ASSERT( ! FollowersMatch );
++CountUnmatchedE8Followers;
}
else {
++CountUnmatchedE8Instructions;
printf( "\rUnmatched E8 at old RVA %08X (VA %08X, FO %08X)\n"
" with either new RVA %08X (VA %08X, FO %08X)\n"
" or backcoasted RVA %08X (VA %08X, FO %08X)\n\n",
OriginRva - 5,
( OriginRva - 5 ) + NtHeader->OptionalHeader.ImageBase,
FileOffset,
NewOriginRva1,
NewOriginVa1,
NewOriginMo1,
NewOriginRva2,
NewOriginVa2,
NewOriginMo2
);
}
break;
case 0xE9:
++CountUnmatchedE9;
if ( OriginFound ) {
++CountUnmatchedE9Targets;
}
else {
++CountUnmatchedE9Instructions;
}
break;
default:
++CountUnmatched0F;
if ( OriginFound ) {
++CountUnmatched0FTargets;
}
else if ( InstructionsMatch ) {
ASSERT( ! FollowersMatch );
++CountUnmatched0FFollowers;
}
else {
++CountUnmatched0FInstructions;
}
if ( BranchInversion ) {
++CountBranchInversions;
}
break;
}
}
#endif // TESTCODE
}
#endif // PATCH_APPLY_CODE_ONLY
NewTargetRva = GetNewRvaFromRiftTable( RiftTable, TargetRva );
NewOriginRva = GetNewRvaFromRiftTable( RiftTable, OriginRva );
NewDisplacement = NewTargetRva - NewOriginRva;
if ( NewDisplacement != DisplacementValue ) {
*(UNALIGNED LONG*)( OldFileMapped + FileOffset + DisplacementOffset ) = NewDisplacement;
#ifdef TESTCODE
++CountRelativeBranchChanges;
#endif // TESTCODE
}
FileOffset = DisplacementOrigin - 1;
}
}
else if ( NtHeader->FileHeader.Machine == IMAGE_FILE_MACHINE_ALPHA ) {
//
// Need to implement the scan for Alpha platform
// relative call/jmp/jcc opcodes.
//
}
}
}
}
#ifdef TESTCODE
printf( "\r%d modified relative branches\n", CountRelativeBranchChanges );
printf( "%d rift back-coasting modifications due to branch inspection\n", CountRiftModifications );
printf( "%d rift deletions due to branch inspection back-coasting\n", CountRiftDeletions );
printf( "%d total unmatched relative branches, composed of:\n", CountUnmatchedBranches );
printf( "\t%d unmatched E8 (call)\n", CountUnmatchedE8 );
printf( "\t\t%d unmatched E8 (call) instructions\n", CountUnmatchedE8Instructions );
printf( "\t\t%d unmatched E8 (call) followers\n", CountUnmatchedE8Followers );
printf( "\t\t%d unmatched E8 (call) targets\n", CountUnmatchedE8Targets );
printf( "\t%d unmatched E9 (jmp)\n", CountUnmatchedE9 );
printf( "\t\t%d unmatched E9 (jmp) instructions\n", CountUnmatchedE9Instructions );
printf( "\t\t%d unmatched E9 (jmp) targets\n", CountUnmatchedE9Targets );
printf( "\t%d unmatched 0F 8x (jcc)\n", CountUnmatched0F );
printf( "\t\t%d unmatched 0F 8x (jcc) instructions\n", CountUnmatched0FInstructions );
printf( "\t\t\t%d unmatched 0F 8x (jcc) instruction inversions\n", CountBranchInversions );
printf( "\t\t%d unmatched 0F 8x (jcc) followers\n", CountUnmatched0FFollowers );
printf( "\t\t%d unmatched 0F 8x (jcc) targets\n", CountUnmatched0FTargets );
#endif // TESTCODE
}
#endif // DONTCOMPILE
VOID
TransformOldFile_PE_RelativeJmps(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN PVOID FileMappedImage,
IN ULONG FileSize,
IN PRIFT_TABLE RiftTable,
IN PUCHAR HintMap
)
{
UP_IMAGE_SECTION_HEADER SectionHeader;
ULONG SectionCount;
PUCHAR SectionStart;
PUCHAR SearchExtent;
ULONG SectionLength;
ULONG SectionOffset;
ULONG SectionBaseRva;
ULONG ImageLastRva;
LONG Displacement;
LONG NewDisplacement;
ULONG OffsetInSection;
ULONG OriginRva;
ULONG TargetRva;
ULONG NewOriginRva;
ULONG NewTargetRva;
ULONG TargetOffset;
BOOL Skip;
ULONG i;
ULONG j;
PUCHAR p;
//
// For each executable section, scan for opcodes that indicate
// relative branch instructions (different opcodes for different
// machine types).
//
#ifdef TESTCODE
ULONG CountRelativeBranchChanges = 0;
#endif // TESTCODE
ImageLastRva = NtHeader->OptionalHeader.SizeOfImage;
SectionHeader = IMAGE_FIRST_SECTION( NtHeader );
SectionCount = NtHeader->FileHeader.NumberOfSections;
for ( i = 0; i < SectionCount; i++ ) {
if ( SectionHeader[ i ].Characteristics & IMAGE_SCN_MEM_EXECUTE ) {
SectionBaseRva = SectionHeader[ i ].VirtualAddress;
SectionLength = MIN( SectionHeader[ i ].Misc.VirtualSize, SectionHeader[ i ].SizeOfRawData );
SectionOffset = SectionHeader[ i ].PointerToRawData;
SectionStart = (PUCHAR)FileMappedImage + SectionOffset;
if (( SectionOffset < FileSize ) &&
(( SectionOffset + SectionLength ) <= FileSize )) {
if ( NtHeader->FileHeader.Machine == IMAGE_FILE_MACHINE_I386 ) {
SearchExtent = SectionStart + SectionLength - 5;
for ( p = SectionStart; p < SearchExtent; p++ ) {
if (( *p == 0xE9 ) || // jmp relative32 (E9)
(( *p == 0x0F ) && // jcc relative32 (0F 8x)
(( *( p + 1 ) & 0xF0 ) == 0x80 ) &&
( ++p < SearchExtent ))) {
//
// Validate that instruction and target are NOT
// something we've already identified as something
// else (reloc target, etc).
//
Skip = FALSE;
if (( *p & 0xF0 ) == 0x80 ) {
if ( HintMap[ SectionOffset + ( p - SectionStart ) - 1 ] & 0x01 ) {
Skip = TRUE;
}
}
if ( ! Skip ) {
for ( j = 0; j < 5; j++ ) {
if ( HintMap[ SectionOffset + ( p - SectionStart ) + j ] & 0x01 ) {
Skip = TRUE;
break;
}
}
}
if ( ! Skip ) {
//
// Relative displacement is stored as 32-bit
// signed value following these opcodes. The
// displacement is relative to the NEXT
// instruction, which is at (p + 5).
//
// Also, for jmp and jcc instructions, verify that
// the displacement is larger than +/- 127 because
// if it wasn't, the instruction should have been
// encoded as an 8-bit near branch, not a 32-bit
// branch. This prevents us from falsely matching
// data that looks like:
//
// xxE9xxxx 00000000
//
Displacement = *(UNALIGNED LONG*)( p + 1 );
if (( Displacement > 127 ) ||
( Displacement < -128 )) {
OffsetInSection = (ULONG)(( p + 5 ) - SectionStart );
OriginRva = SectionBaseRva + OffsetInSection;
TargetRva = OriginRva + Displacement;
//
// We expect a lot of false positives here because
// occurences of <E9>, and <0F><8x> will
// likely occur in other parts of the instruction
// stream so now we validate that the TargetRva
// falls within the image and within an executable
// section.
//
if ( TargetRva < ImageLastRva ) {
TargetOffset = ImageRvaToFileOffset( NtHeader, TargetRva );
if ( ! ( HintMap[ TargetOffset ] & 0x01 )) {
//
// Looks like a valid TargetRva, so lookup its
// corresponding "new" RVA in the rift table.
//
NewTargetRva = GetNewRvaFromRiftTable( RiftTable, TargetRva );
NewOriginRva = GetNewRvaFromRiftTable( RiftTable, OriginRva );
NewDisplacement = NewTargetRva - NewOriginRva;
if (( NewDisplacement > 127 ) ||
( NewDisplacement < -128 )) {
if ( NewDisplacement != Displacement ) {
*(UNALIGNED LONG*)( p + 1 ) = NewDisplacement;
#ifdef TESTCODE
++CountRelativeBranchChanges;
#endif // TESTCODE
}
}
else {
//
// If new displacement is 8 bits, it would be
// encoded as an 8-bit relative instruction.
// For E9, instructions, that is EB. For
// 0F 8x instructions, that is 7x. In both
// cases, we're shrinking the instruction stream.
// We'll leave the extra bytes alone.
//
if ( *p == 0xE9 ) {
*p = 0xEB;
*( p + 1 ) = (CHAR) NewDisplacement;
}
else {
*( p - 1 ) = (UCHAR)(( *p & 0x0F ) | ( 0x70 ));
*p = (CHAR) NewDisplacement;
}
#ifdef TESTCODE
++CountRelativeBranchChanges;
#endif // TESTCODE
}
p += 4;
}
}
}
}
}
}
}
else if ( NtHeader->FileHeader.Machine == IMAGE_FILE_MACHINE_ALPHA ) {
//
// Need to implement the scan for Alpha platform
// relative jmp/jcc opcodes.
//
}
}
}
}
#ifdef TESTCODE
printf( "\r%9d modified relative branches\n", CountRelativeBranchChanges );
#endif // TESTCODE
}
VOID
TransformOldFile_PE_RelativeCalls(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN PVOID FileMappedImage,
IN ULONG FileSize,
IN PRIFT_TABLE RiftTable,
IN PUCHAR HintMap
)
{
UP_IMAGE_SECTION_HEADER SectionHeader;
ULONG SectionCount;
PUCHAR SectionStart;
PUCHAR SearchExtent;
ULONG SectionLength;
ULONG SectionOffset;
ULONG SectionBaseRva;
ULONG ImageLastRva;
LONG Displacement;
LONG NewDisplacement;
ULONG OffsetInSection;
ULONG OriginRva;
ULONG TargetRva;
ULONG NewOriginRva;
ULONG NewTargetRva;
ULONG TargetOffset;
BOOL Skip;
ULONG i;
ULONG j;
PUCHAR p;
//
// For each executable section, scan for opcodes that indicate
// relative call or branch instructions (different opcodes for
// different machine types).
//
#ifdef TESTCODE
ULONG CountRelativeCallChanges = 0;
#endif // TESTCODE
ImageLastRva = NtHeader->OptionalHeader.SizeOfImage;
SectionHeader = IMAGE_FIRST_SECTION( NtHeader );
SectionCount = NtHeader->FileHeader.NumberOfSections;
for ( i = 0; i < SectionCount; i++ ) {
if ( SectionHeader[ i ].Characteristics & IMAGE_SCN_MEM_EXECUTE ) {
SectionBaseRva = SectionHeader[ i ].VirtualAddress;
SectionLength = MIN( SectionHeader[ i ].Misc.VirtualSize, SectionHeader[ i ].SizeOfRawData );
SectionOffset = SectionHeader[ i ].PointerToRawData;
SectionStart = (PUCHAR)FileMappedImage + SectionOffset;
if (( SectionOffset < FileSize ) &&
(( SectionOffset + SectionLength ) <= FileSize )) {
if ( NtHeader->FileHeader.Machine == IMAGE_FILE_MACHINE_I386 ) {
SearchExtent = SectionStart + SectionLength - 5;
for ( p = SectionStart; p < SearchExtent; p++ ) {
if ( *p == 0xE8 ) { // call relative32
//
// Validate that instruction and target are NOT
// something we've already identified as something
// else (reloc target, etc).
//
Skip = FALSE;
for ( j = 0; j < 5; j++ ) {
if ( HintMap[ SectionOffset + ( p - SectionStart ) + j ] & 0x01 ) {
Skip = TRUE;
break;
}
}
if ( ! Skip ) {
//
// Relative displacement is stored as 32-bit
// signed value following these opcodes. The
// displacement is relative to the NEXT
// instruction, which is at (p + 5).
//
Displacement = *(UNALIGNED LONG*)( p + 1 );
OffsetInSection = (ULONG)(( p + 5 ) - SectionStart );
OriginRva = SectionBaseRva + OffsetInSection;
TargetRva = OriginRva + Displacement;
//
// We expect a lot of false positives here because
// occurences of <E8> will
// likely occur in other parts of the instruction
// stream so now we validate that the TargetRva
// falls within the image and within an executable
// section.
//
if ( TargetRva < ImageLastRva ) {
TargetOffset = ImageRvaToFileOffset( NtHeader, TargetRva );
if ( ! ( HintMap[ TargetOffset ] & 0x01 )) {
//
// Looks like a valid TargetRva, so lookup its
// corresponding "new" RVA in the rift table.
//
NewTargetRva = GetNewRvaFromRiftTable( RiftTable, TargetRva );
NewOriginRva = GetNewRvaFromRiftTable( RiftTable, OriginRva );
NewDisplacement = NewTargetRva - NewOriginRva;
if ( NewDisplacement != Displacement ) {
*(UNALIGNED LONG*)( p + 1 ) = NewDisplacement;
#ifdef TESTCODE
++CountRelativeCallChanges;
#endif // TESTCODE
}
p += 4;
}
}
}
}
}
}
else if ( NtHeader->FileHeader.Machine == IMAGE_FILE_MACHINE_ALPHA ) {
//
// Need to implement the scan for Alpha platform
// relative call/jmp/jcc opcodes.
//
}
}
}
}
#ifdef TESTCODE
printf( "\r%9d modified relative calls\n", CountRelativeCallChanges );
#endif // TESTCODE
}
VOID
TransformOldFile_PE_MarkNonExe(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN PUCHAR OldFileMapped,
IN ULONG OldFileSize,
IN PUCHAR HintMap
)
{
UP_IMAGE_SECTION_HEADER SectionHeader;
ULONG SectionCount;
ULONG Offset;
ULONG Size;
ULONG Rva;
ULONG i;
UNREFERENCED_PARAMETER( OldFileMapped );
UNREFERENCED_PARAMETER( OldFileSize );
//
// Need to mark all non-exectuble bytes in hint map:
//
// Image header
// All PE image directories (import, export, etc)
// All non-executable sections
// All relocation targets
// (a reloc target can be in the middle of an instruction, but
// never the first byte of an instruction)
//
// If we use other bits in hint map, may need to change these
// memsets to bitwise OR.
//
memset( HintMap + 0, 0x01, NtHeader->OptionalHeader.SizeOfHeaders );
for ( i = 0; i < IMAGE_NUMBEROF_DIRECTORY_ENTRIES; i++ ) {
Rva = NtHeader->OptionalHeader.DataDirectory[ i ].VirtualAddress;
Size = NtHeader->OptionalHeader.DataDirectory[ i ].Size;
if (( Rva != 0 ) && ( Size != 0 )) {
Offset = ImageRvaToFileOffset( NtHeader, Rva );
memset( HintMap + Offset, 0x01, Size );
}
}
SectionHeader = IMAGE_FIRST_SECTION( NtHeader );
SectionCount = NtHeader->FileHeader.NumberOfSections;
for ( i = 0; i < SectionCount; i++ ) {
if ( ! ( SectionHeader[ i ].Characteristics & IMAGE_SCN_MEM_EXECUTE )) {
memset( HintMap + SectionHeader[ i ].PointerToRawData, 0x01, SectionHeader[ i ].SizeOfRawData );
}
}
}
typedef struct _RES_RECURSION_CONTEXT {
PRIFT_TABLE RiftTable;
PUCHAR ResBase;
PUCHAR ResEnd;
ULONG ResSize;
ULONG ResDone;
ULONG ResTime;
ULONG OldResRva;
ULONG NewResRva;
} RES_RECURSION_CONTEXT, *PRES_RECURSION_CONTEXT;
VOID
TransformResourceRecursive(
IN PRES_RECURSION_CONTEXT ResContext,
IN UP_IMAGE_RESOURCE_DIRECTORY ResDir
)
{
UP_IMAGE_RESOURCE_DIRECTORY_ENTRY ResEntry;
UP_IMAGE_RESOURCE_DATA_ENTRY ResData;
ULONG ResEntryCount;
ULONG NewOffset;
ULONG NewRva;
if (((PUCHAR)ResDir + sizeof( IMAGE_RESOURCE_DIRECTORY )) < ResContext->ResEnd ) {
ResContext->ResDone += sizeof( *ResDir );
if ( ResContext->ResDone > ResContext->ResSize ) {
return;
}
if ( ResDir->TimeDateStamp != ResContext->ResTime ) {
ResDir->TimeDateStamp = ResContext->ResTime;
}
ResEntryCount = ResDir->NumberOfNamedEntries + ResDir->NumberOfIdEntries;
ResEntry = (UP_IMAGE_RESOURCE_DIRECTORY_ENTRY)( ResDir + 1 );
while (( ResEntryCount > 0 ) && ((PUCHAR)ResEntry < ( ResContext->ResEnd - sizeof( *ResEntry )))) {
if ( ResEntry->DataIsDirectory ) {
TransformResourceRecursive(
ResContext,
(UP_IMAGE_RESOURCE_DIRECTORY)( ResContext->ResBase + ResEntry->OffsetToDirectory )
);
}
else {
ResData = (UP_IMAGE_RESOURCE_DATA_ENTRY)( ResContext->ResBase + ResEntry->OffsetToData );
if (((PUCHAR)ResData > ( ResContext->ResBase )) &&
((PUCHAR)ResData < ( ResContext->ResEnd - sizeof( *ResData )))) {
ResContext->ResDone += ResData->Size;
if ( ResContext->ResDone > ResContext->ResSize ) {
return;
}
NewRva = GetNewRvaFromRiftTable( ResContext->RiftTable, ResData->OffsetToData );
if ( ResData->OffsetToData != NewRva ) {
ResData->OffsetToData = NewRva;
}
}
}
NewOffset = GetNewRvaFromRiftTable( ResContext->RiftTable, ResContext->OldResRva + ResEntry->OffsetToDirectory ) - ResContext->NewResRva;
if ( ResEntry->OffsetToDirectory != NewOffset ) {
ResEntry->OffsetToDirectory = NewOffset;
}
if ( ResEntry->NameIsString ) {
NewOffset = GetNewRvaFromRiftTable( ResContext->RiftTable, ResContext->OldResRva + ResEntry->NameOffset ) - ResContext->NewResRva;
if ( ResEntry->NameOffset != NewOffset ) {
ResEntry->NameOffset = NewOffset;
}
}
ResContext->ResDone += sizeof( *ResEntry );
if ( ResContext->ResDone > ResContext->ResSize ) {
return;
}
++ResEntry;
--ResEntryCount;
}
}
}
VOID
TransformOldFile_PE_Resources(
IN UP_IMAGE_NT_HEADERS32 NtHeader,
IN PUCHAR OldFileMapped,
IN ULONG OldFileSize,
IN ULONG NewFileResTime,
IN PRIFT_TABLE RiftTable
)
{
RES_RECURSION_CONTEXT ResContext;
ResContext.ResBase = ImageDirectoryMappedAddress(
NtHeader,
IMAGE_DIRECTORY_ENTRY_RESOURCE,
&ResContext.ResSize,
OldFileMapped,
OldFileSize
);
if ( ResContext.ResBase ) {
ResContext.ResEnd = ResContext.ResBase + ResContext.ResSize;
ResContext.ResDone = 0;
ResContext.OldResRva = ImageDirectoryRvaAndSize( NtHeader, IMAGE_DIRECTORY_ENTRY_RESOURCE, NULL );
ResContext.NewResRva = GetNewRvaFromRiftTable( RiftTable, ResContext.OldResRva );
ResContext.ResTime = NewFileResTime;
ResContext.RiftTable = RiftTable;
TransformResourceRecursive(
&ResContext,
(UP_IMAGE_RESOURCE_DIRECTORY) ResContext.ResBase
);
}
}
BOOL
TransformCoffImage(
IN ULONG TransformOptions,
IN OUT UP_IMAGE_NT_HEADERS32 NtHeader,
IN OUT PUCHAR OldFileMapped,
IN ULONG OldFileSize,
IN ULONG NewFileResTime,
IN OUT PRIFT_TABLE RiftTable,
IN OUT PUCHAR HintMap,
...
)
{
PUCHAR InternalHintMap = NULL;
//
// First, zero out the rift usage array
//
if ( RiftTable->RiftUsageArray != NULL ) {
ZeroMemory( RiftTable->RiftUsageArray, RiftTable->RiftEntryAlloc * sizeof( RiftTable->RiftUsageArray[ 0 ] ));
}
//
// Allocated parallel "hint" mapping the same size as the old
// file. Each one of the 8 bits corresponding to each byte in
// the old file can be used to track information about that
// byte during the transformations.
//
if ( HintMap == NULL ) {
InternalHintMap = MyVirtualAlloc( OldFileSize );
HintMap = InternalHintMap;
}
if ( HintMap != NULL ) {
//
// Apply PE image transforms (each inside try/except)
//
__try {
TransformOldFile_PE_MarkNonExe( NtHeader, OldFileMapped, OldFileSize, HintMap );
}
__except( EXCEPTION_EXECUTE_HANDLER ) {
}
if ( ! ( TransformOptions & PATCH_TRANSFORM_NO_RELOCS )) {
__try {
TransformOldFile_PE_Relocations( NtHeader, OldFileMapped, OldFileSize, RiftTable, HintMap );
}
__except( EXCEPTION_EXECUTE_HANDLER ) {
}
}
if ( ! ( TransformOptions & PATCH_TRANSFORM_NO_IMPORTS )) {
__try {
TransformOldFile_PE_Imports( NtHeader, OldFileMapped, OldFileSize, RiftTable, HintMap );
}
__except( EXCEPTION_EXECUTE_HANDLER ) {
}
}
if ( ! ( TransformOptions & PATCH_TRANSFORM_NO_EXPORTS )) {
__try {
TransformOldFile_PE_Exports( NtHeader, OldFileMapped, OldFileSize, RiftTable, HintMap );
}
__except( EXCEPTION_EXECUTE_HANDLER ) {
}
}
if ( ! ( TransformOptions & PATCH_TRANSFORM_NO_RELJMPS )) {
__try {
TransformOldFile_PE_RelativeJmps( NtHeader, OldFileMapped, OldFileSize, RiftTable, HintMap );
}
__except( EXCEPTION_EXECUTE_HANDLER ) {
}
}
if ( ! ( TransformOptions & PATCH_TRANSFORM_NO_RELCALLS )) {
__try {
TransformOldFile_PE_RelativeCalls( NtHeader, OldFileMapped, OldFileSize, RiftTable, HintMap );
}
__except( EXCEPTION_EXECUTE_HANDLER ) {
}
}
if ( ! ( TransformOptions & PATCH_TRANSFORM_NO_RESOURCE )) {
__try {
TransformOldFile_PE_Resources( NtHeader, OldFileMapped, OldFileSize, NewFileResTime, RiftTable );
}
__except( EXCEPTION_EXECUTE_HANDLER ) {
}
}
if ( InternalHintMap != NULL ) {
MyVirtualFree( InternalHintMap );
}
}
return TRUE;
}
#ifndef PATCH_APPLY_CODE_ONLY
BOOL
AddRiftEntryToTable(
IN PRIFT_TABLE RiftTable,
IN ULONG OldRva,
IN ULONG NewRva
)
{
ULONG RiftIndex;
if (( OldRva != 0 ) && ( NewRva != 0 )) {
RiftIndex = RiftTable->RiftEntryCount;
if (( RiftIndex + 1 ) < RiftTable->RiftEntryAlloc ) {
RiftTable->RiftEntryCount = RiftIndex + 1;
RiftTable->RiftEntryArray[ RiftIndex ].OldFileRva = OldRva;
RiftTable->RiftEntryArray[ RiftIndex ].NewFileRva = NewRva;
return TRUE;
}
}
return FALSE;
}
BOOL
InsertRiftEntryInSortedTable(
IN PRIFT_TABLE RiftTable,
IN ULONG RiftIndex,
IN ULONG OldRva,
IN ULONG NewRva
)
{
if (( OldRva != 0 ) && ( NewRva != 0 )) {
//
// First scoot to the correct index in case RiftIndex is off by a few.
//
while (( RiftIndex > 0 ) && ( RiftTable->RiftEntryArray[ RiftIndex ].OldFileRva > OldRva )) {
--RiftIndex;
}
while (( RiftIndex < RiftTable->RiftEntryCount ) && ( RiftTable->RiftEntryArray[ RiftIndex ].OldFileRva < OldRva )) {
++RiftIndex;
}
if ( RiftIndex < RiftTable->RiftEntryCount ) {
if ( RiftTable->RiftEntryArray[ RiftIndex ].OldFileRva == OldRva ) {
//
// Don't insert duplicates. If it matches an existing OldRva,
// just warn if the NewRva doesn't match the rift.
//
#ifdef TESTCODE
if ( RiftTable->RiftEntryArray[ RiftIndex ].NewFileRva != NewRva ) {
printf( "\rAttempt to insert different rift at same OldRva\n"
" OldRva:%08X NewRva:%08X (discarded)\n"
" OldRva:%08X NewRva:%08X (kept)\n\n",
OldRva,
NewRva,
RiftTable->RiftEntryArray[ RiftIndex ].OldFileRva,
RiftTable->RiftEntryArray[ RiftIndex ].NewFileRva
);
return FALSE;
}
#endif /* TESTCODE */
return TRUE;
}
}
//
// Verify we have enough allocation to insert a new entry.
//
if (( RiftTable->RiftEntryCount + 1 ) < RiftTable->RiftEntryAlloc ) {
//
// Slide everything from RiftIndex to make room for new
// entry at RiftIndex.
//
LONG CountToMove = RiftTable->RiftEntryCount - RiftIndex;
if ( CountToMove > 0 ) {
MoveMemory(
&RiftTable->RiftEntryArray[ RiftIndex + 1 ],
&RiftTable->RiftEntryArray[ RiftIndex ],
CountToMove * sizeof( RiftTable->RiftEntryArray[ 0 ] )
);
#ifdef DONTCOMPILE // we don't use the RiftUsageArray when we're inserting
if ( RiftTable->RiftUsageArray ) {
MoveMemory(
&RiftTable->RiftUsageArray[ RiftIndex + 1 ],
&RiftTable->RiftUsageArray[ RiftIndex ],
CountToMove * sizeof( RiftTable->RiftUsageArray[ 0 ] )
);
}
#endif // DONTCOMPILE
}
#ifdef DONTCOMPILE // we don't use the RiftUsageArray when we're inserting
RiftTable->RiftUsageArray[ RiftIndex ] = 0;
#endif // DONTCOMPILE
RiftTable->RiftEntryArray[ RiftIndex ].OldFileRva = OldRva;
RiftTable->RiftEntryArray[ RiftIndex ].NewFileRva = NewRva;
RiftTable->RiftEntryCount++;
return TRUE;
}
}
return FALSE;
}
VOID
__inline
SwapRifts(
PRIFT_ENTRY One,
PRIFT_ENTRY Two
)
{
RIFT_ENTRY Tmp;
Tmp = *One;
*One = *Two;
*Two = Tmp;
}
VOID
__fastcall
RiftQsort(
PRIFT_ENTRY LowerBound,
PRIFT_ENTRY UpperBound
)
{
PRIFT_ENTRY Lower = LowerBound;
PRIFT_ENTRY Upper = UpperBound;
PRIFT_ENTRY Pivot = Lower + (( Upper - Lower ) / 2 );
ULONG PivotRva = Pivot->OldFileRva;
do {
while (( Lower <= Upper ) && ( Lower->OldFileRva <= PivotRva )) {
++Lower;
}
while (( Upper >= Lower ) && ( Upper->OldFileRva >= PivotRva )) {
--Upper;
}
if ( Lower < Upper ) {
SwapRifts( Lower++, Upper-- );
}
}
while ( Lower <= Upper );
if ( Lower < Pivot ) {
SwapRifts( Lower, Pivot );
Pivot = Lower;
}
else if ( Upper > Pivot ) {
SwapRifts( Upper, Pivot );
Pivot = Upper;
}
if ( LowerBound < ( Pivot - 1 )) {
RiftQsort( LowerBound, Pivot - 1 );
}
if (( Pivot + 1 ) < UpperBound ) {
RiftQsort( Pivot + 1, UpperBound );
}
}
VOID
RiftSortAndRemoveDuplicates(
IN PUCHAR OldFileMapped,
IN ULONG OldFileSize,
IN UP_IMAGE_NT_HEADERS32 OldFileNtHeader,
IN PUCHAR NewFileMapped,
IN ULONG NewFileSize,
IN UP_IMAGE_NT_HEADERS32 NewFileNtHeader,
IN OUT PRIFT_TABLE RiftTable
)
{
ULONG i, n;
if ( RiftTable->RiftEntryCount > 1 ) {
n = RiftTable->RiftEntryCount - 1;
RiftQsort( &RiftTable->RiftEntryArray[ 0 ], &RiftTable->RiftEntryArray[ n ] );
for ( i = 0; i < n; i++ ) {
while (( i < n ) &&
( RiftTable->RiftEntryArray[ i ].OldFileRva ==
RiftTable->RiftEntryArray[ i + 1 ].OldFileRva )) {
if ( RiftTable->RiftEntryArray[ i ].NewFileRva !=
RiftTable->RiftEntryArray[ i + 1 ].NewFileRva ) {
//
// This is an ambiguous entry since the OldRva values
// match but the NewRva values do not. Inspect the
// bytes in the old and new files and choose the one
// that is correct. If both are correct, or neither is
// correct, choose the lower of the two NewRva values.
//
ULONG ChosenNewRva;
PUCHAR OldFileRiftMa;
PUCHAR NewFileRiftMa1;
PUCHAR NewFileRiftMa2;
#ifdef TESTCODE
LPSTR Method = "lower";
#endif
ChosenNewRva = MIN( RiftTable->RiftEntryArray[ i ].NewFileRva,
RiftTable->RiftEntryArray[ i + 1 ].NewFileRva );
OldFileRiftMa = ImageRvaToMappedAddress(
OldFileNtHeader,
RiftTable->RiftEntryArray[ i ].OldFileRva,
OldFileMapped,
OldFileSize
);
NewFileRiftMa1 = ImageRvaToMappedAddress(
NewFileNtHeader,
RiftTable->RiftEntryArray[ i ].NewFileRva,
NewFileMapped,
NewFileSize
);
NewFileRiftMa2 = ImageRvaToMappedAddress(
NewFileNtHeader,
RiftTable->RiftEntryArray[ i + 1 ].NewFileRva,
NewFileMapped,
NewFileSize
);
//
// Use try/except to touch the mapped files.
//
__try {
if ( OldFileRiftMa != NULL ) {
if (( NewFileRiftMa1 != NULL ) &&
( *NewFileRiftMa1 == *OldFileRiftMa ) &&
(( NewFileRiftMa2 == NULL ) ||
( *NewFileRiftMa2 != *OldFileRiftMa ))) {
ChosenNewRva = RiftTable->RiftEntryArray[ i ].NewFileRva;
#ifdef TESTCODE
Method = "match inspection";
#endif
}
else if (( NewFileRiftMa2 != NULL ) &&
( *NewFileRiftMa2 == *OldFileRiftMa ) &&
(( NewFileRiftMa1 == NULL ) ||
( *NewFileRiftMa1 != *OldFileRiftMa ))) {
ChosenNewRva = RiftTable->RiftEntryArray[ i + 1 ].NewFileRva;
#ifdef TESTCODE
Method = "match inspection";
#endif
}
}
}
__except( EXCEPTION_EXECUTE_HANDLER ) {
}
#ifdef TESTCODE
printf(
"RiftInfo contains ambiguous entries:\n"
" OldRva:%08X NewRva:%08X (discarded)\n"
" OldRva:%08X NewRva:%08X (kept %s)\n\n",
RiftTable->RiftEntryArray[ i ].OldFileRva,
( RiftTable->RiftEntryArray[ i ].NewFileRva == ChosenNewRva ) ?
RiftTable->RiftEntryArray[ i + 1 ].NewFileRva :
RiftTable->RiftEntryArray[ i ].NewFileRva,
RiftTable->RiftEntryArray[ i ].OldFileRva,
ChosenNewRva,
Method
);
#endif
RiftTable->RiftEntryArray[ i + 1 ].NewFileRva = ChosenNewRva;
}
MoveMemory(
&RiftTable->RiftEntryArray[ i ],
&RiftTable->RiftEntryArray[ i + 1 ],
( n - i ) * sizeof( RIFT_ENTRY )
);
--n;
}
}
RiftTable->RiftEntryCount = n + 1;
}
}
#ifdef _M_IX86
//
// The x86 compiler might not optimize (a=x/y;b=x%y) into a single
// divide instruction that provides both the quotient and the remainder.
//
#pragma warning( disable: 4035 ) // no return value
__inline
DWORDLONG
QuotientAndRemainder(
IN ULONG Dividend,
IN ULONG Divisor
)
{
__asm {
mov eax, Dividend
xor edx, edx
div Divisor ; eax <- quotient, edx <- remainder
}
}
#pragma warning( default: 4035 ) // no return value
#else // ! _M_IX86
__inline
DWORDLONG
QuotientAndRemainder(
IN ULONG Dividend,
IN ULONG Divisor
)
{
ULONG Quotient = ( Dividend / Divisor );
ULONG Remainder = ( Dividend % Divisor );
return (((DWORDLONG)Remainder << 32 ) | Quotient );
}
#endif // ! _M_IX86
BOOL
IsMatchingResourceString(
IN UP_IMAGE_RESOURCE_DIR_STRING_U OldString,
IN UP_IMAGE_RESOURCE_DIR_STRING_U NewString
)
{
USHORT Length;
if ( OldString->Length != NewString->Length ) {
return FALSE;
}
Length = OldString->Length;
while ( Length-- ) {
if ( OldString->NameString[ Length ] != NewString->NameString[ Length ] ) {
return FALSE;
}
}
return TRUE;
}
VOID
GetResourceRiftInfoRecursive(
IN UP_IMAGE_RESOURCE_DIRECTORY OldResDir,
IN PUCHAR OldResBase,
IN PUCHAR OldResEnd,
IN ULONG OldResRva,
IN UP_IMAGE_RESOURCE_DIRECTORY NewResDir,
IN PUCHAR NewResBase,
IN PUCHAR NewResEnd,
IN ULONG NewResRva,
IN PRIFT_TABLE RiftTable
)
{
UP_IMAGE_RESOURCE_DIRECTORY_ENTRY OldResEntry;
UP_IMAGE_RESOURCE_DIRECTORY_ENTRY NewResEntry;
UP_IMAGE_RESOURCE_DATA_ENTRY OldResData;
UP_IMAGE_RESOURCE_DATA_ENTRY NewResData;
ULONG OldResEntryCount;
ULONG NewResEntryCount;
if ((( (PUCHAR) OldResDir + sizeof( IMAGE_RESOURCE_DIRECTORY )) < OldResEnd ) &&
(( (PUCHAR) NewResDir + sizeof( IMAGE_RESOURCE_DIRECTORY )) < NewResEnd )) {
OldResEntryCount = OldResDir->NumberOfNamedEntries + OldResDir->NumberOfIdEntries;
OldResEntry = (UP_IMAGE_RESOURCE_DIRECTORY_ENTRY) ( OldResDir + 1 );
while (( OldResEntryCount > 0 ) && ((PUCHAR)OldResEntry < OldResEnd )) {
NewResEntryCount = NewResDir->NumberOfNamedEntries + NewResDir->NumberOfIdEntries;
NewResEntry = (UP_IMAGE_RESOURCE_DIRECTORY_ENTRY)( NewResDir + 1 );
while ( NewResEntryCount > 0 ) {
if ( (PUCHAR) NewResEntry > NewResEnd ) {
NewResEntryCount = 0;
break;
}
if ( !OldResEntry->NameIsString && !NewResEntry->NameIsString &&
( OldResEntry->Id == NewResEntry->Id )) {
break;
}
else if (( OldResEntry->NameIsString && NewResEntry->NameIsString ) &&
IsMatchingResourceString(
(UP_IMAGE_RESOURCE_DIR_STRING_U)( OldResBase + OldResEntry->NameOffset ),
(UP_IMAGE_RESOURCE_DIR_STRING_U)( NewResBase + NewResEntry->NameOffset ))) {
break;
}
++NewResEntry;
--NewResEntryCount;
}
if ( NewResEntryCount > 0 ) {
if ( OldResEntry->NameIsString ) {
AddRiftEntryToTable(
RiftTable,
OldResRva + OldResEntry->NameOffset,
NewResRva + NewResEntry->NameOffset
);
}
AddRiftEntryToTable(
RiftTable,
OldResRva + OldResEntry->OffsetToDirectory,
NewResRva + NewResEntry->OffsetToDirectory
);
if ( OldResEntry->DataIsDirectory ) {
GetResourceRiftInfoRecursive(
(UP_IMAGE_RESOURCE_DIRECTORY)( OldResBase + OldResEntry->OffsetToDirectory ),
OldResBase,
OldResEnd,
OldResRva,
(UP_IMAGE_RESOURCE_DIRECTORY)( NewResBase + NewResEntry->OffsetToDirectory ),
NewResBase,
NewResEnd,
NewResRva,
RiftTable
);
}
else {
OldResData = (UP_IMAGE_RESOURCE_DATA_ENTRY)( OldResBase + OldResEntry->OffsetToData );
NewResData = (UP_IMAGE_RESOURCE_DATA_ENTRY)( NewResBase + NewResEntry->OffsetToData );
AddRiftEntryToTable(
RiftTable,
OldResData->OffsetToData,
NewResData->OffsetToData
);
}
}
++OldResEntry;
--OldResEntryCount;
}
}
}
BOOL
GetImageNonSymbolRiftInfo(
IN PUCHAR OldFileMapped,
IN ULONG OldFileSize,
IN UP_IMAGE_NT_HEADERS32 OldFileNtHeader,
IN PUCHAR NewFileMapped,
IN ULONG NewFileSize,
IN UP_IMAGE_NT_HEADERS32 NewFileNtHeader,
IN HANDLE SubAllocator,
IN PRIFT_TABLE RiftTable
)
{
//
// Create rifts for sections by section names.
//
{
UP_IMAGE_SECTION_HEADER OldSectionHeader;
UP_IMAGE_SECTION_HEADER NewSectionHeader;
ULONG OldSectionCount;
ULONG NewSectionCount;
ULONG i, j;
OldSectionHeader = IMAGE_FIRST_SECTION( OldFileNtHeader );
OldSectionCount = OldFileNtHeader->FileHeader.NumberOfSections;
NewSectionHeader = IMAGE_FIRST_SECTION( NewFileNtHeader );
NewSectionCount = NewFileNtHeader->FileHeader.NumberOfSections;
ASSERT( sizeof( OldSectionHeader->Name ) == sizeof( DWORDLONG ));
for ( i = 0; i < OldSectionCount; i++ ) {
for ( j = 0; j < NewSectionCount; j++ ) {
if ( *(UNALIGNED DWORDLONG *)OldSectionHeader[ i ].Name ==
*(UNALIGNED DWORDLONG *)NewSectionHeader[ j ].Name ) {
//
// Add a rift entry for this section name match.
//
// Note that we create rift values here that are minus
// one from the actual section boundary because if a
// symbol exists at the start of the section, its rift
// entry would conflict with this section entry.
//
AddRiftEntryToTable(
RiftTable,
OldSectionHeader[ i ].VirtualAddress - 1,
NewSectionHeader[ i ].VirtualAddress - 1
);
break;
}
}
}
}
//
// Create rifts for image directories.
//
{
ULONG i, n;
n = MIN( OldFileNtHeader->OptionalHeader.NumberOfRvaAndSizes,
NewFileNtHeader->OptionalHeader.NumberOfRvaAndSizes );
for ( i = 0; i < n; i++ ) {
if (( OldFileNtHeader->OptionalHeader.DataDirectory[ i ].VirtualAddress ) &&
( OldFileNtHeader->OptionalHeader.DataDirectory[ i ].Size ) &&
( NewFileNtHeader->OptionalHeader.DataDirectory[ i ].VirtualAddress ) &&
( NewFileNtHeader->OptionalHeader.DataDirectory[ i ].Size )) {
AddRiftEntryToTable(
RiftTable,
OldFileNtHeader->OptionalHeader.DataDirectory[ i ].VirtualAddress,
NewFileNtHeader->OptionalHeader.DataDirectory[ i ].VirtualAddress
);
}
}
}
//
// Create rifts for image export directory
//
{
UP_IMAGE_EXPORT_DIRECTORY OldExportDir;
UP_IMAGE_EXPORT_DIRECTORY NewExportDir;
ULONG OldExportIndex;
ULONG NewExportIndex;
ULONG OldExportNameCount;
ULONG NewExportNameCount;
ULONG OldExportFunctionCount;
ULONG NewExportFunctionCount;
ULONG UNALIGNED* OldExportFunctionArray;
ULONG UNALIGNED* NewExportFunctionArray;
USHORT UNALIGNED* OldExportNameToOrdinal;
USHORT UNALIGNED* NewExportNameToOrdinal;
ULONG UNALIGNED* OldExportNameArray;
ULONG UNALIGNED* NewExportNameArray;
LPSTR OldExportName;
LPSTR NewExportName;
ULONG OldOrdinal;
ULONG NewOrdinal;
LONG OrdinalBaseNewToOld;
PBYTE NewExportOrdinalNameExists;
PSYMBOL_NODE NewExportSymbolNode;
SYMBOL_TREE NewExportNameTree;
OldExportDir = ImageDirectoryMappedAddress(
OldFileNtHeader,
IMAGE_DIRECTORY_ENTRY_EXPORT,
NULL,
OldFileMapped,
OldFileSize
);
NewExportDir = ImageDirectoryMappedAddress(
NewFileNtHeader,
IMAGE_DIRECTORY_ENTRY_EXPORT,
NULL,
NewFileMapped,
NewFileSize
);
if (( OldExportDir ) && ( NewExportDir )) {
AddRiftEntryToTable( RiftTable, (ULONG)( OldExportDir->Name ), (ULONG)( NewExportDir->Name ));
AddRiftEntryToTable( RiftTable, (ULONG)( OldExportDir->AddressOfFunctions ), (ULONG)( NewExportDir->AddressOfFunctions ));
AddRiftEntryToTable( RiftTable, (ULONG)( OldExportDir->AddressOfNames ), (ULONG)( NewExportDir->AddressOfNames ));
AddRiftEntryToTable( RiftTable, (ULONG)( OldExportDir->AddressOfNameOrdinals ), (ULONG)( NewExportDir->AddressOfNameOrdinals ));
//
// Now build a tree of new export names, then walk old export names
// looking for matches in tree of new export names.
//
SymRBInitTree(
&NewExportNameTree,
SubAllocator
);
//
// First insert new export names.
//
NewExportNameCount = NewExportDir->NumberOfNames;
NewExportFunctionCount = NewExportDir->NumberOfFunctions;
NewExportFunctionArray = ImageRvaToMappedAddress( NewFileNtHeader, (ULONG) NewExportDir->AddressOfFunctions, NewFileMapped, NewFileSize );
NewExportNameToOrdinal = ImageRvaToMappedAddress( NewFileNtHeader, (ULONG) NewExportDir->AddressOfNameOrdinals, NewFileMapped, NewFileSize );
NewExportNameArray = ImageRvaToMappedAddress( NewFileNtHeader, (ULONG) NewExportDir->AddressOfNames, NewFileMapped, NewFileSize );
if ( NewExportNameArray ) {
for ( NewExportIndex = 0; NewExportIndex < NewExportNameCount; NewExportIndex++ ) {
if ( NewExportNameArray[ NewExportIndex ] ) {
NewExportName = ImageRvaToMappedAddress( NewFileNtHeader, NewExportNameArray[ NewExportIndex ], NewFileMapped, NewFileSize );
if ( NewExportName ) {
SymRBInsert( &NewExportNameTree, NewExportName, NewExportIndex );
}
}
}
}
//
// Walk old export names and match them up.
//
OldExportNameCount = OldExportDir->NumberOfNames;
OldExportFunctionCount = OldExportDir->NumberOfFunctions;
OldExportFunctionArray = ImageRvaToMappedAddress( OldFileNtHeader, (ULONG) OldExportDir->AddressOfFunctions, OldFileMapped, OldFileSize );
OldExportNameToOrdinal = ImageRvaToMappedAddress( OldFileNtHeader, (ULONG) OldExportDir->AddressOfNameOrdinals, OldFileMapped, OldFileSize );
OldExportNameArray = ImageRvaToMappedAddress( OldFileNtHeader, (ULONG) OldExportDir->AddressOfNames, OldFileMapped, OldFileSize );
if ( OldExportNameArray ) {
for ( OldExportIndex = 0; OldExportIndex < OldExportNameCount; OldExportIndex++ ) {
if ( OldExportNameArray[ OldExportIndex ] ) {
OldExportName = ImageRvaToMappedAddress( OldFileNtHeader, OldExportNameArray[ OldExportIndex ], OldFileMapped, OldFileSize );
if ( OldExportName ) {
NewExportSymbolNode = SymRBFind( &NewExportNameTree, OldExportName );
if ( NewExportSymbolNode ) {
//
// Found a name match. The Rva field in the
// symbol node contains the index into the
// NewExportNameArray.
//
// This match gives us two rift entries: one
// for the locations of the names themselves,
// and another for the locations of the
// functions corresponding to those names.
//
NewExportIndex = NewExportSymbolNode->Rva;
AddRiftEntryToTable(
RiftTable,
OldExportNameArray[ OldExportIndex ],
NewExportNameArray[ NewExportIndex ]
);
if ( OldExportNameToOrdinal && NewExportNameToOrdinal ) {
OldOrdinal = OldExportNameToOrdinal[ OldExportIndex ];
NewOrdinal = NewExportNameToOrdinal[ NewExportIndex ];
if (( OldOrdinal < OldExportFunctionCount ) &&
( NewOrdinal < NewExportFunctionCount )) {
AddRiftEntryToTable(
RiftTable,
OldExportFunctionArray[ OldOrdinal ],
NewExportFunctionArray[ NewOrdinal ]
);
}
}
}
}
}
}
}
//
// Now use ordinals to match any exports that don't have names.
// We use the NameToOrdinal table to determine if a name exists.
// For all ordinals that don't have a NameToOrdinal entry, we
// create a match.
//
if (( NewExportFunctionArray ) && ( NewExportNameToOrdinal )) {
NewExportOrdinalNameExists = SubAllocate( SubAllocator, NewExportFunctionCount );
if ( NewExportOrdinalNameExists != NULL ) {
for ( NewExportIndex = 0; NewExportIndex < NewExportNameCount; NewExportIndex++ ) {
NewOrdinal = NewExportNameToOrdinal[ NewExportIndex ];
if ( NewOrdinal < NewExportFunctionCount ) {
NewExportOrdinalNameExists[ NewOrdinal ] = TRUE;
}
}
OrdinalBaseNewToOld = (LONG)NewExportDir->Base - (LONG)OldExportDir->Base;
for ( NewOrdinal = 0; NewOrdinal < NewExportFunctionCount; NewOrdinal++ ) {
if ( ! NewExportOrdinalNameExists[ NewOrdinal ] ) {
OldOrdinal = NewOrdinal + OrdinalBaseNewToOld;
if ( OldOrdinal < OldExportFunctionCount ) {
AddRiftEntryToTable(
RiftTable,
OldExportFunctionArray[ OldOrdinal ],
NewExportFunctionArray[ NewOrdinal ]
);
}
}
}
}
}
}
}
//
// Create rifts for image import directory
//
{
UP_IMAGE_IMPORT_DESCRIPTOR OldImportDir;
UP_IMAGE_IMPORT_DESCRIPTOR NewImportDir;
ULONG OldImportDirRva;
ULONG NewImportDirRva;
ULONG OldImportDirIndex;
ULONG NewImportDirIndex;
LPSTR OldImportDllName;
LPSTR NewImportDllName;
LPSTR OldImportDllNameLowercase;
LPSTR NewImportDllNameLowercase;
UP_IMAGE_THUNK_DATA32 OldImportThunk;
UP_IMAGE_THUNK_DATA32 NewImportThunk;
UP_IMAGE_THUNK_DATA32 OldImportOriginalThunk;
UP_IMAGE_THUNK_DATA32 NewImportOriginalThunk;
ULONG OldImportThunkIndex;
ULONG NewImportThunkIndex;
UP_IMAGE_IMPORT_BY_NAME OldImportByName;
UP_IMAGE_IMPORT_BY_NAME NewImportByName;
LPSTR OldImportName;
LPSTR NewImportName;
SYMBOL_TREE NewImportDllNameTree;
SYMBOL_TREE NewImportFunctionNameTree;
PSYMBOL_NODE NewImportDllSymbolNode;
PSYMBOL_NODE NewImportFunctionSymbolNode;
OldImportDirRva = ImageDirectoryRvaAndSize(
OldFileNtHeader,
IMAGE_DIRECTORY_ENTRY_IMPORT,
NULL
);
NewImportDirRva = ImageDirectoryRvaAndSize(
NewFileNtHeader,
IMAGE_DIRECTORY_ENTRY_IMPORT,
NULL
);
OldImportDir = ImageDirectoryMappedAddress(
OldFileNtHeader,
IMAGE_DIRECTORY_ENTRY_IMPORT,
NULL,
OldFileMapped,
OldFileSize
);
NewImportDir = ImageDirectoryMappedAddress(
NewFileNtHeader,
IMAGE_DIRECTORY_ENTRY_IMPORT,
NULL,
NewFileMapped,
NewFileSize
);
if (( OldImportDir ) && ( NewImportDir )) {
//
// Now build a tree of new import names, then walk old export names
// looking for matches in tree of new import names.
//
SymRBInitTree(
&NewImportDllNameTree,
SubAllocator
);
SymRBInitTree(
&NewImportFunctionNameTree,
SubAllocator
);
for ( NewImportDirIndex = 0; NewImportDir[ NewImportDirIndex ].Characteristics; NewImportDirIndex++ ) {
if ( NewImportDir[ NewImportDirIndex ].Name ) {
NewImportDllName = ImageRvaToMappedAddress( NewFileNtHeader, NewImportDir[ NewImportDirIndex ].Name, NewFileMapped, NewFileSize );
if ( NewImportDllName ) {
NewImportDllNameLowercase = MySubAllocStrDup( SubAllocator, NewImportDllName );
if ( NewImportDllNameLowercase ) {
MyLowercase( NewImportDllNameLowercase );
SymRBInsert( &NewImportDllNameTree, NewImportDllNameLowercase, NewImportDirIndex );
NewImportThunk = ImageRvaToMappedAddress( NewFileNtHeader, (ULONG)NewImportDir[ NewImportDirIndex ].FirstThunk, NewFileMapped, NewFileSize );
if ( NewImportThunk ) {
for ( NewImportThunkIndex = 0; NewImportThunk[ NewImportThunkIndex ].u1.Ordinal; NewImportThunkIndex++ ) {
if ( ! IMAGE_SNAP_BY_ORDINAL32( NewImportThunk[ NewImportThunkIndex ].u1.Ordinal )) {
NewImportByName = ImageRvaToMappedAddress( NewFileNtHeader, (ULONG)NewImportThunk[ NewImportThunkIndex ].u1.AddressOfData, NewFileMapped, NewFileSize );
if ( NewImportByName ) {
NewImportName = MySubAllocStrDupAndCat(
SubAllocator,
NewImportDllNameLowercase,
(LPSTR)NewImportByName->Name,
'!'
);
if ( NewImportName ) {
SymRBInsert( &NewImportFunctionNameTree, NewImportName, NewImportThunkIndex );
}
}
}
}
}
}
}
}
}
for ( OldImportDirIndex = 0; OldImportDir[ OldImportDirIndex ].Characteristics; OldImportDirIndex++ ) {
if ( OldImportDir[ OldImportDirIndex ].Name ) {
OldImportDllName = ImageRvaToMappedAddress( OldFileNtHeader, OldImportDir[ OldImportDirIndex ].Name, OldFileMapped, OldFileSize );
if ( OldImportDllName ) {
OldImportDllNameLowercase = MySubAllocStrDup( SubAllocator, OldImportDllName );
if ( OldImportDllNameLowercase ) {
MyLowercase( OldImportDllNameLowercase );
NewImportDllSymbolNode = SymRBFind( &NewImportDllNameTree, OldImportDllNameLowercase );
if ( NewImportDllSymbolNode ) {
//
// Found a matching dll import descriptor.
// This will give us four rifts: one for the
// descriptor itself, another for the
// dll name referenced by the descriptor, and
// the FirstThunk and OriginalFirstThunk
// arrays.
//
// The index of the new import descriptor is
// stored in the Rva field of the node.
//
NewImportDirIndex = NewImportDllSymbolNode->Rva;
AddRiftEntryToTable(
RiftTable,
OldImportDirRva + ( OldImportDirIndex * sizeof( IMAGE_IMPORT_DESCRIPTOR )),
NewImportDirRva + ( NewImportDirIndex * sizeof( IMAGE_IMPORT_DESCRIPTOR ))
);
AddRiftEntryToTable(
RiftTable,
(ULONG)OldImportDir[ OldImportDirIndex ].Name,
(ULONG)NewImportDir[ NewImportDirIndex ].Name
);
AddRiftEntryToTable(
RiftTable,
(ULONG)OldImportDir[ OldImportDirIndex ].OriginalFirstThunk,
(ULONG)NewImportDir[ NewImportDirIndex ].OriginalFirstThunk
);
AddRiftEntryToTable(
RiftTable,
(ULONG)OldImportDir[ OldImportDirIndex ].FirstThunk,
(ULONG)NewImportDir[ NewImportDirIndex ].FirstThunk
);
OldImportThunk = ImageRvaToMappedAddress( OldFileNtHeader, (ULONG)OldImportDir[ OldImportDirIndex ].FirstThunk, OldFileMapped, OldFileSize );
if ( OldImportThunk ) {
for ( OldImportThunkIndex = 0; OldImportThunk[ OldImportThunkIndex ].u1.Ordinal; OldImportThunkIndex++ ) {
if ( ! IMAGE_SNAP_BY_ORDINAL32( OldImportThunk[ OldImportThunkIndex ].u1.Ordinal )) {
OldImportByName = ImageRvaToMappedAddress( OldFileNtHeader, (ULONG)OldImportThunk[ OldImportThunkIndex ].u1.AddressOfData, OldFileMapped, OldFileSize );
if ( OldImportByName ) {
OldImportName = MySubAllocStrDupAndCat(
SubAllocator,
OldImportDllNameLowercase,
(LPSTR)OldImportByName->Name,
'!'
);
if ( OldImportName ) {
NewImportFunctionSymbolNode = SymRBFind( &NewImportFunctionNameTree, OldImportName );
if ( NewImportFunctionSymbolNode ) {
//
// Found a matching import function name.
// This will give us two rifts: one for the
// FirstThunk arrays and another for the
// OriginalFirstThunk arrays.
//
// The index of the new import thunk is
// stored in the Rva field of the node.
//
NewImportThunkIndex = NewImportFunctionSymbolNode->Rva;
NewImportThunk = ImageRvaToMappedAddress( NewFileNtHeader, (ULONG)NewImportDir[ NewImportDirIndex ].FirstThunk, NewFileMapped, NewFileSize );
if ( NewImportThunk ) {
AddRiftEntryToTable(
RiftTable,
(ULONG)OldImportThunk[ OldImportThunkIndex ].u1.AddressOfData,
(ULONG)NewImportThunk[ NewImportThunkIndex ].u1.AddressOfData
);
}
OldImportOriginalThunk = ImageRvaToMappedAddress( OldFileNtHeader, (ULONG)OldImportDir[ OldImportDirIndex ].OriginalFirstThunk, OldFileMapped, OldFileSize );
NewImportOriginalThunk = ImageRvaToMappedAddress( NewFileNtHeader, (ULONG)NewImportDir[ NewImportDirIndex ].OriginalFirstThunk, NewFileMapped, NewFileSize );
if ( OldImportOriginalThunk && NewImportOriginalThunk ) {
AddRiftEntryToTable(
RiftTable,
(ULONG)OldImportOriginalThunk[ OldImportThunkIndex ].u1.AddressOfData,
(ULONG)NewImportOriginalThunk[ NewImportThunkIndex ].u1.AddressOfData
);
}
}
}
}
}
}
}
}
}
}
}
}
}
}
//
// Create rift entries for resources
//
{
PUCHAR OldResBase, NewResBase;
ULONG OldResSize, NewResSize;
ULONG OldResRva, NewResRva;
OldResBase = ImageDirectoryMappedAddress(
OldFileNtHeader,
IMAGE_DIRECTORY_ENTRY_RESOURCE,
&OldResSize,
OldFileMapped,
OldFileSize
);
NewResBase = ImageDirectoryMappedAddress(
NewFileNtHeader,
IMAGE_DIRECTORY_ENTRY_RESOURCE,
&NewResSize,
NewFileMapped,
NewFileSize
);
if ( OldResBase && NewResBase ) {
OldResRva = ImageDirectoryRvaAndSize( OldFileNtHeader, IMAGE_DIRECTORY_ENTRY_RESOURCE, NULL );
NewResRva = ImageDirectoryRvaAndSize( NewFileNtHeader, IMAGE_DIRECTORY_ENTRY_RESOURCE, NULL );
GetResourceRiftInfoRecursive(
(UP_IMAGE_RESOURCE_DIRECTORY) OldResBase,
OldResBase,
OldResBase + OldResSize,
OldResRva,
(UP_IMAGE_RESOURCE_DIRECTORY) NewResBase,
NewResBase,
NewResBase + NewResSize,
NewResRva,
RiftTable
);
}
}
//
// Gen rift info for other non-symbol stuff here.
//
#ifdef TESTCODE
printf( "\r%9d non-symbol rift entries\n", RiftTable->RiftEntryCount );
#endif
return TRUE;
}
VOID
MyUndecorateSymbol(
IN LPCSTR DecoratedSymbol,
OUT LPSTR UndecoratedSymbol,
IN DWORD BufferSize
)
{
LPCSTR d;
LPCSTR e;
ULONG Len;
ULONG Ext;
d = DecoratedSymbol;
if (( d[ 0 ] == '.' ) &&
( d[ 1 ] == '.' ) &&
( d[ 2 ] == '?' )) {
d += 2;
}
if ( *d == '?' ) {
*UndecoratedSymbol = 0; // in case UnDecorateSymbolName fails
Imagehlp.UnDecorateSymbolName( d, UndecoratedSymbol, BufferSize, UNDNAME_NAME_ONLY );
//
// UnDecorateSymbolName will strip any trailing '_nnn' (from BBT omap
// info), but we want to preserved it. Check for that pattern in the
// original, and if found, append it to the new string.
//
d += strlen( d + 1 ); // point d to last character in string
if (( *d >= '0' ) && ( *d <= '9' )) {
do {
--d;
}
while (( *d >= '0' ) && ( *d <= '9' ));
if ( *d == '_' ) {
//
// Matches the '_nnn' pattern, append to new string.
//
if (( strlen( UndecoratedSymbol ) + strlen( d )) < ( BufferSize - 1 )) {
strcat( UndecoratedSymbol, d );
}
}
}
}
else {
//
// Strip any preceding '_' or '@'.
//
if (( *d == '_' ) || ( *d == '@' )) {
++d;
}
//
// Find end of name as either terminator or '@nn'.
//
for ( e = d; ( *e ) && ( *e != '@' ); ) {
++e;
}
//
// Copy as much of name as will fit in the buffer.
//
Len = (ULONG)( e - d );
if ( Len > ( BufferSize - 1 )) {
Len = ( BufferSize - 1 );
}
memcpy( UndecoratedSymbol, d, Len );
if ( *e == '@' ) {
//
// Skip '@nn' to append remainder of symbol
//
do {
++e;
}
while (( *e >= '0' ) && ( *e <= '9' ));
d = e;
while ( *e ) {
++e;
}
//
// Now 'd' points to first character after '@nn' and 'e' points
// to end of the string. If the extension will fit in the buffer,
// append it.
//
Ext = (ULONG)( e - d );
if (( Len + Ext ) < ( BufferSize - 1 )) {
memcpy( UndecoratedSymbol + Len, d, Ext );
}
Len += Ext;
}
//
// Terminate the string.
//
UndecoratedSymbol[ Len ] = 0;
}
}
BOOL
UndecorateSymbolAndAddToTree(
IN LPCSTR SymbolName,
IN ULONG Rva,
IN PSYMBOL_TREE SymbolTree
)
{
ULONG SymbolNameSize = (ULONG) strlen( SymbolName ) + 1;
LPSTR UndecoratedName = _alloca( SymbolNameSize );
PSYMBOL_NODE SymbolNode;
MyUndecorateSymbol(
SymbolName,
UndecoratedName,
SymbolNameSize
);
SymbolNode = SymRBInsert(
SymbolTree,
UndecoratedName,
Rva
);
return ( SymbolNode != NULL );
}
BOOL
CALLBACK
NewFileEnumSymbolsCallback(
LPSTR SymbolName,
ULONG_PTR SymbolAddr,
ULONG SymbolSize,
PVOID Context
)
{
PSYMBOL_CONTEXT SymbolContext = Context;
PSYMBOL_NODE SymbolNode;
ULONG NewRva;
UNREFERENCED_PARAMETER( SymbolSize );
#ifdef TESTCODE
if ( SymbolContext->OutFile != INVALID_HANDLE_VALUE ) {
CHAR TextBuffer[ 16 + MAX_SYMBOL_NAME_LENGTH ];
CHAR Discarded;
DWORD Actual;
Discarded = 'X';
NewRva = SymbolAddr;
if ( NewRva > SymbolContext->NewImageBase ) {
NewRva -= SymbolContext->NewImageBase;
Discarded = ' ';
}
sprintf( TextBuffer, "%08X %c %s\r\n", NewRva, Discarded, SymbolName );
WriteFile( SymbolContext->OutFile, TextBuffer, strlen( TextBuffer ), &Actual, NULL );
}
#endif // TESTCODE
if ( SymbolAddr > SymbolContext->NewImageBase ) {
NewRva = (ULONG)( SymbolAddr - SymbolContext->NewImageBase );
SymbolNode = SymRBInsert(
&SymbolContext->NewDecoratedSymbolTree,
SymbolName,
NewRva
);
return ( SymbolNode != NULL );
}
return TRUE;
}
BOOL
CALLBACK
OldFileEnumSymbolsCallback(
LPSTR SymbolName,
ULONG_PTR SymbolAddr,
ULONG SymbolSize,
PVOID Context
)
{
PSYMBOL_CONTEXT SymbolContext = Context;
PSYMBOL_NODE SymbolNode;
ULONG OldRva;
UNREFERENCED_PARAMETER( SymbolSize );
#ifdef TESTCODE
if ( SymbolContext->OutFile != INVALID_HANDLE_VALUE ) {
CHAR TextBuffer[ 16 + MAX_SYMBOL_NAME_LENGTH ];
CHAR Discarded;
DWORD Actual;
Discarded = 'X';
OldRva = SymbolAddr;
if ( OldRva > SymbolContext->OldImageBase ) {
OldRva -= SymbolContext->OldImageBase;
Discarded = ' ';
}
sprintf( TextBuffer, "%08X %c %s\r\n", OldRva, Discarded, SymbolName );
WriteFile( SymbolContext->OutFile, TextBuffer, strlen( TextBuffer ), &Actual, NULL );
}
#endif // TESTCODE
if ( SymbolAddr > SymbolContext->OldImageBase ) {
OldRva = (ULONG)( SymbolAddr - SymbolContext->OldImageBase );
SymbolNode = SymRBFind(
&SymbolContext->NewDecoratedSymbolTree,
SymbolName
);
if ( SymbolNode ) {
AddRiftEntryToTable( SymbolContext->RiftTable, OldRva, SymbolNode->Rva );
SymbolNode->Hit = 1;
#ifdef TESTCODE
CountDecoratedMatches++;
#endif // TESTCODE
}
else {
//
// Didn't find matching new symbol. Build a tree of unmatched
// old symbols with UNdecorated names. Later we'll match up
// remaining unmatched new symbols to these unmatched old symbols
// by their undecorated names.
//
if ( SymbolContext->SymbolOptionFlags & PATCH_SYMBOL_UNDECORATED_TOO ) {
return UndecorateSymbolAndAddToTree(
SymbolName,
OldRva,
&SymbolContext->OldUndecoratedSymbolTree
);
}
}
}
return TRUE;
}
BOOL
MatchRemainingSymbolsThisNode(
IN PSYMBOL_NODE NewDecoratedSymbolNode,
IN PSYMBOL_TREE NewUndecoratedSymbolTree,
IN PSYMBOL_TREE OldUndecoratedSymbolTree,
IN PRIFT_TABLE RiftTable
)
{
if ( ! NewDecoratedSymbolNode->Hit ) {
ULONG SymbolNameSize = (ULONG) strlen( NewDecoratedSymbolNode->SymbolName ) + 1;
LPSTR NewUndecoratedName = _alloca( SymbolNameSize );
PSYMBOL_NODE NewUndecoratedSymbolNode;
PSYMBOL_NODE OldUndecoratedSymbolNode;
MyUndecorateSymbol(
NewDecoratedSymbolNode->SymbolName,
NewUndecoratedName,
SymbolNameSize
);
OldUndecoratedSymbolNode = SymRBFind(
OldUndecoratedSymbolTree,
NewUndecoratedName
);
if ( OldUndecoratedSymbolNode ) {
AddRiftEntryToTable(
RiftTable,
OldUndecoratedSymbolNode->Rva,
NewDecoratedSymbolNode->Rva
);
OldUndecoratedSymbolNode->Hit = 1;
#ifdef TESTCODE
CountUndecoratedMatches++;
#endif // TESTCODE
}
else {
//
// This new symbol has no match in the old symbol tree. Build a
// tree of unmatched new undecorated symbols.
//
NewUndecoratedSymbolNode = SymRBInsert(
NewUndecoratedSymbolTree,
NewUndecoratedName,
NewDecoratedSymbolNode->Rva
);
return ( NewUndecoratedSymbolNode != NULL );
}
}
return TRUE;
}
BOOL
MatchRemainingSymbolsRecursive(
IN PSYMBOL_NODE NewDecoratedSymbolNode,
IN PSYMBOL_TREE NewUndecoratedSymbolTree,
IN PSYMBOL_TREE OldUndecoratedSymbolTree,
IN PRIFT_TABLE RiftTable
)
{
if ( NewDecoratedSymbolNode == RBNIL ) {
return TRUE;
}
return ( MatchRemainingSymbolsRecursive( NewDecoratedSymbolNode->Left, NewUndecoratedSymbolTree, OldUndecoratedSymbolTree, RiftTable ) &&
MatchRemainingSymbolsRecursive( NewDecoratedSymbolNode->Right, NewUndecoratedSymbolTree, OldUndecoratedSymbolTree, RiftTable ) &&
MatchRemainingSymbolsThisNode( NewDecoratedSymbolNode, NewUndecoratedSymbolTree, OldUndecoratedSymbolTree, RiftTable ));
}
#ifdef TESTCODE
VOID
DumpUnHitSymbolNode(
IN PSYMBOL_NODE SymbolNode,
IN HANDLE hFile
)
{
CHAR TextBuffer[ 16 + MAX_SYMBOL_NAME_LENGTH ];
DWORD Actual;
if ( ! SymbolNode->Hit ) {
sprintf( TextBuffer, "%08X %s\r\n", SymbolNode->Rva, SymbolNode->SymbolName );
WriteFile( hFile, TextBuffer, strlen( TextBuffer ), &Actual, NULL );
}
}
VOID
DumpUnHitSymbolNodesRecursive(
IN PSYMBOL_NODE SymbolNode,
IN HANDLE hFile
)
{
if ( SymbolNode == RBNIL ) {
return;
}
//
// The tree is in hash order, not Rva order, so the output will appear
// to be in random order (easily solved with sort.exe utility).
//
DumpUnHitSymbolNode( SymbolNode, hFile );
DumpUnHitSymbolNodesRecursive( SymbolNode->Left, hFile );
DumpUnHitSymbolNodesRecursive( SymbolNode->Right, hFile );
}
VOID
DumpUnHitSymbolNodes(
IN PSYMBOL_TREE SymbolTree,
IN LPCSTR DumpFileName
)
{
HANDLE hFile;
hFile = CreateFile(
DumpFileName,
GENERIC_WRITE,
FILE_SHARE_READ,
NULL,
CREATE_ALWAYS,
FILE_ATTRIBUTE_NORMAL,
NULL
);
if ( hFile != INVALID_HANDLE_VALUE ) {
DumpUnHitSymbolNodesRecursive( SymbolTree->Root, hFile );
CloseHandle( hFile );
}
}
#endif // TESTCODE
BOOL
MatchRemainingSymbols(
IN PSYMBOL_TREE NewDecoratedSymbolTree,
IN PSYMBOL_TREE NewUndecoratedSymbolTree,
IN PSYMBOL_TREE OldUndecoratedSymbolTree,
IN PRIFT_TABLE RiftTable
)
{
BOOL Success;
//
// Walk old tree, for each unmatched symbol, undecorate it and try to
// find match in the undecorated new symbol tree. If it fails to match,
// add it to the old undecorated tree.
//
Success = MatchRemainingSymbolsRecursive(
NewDecoratedSymbolTree->Root,
NewUndecoratedSymbolTree,
OldUndecoratedSymbolTree,
RiftTable
);
if ( Success ) {
//
// Now we have remaining unmatched undecorated symbols in the
// OldUndecoratedSymbolTree and NewUndecoratedSymbolTree.
//
// Here is an opportunity to do soft name matching, like for
// BBT omap generated symbol names (have trailing '_nnn').
// Unfortunately, current versions of imagehlp append an '_nnn'
// value that is useless becaue it is not the offset from the
// start of the function.
//
#ifdef TESTCODE
DumpUnHitSymbolNodes( OldUndecoratedSymbolTree, "UnmatchedOldSymbols.out" );
DumpUnHitSymbolNodes( NewUndecoratedSymbolTree, "UnmatchedNewSymbols.out" );
#endif // TESTCODE
}
return Success;
}
BOOL
GetImageSymbolRiftInfo(
IN HANDLE OldFileHandle,
IN PUCHAR OldFileMapped,
IN ULONG OldFileSize,
IN UP_IMAGE_NT_HEADERS32 OldFileNtHeader,
IN LPCSTR OldFileSymPath,
IN ULONG OldFileOriginalChecksum,
IN ULONG OldFileOriginalTimeDate,
IN ULONG OldFileIndex,
IN HANDLE NewFileHandle,
IN PUCHAR NewFileMapped,
IN ULONG NewFileSize,
IN UP_IMAGE_NT_HEADERS32 NewFileNtHeader,
IN LPCSTR NewFileSymPath,
IN ULONG SymbolOptionFlags,
IN HANDLE SubAllocator,
IN PRIFT_TABLE RiftTable,
IN PPATCH_SYMLOAD_CALLBACK SymLoadCallback,
IN PVOID SymLoadContext
)
{
SYMBOL_CONTEXT SymbolContext;
DWORD SymOptions;
ULONG_PTR OldBase;
ULONG_PTR NewBase;
BOOL Success;
#ifdef TESTCODE
ULONG InitialRiftEntries = RiftTable->RiftEntryCount;
#endif
UNREFERENCED_PARAMETER( OldFileNtHeader );
UNREFERENCED_PARAMETER( OldFileMapped );
UNREFERENCED_PARAMETER( OldFileSize );
UNREFERENCED_PARAMETER( NewFileMapped );
UNREFERENCED_PARAMETER( NewFileSize );
InitImagehlpCritSect();
EnterCriticalSection( &ImagehlpCritSect );
Success = LoadImagehlp();
if ( Success ) {
__try {
SymOptions = Imagehlp.SymGetOptions();
SymOptions &= ~SYMOPT_CASE_INSENSITIVE;
SymOptions &= ~SYMOPT_UNDNAME;
SymOptions &= ~SYMOPT_DEFERRED_LOADS;
Imagehlp.SymSetOptions( SymOptions );
Success = Imagehlp.SymInitialize( hProc, NewFileSymPath, FALSE );
if ( Success ) {
__try {
SymRBInitTree(
&SymbolContext.NewDecoratedSymbolTree,
SubAllocator
);
SymRBInitTree(
&SymbolContext.NewUndecoratedSymbolTree,
SubAllocator
);
SymRBInitTree(
&SymbolContext.OldUndecoratedSymbolTree,
SubAllocator
);
NewBase = Imagehlp.SymLoadModule( hProc, NewFileHandle, NULL, "New", (ULONG_PTR)NewFileMapped, NewFileSize );
Success = ( NewBase != 0 );
if ( Success ) {
__try {
if ( SymLoadCallback ) {
ZeroMemory( &ImagehlpModuleInfo, sizeof( ImagehlpModuleInfo ));
ImagehlpModuleInfo.SizeOfStruct = sizeof( ImagehlpModuleInfo );
Success = Imagehlp.SymGetModuleInfo(
hProc,
NewBase,
&ImagehlpModuleInfo
);
if ( Success ) {
Success = SymLoadCallback(
0,
ImagehlpModuleInfo.LoadedImageName,
ImagehlpModuleInfo.SymType,
ImagehlpModuleInfo.CheckSum,
ImagehlpModuleInfo.TimeDateStamp,
NewFileNtHeader->OptionalHeader.CheckSum,
NewFileNtHeader->FileHeader.TimeDateStamp,
SymLoadContext
);
}
}
if ( Success ) {
SymbolContext.NewImageBase = NewBase;
SymbolContext.SymbolOptionFlags = SymbolOptionFlags;
SymbolContext.RiftTable = RiftTable;
#ifdef TESTCODE
CountDecoratedMatches = 0;
CountUndecoratedMatches = 0;
SymbolContext.OutFile = CreateFile(
"NewSymbols.out",
GENERIC_WRITE,
FILE_SHARE_READ,
NULL,
CREATE_ALWAYS,
FILE_ATTRIBUTE_NORMAL,
NULL
);
#endif // TESTCODE
Success = Imagehlp.SymEnumerateSymbols( hProc, NewBase, NewFileEnumSymbolsCallback, &SymbolContext );
#ifdef TESTCODE
if ( SymbolContext.OutFile != INVALID_HANDLE_VALUE ) {
CloseHandle( SymbolContext.OutFile );
}
#endif // TESTCODE
}
}
__except( EXCEPTION_EXECUTE_HANDLER ) {
Success = FALSE;
}
Imagehlp.SymUnloadModule( hProc, NewBase );
}
}
__except( EXCEPTION_EXECUTE_HANDLER ) {
Success = FALSE;
}
//
// Must do cleanup and reinitialize Imagehlp for this
// process identifier. Otherwise it thinks the old
// module is still hanging around.
//
Imagehlp.SymCleanup( hProc );
if ( Success ) {
Success = Imagehlp.SymInitialize( hProc, OldFileSymPath, FALSE );
if ( Success ) {
__try {
OldBase = Imagehlp.SymLoadModule( hProc, OldFileHandle, NULL, "Old", (ULONG_PTR)OldFileMapped, OldFileSize );
Success = ( OldBase != 0 );
if ( Success ) {
__try {
if ( SymLoadCallback ) {
ZeroMemory( &ImagehlpModuleInfo, sizeof( ImagehlpModuleInfo ));
ImagehlpModuleInfo.SizeOfStruct = sizeof( ImagehlpModuleInfo );
Success = Imagehlp.SymGetModuleInfo(
hProc,
OldBase,
&ImagehlpModuleInfo
);
if ( Success ) {
Success = SymLoadCallback(
OldFileIndex + 1,
ImagehlpModuleInfo.LoadedImageName,
ImagehlpModuleInfo.SymType,
ImagehlpModuleInfo.CheckSum,
ImagehlpModuleInfo.TimeDateStamp,
OldFileOriginalChecksum,
OldFileOriginalTimeDate,
SymLoadContext
);
}
}
if ( Success ) {
SymbolContext.OldImageBase = OldBase;
#ifdef TESTCODE
SymbolContext.OutFile = CreateFile(
"OldSymbols.out",
GENERIC_WRITE,
FILE_SHARE_READ,
NULL,
CREATE_ALWAYS,
FILE_ATTRIBUTE_NORMAL,
NULL
);
#endif // TESTCODE
Success = Imagehlp.SymEnumerateSymbols( hProc, OldBase, OldFileEnumSymbolsCallback, &SymbolContext );
#ifdef TESTCODE
if ( SymbolContext.OutFile != INVALID_HANDLE_VALUE ) {
CloseHandle( SymbolContext.OutFile );
}
#endif // TESTCODE
}
if ( Success ) {
//
// Need to match remaining decorated new symbols in tree
// with unmatched now-undecorated old symbols in other tree.
//
if ( SymbolOptionFlags & PATCH_SYMBOL_UNDECORATED_TOO ) {
Success = MatchRemainingSymbols(
&SymbolContext.NewDecoratedSymbolTree,
&SymbolContext.NewUndecoratedSymbolTree,
&SymbolContext.OldUndecoratedSymbolTree,
RiftTable
);
}
}
}
__except( EXCEPTION_EXECUTE_HANDLER ) {
Success = FALSE;
}
Imagehlp.SymUnloadModule( hProc, OldBase );
}
}
__except( EXCEPTION_EXECUTE_HANDLER ) {
Success = FALSE;
}
Imagehlp.SymCleanup( hProc );
}
}
}
}
__except( EXCEPTION_EXECUTE_HANDLER ) {
Success = FALSE;
}
}
LeaveCriticalSection( &ImagehlpCritSect );
if ( ! Success ) {
SetLastError( ERROR_PATCH_IMAGEHLP_FAILURE );
}
#ifdef TESTCODE
printf( "\r%9d decorated symbol matches\n", CountDecoratedMatches );
printf( "\r%9d undecorated symbol matches\n", CountUndecoratedMatches );
printf( "\r%9d rift entries from symbols\n", RiftTable->RiftEntryCount - InitialRiftEntries );
#endif
return Success;
}
BOOL
OptimizeImageRiftInfo(
IN PUCHAR OldFileMapped,
IN ULONG OldFileSize,
IN UP_IMAGE_NT_HEADERS32 OldFileNtHeader,
IN PUCHAR NewFileMapped,
IN ULONG NewFileSize,
IN UP_IMAGE_NT_HEADERS32 NewFileNtHeader,
IN HANDLE SubAllocator,
IN PRIFT_TABLE RiftTable
)
{
UNREFERENCED_PARAMETER( OldFileMapped );
UNREFERENCED_PARAMETER( OldFileSize );
UNREFERENCED_PARAMETER( OldFileNtHeader );
UNREFERENCED_PARAMETER( NewFileMapped );
UNREFERENCED_PARAMETER( NewFileSize );
UNREFERENCED_PARAMETER( NewFileNtHeader );
UNREFERENCED_PARAMETER( SubAllocator );
UNREFERENCED_PARAMETER( RiftTable );
return TRUE;
}
#if 0 // This is test code
BOOL
OptimizeImageRiftInfo(
IN PUCHAR OldFileMapped,
IN ULONG OldFileSize,
IN UP_IMAGE_NT_HEADERS32 OldFileNtHeader,
IN PUCHAR NewFileMapped,
IN ULONG NewFileSize,
IN UP_IMAGE_NT_HEADERS32 NewFileNtHeader,
IN HANDLE SubAllocator,
IN PRIFT_TABLE RiftTable
)
{
UP_IMAGE_SECTION_HEADER SectionHeader;
ULONG SectionCount;
PUCHAR SectionStart;
PUCHAR SearchExtent;
ULONG SectionLength;
ULONG SectionOffset;
ULONG SectionBaseRva;
ULONG OldFileLastRva;
ULONG NewFileLastRva;
LONG OldDisplacement;
LONG NewDisplacement;
ULONG OffsetInSection;
ULONG OldOriginRva;
ULONG OldTargetRva;
ULONG TargetOffset;
PUCHAR OldFileHintMap;
PUCHAR NewFileHintMap;
PUCHAR OldFileCopy;
PUCHAR NewFileCopy;
PVOID OldFileCopyNtHeader;
PVOID NewFileCopyNtHeader;
BOOL Success;
BOOL Skip;
ULONG i;
ULONG j;
PUCHAR p;
#ifdef TESTCODE
ULONG CountVerifiedE8Rifts = 0;
ULONG CountDiscoveredE8Rifts = 0;
#endif // TESTCODE
//
// Stage1:
//
// Trusting existing rift info, search for E8/E9/Jcc instructions in
// the Old file, get the corresponding rift, inspect the corresponding
// instruction in the New file. If they match, great. If they don't
// match, search for a correponding instruction in the new file by
// looking forward up to the next rift. If find a suitable match,
// create a new rift entry to support it.
//
// We don't have the benefit of non-exe marked bytes here.
//
if ( OldFileNtHeader->FileHeader.Machine != NewFileNtHeader->FileHeader.Machine ) {
return TRUE; // not much we can do here!
}
//
// We need the HintMap to determine which bytes in the files are not
// executable. The Transform function currently provides this, but
// we don't want to modify our mapped file views here. So, allocate
// a range of VM and make a copy of the file to Transform, perform
// the transformations on that copy just to produce a hint map, then
// free the transformed copy (do this for both old and new files).
//
Success = FALSE;
OldFileHintMap = MyVirtualAlloc( OldFileSize );
NewFileHintMap = MyVirtualAlloc( NewFileSize );
if ( OldFileHintMap && NewFileHintMap ) {
OldFileCopy = MyVirtualAlloc( OldFileSize );
if ( OldFileCopy ) {
CopyMemory( OldFileCopy, OldFileMapped, OldFileSize );
OldFileCopyNtHeader = GetNtHeader( OldFileCopy, OldFileSize );
Success = TransformCoffImage(
( PATCH_TRANSFORM_NO_RELJMPS | PATCH_TRANSFORM_NO_RELCALLS | PATCH_TRANSFORM_NO_RESOURCE ),
OldFileCopyNtHeader,
OldFileCopy,
OldFileSize,
0,
RiftTable,
OldFileHintMap
);
MyVirtualFree( OldFileCopy );
}
if ( Success ) {
Success = FALSE;
NewFileCopy = MyVirtualAlloc( NewFileSize );
if ( NewFileCopy ) {
CopyMemory( NewFileCopy, NewFileMapped, NewFileSize );
NewFileCopyNtHeader = GetNtHeader( NewFileCopy, NewFileSize );
Success = TransformCoffImage(
( PATCH_TRANSFORM_NO_RELJMPS | PATCH_TRANSFORM_NO_RELCALLS | PATCH_TRANSFORM_NO_RESOURCE ),
NewFileCopyNtHeader,
NewFileCopy,
NewFileSize,
0,
RiftTable,
NewFileHintMap
);
MyVirtualFree( NewFileCopy );
}
}
}
if ( Success ) {
//
// We now have valid OldFileHintMap and NewFileHintMap.
//
OldFileLastRva = OldFileNtHeader->OptionalHeader.SizeOfImage;
NewFileLastRva = NewFileNtHeader->OptionalHeader.SizeOfImage;
InsertRiftEntryInSortedTable( RiftTable, RiftTable->RiftEntryCount, OldFileLastRva, NewFileLastRva );
SectionHeader = IMAGE_FIRST_SECTION( OldFileNtHeader );
SectionCount = OldFileNtHeader->FileHeader.NumberOfSections;
for ( i = 0; i < SectionCount; i++ ) {
if ( SectionHeader[ i ].Characteristics & IMAGE_SCN_MEM_EXECUTE ) {
SectionBaseRva = SectionHeader[ i ].VirtualAddress;
SectionLength = MIN( SectionHeader[ i ].Misc.VirtualSize, SectionHeader[ i ].SizeOfRawData );
SectionOffset = SectionHeader[ i ].PointerToRawData;
SectionStart = OldFileMapped + SectionOffset;
if ( OldFileNtHeader->FileHeader.Machine == IMAGE_FILE_MACHINE_I386 ) {
SearchExtent = SectionStart + SectionLength - 5;
for ( p = SectionStart; p < SearchExtent; p++ ) {
if ( *p == 0xE8 ) { // call relative32
//
// Validate that instruction is not something that
// the HintMap indicates is not an executable
// instruction. We're looking for a relative
// call instruction here, so it would not be a
// reloc target.
//
Skip = FALSE;
for ( j = 0; j < 5; j++ ) {
if ( OldFileHintMap[ SectionOffset + ( p - SectionStart ) + j ] & 0x01 ) {
Skip = TRUE;
break;
}
}
if ( Skip ) {
continue;
}
//
// Relative displacement is stored as 32-bit
// signed value following these opcodes. The
// displacement is relative to the NEXT
// instruction, which is at (p + 5).
//
OldDisplacement = *(UNALIGNED LONG*)( p + 1 );
OffsetInSection = ( p + 5 ) - SectionStart;
OldOriginRva = SectionBaseRva + OffsetInSection;
OldTargetRva = OldOriginRva + OldDisplacement;
//
// We expect a lot of false positives here because
// occurences of <E8> will
// likely occur in other parts of the instruction
// stream so now we validate that the TargetRva
// falls within the image and within an executable
// section.
//
if ( OldTargetRva < OldFileLastRva ) {
TargetOffset = ImageRvaToFileOffset( OldFileNtHeader, OldTargetRva );
if ( ! ( OldFileHintMap[ TargetOffset ] & 0x01 )) {
//
// Looks like a valid TargetRva, so lookup the
// corresponding "new" RVAs in the rift table.
//
ULONG RiftIndexOrigin = FindRiftTableEntryForOldRva( RiftTable, OldOriginRva );
ULONG RiftIndexTarget = FindRiftTableEntryForOldRva( RiftTable, OldTargetRva );
ULONG NewOriginRva = OldOriginRva + (LONG)( RiftTable->RiftEntryArray[ RiftIndexOrigin ].NewFileRva - RiftTable->RiftEntryArray[ RiftIndexOrigin ].OldFileRva );
ULONG NewTargetRva = OldTargetRva + (LONG)( RiftTable->RiftEntryArray[ RiftIndexTarget ].NewFileRva - RiftTable->RiftEntryArray[ RiftIndexTarget ].OldFileRva );
PUCHAR NewOriginMa = ImageRvaToMappedAddress( NewFileNtHeader, NewOriginRva, NewFileMapped, NewFileSize );
PUCHAR NewTargetMa = ImageRvaToMappedAddress( NewFileNtHeader, NewTargetRva, NewFileMapped, NewFileSize );
PUCHAR OldTargetMa = ImageRvaToMappedAddress( OldFileNtHeader, OldTargetRva, OldFileMapped, OldFileSize );
PUCHAR OldOriginMa = p + 5;
if (( NewOriginMa ) && ( NewTargetMa ) && ( OldTargetMa )) {
PUCHAR OldInstruct = p;
PUCHAR NewInstruct = NewOriginMa - 5;
//
// A verified call instruction should match the
// instruction byte, the byte following the
// instruction, and the target byte, because
// they should all be executable code that is
// not modified by relocs.
//
// Also verify the NewFileHintMap.
//
if (( *OldInstruct == *NewInstruct ) &&
( *OldOriginMa == *NewOriginMa ) &&
( *OldTargetMa == *NewTargetMa )) {
ULONG NewInstructOffset = NewInstruct - NewFileMapped;
ULONG NewTargetOffset = NewTargetMa - NewFileMapped;
BOOL Skip = FALSE;
for ( j = 0; j < 5; j++ ) {
if ( NewFileHintMap[ NewInstructOffset + j ] & 0x01 ) {
Skip = TRUE;
break;
}
}
if ( NewFileHintMap[ NewTargetOffset + j ] & 0x01 ) {
Skip = TRUE;
}
if ( ! Skip ) {
//
// This is a bonafide good match. Add a rift entry
// for both the instruction and the target. We do
// this so that subsequent rift insertions don't get
// between the rift that coasted to these and these.
//
InsertRiftEntryInSortedTable( RiftTable, RiftIndexOrigin, OldOriginRva - 5, NewOriginRva - 5 );
InsertRiftEntryInSortedTable( RiftTable, RiftIndexTarget, OldTargetRva, NewTargetRva );
#ifdef TESTCODE
CountVerifiedE8Rifts++;
#endif // TESTCODE
}
}
}
}
}
}
}
}
else if ( OldFileNtHeader->FileHeader.Machine == IMAGE_FILE_MACHINE_ALPHA ) {
//
// Implement Alpha platform stuff here.
//
}
}
}
for ( i = 0; i < SectionCount; i++ ) {
if ( SectionHeader[ i ].Characteristics & IMAGE_SCN_MEM_EXECUTE ) {
SectionBaseRva = SectionHeader[ i ].VirtualAddress;
SectionLength = MIN( SectionHeader[ i ].Misc.VirtualSize, SectionHeader[ i ].SizeOfRawData );
SectionOffset = SectionHeader[ i ].PointerToRawData;
SectionStart = OldFileMapped + SectionOffset;
if ( OldFileNtHeader->FileHeader.Machine == IMAGE_FILE_MACHINE_I386 ) {
SearchExtent = SectionStart + SectionLength - 5;
for ( p = SectionStart; p < SearchExtent; p++ ) {
if ( *p == 0xE8 ) { // call relative32
//
// Validate that instruction is not something that
// the HintMap indicates is not an executable
// instruction. We're looking for a relative
// call instruction here, so it would not be a
// reloc target.
//
Skip = FALSE;
for ( j = 0; j < 5; j++ ) {
if ( OldFileHintMap[ SectionOffset + ( p - SectionStart ) + j ] & 0x01 ) {
Skip = TRUE;
break;
}
}
if ( Skip ) {
continue;
}
//
// Relative displacement is stored as 32-bit
// signed value following these opcodes. The
// displacement is relative to the NEXT
// instruction, which is at (p + 5).
//
OldDisplacement = *(UNALIGNED LONG*)( p + 1 );
OffsetInSection = ( p + 5 ) - SectionStart;
OldOriginRva = SectionBaseRva + OffsetInSection;
OldTargetRva = OldOriginRva + OldDisplacement;
//
// We expect a lot of false positives here because
// occurences of <E8> will
// likely occur in other parts of the instruction
// stream so now we validate that the TargetRva
// falls within the image and within an executable
// section.
//
if ( OldTargetRva < OldFileLastRva ) {
TargetOffset = ImageRvaToFileOffset( OldFileNtHeader, OldTargetRva );
if ( ! ( OldFileHintMap[ TargetOffset ] & 0x01 )) {
//
// Looks like a valid TargetRva, so lookup the
// corresponding "new" RVAs in the rift table.
//
ULONG RiftIndexOrigin = FindRiftTableEntryForOldRva( RiftTable, OldOriginRva );
ULONG RiftIndexTarget = FindRiftTableEntryForOldRva( RiftTable, OldTargetRva );
ULONG NewOriginRva = OldOriginRva + (LONG)( RiftTable->RiftEntryArray[ RiftIndexOrigin ].NewFileRva - RiftTable->RiftEntryArray[ RiftIndexOrigin ].OldFileRva );
ULONG NewTargetRva = OldTargetRva + (LONG)( RiftTable->RiftEntryArray[ RiftIndexTarget ].NewFileRva - RiftTable->RiftEntryArray[ RiftIndexTarget ].OldFileRva );
PUCHAR NewOriginMa = ImageRvaToMappedAddress( NewFileNtHeader, NewOriginRva, NewFileMapped, NewFileSize );
PUCHAR NewTargetMa = ImageRvaToMappedAddress( NewFileNtHeader, NewTargetRva, NewFileMapped, NewFileSize );
PUCHAR OldTargetMa = ImageRvaToMappedAddress( OldFileNtHeader, OldTargetRva, OldFileMapped, OldFileSize );
PUCHAR OldOriginMa = p + 5;
if (( NewOriginMa ) && ( NewTargetMa ) && ( OldTargetMa )) {
PUCHAR OldInstruct = p;
PUCHAR NewInstruct = NewOriginMa - 5;
//
// A verified call instruction should match the
// instruction byte, the byte following the
// instruction, and the target byte, because
// they should all be executable code that is
// not modified by relocs.
//
// Check NewHintMap too.
//
if (( *OldInstruct == *NewInstruct ) &&
( *OldOriginMa == *NewOriginMa ) &&
( *OldTargetMa == *NewTargetMa )) {
ULONG NewInstructOffset = NewInstruct - NewFileMapped;
ULONG NewTargetOffset = NewTargetMa - NewFileMapped;
BOOL Skip = FALSE;
for ( j = 0; j < 5; j++ ) {
if ( NewFileHintMap[ NewInstructOffset + j ] & 0x01 ) {
Skip = TRUE;
break;
}
}
if ( NewFileHintMap[ NewTargetOffset + j ] & 0x01 ) {
Skip = TRUE;
}
if ( ! Skip ) {
//
// This is a bonafide good match.
//
continue;
}
}
{
//
// Instructions don't match. Scan to find
// matching instruction in new file. Scan
// the extent of this rift entry.
//
PUCHAR ScanInstruct;
PUCHAR LowestMaToScan;
PUCHAR HighestMaToScan;
ULONG LowestRvaToScan = RiftTable->RiftEntryArray[ RiftIndexOrigin ].NewFileRva;
ULONG HighestRvaToScan = RiftTable->RiftEntryArray[ RiftIndexOrigin + 1 ].NewFileRva;
ULONG ExpectedTargetRva = NewTargetRva;
BOOL Found = FALSE;
LowestMaToScan = ImageRvaToMappedAddress( NewFileNtHeader, LowestRvaToScan, NewFileMapped, NewFileSize );
HighestMaToScan = ImageRvaToMappedAddress( NewFileNtHeader, HighestRvaToScan, NewFileMapped, NewFileSize );
HighestMaToScan -= 5; // size of instruction
for ( ScanInstruct = NewInstruct + 1; ScanInstruct <= HighestMaToScan; ScanInstruct++ ) {
if ( *ScanInstruct == 0xE8 ) {
//
// check NewHintMap
//
NewOriginMa = ScanInstruct + 5;
NewOriginRva = MappedAddressToImageRva( NewFileNtHeader, NewOriginMa, NewFileMapped );
NewDisplacement = *(UNALIGNED LONG*)( ScanInstruct + 1 );
NewTargetRva = NewOriginRva + NewDisplacement;
NewTargetMa = ImageRvaToMappedAddress( NewFileNtHeader, NewTargetRva, NewFileMapped, NewFileSize );
if (( NewOriginRva ) && ( NewTargetMa )) {
//
// We already know *OldInstruct == *ScanInstruct
//
if (( *OldOriginMa == *NewOriginMa ) &&
( *OldTargetMa == *NewTargetMa ) &&
( NewTargetRva == ExpectedTargetRva )) {
ULONG NewInstructOffset = ScanInstruct - NewFileMapped;
ULONG NewTargetOffset = NewTargetMa - NewFileMapped;
BOOL Skip = FALSE;
for ( j = 0; j < 5; j++ ) {
if ( NewFileHintMap[ NewInstructOffset + j ] & 0x01 ) {
Skip = TRUE;
break;
}
}
if ( NewFileHintMap[ NewTargetOffset + j ] & 0x01 ) {
Skip = TRUE;
}
if ( ! Skip ) {
InsertRiftEntryInSortedTable( RiftTable, RiftIndexOrigin, OldOriginRva - 5, NewOriginRva - 5 );
InsertRiftEntryInSortedTable( RiftTable, RiftIndexTarget, OldTargetRva, NewTargetRva );
Found = TRUE;
#ifdef TESTCODE
CountDiscoveredE8Rifts++;
#endif // TESTCODE
break;
}
}
}
}
}
if ( Found ) {
continue;
}
for ( ScanInstruct = NewInstruct - 1; ScanInstruct >= LowestMaToScan; ScanInstruct-- ) {
if ( *ScanInstruct == 0xE8 ) {
//
// check NewHintMap
//
NewOriginMa = ScanInstruct + 5;
NewOriginRva = MappedAddressToImageRva( NewFileNtHeader, NewOriginMa, NewFileMapped );
NewDisplacement = *(UNALIGNED LONG*)( ScanInstruct + 1 );
NewTargetRva = NewOriginRva + NewDisplacement;
NewTargetMa = ImageRvaToMappedAddress( NewFileNtHeader, NewTargetRva, NewFileMapped, NewFileSize );
if (( NewOriginRva ) && ( NewTargetMa )) {
//
// We already know *OldInstruct == *ScanInstruct
//
if (( *OldOriginMa == *NewOriginMa ) &&
( *OldTargetMa == *NewTargetMa ) &&
( NewTargetRva == ExpectedTargetRva )) {
ULONG NewInstructOffset = ScanInstruct - NewFileMapped;
ULONG NewTargetOffset = NewTargetMa - NewFileMapped;
BOOL Skip = FALSE;
for ( j = 0; j < 5; j++ ) {
if ( NewFileHintMap[ NewInstructOffset + j ] & 0x01 ) {
Skip = TRUE;
break;
}
}
if ( NewFileHintMap[ NewTargetOffset + j ] & 0x01 ) {
Skip = TRUE;
}
if ( ! Skip ) {
InsertRiftEntryInSortedTable( RiftTable, RiftIndexOrigin, OldOriginRva - 5, NewOriginRva - 5 );
InsertRiftEntryInSortedTable( RiftTable, RiftIndexTarget, OldTargetRva, NewTargetRva );
Found = TRUE;
#ifdef TESTCODE
CountDiscoveredE8Rifts++;
#endif // TESTCODE
break;
}
}
}
}
}
}
}
}
}
}
}
}
else if ( OldFileNtHeader->FileHeader.Machine == IMAGE_FILE_MACHINE_ALPHA ) {
//
// Implement Alpha platform stuff here.
//
}
}
}
}
#ifdef TESTCODE
printf( "\r%9d verified E8 rifts\n", CountVerifiedE8Rifts );
printf( "\r%9d discovered E8 rifts\n", CountDiscoveredE8Rifts );
#endif // TESTCODE
if ( OldFileHintMap ) {
MyVirtualFree( OldFileHintMap );
}
if ( NewFileHintMap ) {
MyVirtualFree( NewFileHintMap );
}
return Success;
}
#endif // 0 (test code)
BOOL
GenerateRiftTable(
IN HANDLE OldFileHandle,
IN PUCHAR OldFileMapped,
IN ULONG OldFileSize,
IN ULONG OldFileOriginalChecksum,
IN ULONG OldFileOriginalTimeDate,
IN HANDLE NewFileHandle,
IN PUCHAR NewFileMapped,
IN ULONG NewFileSize,
IN ULONG OptionFlags,
IN PPATCH_OPTION_DATA OptionData,
IN ULONG OldFileIndex,
IN PRIFT_TABLE RiftTable
)
{
UP_IMAGE_NT_HEADERS32 OldFileNtHeader;
UP_IMAGE_NT_HEADERS32 NewFileNtHeader;
LPCSTR OldFileSymPath;
LPCSTR NewFileSymPath;
HANDLE SubAllocator;
ULONG SymbolOptionFlags;
BOOL Success = FALSE;
UNREFERENCED_PARAMETER( OptionFlags );
SymbolOptionFlags = 0;
SubAllocator = NULL;
__try {
//
// See if both files are PE images.
//
OldFileNtHeader = GetNtHeader( OldFileMapped, OldFileSize );
if ( OldFileNtHeader ) {
NewFileNtHeader = GetNtHeader( NewFileMapped, NewFileSize );
if ( NewFileNtHeader ) {
//
// Both files are PE images.
//
SubAllocator = CreateSubAllocator( 0x100000, 0x100000 );
if ( ! SubAllocator ) {
Success = FALSE;
__leave;
}
//
// Before we bother with debug info, we can create initial
// rift data from the section headers to compensate for any
// section base RVA differences. This will work even if we
// don't have debug symbols.
//
Success = GetImageNonSymbolRiftInfo(
OldFileMapped,
OldFileSize,
OldFileNtHeader,
NewFileMapped,
NewFileSize,
NewFileNtHeader,
SubAllocator,
RiftTable
);
//
// Now get rift info from symbols
//
if ( Success ) {
if (( OptionData ) && ( OptionData->SizeOfThisStruct >= sizeof( PATCH_OPTION_DATA ))) {
SymbolOptionFlags = OptionData->SymbolOptionFlags;
if ( ! ( SymbolOptionFlags & PATCH_SYMBOL_NO_IMAGEHLP )) {
if ( OptionData->OldFileSymbolPathArray ) {
OldFileSymPath = OptionData->OldFileSymbolPathArray[ OldFileIndex ];
NewFileSymPath = OptionData->NewFileSymbolPath;
if (( OldFileSymPath ) && ( NewFileSymPath )) {
Success = GetImageSymbolRiftInfo(
OldFileHandle,
OldFileMapped,
OldFileSize,
OldFileNtHeader,
OldFileSymPath,
OldFileOriginalChecksum,
OldFileOriginalTimeDate,
OldFileIndex,
NewFileHandle,
NewFileMapped,
NewFileSize,
NewFileNtHeader,
NewFileSymPath,
SymbolOptionFlags,
SubAllocator,
RiftTable,
OptionData->SymLoadCallback,
OptionData->SymLoadContext
);
if ( SymbolOptionFlags & PATCH_SYMBOL_NO_FAILURES ) {
#ifdef TESTCODE
if (( ! Success ) && ( GetLastError() == ERROR_PATCH_IMAGEHLP_FAILURE )) {
printf( "\rWARNING: Imagehlp.Dll failure\n" );
}
#endif
Success = TRUE;
}
}
}
}
}
}
if ( Success ) {
RiftSortAndRemoveDuplicates(
OldFileMapped,
OldFileSize,
OldFileNtHeader,
NewFileMapped,
NewFileSize,
NewFileNtHeader,
RiftTable
);
//
// Now we can optimize the rift info by peeking into
// the mapped files.
//
Success = OptimizeImageRiftInfo(
OldFileMapped,
OldFileSize,
OldFileNtHeader,
NewFileMapped,
NewFileSize,
NewFileNtHeader,
SubAllocator,
RiftTable
);
}
#ifdef TESTCODE
if ( Success ) {
HANDLE hFile = CreateFile(
"RiftInfo.out",
GENERIC_WRITE,
FILE_SHARE_READ,
NULL,
CREATE_ALWAYS,
FILE_ATTRIBUTE_NORMAL,
NULL
);
if ( hFile != INVALID_HANDLE_VALUE ) {
CHAR TextBuffer[ 24 ];
DWORD Actual;
ULONG i;
for ( i = 0; i < RiftTable->RiftEntryCount; i++ ) {
sprintf( TextBuffer, "%08X %08X\r\n", RiftTable->RiftEntryArray[ i ].OldFileRva, RiftTable->RiftEntryArray[ i ].NewFileRva );
WriteFile( hFile, TextBuffer, 19, &Actual, NULL );
}
CloseHandle( hFile );
}
}
#endif // TESTCODE
}
}
}
__except( EXCEPTION_EXECUTE_HANDLER ) {
SetLastError( GetExceptionCode() );
Success = FALSE;
}
if ( SubAllocator ) {
DestroySubAllocator( SubAllocator );
}
return Success;
}
#endif // PATCH_APPLY_CODE_ONLY