Textractor_test/vnrhook/util/memdbg/memsearch.cc

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// memsearch.cc
// 4/20/2014 jichi
#include "memdbg/memsearch.h"
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#include "ithsys/ithsys.h"
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#include <windows.h>
// Helpers
namespace { // unnamed
enum : BYTE { byte_nop = 0x90 };
enum : BYTE { byte_int3 = 0xcc };
enum : WORD { word_2int3 = 0xcccc };
// jichi 4/19/2014: Return the integer that can mask the signature
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// Artikash 8/4/2018: change implementation
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DWORD sigMask(DWORD sig)
{
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DWORD count = 0;
while (sig)
{
sig >>= 8;
++count;
}
count -= 4;
count = -count;
return 0xffffffff >> (count << 3);
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}
// Modified from ITH findCallOrJmpAbs
// Example call:
// 00449063 |. ff15 5cf05300 call dword ptr ds:[<&gdi32.getglyphoutli>; \GetGlyphOutlineA
enum : WORD {
word_jmp = 0x25ff // long jump
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, word_call = 0x15ff // far call
};
// Modified from ITH findCallOrJmpAbs
enum : BYTE {
byte_jmp = 0xe9 // long call
, byte_call = 0xe8 // near call
, byte_push_small = 0x6a // push byte operand
, byte_push_large = 0x68 // push operand > 0xff
};
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/***
* Return the absolute address of op. Op takes 1 parameter.
* DWORD call with absolute address.
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*
* @param op first half of the operator
* @param arg1 the function address
* @param start address
* @param stop address
* @param offset search after start address
* @param range search size
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* @return absolute address or 0
*/
DWORD findWordCall(WORD op, DWORD arg1, DWORD start, DWORD stop, DWORD offset, DWORD range)
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{
typedef WORD optype;
typedef DWORD argtype;
for (DWORD i = offset; i < offset + range - sizeof(argtype); i++)
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if (op == *(optype *)(start + i)) {
DWORD t = *(DWORD *)(start + i + sizeof(optype));
if (t > start && t < stop) {
if (arg1 == *(argtype *)t) // absolute address
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return start + i;
//i += sizeof(optype) + sizeof(argtype) - 1; // == 5
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}
}
return 0;
}
DWORD findLastWordCall(WORD op, DWORD arg1, DWORD start, DWORD stop, DWORD offset, DWORD range)
{
typedef WORD optype;
typedef DWORD argtype;
DWORD ret = 0;
for (DWORD i = offset; i < offset + range - sizeof(argtype); i++)
if (op == *(optype *)(start + i)) {
DWORD t = *(DWORD *)(start + i + sizeof(optype));
if (t > start && t < stop) {
if (arg1 == *(argtype *)t) // absolute address
ret = start + i;
//i += sizeof(optype) + sizeof(argtype) - 1; // == 5
}
}
return ret;
}
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/***
* Return the absolute address of op. Op takes 1 address parameter.
* BYTE call with relative address.
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*
* @param op first half of the operator
* @param arg1 the function address
* @param start address
* @param offset search after start address
* @param range search size
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* @return absolute address or 0
*/
DWORD findByteCall(BYTE op, DWORD arg1, DWORD start, DWORD offset, DWORD range)
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{
typedef BYTE optype;
typedef DWORD argtype;
for (DWORD i = offset; i < offset + range - sizeof(argtype); i++)
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if (op == *(optype *)(start + i)) {
DWORD t = *(argtype *)(start + i + sizeof(optype));
//if (t > start && t < stop) {
if (arg1 == t + start + i + sizeof(optype) + sizeof(argtype)) // relative address
return start + i;
//i += sizeof(optype) + sizeof(argtype) - 1; // == 4
//}
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}
return 0;
}
DWORD findLastByteCall(BYTE op, DWORD arg1, DWORD start, DWORD offset, DWORD range)
{
typedef BYTE optype;
typedef DWORD argtype;
DWORD ret = 0;
for (DWORD i = offset; i < offset + range - sizeof(argtype); i++)
if (op == *(optype *)(start + i)) {
DWORD t = *(argtype *)(start + i + sizeof(optype));
//if (t > start && t < stop) {
if (arg1 == t + start + i + sizeof(optype) + sizeof(argtype)) // relative address
ret = start + i;
//i += sizeof(optype) + sizeof(argtype) - 1; // == 4
//}
}
return ret;
}
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/***
* Return the absolute address of op. Op takes 1 parameter.
*
* @param op first half of the operator
* @param arg1 the first operand
* @param start address
* @param search range
* @return absolute address or 0
*/
//DWORD findByteOp1(BYTE op, DWORD arg1, DWORD start, DWORD size, DWORD offset)
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//{
// typedef BYTE optype;
// typedef DWORD argtype;
//
// for (DWORD i = offset; i < size - sizeof(argtype); i++)
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// if (op == *(optype *)(start + i)) {
// DWORD t = *(DWORD *)(start + i + sizeof(optype));
// if (t == arg1) {
// return start + i;
// else
// i += sizeof(optype) + sizeof(argtype) - 1; // == 4
// }
// }
// return 0;
//}
} // namespace unnamed
MEMDBG_BEGIN_NAMESPACE
DWORD findLongJumpAddress(DWORD funcAddr, DWORD lowerBound, DWORD upperBound, DWORD offset, DWORD range)
{ return findWordCall(word_jmp, funcAddr, lowerBound, upperBound, offset, range ? range : (upperBound - lowerBound - offset)); }
DWORD findShortJumpAddress(DWORD funcAddr, DWORD lowerBound, DWORD upperBound, DWORD offset, DWORD range)
{ return findByteCall(byte_jmp, funcAddr, lowerBound, offset, range ? range : (upperBound - lowerBound - offset)); }
DWORD findFarCallAddress(DWORD funcAddr, DWORD lowerBound, DWORD upperBound, DWORD offset, DWORD range)
{ return findWordCall(word_call, funcAddr, lowerBound, upperBound, offset, range ? range : (upperBound - lowerBound - offset)); }
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DWORD findNearCallAddress(DWORD funcAddr, DWORD lowerBound, DWORD upperBound, DWORD offset, DWORD range)
{ return findByteCall(byte_call, funcAddr, lowerBound, offset, range ? range : (upperBound - lowerBound - offset)); }
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DWORD findLastLongJumpAddress(DWORD funcAddr, DWORD lowerBound, DWORD upperBound, DWORD offset, DWORD range)
{ return findLastWordCall(word_jmp, funcAddr, lowerBound, upperBound, offset, range ? range : (upperBound - lowerBound - offset)); }
DWORD findLastShortJumpAddress(DWORD funcAddr, DWORD lowerBound, DWORD upperBound, DWORD offset, DWORD range)
{ return findLastByteCall(byte_jmp, funcAddr, lowerBound, offset, range ? range : (upperBound - lowerBound - offset)); }
DWORD findLastFarCallAddress(DWORD funcAddr, DWORD lowerBound, DWORD upperBound, DWORD offset, DWORD range)
{ return findLastWordCall(word_call, funcAddr, lowerBound, upperBound, offset, range ? range : (upperBound - lowerBound - offset)); }
DWORD findLastNearCallAddress(DWORD funcAddr, DWORD lowerBound, DWORD upperBound, DWORD offset, DWORD range)
{ return findLastByteCall(byte_call, funcAddr, lowerBound, offset, range ? range : (upperBound - lowerBound - offset)); }
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DWORD findPushDwordAddress(DWORD value, DWORD lowerBound, DWORD upperBound)
{
//value = _byteswap_ulong(value); // swap to bigendian
const BYTE *p = (BYTE *)&value;
const BYTE bytes[] = {byte_push_large, p[0], p[1], p[2], p[3]};
return findBytes(bytes, sizeof(bytes), lowerBound, upperBound);
}
DWORD findPushByteAddress(BYTE value, DWORD lowerBound, DWORD upperBound)
{
const BYTE bytes[] = {byte_push_small, value};
return findBytes(bytes, sizeof(bytes), lowerBound, upperBound);
}
DWORD findCallerAddress(DWORD funcAddr, DWORD sig, DWORD lowerBound, DWORD upperBound, DWORD reverseLength, DWORD offset)
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{
enum { PatternSize = 4 };
const DWORD size = upperBound - lowerBound - PatternSize;
const DWORD fun = (DWORD)funcAddr;
// Example function call:
// 00449063 |. ff15 5cf05300 call dword ptr ds:[<&gdi32.getglyphoutli>; \GetGlyphOutlineA
//WCHAR str[0x40];
const DWORD mask = sigMask(sig);
for (DWORD i = offset; i < size; i++)
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if (*(WORD *)(lowerBound + i) == word_call) {
DWORD t = *(DWORD *)(lowerBound + i + 2); // 2 = sizeof(word)
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if (t >= lowerBound && t <= upperBound - PatternSize) {
if (*(DWORD *)t == fun)
//swprintf(str,L"CALL addr: 0x%.8X",lowerBound + i);
//OutputConsole(str);
for (DWORD j = i ; j > i - reverseLength; j--)
if ((*(DWORD *)(lowerBound + j) & mask) == sig) // Fun entry 1.
//swprintf(str,L"Entry: 0x%.8X",lowerBound + j);
//OutputConsole(str);
return lowerBound + j;
} else
i += 6;
}
//OutputConsole(L"Find call and entry failed.");
return 0;
}
#ifndef MEMDBG_NO_STL
bool iterFindBytes(const address_fun_t &fun, const void *pattern, DWORD patternSize, DWORD lowerBound, DWORD upperBound)
{
for (DWORD addr = lowerBound; addr < upperBound - patternSize; addr += patternSize) {
addr = findBytes(pattern, patternSize, addr, upperBound);
if (!addr || !fun(addr))
return false;
}
return true;
}
bool iterMatchBytes(const address_fun_t &fun, const void *pattern, DWORD patternSize, DWORD lowerBound, DWORD upperBound)
{
for (DWORD addr = lowerBound; addr < upperBound - patternSize; addr += patternSize) { ;
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addr = findBytes(pattern, patternSize, addr, upperBound);
if (!addr || !fun(addr))
return false;
}
return true;
}
bool iterWordCall(const address_fun_t &callback, WORD op, DWORD arg1, DWORD start, DWORD stop, DWORD offset, DWORD range)
{
typedef WORD optype;
typedef DWORD argtype;
for (DWORD i = offset; i < offset + range - sizeof(argtype); i++)
if (op == *(optype *)(start + i)) {
DWORD t = *(DWORD *)(start + i + sizeof(optype));
if (t > start && t < stop) {
if (arg1 == *(argtype *)t // absolute address
&& !callback(start + i))
return false;
//i += sizeof(optype) + sizeof(argtype) - 1; // == 5
}
}
return true;
}
bool iterByteCall(const address_fun_t &callback, BYTE op, DWORD arg1, DWORD start, DWORD offset, DWORD range)
{
typedef BYTE optype;
typedef DWORD argtype;
for (DWORD i = offset; i < offset + range - sizeof(argtype); i++)
if (op == *(optype *)(start + i)) {
DWORD t = *(argtype *)(start + i + sizeof(optype));
//if (t > start && t < stop) {
if (arg1 == t + start + i + sizeof(optype) + sizeof(argtype) // relative address
&& !callback(start + i))
return false;
//i += sizeof(optype) + sizeof(argtype) - 1; // == 4
//}
}
return true;
}
bool iterCallerAddress(const address2_fun_t &callback, DWORD funcAddr, DWORD sig, DWORD lowerBound, DWORD upperBound, DWORD reverseLength, DWORD offset)
{
enum { PatternSize = 4 };
const DWORD size = upperBound - lowerBound - PatternSize;
const DWORD fun = (DWORD)funcAddr;
// Example function call:
// 00449063 |. ff15 5cf05300 call dword ptr ds:[<&gdi32.getglyphoutli>; \GetGlyphOutlineA
//WCHAR str[0x40];
const DWORD mask = sigMask(sig);
for (DWORD i = offset; i < size; i++)
if (*(WORD *)(lowerBound + i) == word_call) {
DWORD t = *(DWORD *)(lowerBound + i + 2); // 2 = sizeof(word)
if (t >= lowerBound && t <= upperBound - PatternSize) {
if (*(DWORD *)t == fun)
//swprintf(str,L"CALL addr: 0x%.8X",lowerBound + i);
//OutputConsole(str);
for (DWORD j = i ; j > i - reverseLength; j--)
if ((*(DWORD *)(lowerBound + j) & mask) == sig) {
if (!callback(lowerBound + j, lowerBound + i))
return false;
break;
}
} else
i += 6;
}
//OutputConsole(L"Find call and entry failed.");
return true;
}
bool iterCallerAddressAfterInt3(const address2_fun_t &fun, dword_t funcAddr, dword_t lowerBound, dword_t upperBound, dword_t callerSearchSize, dword_t offset)
{
auto callback = [&fun](dword_t addr, dword_t call) -> bool {
while (byte_int3 == *(BYTE *)++addr); // skip leading int3
return fun(addr, call);
};
return iterCallerAddress(callback, funcAddr, word_2int3, lowerBound, upperBound, callerSearchSize, offset);
}
bool iterUniqueCallerAddress(const address_fun_t &fun, dword_t funcAddr, dword_t funcInst, dword_t lowerBound, dword_t upperBound, dword_t callerSearchSize, dword_t offset)
{
dword_t prevAddr = 0;
auto callback = [&fun, &prevAddr](dword_t addr, dword_t) -> bool {
if (prevAddr == addr)
return true;
prevAddr = addr;
return fun(addr);
};
return iterCallerAddress(callback, funcAddr, funcInst, lowerBound, upperBound, callerSearchSize, offset);
}
bool iterUniqueCallerAddressAfterInt3(const address_fun_t &fun, dword_t funcAddr, dword_t lowerBound, dword_t upperBound, dword_t callerSearchSize, dword_t offset)
{
auto callback = [&fun](dword_t addr) -> bool {
while (byte_int3 == *(BYTE *)++addr); // skip leading int3
return fun(addr);
};
return iterUniqueCallerAddress(callback, funcAddr, word_2int3, lowerBound, upperBound, callerSearchSize, offset);
}
bool iterLongJumpAddress(const address_fun_t &fun, DWORD funcAddr, DWORD lowerBound, DWORD upperBound, DWORD offset, DWORD range)
{ return iterWordCall(fun, word_jmp, funcAddr, lowerBound, upperBound, offset, range ? range : (upperBound - lowerBound - offset)); }
bool iterShortJumpAddress(const address_fun_t &fun, DWORD funcAddr, DWORD lowerBound, DWORD upperBound, DWORD offset, DWORD range)
{ return iterByteCall(fun, byte_jmp, funcAddr, lowerBound, offset, range ? range : (upperBound - lowerBound - offset)); }
bool iterFarCallAddress(const address_fun_t &fun, DWORD funcAddr, DWORD lowerBound, DWORD upperBound, DWORD offset, DWORD range)
{ return iterWordCall(fun, word_call, funcAddr, lowerBound, upperBound, offset, range ? range : (upperBound - lowerBound - offset)); }
bool iterNearCallAddress(const address_fun_t &fun, DWORD funcAddr, DWORD lowerBound, DWORD upperBound, DWORD offset, DWORD range)
{ return iterByteCall(fun, byte_call, funcAddr, lowerBound, offset, range ? range : (upperBound - lowerBound - offset)); }
bool iterAlignedNearCallerAddress(const address_fun_t &fun, dword_t funcAddr, dword_t lowerBound, dword_t upperBound, dword_t callerSearchSize, dword_t offset)
{
dword_t prevAddr = 0;
auto callback = [&fun, &prevAddr, callerSearchSize](dword_t addr) -> bool {
if ((addr = findEnclosingAlignedFunction(addr, callerSearchSize))
&& prevAddr != addr) {
prevAddr = addr;
return fun(addr);
}
return true;
};
return iterNearCallAddress(callback, funcAddr, lowerBound, upperBound, offset);
}
#endif // MEMDBG_NO_STL
DWORD findMultiCallerAddress(DWORD funcAddr, const DWORD sigs[], DWORD sigCount, DWORD lowerBound, DWORD upperBound, DWORD reverseLength, DWORD offset)
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{
enum { PatternSize = 4 };
const DWORD size = upperBound - lowerBound - PatternSize;
const DWORD fun = (DWORD)funcAddr;
// Example function call:
// 00449063 |. ff15 5cf05300 call dword ptr ds:[<&gdi32.getglyphoutli>; \GetGlyphOutlineA
//WCHAR str[0x40];
enum { MaxSigCount = 0x10 }; // mast be larger than maximum sigCount
DWORD masks[MaxSigCount];
for (DWORD k = 0; k < sigCount; k++)
masks[k] = sigMask(sigs[k]);
for (DWORD i = offset; i < size; i++)
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if (*(WORD *)(lowerBound + i) == word_call) {
DWORD t = *(DWORD *)(lowerBound + i + 2); // 2 = sizeof(word)
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if (t >= lowerBound && t <= upperBound - PatternSize) {
if (*(DWORD *)t == fun)
//swprintf(str,L"CALL addr: 0x%.8X",lowerBound + i);
//OutputConsole(str);
for (DWORD j = i ; j > i - reverseLength; j--) {
DWORD ret = lowerBound + j,
inst = *(DWORD *)ret;
for (DWORD k = 0; k < sigCount; k++)
if ((inst & masks[k]) == sigs[k]) // Fun entry 1.
//swprintf(str,L"Entry: 0x%.8X",lowerBound + j);
//OutputConsole(str);
return ret;
}
} else
i += 6;
}
//OutputConsole(L"Find call and entry failed.");
return 0;
}
DWORD findLastCallerAddress(DWORD funcAddr, DWORD sig, DWORD lowerBound, DWORD upperBound, DWORD reverseLength, DWORD offset)
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{
enum { PatternSize = 4 };
const DWORD size = upperBound - lowerBound - PatternSize;
const DWORD fun = (DWORD)funcAddr;
//WCHAR str[0x40];
DWORD ret = 0;
const DWORD mask = sigMask(sig);
for (DWORD i = offset; i < size; i++)
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if (*(WORD *)(lowerBound + i) == word_call) {
DWORD t = *(DWORD *)(lowerBound + i + 2);
if (t >= lowerBound && t <= upperBound - PatternSize) {
if (*(DWORD *)t == fun)
//swprintf(str,L"CALL addr: 0x%.8X",lowerBound + i);
//OutputConsole(str);
for (DWORD j = i ; j > i - reverseLength; j--)
if ((*(DWORD *)(lowerBound + j) & mask) == sig) { // Fun entry 1.
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//swprintf(str,L"Entry: 0x%.8X",lowerBound + j);
//OutputConsole(str);
ret = lowerBound + j;
break;
}
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} else
i += 6;
}
//OutputConsole(L"Find call and entry failed.");
return ret;
}
DWORD findCallerAddressAfterInt3(dword_t funcAddr, dword_t lowerBound, dword_t upperBound, dword_t callerSearchSize, dword_t offset)
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{
DWORD addr = findCallerAddress(funcAddr, word_2int3, lowerBound, upperBound, callerSearchSize, offset);
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if (addr)
while (byte_int3 == *(BYTE *)++addr);
return addr;
}
DWORD findLastCallerAddressAfterInt3(dword_t funcAddr, dword_t lowerBound, dword_t upperBound, dword_t callerSearchSize, dword_t offset)
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{
DWORD addr = findLastCallerAddress(funcAddr, word_2int3, lowerBound, upperBound, callerSearchSize, offset);
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if (addr)
while (byte_int3 == *(BYTE *)++addr);
return addr;
}
DWORD findAlignedNearCallerAddress(dword_t funcAddr, dword_t lowerBound, dword_t upperBound, dword_t callerSearchSize, dword_t offset)
{
if (DWORD addr = findNearCallAddress(funcAddr, lowerBound, upperBound, offset))
return findEnclosingAlignedFunction(addr, callerSearchSize);
return 0;
}
DWORD findLastAlignedNearCallerAddress(dword_t funcAddr, dword_t lowerBound, dword_t upperBound, dword_t callerSearchSize, dword_t offset)
{
if (DWORD addr = findLastCallerAddressAfterInt3(funcAddr, lowerBound, upperBound, callerSearchSize, offset))
return findEnclosingAlignedFunction(addr, callerSearchSize);
return 0;
}
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DWORD findEnclosingAlignedFunction(DWORD start, DWORD back_range)
{
start &= ~0xf;
for (DWORD i = start, j = start - back_range; i > j; i-=0x10) {
DWORD k = *(DWORD *)(i-4);
if (k == 0xcccccccc
|| k == 0x90909090
|| k == 0xccccccc3
|| k == 0x909090c3
)
return i;
DWORD t = k & 0xff0000ff;
if (t == 0xcc0000c2 || t == 0x900000c2)
return i;
k >>= 8;
if (k == 0xccccc3 || k == 0x9090c3)
return i;
t = k & 0xff;
if (t == 0xc2)
return i;
k >>= 8;
if (k == 0xccc3 || k == 0x90c3)
return i;
k >>= 8;
if (k == 0xc3)
return i;
}
return 0;
}
DWORD findEnclosingFunctionAfterDword(DWORD sig, DWORD start, DWORD back_range, DWORD step)
{
start &= ~0xf;
for (DWORD i = start, j = start - back_range; i > j; i-=step) { // 0x10 is aligned
DWORD k = *(DWORD *)(i-4); // 4 = sizeof(DWORD)
if (k == sig)
return i;
}
return 0;
}
DWORD findEnclosingFunctionBeforeDword(DWORD sig, DWORD start, DWORD back_range,DWORD step)
{
DWORD addr = findEnclosingFunctionAfterDword(sig, start, back_range, step);
if (addr)
addr -= sizeof(DWORD);
return addr;
}
DWORD findEnclosingFunctionAfterInt3(DWORD start, DWORD back_range, DWORD step)
{ return findEnclosingFunctionAfterDword(0xcccccccc, start, back_range, step); }
DWORD findEnclosingFunctionAfterNop(DWORD start, DWORD back_range, DWORD step)
{ return findEnclosingFunctionAfterDword(0x90909090,start, back_range, step); }
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DWORD findBytes(const void *pattern, DWORD patternSize, DWORD lowerBound, DWORD upperBound)
{
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DWORD reladdr = SearchPattern(lowerBound, upperBound - lowerBound, pattern, patternSize);
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return reladdr ? lowerBound + reladdr : 0;
}
//DWORD reverseFindBytes(const void *pattern, DWORD patternSize, DWORD lowerBound, DWORD upperBound)
//{
// DWORD reladdr = reverseSearchPattern(lowerBound, upperBound - lowerBound, pattern, patternSize);
// return reladdr ? lowerBound + reladdr : 0;
//}
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#if 0 // not used
DWORD findBytesInPages(const void *pattern, DWORD patternSize, DWORD lowerBound, DWORD upperBound, SearchType search)
{
//enum { MinPageSize = 4 * 1024 }; // 4k
DWORD ret = 0;
DWORD start = lowerBound,
stop = start;
MEMORY_BASIC_INFORMATION mbi = {};
//lowerBound = 0x10000000;
//upperBound = 0x14000000;
//SIZE_T ok = ::VirtualQuery((LPCVOID)lowerBound, &mbi, sizeof(mbi));
//ITH_GROWL_DWORD7(1, start, stop, mbi.RegionSize, mbi.Protect, mbi.Type, mbi.State);
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//return findBytes(pattern, patternSize, lowerBound, upperBound, wildcard);
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while (stop < upperBound) {
SIZE_T ok = ::VirtualQuery((LPCVOID)start, &mbi, sizeof(mbi));
if (!mbi.RegionSize)
break;
// Only visit readable and committed region
// Protect could be zero if not allowed to query
if (!ok || !mbi.Protect || mbi.Protect&PAGE_NOACCESS) {
if (stop > start && (ret = findBytes(pattern, patternSize, lowerBound, upperBound)))
return ret;
if (search != SearchAll)
return 0;
stop += mbi.RegionSize;
start = stop;
} else
stop += mbi.RegionSize;
}
if (stop > start)
ret = findBytes(pattern, patternSize, start, min(upperBound, stop));
return ret;
}
DWORD matchBytesInPages(const void *pattern, DWORD patternSize, DWORD lowerBound, DWORD upperBound, BYTE wildcard, SearchType search)
{
//enum { MinPageSize = 4 * 1024 }; // 4k
DWORD ret = 0;
DWORD start = lowerBound,
stop = start;
MEMORY_BASIC_INFORMATION mbi = {};
//lowerBound = 0x10000000;
//upperBound = 0x14000000;
//SIZE_T ok = ::VirtualQuery((LPCVOID)lowerBound, &mbi, sizeof(mbi));
//ITH_GROWL_DWORD7(1, start, stop, mbi.RegionSize, mbi.Protect, mbi.Type, mbi.State);
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//return findBytes(pattern, patternSize, lowerBound, upperBound, wildcard);
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while (stop < upperBound) {
SIZE_T ok = ::VirtualQuery((LPCVOID)start, &mbi, sizeof(mbi));
if (!mbi.RegionSize)
break;
// Only visit readable and committed region
// Protect could be zero if not allowed to query
if (!ok || !mbi.Protect || mbi.Protect&PAGE_NOACCESS) {
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if (stop > start && (ret = findBytes(pattern, patternSize, lowerBound, upperBound, wildcard)))
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return ret;
if (search != SearchAll)
return 0;
stop += mbi.RegionSize;
start = stop;
} else
stop += mbi.RegionSize;
}
if (stop > start)
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ret = findBytes(pattern, patternSize, start, min(upperBound, stop), wildcard);
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return ret;
}
#endif // 0
MEMDBG_END_NAMESPACE
// EOF