/* * MinHook - The Minimalistic API Hooking Library for x64/x86 * Copyright (C) 2009-2017 Tsuda Kageyu. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A * PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER * OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include #include "buffer.h" // Size of each memory block. (= page size of VirtualAlloc) #define MEMORY_BLOCK_SIZE 0x1000 // Max range for seeking a memory block. (= 1024MB) #define MAX_MEMORY_RANGE 0x7f000000 //0x40000000 https://github.com/TsudaKageyu/minhook/issues/107 // Memory protection flags to check the executable address. #define PAGE_EXECUTE_FLAGS \ (PAGE_EXECUTE | PAGE_EXECUTE_READ | PAGE_EXECUTE_READWRITE | PAGE_EXECUTE_WRITECOPY) // Memory slot. typedef struct _MEMORY_SLOT { union { struct _MEMORY_SLOT *pNext; UINT8 buffer[MEMORY_SLOT_SIZE]; }; } MEMORY_SLOT, *PMEMORY_SLOT; // Memory block info. Placed at the head of each block. typedef struct _MEMORY_BLOCK { struct _MEMORY_BLOCK *pNext; PMEMORY_SLOT pFree; // First element of the free slot list. UINT usedCount; } MEMORY_BLOCK, *PMEMORY_BLOCK; //------------------------------------------------------------------------- // Global Variables: //------------------------------------------------------------------------- // First element of the memory block list. PMEMORY_BLOCK g_pMemoryBlocks; //------------------------------------------------------------------------- VOID InitializeBuffer(VOID) { // Nothing to do for now. } //------------------------------------------------------------------------- VOID UninitializeBuffer(VOID) { PMEMORY_BLOCK pBlock = g_pMemoryBlocks; g_pMemoryBlocks = NULL; while (pBlock) { PMEMORY_BLOCK pNext = pBlock->pNext; VirtualFree(pBlock, 0, MEM_RELEASE); pBlock = pNext; } } //------------------------------------------------------------------------- #if defined(_M_X64) || defined(__x86_64__) static LPVOID FindPrevFreeRegion(LPVOID pAddress, LPVOID pMinAddr, DWORD dwAllocationGranularity) { ULONG_PTR tryAddr = (ULONG_PTR)pAddress; // Round down to the allocation granularity. tryAddr -= tryAddr % dwAllocationGranularity; // Start from the previous allocation granularity multiply. tryAddr -= dwAllocationGranularity; while (tryAddr >= (ULONG_PTR)pMinAddr) { MEMORY_BASIC_INFORMATION mbi; if (VirtualQuery((LPVOID)tryAddr, &mbi, sizeof(mbi)) == 0) break; if (mbi.State == MEM_FREE) return (LPVOID)tryAddr; if ((ULONG_PTR)mbi.AllocationBase < dwAllocationGranularity) break; tryAddr = (ULONG_PTR)mbi.AllocationBase - dwAllocationGranularity; } return NULL; } #endif //------------------------------------------------------------------------- #if defined(_M_X64) || defined(__x86_64__) static LPVOID FindNextFreeRegion(LPVOID pAddress, LPVOID pMaxAddr, DWORD dwAllocationGranularity) { ULONG_PTR tryAddr = (ULONG_PTR)pAddress; // Round down to the allocation granularity. tryAddr -= tryAddr % dwAllocationGranularity; // Start from the next allocation granularity multiply. tryAddr += dwAllocationGranularity; while (tryAddr <= (ULONG_PTR)pMaxAddr) { MEMORY_BASIC_INFORMATION mbi; if (VirtualQuery((LPVOID)tryAddr, &mbi, sizeof(mbi)) == 0) break; if (mbi.State == MEM_FREE) return (LPVOID)tryAddr; tryAddr = (ULONG_PTR)mbi.BaseAddress + mbi.RegionSize; // Round up to the next allocation granularity. tryAddr += dwAllocationGranularity - 1; tryAddr -= tryAddr % dwAllocationGranularity; } return NULL; } #endif //------------------------------------------------------------------------- static PMEMORY_BLOCK GetMemoryBlock(LPVOID pOrigin) { PMEMORY_BLOCK pBlock; #if defined(_M_X64) || defined(__x86_64__) ULONG_PTR minAddr; ULONG_PTR maxAddr; SYSTEM_INFO si; GetSystemInfo(&si); minAddr = (ULONG_PTR)si.lpMinimumApplicationAddress; maxAddr = (ULONG_PTR)si.lpMaximumApplicationAddress; // pOrigin ± 512MB if ((ULONG_PTR)pOrigin > MAX_MEMORY_RANGE && minAddr < (ULONG_PTR)pOrigin - MAX_MEMORY_RANGE) minAddr = (ULONG_PTR)pOrigin - MAX_MEMORY_RANGE; if (maxAddr > (ULONG_PTR)pOrigin + MAX_MEMORY_RANGE) maxAddr = (ULONG_PTR)pOrigin + MAX_MEMORY_RANGE; // Make room for MEMORY_BLOCK_SIZE bytes. maxAddr -= MEMORY_BLOCK_SIZE - 1; #endif // Look the registered blocks for a reachable one. for (pBlock = g_pMemoryBlocks; pBlock != NULL; pBlock = pBlock->pNext) { #if defined(_M_X64) || defined(__x86_64__) // Ignore the blocks too far. if ((ULONG_PTR)pBlock < minAddr || (ULONG_PTR)pBlock >= maxAddr) continue; #endif // The block has at least one unused slot. if (pBlock->pFree != NULL) return pBlock; } #if defined(_M_X64) || defined(__x86_64__) // Alloc a new block above if not found. { LPVOID pAlloc = pOrigin; while ((ULONG_PTR)pAlloc >= minAddr) { pAlloc = FindPrevFreeRegion(pAlloc, (LPVOID)minAddr, si.dwAllocationGranularity); if (pAlloc == NULL) break; pBlock = (PMEMORY_BLOCK)VirtualAlloc( pAlloc, MEMORY_BLOCK_SIZE, MEM_COMMIT | MEM_RESERVE, PAGE_EXECUTE_READWRITE); if (pBlock != NULL) break; } } // Alloc a new block below if not found. if (pBlock == NULL) { LPVOID pAlloc = pOrigin; while ((ULONG_PTR)pAlloc <= maxAddr) { pAlloc = FindNextFreeRegion(pAlloc, (LPVOID)maxAddr, si.dwAllocationGranularity); if (pAlloc == NULL) break; pBlock = (PMEMORY_BLOCK)VirtualAlloc( pAlloc, MEMORY_BLOCK_SIZE, MEM_COMMIT | MEM_RESERVE, PAGE_EXECUTE_READWRITE); if (pBlock != NULL) break; } } #else // In x86 mode, a memory block can be placed anywhere. pBlock = (PMEMORY_BLOCK)VirtualAlloc( NULL, MEMORY_BLOCK_SIZE, MEM_COMMIT | MEM_RESERVE, PAGE_EXECUTE_READWRITE); #endif if (pBlock != NULL) { // Build a linked list of all the slots. PMEMORY_SLOT pSlot = (PMEMORY_SLOT)pBlock + 1; pBlock->pFree = NULL; pBlock->usedCount = 0; do { pSlot->pNext = pBlock->pFree; pBlock->pFree = pSlot; pSlot++; } while ((ULONG_PTR)pSlot - (ULONG_PTR)pBlock <= MEMORY_BLOCK_SIZE - MEMORY_SLOT_SIZE); pBlock->pNext = g_pMemoryBlocks; g_pMemoryBlocks = pBlock; } return pBlock; } //------------------------------------------------------------------------- LPVOID AllocateBuffer(LPVOID pOrigin) { PMEMORY_SLOT pSlot; PMEMORY_BLOCK pBlock = GetMemoryBlock(pOrigin); if (pBlock == NULL) return NULL; // Remove an unused slot from the list. pSlot = pBlock->pFree; pBlock->pFree = pSlot->pNext; pBlock->usedCount++; #ifdef _DEBUG // Fill the slot with INT3 for debugging. memset(pSlot, 0xCC, sizeof(MEMORY_SLOT)); #endif return pSlot; } //------------------------------------------------------------------------- VOID FreeBuffer(LPVOID pBuffer) { PMEMORY_BLOCK pBlock = g_pMemoryBlocks; PMEMORY_BLOCK pPrev = NULL; ULONG_PTR pTargetBlock = ((ULONG_PTR)pBuffer / MEMORY_BLOCK_SIZE) * MEMORY_BLOCK_SIZE; while (pBlock != NULL) { if ((ULONG_PTR)pBlock == pTargetBlock) { PMEMORY_SLOT pSlot = (PMEMORY_SLOT)pBuffer; #ifdef _DEBUG // Clear the released slot for debugging. memset(pSlot, 0x00, sizeof(MEMORY_SLOT)); #endif // Restore the released slot to the list. pSlot->pNext = pBlock->pFree; pBlock->pFree = pSlot; pBlock->usedCount--; // Free if unused. if (pBlock->usedCount == 0) { if (pPrev) pPrev->pNext = pBlock->pNext; else g_pMemoryBlocks = pBlock->pNext; VirtualFree(pBlock, 0, MEM_RELEASE); } break; } pPrev = pBlock; pBlock = pBlock->pNext; } } //------------------------------------------------------------------------- BOOL IsExecutableAddress(LPVOID pAddress) { MEMORY_BASIC_INFORMATION mi; VirtualQuery(pAddress, &mi, sizeof(mi)); return (mi.State == MEM_COMMIT && (mi.Protect & PAGE_EXECUTE_FLAGS)); }