HyperDbg/hyperdbg/libhyperdbg/code/debugger/script-engine/symbol.cpp
2026-06-07 16:57:53 +02:00

1350 lines
43 KiB
C++

/**
* @file symbol.cpp
* @author Alee Amini (alee@hyperdbg.org)
* @author Sina Karvandi (sina@hyperdbg.org)
* @brief symbol parser
* @details
* @version 0.1
* @date 2021-05-20
*
* @copyright This project is released under the GNU Public License v3.
*
*/
#include "pch.h"
//
// Global Variables
//
extern PMODULE_SYMBOL_DETAIL g_SymbolTable;
extern UINT32 g_SymbolTableSize;
extern UINT32 g_SymbolTableCurrentIndex;
extern BOOLEAN g_IsExecutingSymbolLoadingRoutines;
extern BOOLEAN g_AddressConversion;
extern std::map<UINT64, LOCAL_FUNCTION_DESCRIPTION> g_DisassemblerSymbolMap;
using namespace std;
/**
* @brief Initial load of symbols (for previously download symbols)
*
* @return VOID
*/
VOID
SymbolInitialReload()
{
//
// Load already downloaded symbol (won't download at this point)
//
ShowMessages("interpreting symbols and creating symbol maps\n");
SymbolLoadOrDownloadSymbols(FALSE, TRUE);
}
/**
* @brief Locally reload the symbol table
* @param UserProcessId
*
* @return BOOLEAN
*/
BOOLEAN
SymbolLocalReload(UINT32 UserProcessId)
{
ShowMessages("interpreting symbols and creating symbol maps\n");
SymbolBuildSymbolTable(&g_SymbolTable, &g_SymbolTableSize, UserProcessId, FALSE);
//
// And also load the symbols
//
return SymbolLoadOrDownloadSymbols(FALSE, TRUE);
}
/**
* @brief Initial and send the results of serial for the debugger
* in the case of debugger mode
* @param UserProcessId
*
* @return VOID
*/
VOID
SymbolPrepareDebuggerWithSymbolInfo(UINT32 UserProcessId)
{
//
// Load already downloaded symbol (won't download at this point)
//
SymbolBuildSymbolTable(&g_SymbolTable, &g_SymbolTableSize, UserProcessId, TRUE);
}
/**
* @brief Callback for creating symbol map for disassembler
*
* @param Address
* @param ModuleName
* @param ObjectName
* @param ObjectSize
*
* @return VOID
*/
VOID
SymbolCreateDisassemblerMapCallback(UINT64 Address,
CHAR * ModuleName,
CHAR * ObjectName,
UINT32 ObjectSize)
{
//
// It has a string, should not be initialized with zero
//
LOCAL_FUNCTION_DESCRIPTION LocalFunctionDescription = {};
string FinalModuleName = "";
if (ObjectSize == 0)
{
ObjectSize = DISASSEMBLY_MAXIMUM_DISTANCE_FROM_OBJECT_NAME;
}
//
// Convert module name to string
//
if (ModuleName != NULL)
{
FinalModuleName += std::string(ModuleName) + "!";
}
//
// Convert object name to string
//
if (ObjectName != NULL)
{
FinalModuleName += std::string(ObjectName);
}
//
// Create the structure
//
LocalFunctionDescription.ObjectName = std::move(FinalModuleName);
LocalFunctionDescription.ObjectSize = ObjectSize;
//
// Add to disassembler map
//
g_DisassemblerSymbolMap[Address] = LocalFunctionDescription;
}
/**
* @brief Update (or create) symbol map for the disassembler
*
* @return BOOLEAN
*/
BOOLEAN
SymbolCreateDisassemblerSymbolMap()
{
//
// Clear the map table
//
g_DisassemblerSymbolMap.clear();
//
// Get all the symbols in the callback
//
ScriptEngineCreateSymbolTableForDisassemblerWrapper(SymbolCreateDisassemblerMapCallback);
return TRUE;
}
/**
* @brief shows the functions' name for the disassembler
* @param Address
* @param UsedBaseAddress
*
* @return BOOLEAN
*/
BOOLEAN
SymbolShowFunctionNameBasedOnAddress(UINT64 Address, PUINT64 UsedBaseAddress)
{
std::map<UINT64, LOCAL_FUNCTION_DESCRIPTION>::iterator Low, Prev;
UINT64 Pos = Address;
//
// Check if showing function (object) names is not prohibited
// form settings command
//
if (!g_AddressConversion)
{
return FALSE;
}
//
// Check if we already built the symbol map for disassembler or not
//
if (!g_DisassemblerSymbolMap.empty())
{
Low = g_DisassemblerSymbolMap.lower_bound(Pos);
if (Low == g_DisassemblerSymbolMap.end())
{
//
// Nothing found, maybe use rbegin()
//
return FALSE;
}
else if (Low == g_DisassemblerSymbolMap.begin() && Low->first > Address)
{
//
// Nothing to do, address is below the lowest entry in symbol table
//
return FALSE;
}
else if (Low->first == Address)
{
if (*UsedBaseAddress != Address)
{
ShowMessages("%s", Low->second.ObjectName.c_str());
*UsedBaseAddress = Address;
return TRUE;
}
return FALSE;
}
else
{
Prev = std::prev(Low);
UINT64 Diff = Address - Prev->first;
//
// Check, so we have a threshold boundary to add +xx to the
// symbols function name, in otherwords, the maximum number of
// bytes that a function could contain (it's definitely not the
// best option to find start and end of function, it's an approximate
// and not always might be true)
//
if (Prev->second.ObjectSize >= Diff)
{
if (*UsedBaseAddress != Prev->first)
{
ShowMessages("%s+0x%x", Prev->second.ObjectName.c_str(), Diff);
*UsedBaseAddress = Prev->first;
return TRUE;
}
return FALSE;
}
else if (DISASSEMBLY_MAXIMUM_DISTANCE_FROM_OBJECT_NAME >= Diff)
{
//
// We add the logic of adding Name+X+X to show that a address is x bytes
// after the Object Name and not within the size of the function but x
// bytes from the above of the function
//
if (*UsedBaseAddress != Prev->first)
{
ShowMessages("%s+0x%x+0x%x", Prev->second.ObjectName.c_str(), Diff, Diff - Prev->second.ObjectSize);
*UsedBaseAddress = Prev->first;
return TRUE;
}
return FALSE;
}
}
}
//
// Nothing is showed
//
return FALSE;
}
/**
* @brief Build and show symbol table details
* @param BuildLocalSymTable Should this function call to build local symbol
* or the symbols are from a remote debuggee in debugger mode
*
* @return VOID
*/
VOID
SymbolBuildAndShowSymbolTable()
{
if (g_SymbolTable == NULL || g_SymbolTableSize == NULL)
{
ShowMessages("err, symbol table is empty. please use '.sym reload' "
"to build the symbol table\n");
return;
}
//
// show packet details
//
for (SIZE_T i = 0; i < g_SymbolTableSize / sizeof(MODULE_SYMBOL_DETAIL); i++)
{
ShowMessages("is pdb details available? : %s\n", g_SymbolTable[i].IsSymbolDetailsFound ? "true" : "false");
ShowMessages("is pdb a path instead of module name? : %s\n", g_SymbolTable[i].IsLocalSymbolPath ? "true" : "false");
ShowMessages("base address : %llx\n", g_SymbolTable[i].BaseAddress);
ShowMessages("file path : %s\n", g_SymbolTable[i].FilePath);
ShowMessages("guid and age : %s\n", g_SymbolTable[i].ModuleSymbolGuidAndAge);
ShowMessages("module symbol path/name : %s\n", g_SymbolTable[i].ModuleSymbolPath);
ShowMessages("is user-mode? : %s - is 32-bit? %s\n",
g_SymbolTable[i].IsUserMode ? "true" : "false",
g_SymbolTable[i].Is32Bit ? "true" : "false");
ShowMessages("========================================================================\n");
}
}
/**
* @brief Load or download symbols
* @param IsDownload Download from remote server if not available locally
* @param SilentLoad Load without any message
*
* @return BOOLEAN
*/
BOOLEAN
SymbolLoadOrDownloadSymbols(BOOLEAN IsDownload, BOOLEAN SilentLoad)
{
string SymbolServer;
BOOLEAN Result = FALSE;
//
// *** Read symbol path/server from config file ***
//
if (!CommandSettingsGetValueFromConfigFile("SymbolServer", SymbolServer))
{
ShowMessages("please configure the symbol path (use '.help .sympath' for more information)\n");
return FALSE;
}
//
// Check if symbol table is empty
//
if (g_SymbolTable == NULL || g_SymbolTableSize == NULL)
{
ShowMessages("symbol table is empty, please use '.sym reload' to build a symbol table\n");
return FALSE;
}
//
// *** Load or download available symbols ***
//
//
// Indicate that we're in loading routines
//
g_IsExecutingSymbolLoadingRoutines = TRUE;
Result = ScriptEngineSymbolInitLoadWrapper(g_SymbolTable,
g_SymbolTableSize,
IsDownload,
SymbolServer.c_str(),
SilentLoad);
//
// Build symbol table for disassembler
//
SymbolCreateDisassemblerSymbolMap();
//
// Not in loading routines anymore
//
g_IsExecutingSymbolLoadingRoutines = FALSE;
return Result;
}
/**
* @brief check and convert string to a 64 bit unsigned integer and also
* check for symbol object names and evaluate expressions
*
* @param TextToConvert the target string
* @param Result result will be save to the pointer
*
* @return BOOLEAN shows whether the conversion was successful or not
*/
BOOLEAN
SymbolConvertNameOrExprToAddress(const string & TextToConvert, PUINT64 Result)
{
BOOLEAN IsFound = FALSE;
BOOLEAN HasError = NULL;
UINT64 Address = NULL;
if (!ConvertStringToUInt64(TextToConvert, &Address))
{
//
// Check for symbol object names
//
string ConstTextToConvert = TextToConvert;
Address = ScriptEngineConvertNameToAddressWrapper(ConstTextToConvert.c_str(), &IsFound);
if (!IsFound)
{
//
// It's neither a number, nor a founded object name,
// as the last resort, we have to test whether it's an expression or not
// if we're in the Debugger Mode then we have to send it the kernel to get
// the evaluation, if we're in VMI mode, then we evaluate it here with all
// registers set to Zero
//
Address = ScriptEngineEvalSingleExpression(TextToConvert, &HasError);
if (HasError)
{
//
// Not found or has error
//
IsFound = FALSE;
}
else
{
//
// Expression evaluated successfully
//
IsFound = TRUE;
}
}
else
{
//
// Object name is found
//
IsFound = TRUE;
}
}
else
{
//
// It's a hex number
//
IsFound = TRUE;
}
//
// Set the number if the address is founded
//
if (IsFound)
{
*Result = Address;
}
return IsFound;
}
/**
* @brief Read user virtual memory of the debuggee process
*
* @param BaseAddress the base address to read from
* @param UserProcessId the target process id to read its memory
* @param ReadSize the size of bytes to read
* @param Bytes the output vector to receive the read bytes
*
* @return BOOLEAN shows whether the reading was successful or not
*/
static BOOLEAN
SymbolReadUserVirtualMemoryExact(UINT64 BaseAddress, UINT32 UserProcessId, UINT32 ReadSize, std::vector<BYTE> & Bytes)
{
BOOL Status = FALSE;
ULONG ReturnedLength = 0;
if (ReadSize > 0xffffffffu - SIZEOF_DEBUGGER_READ_MEMORY)
{
return FALSE;
}
UINT32 SizeOfTargetBuffer = SIZEOF_DEBUGGER_READ_MEMORY + ReadSize;
DEBUGGER_READ_MEMORY ReadMemoryRequest = {0};
DEBUGGER_READ_MEMORY * MemReadRequest = NULL;
Bytes.clear();
if (g_DeviceHandle == NULL || BaseAddress == 0 || UserProcessId == 0 || ReadSize == 0)
{
return FALSE;
}
MemReadRequest = (DEBUGGER_READ_MEMORY *)malloc(SizeOfTargetBuffer);
if (MemReadRequest == NULL)
{
return FALSE;
}
ReadMemoryRequest.Address = BaseAddress;
ReadMemoryRequest.Pid = UserProcessId;
ReadMemoryRequest.Size = ReadSize;
ReadMemoryRequest.MemoryType = DEBUGGER_READ_VIRTUAL_ADDRESS;
ReadMemoryRequest.ReadingType = READ_FROM_KERNEL;
RtlZeroMemory(MemReadRequest, SizeOfTargetBuffer);
memcpy(MemReadRequest, &ReadMemoryRequest, sizeof(DEBUGGER_READ_MEMORY));
Status = DeviceIoControl(g_DeviceHandle,
IOCTL_DEBUGGER_READ_MEMORY,
MemReadRequest,
SIZEOF_DEBUGGER_READ_MEMORY,
MemReadRequest,
SizeOfTargetBuffer,
&ReturnedLength,
NULL);
if (!Status || MemReadRequest->KernelStatus != DEBUGGER_OPERATION_WAS_SUCCESSFUL || ReturnedLength != SizeOfTargetBuffer)
{
free(MemReadRequest);
return FALSE;
}
Bytes.resize(ReadSize);
memcpy(Bytes.data(), ((UCHAR *)MemReadRequest) + SIZEOF_DEBUGGER_READ_MEMORY, ReadSize);
free(MemReadRequest);
return TRUE;
}
/**
* @brief Check if the provided range is valid and update the required size to read if needed
*
* @param Offset the offset of the range to check
* @param Length the length of the range to check
* @param RequiredSize a pointer to the variable containing the current required size, which will be updated if the end of the range exceeds it
*
* @return BOOLEAN TRUE if the range is valid and RequiredSize is updated if needed, FALSE if the range is invalid (e.g., due to overflow)
*/
static BOOLEAN
SymbolAddLoadedImageReadRange(UINT32 Offset, UINT32 Length, UINT32 * RequiredSize)
{
UINT32 EndOffset = 0;
if (RequiredSize == NULL)
{
return FALSE;
}
if (Length == 0)
{
return TRUE;
}
if (Offset > 0xffffffffu - Length)
{
return FALSE;
}
EndOffset = Offset + Length;
if (EndOffset > *RequiredSize)
{
*RequiredSize = EndOffset;
}
return TRUE;
}
/**
* @brief Check if the provided range is within the bounds of the loaded image bytes
*
* @param LoadedImageBytes the vector containing the bytes of the loaded image
* @param Offset the offset of the range to check
* @param Length the length of the range to check
*
* @return BOOLEAN TRUE if the range is within bounds, FALSE otherwise
*/
static BOOLEAN
SymbolLoadedImageHasRange(const std::vector<BYTE> & LoadedImageBytes, UINT32 Offset, UINT32 Length)
{
return Length <= LoadedImageBytes.size() && Offset <= LoadedImageBytes.size() - Length;
}
/**
* @brief Parse the headers of a loaded PE image from the provided bytes and extract the SizeOfImage and DebugDirectory details
*
* @param LoadedImagePrefix a vector containing the initial bytes of the loaded image, which should include at least the DOS header and NT headers
* @param SizeOfImage an output pointer to receive the SizeOfImage extracted from the optional header
* @param DebugDirectory an optional output pointer to receive the IMAGE_DATA_DIRECTORY entry for the debug directory if available (can be NULL if not needed)
*
* @return BOOLEAN TRUE if the headers were successfully parsed and SizeOfImage was extracted, FALSE otherwise (e.g., if the headers are invalid or incomplete)
*/
static BOOLEAN
SymbolGetLoadedImageHeaderDetails(const std::vector<BYTE> & LoadedImagePrefix, UINT32 * SizeOfImage, IMAGE_DATA_DIRECTORY * DebugDirectory)
{
if (LoadedImagePrefix.size() < sizeof(IMAGE_DOS_HEADER) || SizeOfImage == NULL)
{
return FALSE;
}
if (DebugDirectory != NULL)
{
RtlZeroMemory(DebugDirectory, sizeof(*DebugDirectory));
}
const IMAGE_DOS_HEADER * DosHeader = (const IMAGE_DOS_HEADER *)LoadedImagePrefix.data();
if (DosHeader->e_magic != IMAGE_DOS_SIGNATURE || DosHeader->e_lfanew < 0)
{
return FALSE;
}
SIZE_T NtHeaderOffset = (SIZE_T)DosHeader->e_lfanew;
if (NtHeaderOffset > LoadedImagePrefix.size() || sizeof(DWORD) + sizeof(IMAGE_FILE_HEADER) > LoadedImagePrefix.size() - NtHeaderOffset)
{
return FALSE;
}
const BYTE * NtHeaders = LoadedImagePrefix.data() + NtHeaderOffset;
if (*(const DWORD *)NtHeaders != IMAGE_NT_SIGNATURE)
{
return FALSE;
}
const IMAGE_FILE_HEADER * FileHeader = (const IMAGE_FILE_HEADER *)(NtHeaders + sizeof(DWORD));
SIZE_T OptionalHeaderOffset = NtHeaderOffset + sizeof(DWORD) + sizeof(IMAGE_FILE_HEADER);
if (OptionalHeaderOffset > LoadedImagePrefix.size() || FileHeader->SizeOfOptionalHeader < sizeof(WORD) ||
FileHeader->SizeOfOptionalHeader > LoadedImagePrefix.size() - OptionalHeaderOffset)
{
return FALSE;
}
const BYTE * OptionalHeader = LoadedImagePrefix.data() + OptionalHeaderOffset;
WORD Magic = *(const WORD *)OptionalHeader;
if (Magic == IMAGE_NT_OPTIONAL_HDR32_MAGIC && FileHeader->SizeOfOptionalHeader >= sizeof(IMAGE_OPTIONAL_HEADER32))
{
const IMAGE_OPTIONAL_HEADER32 * OptionalHeader32 = (const IMAGE_OPTIONAL_HEADER32 *)OptionalHeader;
*SizeOfImage = OptionalHeader32->SizeOfImage;
if (DebugDirectory != NULL && OptionalHeader32->NumberOfRvaAndSizes > IMAGE_DIRECTORY_ENTRY_DEBUG)
{
*DebugDirectory = OptionalHeader32->DataDirectory[IMAGE_DIRECTORY_ENTRY_DEBUG];
}
return TRUE;
}
if (Magic == IMAGE_NT_OPTIONAL_HDR64_MAGIC && FileHeader->SizeOfOptionalHeader >= sizeof(IMAGE_OPTIONAL_HEADER64))
{
const IMAGE_OPTIONAL_HEADER64 * OptionalHeader64 = (const IMAGE_OPTIONAL_HEADER64 *)OptionalHeader;
*SizeOfImage = OptionalHeader64->SizeOfImage;
if (DebugDirectory != NULL && OptionalHeader64->NumberOfRvaAndSizes > IMAGE_DIRECTORY_ENTRY_DEBUG)
{
*DebugDirectory = OptionalHeader64->DataDirectory[IMAGE_DIRECTORY_ENTRY_DEBUG];
}
return TRUE;
}
return FALSE;
}
/**
* @brief Read the necessary bytes of a loaded user-mode module to extract the debug directory and code view information for symbol loading
*
* @param BaseAddress the base address of the loaded module in the user process
* @param UserProcessId the target process id to read its memory
* @param LoadedImageBytes an output vector to receive the bytes of the loaded image that are necessary for symbol extraction (should be cleared and filled by this function)
*
* @return BOOLEAN TRUE if the necessary bytes were successfully read, FALSE otherwise (e.g., if memory reading failed or headers are invalid)
*/
static BOOLEAN
SymbolReadLoadedUserModuleForCodeView(UINT64 BaseAddress, UINT32 UserProcessId, std::vector<BYTE> & LoadedImageBytes)
{
static constexpr UINT32 InitialLoadedImagePrefixSize = 4 * 1024;
static constexpr UINT32 MaximumLoadedImageCodeViewReadSize = 4 * 1024 * 1024;
UINT32 SizeOfImage = 0;
UINT32 RequiredSize = InitialLoadedImagePrefixSize;
IMAGE_DATA_DIRECTORY DebugDirectory = {0};
if (!SymbolReadUserVirtualMemoryExact(BaseAddress, UserProcessId, InitialLoadedImagePrefixSize, LoadedImageBytes))
{
return FALSE;
}
if (!SymbolGetLoadedImageHeaderDetails(LoadedImageBytes, &SizeOfImage, &DebugDirectory) || SizeOfImage == 0)
{
return TRUE;
}
if (DebugDirectory.VirtualAddress == 0 || DebugDirectory.Size < sizeof(IMAGE_DEBUG_DIRECTORY) ||
DebugDirectory.Size % sizeof(IMAGE_DEBUG_DIRECTORY) != 0)
{
return TRUE;
}
if (!SymbolAddLoadedImageReadRange(DebugDirectory.VirtualAddress, DebugDirectory.Size, &RequiredSize) ||
RequiredSize > SizeOfImage ||
RequiredSize > MaximumLoadedImageCodeViewReadSize)
{
return TRUE;
}
if (RequiredSize > LoadedImageBytes.size() && !SymbolReadUserVirtualMemoryExact(BaseAddress, UserProcessId, RequiredSize, LoadedImageBytes))
{
return FALSE;
}
if (SymbolLoadedImageHasRange(LoadedImageBytes, DebugDirectory.VirtualAddress, DebugDirectory.Size))
{
const IMAGE_DEBUG_DIRECTORY * DebugEntries = (const IMAGE_DEBUG_DIRECTORY *)(LoadedImageBytes.data() + DebugDirectory.VirtualAddress);
DWORD DebugEntryCount = DebugDirectory.Size / sizeof(IMAGE_DEBUG_DIRECTORY);
for (DWORD Index = 0; Index < DebugEntryCount; Index++)
{
const IMAGE_DEBUG_DIRECTORY * DebugEntry = &DebugEntries[Index];
if (DebugEntry->Type != IMAGE_DEBUG_TYPE_CODEVIEW ||
DebugEntry->SizeOfData < sizeof(DWORD) + sizeof(GUID) + sizeof(DWORD))
{
continue;
}
UINT32 NextRequiredSize = RequiredSize;
if (!SymbolAddLoadedImageReadRange(DebugEntry->AddressOfRawData, DebugEntry->SizeOfData, &NextRequiredSize) ||
NextRequiredSize > SizeOfImage ||
NextRequiredSize > MaximumLoadedImageCodeViewReadSize)
{
continue;
}
RequiredSize = NextRequiredSize;
}
}
if (RequiredSize <= LoadedImageBytes.size())
{
LoadedImageBytes.resize(RequiredSize);
return TRUE;
}
return SymbolReadUserVirtualMemoryExact(BaseAddress, UserProcessId, RequiredSize, LoadedImageBytes);
}
/**
* @brief Delete and free structures and variables related to the symbols
*
* @return BOOLEAN shows whether the operation was successful or not
*/
BOOLEAN
SymbolDeleteSymTable()
{
//
// Unload all symbols
//
ScriptEngineUnloadAllSymbolsWrapper();
//
// Delete symbols
//
if (g_SymbolTable != NULL)
{
free(g_SymbolTable);
g_SymbolTable = NULL;
g_SymbolTableSize = NULL;
g_SymbolTableCurrentIndex = 0;
return TRUE;
}
else
{
return FALSE;
}
}
/**
* @brief make the initial packet required for symbol server
* or reload packet
*
* @param BufferToStoreDetails Pointer to a buffer to store the symbols details
* this buffer will be allocated by this function and needs to be freed by caller
* @param StoredLength The length that stored on the BufferToStoreDetails
* @param UserProcessId Which user mode process to get its modules
* @param SendOverSerial Shows whether the packet should be sent to the debugger
* over the serial or not
*
* @return BOOLEAN shows whether the operation was successful or not
*/
BOOLEAN
SymbolBuildSymbolTable(PMODULE_SYMBOL_DETAIL * BufferToStoreDetails,
PUINT32 StoredLength,
UINT32 UserProcessId,
BOOLEAN SendOverSerial)
{
BOOLEAN Status;
ULONG ReturnedLength;
PRTL_PROCESS_MODULES ModuleInfo = NULL;
PMODULE_SYMBOL_DETAIL ModuleSymDetailArray = NULL;
CHAR SystemRoot[MAX_PATH] = {0};
CHAR ModuleSymbolPath[MAX_PATH] = {0};
CHAR TempPath[MAX_PATH] = {0};
CHAR ModuleSymbolGuidAndAge[MAXIMUM_GUID_AND_AGE_SIZE] = {0};
BOOLEAN IsSymbolPdbDetailAvailable = FALSE;
BOOLEAN IsFreeUsermodeModulesBuffer = FALSE;
UINT32 ModuleDetailsSize = 0;
UINT32 ModulesCount = 0;
PUSERMODE_LOADED_MODULE_DETAILS ModuleDetailsRequest = NULL;
PUSERMODE_LOADED_MODULE_SYMBOLS Modules = NULL;
USERMODE_LOADED_MODULE_DETAILS ModuleCountRequest = {0};
//
// Check if we found an already built symbol table
//
SymbolDeleteSymTable();
//
// Get system root
//
if (GetSystemDirectoryA(SystemRoot, MAX_PATH) == NULL)
{
ShowMessages("err, unable to get system directory (%x)\n",
GetLastError());
return FALSE;
}
string SystemRootString(SystemRoot);
//
// Convert root path to lower-case
//
transform(SystemRootString.begin(),
SystemRootString.end(),
SystemRootString.begin(),
[](UCHAR c) { return std::tolower(c); });
//
// Remove system32 from the root
//
Replace(SystemRootString, "\\system32", "");
//
// *****************************************************************
// Get kernel-mode modules information
// *****************************************************************
//
if (SymbolCheckAndAllocateModuleInformation(&ModuleInfo) == FALSE)
{
ShowMessages("err, unable to get module information\n");
return FALSE;
}
//
// *****************************************************************
// Get user-mode modules information
// *****************************************************************
//
//
// We won't fail the entire process if the user-mode modules is failed
//
do
{
//
// Check if debugger is loaded or not
//
if (!g_DeviceHandle)
{
break;
}
//
// Set the module details to get the details
//
ModuleCountRequest.ProcessId = UserProcessId;
ModuleCountRequest.OnlyCountModules = TRUE;
//
// Send the request to the kernel
//
Status = DeviceIoControl(
g_DeviceHandle, // Handle to device
IOCTL_GET_USER_MODE_MODULE_DETAILS, // IO Control
// code
&ModuleCountRequest, // Input Buffer to driver.
sizeof(USERMODE_LOADED_MODULE_DETAILS), // Input buffer length
&ModuleCountRequest, // Output Buffer from driver.
sizeof(USERMODE_LOADED_MODULE_DETAILS), // Length of output
// buffer in bytes.
&ReturnedLength, // Bytes placed in buffer.
NULL // synchronous call
);
if (!Status)
{
break;
}
//
// Check if counting modules was successful or not
//
if (ModuleCountRequest.Result == DEBUGGER_OPERATION_WAS_SUCCESSFUL)
{
ModulesCount = ModuleCountRequest.ModulesCount;
// ShowMessages("Count of modules : 0x%x\n", ModuleCountRequest.ModulesCount);
ModuleDetailsSize = sizeof(USERMODE_LOADED_MODULE_DETAILS) +
(ModuleCountRequest.ModulesCount * sizeof(USERMODE_LOADED_MODULE_SYMBOLS));
ModuleDetailsRequest = (PUSERMODE_LOADED_MODULE_DETAILS)malloc(ModuleDetailsSize);
if (ModuleDetailsRequest == NULL)
{
break;
}
RtlZeroMemory(ModuleDetailsRequest, ModuleDetailsSize);
//
// Set the module details to get the modules (not count)
//
ModuleDetailsRequest->ProcessId = UserProcessId;
ModuleDetailsRequest->OnlyCountModules = FALSE;
//
// Send the request to the kernel
//
Status = DeviceIoControl(
g_DeviceHandle, // Handle to device
IOCTL_GET_USER_MODE_MODULE_DETAILS, // IO Control
// code
ModuleDetailsRequest, // Input Buffer to driver.
sizeof(USERMODE_LOADED_MODULE_DETAILS), // Input buffer length
ModuleDetailsRequest, // Output Buffer from driver.
ModuleDetailsSize, // Length of output
// buffer in bytes.
&ReturnedLength, // Bytes placed in buffer.
NULL // synchronous call
);
if (!Status)
{
free(ModuleDetailsRequest);
break;
}
//
// check the module list
//
if (ModuleDetailsRequest->Result == DEBUGGER_OPERATION_WAS_SUCCESSFUL)
{
//
// Se the modules buffer
//
Modules = (PUSERMODE_LOADED_MODULE_SYMBOLS)((UINT64)ModuleDetailsRequest +
sizeof(USERMODE_LOADED_MODULE_DETAILS));
//
// Check if modules buffer is valid
//
if (Modules == NULL)
{
ModulesCount = 0;
free(ModuleDetailsRequest);
break;
}
}
else
{
ShowErrorMessage(ModuleDetailsRequest->Result);
free(ModuleDetailsRequest);
break;
}
//
// Everything is okay when we reached here
//
IsFreeUsermodeModulesBuffer = TRUE;
}
else
{
ShowErrorMessage(ModuleCountRequest.Result);
break;
}
} while (FALSE);
//
// *****************************************************************
//
//
// Allocate Details buffer
//
ModuleSymDetailArray = (PMODULE_SYMBOL_DETAIL)malloc(
(ModuleInfo->NumberOfModules + ModulesCount) * sizeof(MODULE_SYMBOL_DETAIL));
if (ModuleSymDetailArray == NULL)
{
ShowMessages("err, unable to allocate memory for module list (%x)\n",
GetLastError());
if (IsFreeUsermodeModulesBuffer)
{
free(ModuleDetailsRequest);
}
free(ModuleInfo);
return FALSE;
}
//
// Make sure buffer is zero
//
RtlZeroMemory(ModuleSymDetailArray, (ModuleInfo->NumberOfModules + ModulesCount) * sizeof(MODULE_SYMBOL_DETAIL));
//
// ----------------------------------------------------------------------------------
// Add user-modules
// ----------------------------------------------------------------------------------
//
if (ModulesCount != 0)
{
for (UINT32 i = 0; i < ModulesCount; i++)
{
//
// For logging purpose
//
/*
ShowMessages("%016llx\t%016llx\t%ws\n",
Modules[i].BaseAddress,
Modules[i].Entrypoint,
Modules[i].FilePath);
*/
//
// Read symbol signature details
//
RtlZeroMemory(ModuleSymbolPath, sizeof(ModuleSymbolPath));
RtlZeroMemory(TempPath, sizeof(TempPath));
RtlZeroMemory(ModuleSymbolGuidAndAge, sizeof(ModuleSymbolGuidAndAge));
std::vector<BYTE> LoadedImageBytes;
//
// Convert symbol path from unicode to ascii
//
wcstombs(TempPath, Modules[i].FilePath, MAX_PATH);
if (SendOverSerial && Modules[i].BaseAddress != 0 &&
SymbolReadLoadedUserModuleForCodeView(Modules[i].BaseAddress, UserProcessId, LoadedImageBytes) &&
ScriptEngineConvertLoadedModuleToPdbFileAndGuidAndAgeDetailsWrapper(LoadedImageBytes.data(),
LoadedImageBytes.size(),
TempPath,
ModuleSymbolPath,
ModuleSymbolGuidAndAge,
ModuleDetailsRequest->Is32Bit))
{
IsSymbolPdbDetailAvailable = TRUE;
// ShowMessages("Hash : %s , Symbol path : %s\n", ModuleSymbolGuidAndAge, ModuleSymbolPath);
}
else if (ScriptEngineConvertFileToPdbFileAndGuidAndAgeDetailsWrapper(
TempPath,
ModuleSymbolPath,
ModuleSymbolGuidAndAge,
ModuleDetailsRequest->Is32Bit))
{
IsSymbolPdbDetailAvailable = TRUE;
// ShowMessages("Hash : %s , Symbol path : %s\n", ModuleSymbolGuidAndAge, ModuleSymbolPath);
}
else
{
IsSymbolPdbDetailAvailable = FALSE;
// ShowMessages("err, unable to get module pdb details\n");
}
//
// Build the structure for this module
//
ModuleSymDetailArray[i].BaseAddress = Modules[i].BaseAddress;
ModuleSymDetailArray[i].IsUserMode = TRUE;
ModuleSymDetailArray[i].Is32Bit = ModuleDetailsRequest->Is32Bit;
memcpy(ModuleSymDetailArray[i].FilePath, TempPath, strlen(TempPath));
if (IsSymbolPdbDetailAvailable)
{
ModuleSymDetailArray[i].IsSymbolDetailsFound = TRUE;
memcpy(ModuleSymDetailArray[i].ModuleSymbolGuidAndAge, ModuleSymbolGuidAndAge, MAXIMUM_GUID_AND_AGE_SIZE);
memcpy(ModuleSymDetailArray[i].ModuleSymbolPath, ModuleSymbolPath, MAX_PATH);
//
// Check if pdb file name is a real path or a module name
//
string ModuleSymbolPathString(ModuleSymbolPath);
if (ModuleSymbolPathString.find(":\\") != std::string::npos)
ModuleSymDetailArray[i].IsLocalSymbolPath = TRUE;
else
ModuleSymDetailArray[i].IsLocalSymbolPath = FALSE;
}
else
{
ModuleSymDetailArray[i].IsSymbolDetailsFound = FALSE;
}
//
// Check if it should be send to the remote debugger over serial
// and also make sure that we're connected to the remote debugger
// and this is a debuggee
//
if (SendOverSerial)
{
KdSendSymbolDetailPacket(&ModuleSymDetailArray[i], i, ModuleInfo->NumberOfModules + ModulesCount);
}
}
}
//
// ----------------------------------------------------------------------------------
// Add kernel-modules
// ----------------------------------------------------------------------------------
//
for (UINT32 i = 0; i < ModuleInfo->NumberOfModules; i++)
{
UINT32 IndexInSymbolBuffer = ModulesCount + i;
auto PathName = ModuleInfo->Modules[i].FullPathName + ModuleInfo->Modules[i].OffsetToFileName;
//
// Read symbol signature details
//
RtlZeroMemory(ModuleSymbolPath, sizeof(ModuleSymbolPath));
RtlZeroMemory(ModuleSymbolGuidAndAge, sizeof(ModuleSymbolGuidAndAge));
string ModuleFullPath((const CHAR *)ModuleInfo->Modules[i].FullPathName);
if (ModuleFullPath.rfind("\\SystemRoot\\", 0) == 0)
{
//
// Path starts with \SystemRoot\
// we should change it to the real system root
// path
//
Replace(ModuleFullPath, "\\SystemRoot", SystemRootString);
}
//
// Kernel modules are all 64-bit
//
if (ScriptEngineConvertFileToPdbFileAndGuidAndAgeDetailsWrapper(ModuleFullPath.c_str(),
ModuleSymbolPath,
ModuleSymbolGuidAndAge,
FALSE))
{
IsSymbolPdbDetailAvailable = TRUE;
//
// ShowMessages("Hash : %s , Symbol path : %s\n", ModuleSymbolGuidAndAge, ModuleSymbolPath);
//
}
else
{
IsSymbolPdbDetailAvailable = FALSE;
//
// ShowMessages("err, unable to get module pdb details\n");
//
}
//
// Build the structure for this module
//
ModuleSymDetailArray[IndexInSymbolBuffer].BaseAddress = (UINT64)ModuleInfo->Modules[i].ImageBase;
memcpy(ModuleSymDetailArray[IndexInSymbolBuffer].FilePath, ModuleFullPath.c_str(), ModuleFullPath.size());
if (IsSymbolPdbDetailAvailable)
{
ModuleSymDetailArray[IndexInSymbolBuffer].IsSymbolDetailsFound = TRUE;
memcpy(ModuleSymDetailArray[IndexInSymbolBuffer].ModuleSymbolGuidAndAge, ModuleSymbolGuidAndAge, MAXIMUM_GUID_AND_AGE_SIZE);
memcpy(ModuleSymDetailArray[IndexInSymbolBuffer].ModuleSymbolPath, ModuleSymbolPath, MAX_PATH);
//
// Check if pdb file name is a real path or a module name
//
string ModuleSymbolPathString(ModuleSymbolPath);
if (ModuleSymbolPathString.find(":\\") != std::string::npos)
ModuleSymDetailArray[IndexInSymbolBuffer].IsLocalSymbolPath = TRUE;
else
ModuleSymDetailArray[IndexInSymbolBuffer].IsLocalSymbolPath = FALSE;
}
else
{
ModuleSymDetailArray[IndexInSymbolBuffer].IsSymbolDetailsFound = FALSE;
}
//
// Check if it should be send to the remote debugger over serial
// and also make sure that we're connected to the remote debugger
// and this is a debuggee
//
if (SendOverSerial)
{
KdSendSymbolDetailPacket(&ModuleSymDetailArray[IndexInSymbolBuffer], IndexInSymbolBuffer, ModuleInfo->NumberOfModules + ModulesCount);
}
}
//
// ----------------------------------------------------------------------------------
//
//
// Store the buffer and length of module symbols details
//
*BufferToStoreDetails = ModuleSymDetailArray;
*StoredLength = (ModuleInfo->NumberOfModules + ModulesCount) * sizeof(MODULE_SYMBOL_DETAIL);
free(ModuleInfo);
if (IsFreeUsermodeModulesBuffer)
{
free(ModuleDetailsRequest);
}
return TRUE;
}
/**
* @brief Allocate (build) and update the symbol table whenever a debuggee is attached
* on the debugger mode
*
* @param SymbolDetail Pointer to a buffer that was received as the single
* symbol info
*
* @return BOOLEAN shows whether the operation was successful or not
*/
BOOLEAN
SymbolBuildAndUpdateSymbolTable(PMODULE_SYMBOL_DETAIL SymbolDetail)
{
//
// Check to avoid overflow in symbol table
//
if (g_SymbolTableCurrentIndex >= MAXIMUM_SUPPORTED_SYMBOLS)
{
ShowMessages("err, the symbol table buffer is full, unable to add new symbol\n");
return FALSE;
}
//
// Check if we found an already built symbol table
//
if (g_SymbolTable == NULL)
{
//
// Allocate Details buffer
//
g_SymbolTable = (PMODULE_SYMBOL_DETAIL)malloc(MAXIMUM_SUPPORTED_SYMBOLS * sizeof(MODULE_SYMBOL_DETAIL));
if (g_SymbolTable == NULL)
{
ShowMessages("err, unable to allocate memory for module list (%x)\n",
GetLastError());
return FALSE;
}
//
// Reset the index
//
g_SymbolTableCurrentIndex = 0;
//
// Make sure buffer is zero
//
RtlZeroMemory(g_SymbolTable, MAXIMUM_SUPPORTED_SYMBOLS * sizeof(MODULE_SYMBOL_DETAIL));
}
//
// Move it to the new buffer
//
memcpy(&g_SymbolTable[g_SymbolTableCurrentIndex], SymbolDetail, sizeof(MODULE_SYMBOL_DETAIL));
//
// Add to index for future symbols
//
g_SymbolTableCurrentIndex++;
//
// Compute the (new) current size
//
g_SymbolTableSize = g_SymbolTableCurrentIndex * sizeof(MODULE_SYMBOL_DETAIL);
return TRUE;
}
/**
* @brief Update the symbol table from remote debuggee in debugger mode
* @param ProcessId
*
* @return BOOLEAN shows whether the operation was successful or not
*/
BOOLEAN
SymbolReloadSymbolTableInDebuggerMode(UINT32 ProcessId)
{
//
// Check if we found an already built symbol table
//
SymbolDeleteSymTable();
//
// Request to send new symbol details
//
if (KdSendSymbolReloadPacketToDebuggee(ProcessId))
{
ShowMessages("symbol table updated successfully\n");
return TRUE;
}
else
{
return FALSE;
}
}
/**
* @brief Check and allocate module information
* @details The caller should free the buffer
* @param Modules
*
* @return BOOLEAN
*/
BOOLEAN
SymbolCheckAndAllocateModuleInformation(PRTL_PROCESS_MODULES * Modules)
{
NTSTATUS Status = STATUS_UNSUCCESSFUL;
ULONG SysModuleInfoBufferSize = 0;
//
// Enable Debug privilege to the current token
//
if (!WindowsSetDebugPrivilege())
{
ShowMessages("err, couldn't set debug privilege\n");
return FALSE;
}
//
// Get required size of "RTL_PROCESS_MODULES" buffer
//
Status = NtQuerySystemInformation((SYSTEM_INFORMATION_CLASS)SystemModuleInformation, NULL, NULL, &SysModuleInfoBufferSize);
//
// print the size of the buffer
//
// ShowMessages("size of the buffer : %x\n", SysModuleInfoBufferSize);
*Modules = (PRTL_PROCESS_MODULES)malloc(SysModuleInfoBufferSize);
if (*Modules == NULL)
{
ShowMessages("err, unable to allocate memory for module list (%x)\n",
GetLastError());
return FALSE;
}
//
// Get the module list
//
Status = NtQuerySystemInformation((SYSTEM_INFORMATION_CLASS)SystemModuleInformation, *Modules, SysModuleInfoBufferSize, NULL);
if (!NT_SUCCESS(Status))
{
ShowMessages("err, unable to query module list (%x)\n", Status);
free(*Modules);
return FALSE;
}
return TRUE;
}