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[Rel21] Stage 1 of updates for Rel21 Build System

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Antz 2015-07-28 10:59:34 +01:00 committed by Antz
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src/shared/WheatyExceptionReport.cpp
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//==========================================
// Matt Pietrek
// MSDN Magazine, 2002
// FILE: WheatyExceptionReport.CPP
//==========================================
#define WIN32_LEAN_AND_MEAN
#pragma warning(disable:4996)
#pragma warning(disable:4312)
#pragma warning(disable:4311)
#include <windows.h>
#include <tlhelp32.h>
#include <stdio.h>
#include <tchar.h>
#define _NO_CVCONST_H
#include <dbghelp.h>
#include "WheatyExceptionReport.h"
#include "revision_nr.h"
#define CrashFolder _T("Crashes")
//#pragma comment(linker, "/defaultlib:dbghelp.lib")
inline LPTSTR ErrorMessage(DWORD dw)
{
LPVOID lpMsgBuf;
FormatMessage(
FORMAT_MESSAGE_ALLOCATE_BUFFER |
FORMAT_MESSAGE_FROM_SYSTEM,
NULL,
dw,
MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT),
(LPTSTR) &lpMsgBuf,
0, NULL);
return (LPTSTR)lpMsgBuf;
}
//============================== Global Variables =============================
//
// Declare the static variables of the WheatyExceptionReport class
//
TCHAR WheatyExceptionReport::m_szLogFileName[MAX_PATH];
LPTOP_LEVEL_EXCEPTION_FILTER WheatyExceptionReport::m_previousFilter;
HANDLE WheatyExceptionReport::m_hReportFile;
HANDLE WheatyExceptionReport::m_hProcess;
// Declare global instance of class
WheatyExceptionReport g_WheatyExceptionReport;
//============================== Class Methods =============================
WheatyExceptionReport::WheatyExceptionReport() // Constructor
{
// Install the unhandled exception filter function
m_previousFilter = SetUnhandledExceptionFilter(WheatyUnhandledExceptionFilter);
m_hProcess = GetCurrentProcess();
}
//============
// Destructor
//============
WheatyExceptionReport::~WheatyExceptionReport()
{
if (m_previousFilter)
{ SetUnhandledExceptionFilter(m_previousFilter); }
}
//===========================================================
// Entry point where control comes on an unhandled exception
//===========================================================
LONG WINAPI WheatyExceptionReport::WheatyUnhandledExceptionFilter(
PEXCEPTION_POINTERS pExceptionInfo)
{
TCHAR module_folder_name[MAX_PATH];
GetModuleFileName(0, module_folder_name, MAX_PATH);
TCHAR* pos = _tcsrchr(module_folder_name, '\\');
if (!pos)
{ return 0; }
pos[0] = '\0';
++pos;
TCHAR crash_folder_path[MAX_PATH];
sprintf(crash_folder_path, "%s\\%s", module_folder_name, CrashFolder);
if (!CreateDirectory(crash_folder_path, NULL))
{
if (GetLastError() != ERROR_ALREADY_EXISTS)
{ return 0; }
}
SYSTEMTIME systime;
GetLocalTime(&systime);
sprintf(m_szLogFileName, "%s\\%s_[%u-%u_%u-%u-%u].txt",
crash_folder_path, pos, systime.wDay, systime.wMonth, systime.wHour, systime.wMinute, systime.wSecond);
m_hReportFile = CreateFile(m_szLogFileName,
GENERIC_WRITE,
0,
0,
OPEN_ALWAYS,
FILE_FLAG_WRITE_THROUGH,
0);
if (m_hReportFile)
{
SetFilePointer(m_hReportFile, 0, 0, FILE_END);
GenerateExceptionReport(pExceptionInfo);
CloseHandle(m_hReportFile);
m_hReportFile = 0;
}
if (m_previousFilter)
{ return m_previousFilter(pExceptionInfo); }
else
{ return EXCEPTION_EXECUTE_HANDLER/*EXCEPTION_CONTINUE_SEARCH*/; }
}
BOOL WheatyExceptionReport::_GetProcessorName(TCHAR* sProcessorName, DWORD maxcount)
{
if (!sProcessorName)
{ return FALSE; }
HKEY hKey;
LONG lRet;
lRet = ::RegOpenKeyEx(HKEY_LOCAL_MACHINE, _T("HARDWARE\\DESCRIPTION\\System\\CentralProcessor\\0"),
0, KEY_QUERY_VALUE, &hKey);
if (lRet != ERROR_SUCCESS)
{ return FALSE; }
TCHAR szTmp[2048];
DWORD cntBytes = sizeof(szTmp);
lRet = ::RegQueryValueEx(hKey, _T("ProcessorNameString"), NULL, NULL,
(LPBYTE)szTmp, &cntBytes);
if (lRet != ERROR_SUCCESS)
{ return FALSE; }
::RegCloseKey(hKey);
sProcessorName[0] = '\0';
// Skip spaces
TCHAR* psz = szTmp;
while (iswspace(*psz))
{ ++psz; }
_tcsncpy(sProcessorName, psz, maxcount);
return TRUE;
}
BOOL WheatyExceptionReport::_GetWindowsVersion(TCHAR* szVersion, DWORD cntMax)
{
// Try calling GetVersionEx using the OSVERSIONINFOEX structure.
// If that fails, try using the OSVERSIONINFO structure.
OSVERSIONINFOEX osvi = { 0 };
osvi.dwOSVersionInfoSize = sizeof(OSVERSIONINFOEX);
BOOL bOsVersionInfoEx;
bOsVersionInfoEx = ::GetVersionEx((LPOSVERSIONINFO)(&osvi));
if (!bOsVersionInfoEx)
{
osvi.dwOSVersionInfoSize = sizeof(OSVERSIONINFO);
if (!::GetVersionEx((OSVERSIONINFO*)&osvi))
{ return FALSE; }
}
*szVersion = _T('\0');
TCHAR wszTmp[128];
// print version
switch (osvi.dwMajorVersion)
{
case 6:
switch (osvi.dwMinorVersion)
{
default: // 2
if (osvi.wProductType == VER_NT_WORKSTATION)
{ _tcsncat(szVersion, _T("Windows 8 "), cntMax); }
else
{ _tcsncat(szVersion, _T("Windows Server 2012 "), cntMax); }
break;
case 1:
if (osvi.wProductType == VER_NT_WORKSTATION)
{ _tcsncat(szVersion, _T("Windows 7 "), cntMax); }
else
{ _tcsncat(szVersion, _T("Windows Server 2008 R2 "), cntMax); }
break;
case 0:
if (osvi.wProductType == VER_NT_WORKSTATION)
{ _tcsncat(szVersion, _T("Windows Vista "), cntMax); }
else
{ _tcsncat(szVersion, _T("Windows Server 2008 "), cntMax); }
break;
}
break;
case 5:
switch (osvi.dwMinorVersion)
{
default: // 2
_tcsncat(szVersion, _T("Windows Server 2003 "), cntMax);
break;
case 1:
_tcsncat(szVersion, _T("Windows XP "), cntMax);
break;
case 0:
_tcsncat(szVersion, _T("Windows 2000 "), cntMax);
break;
}
break;
default:
_tcsncat(szVersion, _T("Windows NT or lower "), cntMax);
break;
}
// print service pack if one is installed
if (_tcslen(osvi.szCSDVersion))
_stprintf(wszTmp, _T("%s (Version %d.%d, Build %d)"),
osvi.szCSDVersion, osvi.dwMajorVersion, osvi.dwMinorVersion, osvi.dwBuildNumber & 0xFFFF);
else
_stprintf(wszTmp, _T("(Version %d.%d, Build %d)"),
osvi.dwMajorVersion, osvi.dwMinorVersion, osvi.dwBuildNumber & 0xFFFF);
_tcsncat(szVersion, wszTmp, cntMax);
return TRUE;
}
void WheatyExceptionReport::PrintSystemInfo()
{
SYSTEM_INFO SystemInfo;
::GetSystemInfo(&SystemInfo);
MEMORYSTATUS MemoryStatus;
MemoryStatus.dwLength = sizeof(MEMORYSTATUS);
::GlobalMemoryStatus(&MemoryStatus);
TCHAR sString[1024];
_tprintf(_T("//=====================================================\r\n"));
if (_GetProcessorName(sString, countof(sString)))
_tprintf(_T("*** Hardware ***\r\nProcessor: %s\r\nNumber Of Processors: %d\r\nPhysical Memory: %d KB (Available: %d KB)\r\nCommit Charge Limit: %d KB\r\n"),
sString, SystemInfo.dwNumberOfProcessors, MemoryStatus.dwTotalPhys / 0x400, MemoryStatus.dwAvailPhys / 0x400, MemoryStatus.dwTotalPageFile / 0x400);
else
_tprintf(_T("*** Hardware ***\r\nProcessor: <unknown>\r\nNumber Of Processors: %d\r\nPhysical Memory: %d KB (Available: %d KB)\r\nCommit Charge Limit: %d KB\r\n"),
SystemInfo.dwNumberOfProcessors, MemoryStatus.dwTotalPhys / 0x400, MemoryStatus.dwAvailPhys / 0x400, MemoryStatus.dwTotalPageFile / 0x400);
if (_GetWindowsVersion(sString, countof(sString)))
{ _tprintf(_T("\r\n*** Operation System ***\r\n%s\r\n"), sString); }
else
{ _tprintf(_T("\r\n*** Operation System:\r\n<unknown>\r\n")); }
}
//===========================================================================
void WheatyExceptionReport::printTracesForAllThreads()
{
HANDLE hThreadSnap = INVALID_HANDLE_VALUE;
THREADENTRY32 te32;
DWORD dwOwnerPID = GetCurrentProcessId();
m_hProcess = GetCurrentProcess();
// Take a snapshot of all running threads
hThreadSnap = CreateToolhelp32Snapshot(TH32CS_SNAPTHREAD, 0);
if (hThreadSnap == INVALID_HANDLE_VALUE)
{ return; }
// Fill in the size of the structure before using it.
te32.dwSize = sizeof(THREADENTRY32);
// Retrieve information about the first thread,
// and exit if unsuccessful
if (!Thread32First(hThreadSnap, &te32))
{
CloseHandle(hThreadSnap); // Must clean up the
// snapshot object!
return;
}
// Now walk the thread list of the system,
// and display information about each thread
// associated with the specified process
do
{
if (te32.th32OwnerProcessID == dwOwnerPID)
{
CONTEXT context;
context.ContextFlags = 0xffffffff;
HANDLE threadHandle = OpenThread(THREAD_GET_CONTEXT | THREAD_QUERY_INFORMATION, false, te32.th32ThreadID);
if (threadHandle && GetThreadContext(threadHandle, &context))
{
WriteStackDetails(&context, false, threadHandle);
}
CloseHandle(threadHandle);
}
}
while (Thread32Next(hThreadSnap, &te32));
// Don't forget to clean up the snapshot object.
CloseHandle(hThreadSnap);
}
//===========================================================================
// Open the report file, and write the desired information to it. Called by
// WheatyUnhandledExceptionFilter
//===========================================================================
void WheatyExceptionReport::GenerateExceptionReport(
PEXCEPTION_POINTERS pExceptionInfo)
{
SYSTEMTIME systime;
GetLocalTime(&systime);
// Start out with a banner
_tprintf(_T("Revision: %s\r\n"), REVISION_NR);
_tprintf(_T("Date %u:%u:%u. Time %u:%u \r\n"), systime.wDay, systime.wMonth, systime.wYear, systime.wHour, systime.wMinute);
PEXCEPTION_RECORD pExceptionRecord = pExceptionInfo->ExceptionRecord;
PrintSystemInfo();
// First print information about the type of fault
_tprintf(_T("\r\n//=====================================================\r\n"));
_tprintf(_T("Exception code: %08X %s\r\n"),
pExceptionRecord->ExceptionCode,
GetExceptionString(pExceptionRecord->ExceptionCode));
// Now print information about where the fault occured
TCHAR szFaultingModule[MAX_PATH];
DWORD section;
DWORD_PTR offset;
GetLogicalAddress(pExceptionRecord->ExceptionAddress,
szFaultingModule,
sizeof(szFaultingModule),
section, offset);
#ifdef _M_IX86
_tprintf(_T("Fault address: %08X %02X:%08X %s\r\n"),
pExceptionRecord->ExceptionAddress,
section, offset, szFaultingModule);
#endif
#ifdef _M_X64
_tprintf(_T("Fault address: %016I64X %02X:%016I64X %s\r\n"),
pExceptionRecord->ExceptionAddress,
section, offset, szFaultingModule);
#endif
PCONTEXT pCtx = pExceptionInfo->ContextRecord;
// Show the registers
#ifdef _M_IX86 // X86 Only!
_tprintf(_T("\r\nRegisters:\r\n"));
_tprintf(_T("EAX:%08X\r\nEBX:%08X\r\nECX:%08X\r\nEDX:%08X\r\nESI:%08X\r\nEDI:%08X\r\n")
, pCtx->Eax, pCtx->Ebx, pCtx->Ecx, pCtx->Edx,
pCtx->Esi, pCtx->Edi);
_tprintf(_T("CS:EIP:%04X:%08X\r\n"), pCtx->SegCs, pCtx->Eip);
_tprintf(_T("SS:ESP:%04X:%08X EBP:%08X\r\n"),
pCtx->SegSs, pCtx->Esp, pCtx->Ebp);
_tprintf(_T("DS:%04X ES:%04X FS:%04X GS:%04X\r\n"),
pCtx->SegDs, pCtx->SegEs, pCtx->SegFs, pCtx->SegGs);
_tprintf(_T("Flags:%08X\r\n"), pCtx->EFlags);
#endif
#ifdef _M_X64
_tprintf(_T("\r\nRegisters:\r\n"));
_tprintf(_T("RAX:%016I64X\r\nRBX:%016I64X\r\nRCX:%016I64X\r\nRDX:%016I64X\r\nRSI:%016I64X\r\nRDI:%016I64X\r\n")
_T("R8: %016I64X\r\nR9: %016I64X\r\nR10:%016I64X\r\nR11:%016I64X\r\nR12:%016I64X\r\nR13:%016I64X\r\nR14:%016I64X\r\nR15:%016I64X\r\n")
, pCtx->Rax, pCtx->Rbx, pCtx->Rcx, pCtx->Rdx,
pCtx->Rsi, pCtx->Rdi , pCtx->R9, pCtx->R10, pCtx->R11, pCtx->R12, pCtx->R13, pCtx->R14, pCtx->R15);
_tprintf(_T("CS:RIP:%04X:%016I64X\r\n"), pCtx->SegCs, pCtx->Rip);
_tprintf(_T("SS:RSP:%04X:%016X RBP:%08X\r\n"),
pCtx->SegSs, pCtx->Rsp, pCtx->Rbp);
_tprintf(_T("DS:%04X ES:%04X FS:%04X GS:%04X\r\n"),
pCtx->SegDs, pCtx->SegEs, pCtx->SegFs, pCtx->SegGs);
_tprintf(_T("Flags:%08X\r\n"), pCtx->EFlags);
#endif
SymSetOptions(SYMOPT_DEFERRED_LOADS);
// Initialize DbgHelp
if (!SymInitialize(GetCurrentProcess(), 0, TRUE))
{
_tprintf(_T("\n\rCRITICAL ERROR.\n\r Couldn't initialize the symbol handler for process.\n\rError [%s].\n\r\n\r"),
ErrorMessage(GetLastError()));
}
CONTEXT trashableContext = *pCtx;
WriteStackDetails(&trashableContext, false, NULL);
printTracesForAllThreads();
// #ifdef _M_IX86 // X86 Only!
_tprintf(_T("========================\r\n"));
_tprintf(_T("Local Variables And Parameters\r\n"));
trashableContext = *pCtx;
WriteStackDetails(&trashableContext, true, NULL);
_tprintf(_T("========================\r\n"));
_tprintf(_T("Global Variables\r\n"));
SymEnumSymbols(GetCurrentProcess(),
(DWORD64)GetModuleHandle(szFaultingModule),
0, EnumerateSymbolsCallback, 0);
// #endif // X86 Only!
SymCleanup(GetCurrentProcess());
_tprintf(_T("\r\n"));
}
//======================================================================
// Given an exception code, returns a pointer to a static string with a
// description of the exception
//======================================================================
LPTSTR WheatyExceptionReport::GetExceptionString(DWORD dwCode)
{
#define EXCEPTION( x ) case EXCEPTION_##x: return _T(#x);
switch (dwCode)
{
EXCEPTION(ACCESS_VIOLATION)
EXCEPTION(DATATYPE_MISALIGNMENT)
EXCEPTION(BREAKPOINT)
EXCEPTION(SINGLE_STEP)
EXCEPTION(ARRAY_BOUNDS_EXCEEDED)
EXCEPTION(FLT_DENORMAL_OPERAND)
EXCEPTION(FLT_DIVIDE_BY_ZERO)
EXCEPTION(FLT_INEXACT_RESULT)
EXCEPTION(FLT_INVALID_OPERATION)
EXCEPTION(FLT_OVERFLOW)
EXCEPTION(FLT_STACK_CHECK)
EXCEPTION(FLT_UNDERFLOW)
EXCEPTION(INT_DIVIDE_BY_ZERO)
EXCEPTION(INT_OVERFLOW)
EXCEPTION(PRIV_INSTRUCTION)
EXCEPTION(IN_PAGE_ERROR)
EXCEPTION(ILLEGAL_INSTRUCTION)
EXCEPTION(NONCONTINUABLE_EXCEPTION)
EXCEPTION(STACK_OVERFLOW)
EXCEPTION(INVALID_DISPOSITION)
EXCEPTION(GUARD_PAGE)
EXCEPTION(INVALID_HANDLE)
}
// If not one of the "known" exceptions, try to get the string
// from NTDLL.DLL's message table.
static TCHAR szBuffer[512] = { 0 };
FormatMessage(FORMAT_MESSAGE_IGNORE_INSERTS | FORMAT_MESSAGE_FROM_HMODULE,
GetModuleHandle(_T("NTDLL.DLL")),
dwCode, 0, szBuffer, sizeof(szBuffer), 0);
return szBuffer;
}
//=============================================================================
// Given a linear address, locates the module, section, and offset containing
// that address.
//
// Note: the szModule paramater buffer is an output buffer of length specified
// by the len parameter (in characters!)
//=============================================================================
BOOL WheatyExceptionReport::GetLogicalAddress(
PVOID addr, PTSTR szModule, DWORD len, DWORD& section, DWORD_PTR& offset)
{
MEMORY_BASIC_INFORMATION mbi;
if (!VirtualQuery(addr, &mbi, sizeof(mbi)))
{ return FALSE; }
DWORD_PTR hMod = (DWORD_PTR)mbi.AllocationBase;
if (!GetModuleFileName((HMODULE)hMod, szModule, len))
{ return FALSE; }
// Point to the DOS header in memory
PIMAGE_DOS_HEADER pDosHdr = (PIMAGE_DOS_HEADER)hMod;
// From the DOS header, find the NT (PE) header
PIMAGE_NT_HEADERS pNtHdr = (PIMAGE_NT_HEADERS)(hMod + DWORD_PTR(pDosHdr->e_lfanew));
PIMAGE_SECTION_HEADER pSection = IMAGE_FIRST_SECTION(pNtHdr);
DWORD_PTR rva = (DWORD_PTR)addr - hMod; // RVA is offset from module load address
// Iterate through the section table, looking for the one that encompasses
// the linear address.
for (unsigned i = 0;
i < pNtHdr->FileHeader.NumberOfSections;
++i, ++pSection)
{
DWORD_PTR sectionStart = pSection->VirtualAddress;
DWORD_PTR sectionEnd = sectionStart
+ DWORD_PTR(max(pSection->SizeOfRawData, pSection->Misc.VirtualSize));
// Is the address in this section???
if ((rva >= sectionStart) && (rva <= sectionEnd))
{
// Yes, address is in the section. Calculate section and offset,
// and store in the "section" & "offset" params, which were
// passed by reference.
section = i + 1;
offset = rva - sectionStart;
return TRUE;
}
}
return FALSE; // Should never get here!
}
// It contains SYMBOL_INFO structure plus additional
// space for the name of the symbol
struct CSymbolInfoPackage : public SYMBOL_INFO_PACKAGE
{
CSymbolInfoPackage()
{
si.SizeOfStruct = sizeof(SYMBOL_INFO);
si.MaxNameLen = sizeof(name);
}
};
//============================================================
// Walks the stack, and writes the results to the report file
//============================================================
void WheatyExceptionReport::WriteStackDetails(
PCONTEXT pContext,
bool bWriteVariables, HANDLE pThreadHandle) // true if local/params should be output
{
_tprintf(_T("\r\nCall stack:\r\n"));
_tprintf(_T("Address Frame Function SourceFile\r\n"));
DWORD dwMachineType = 0;
// Could use SymSetOptions here to add the SYMOPT_DEFERRED_LOADS flag
STACKFRAME64 sf;
memset(&sf, 0, sizeof(sf));
#ifdef _M_IX86
// Initialize the STACKFRAME structure for the first call. This is only
// necessary for Intel CPUs, and isn't mentioned in the documentation.
sf.AddrPC.Offset = pContext->Eip;
sf.AddrPC.Mode = AddrModeFlat;
sf.AddrStack.Offset = pContext->Esp;
sf.AddrStack.Mode = AddrModeFlat;
sf.AddrFrame.Offset = pContext->Ebp;
sf.AddrFrame.Mode = AddrModeFlat;
dwMachineType = IMAGE_FILE_MACHINE_I386;
#endif
#ifdef _M_X64
sf.AddrPC.Offset = pContext->Rip;
sf.AddrPC.Mode = AddrModeFlat;
sf.AddrStack.Offset = pContext->Rsp;
sf.AddrStack.Mode = AddrModeFlat;
sf.AddrFrame.Offset = pContext->Rbp;
sf.AddrFrame.Mode = AddrModeFlat;
dwMachineType = IMAGE_FILE_MACHINE_AMD64;
#endif
while (1)
{
// Get the next stack frame
if (! StackWalk64(dwMachineType,
m_hProcess,
pThreadHandle != NULL ? pThreadHandle : GetCurrentThread(),
&sf,
pContext,
0,
SymFunctionTableAccess64,
SymGetModuleBase64,
0))
{ break; }
if (0 == sf.AddrFrame.Offset) // Basic sanity check to make sure
{ break; } // the frame is OK. Bail if not.
#ifdef _M_IX86
_tprintf(_T("%08X %08X "), sf.AddrPC.Offset, sf.AddrFrame.Offset);
#endif
#ifdef _M_X64
_tprintf(_T("%016I64X %016I64X "), sf.AddrPC.Offset, sf.AddrFrame.Offset);
#endif
DWORD64 symDisplacement = 0; // Displacement of the input address,
// relative to the start of the symbol
// Get the name of the function for this stack frame entry
CSymbolInfoPackage sip;
if (SymFromAddr(
m_hProcess, // Process handle of the current process
sf.AddrPC.Offset, // Symbol address
&symDisplacement, // Address of the variable that will receive the displacement
&sip.si)) // Address of the SYMBOL_INFO structure (inside "sip" object)
{
_tprintf(_T("%hs+%I64X"), sip.si.Name, symDisplacement);
}
else // No symbol found. Print out the logical address instead.
{
TCHAR szModule[MAX_PATH] = _T("");
DWORD section = 0;
DWORD_PTR offset = 0;
GetLogicalAddress((PVOID)sf.AddrPC.Offset,
szModule, sizeof(szModule), section, offset);
#ifdef _M_IX86
_tprintf(_T("%04X:%08X %s"), section, offset, szModule);
#endif
#ifdef _M_X64
_tprintf(_T("%04X:%016I64X %s"), section, offset, szModule);
#endif
}
// Get the source line for this stack frame entry
IMAGEHLP_LINE64 lineInfo = { sizeof(IMAGEHLP_LINE) };
DWORD dwLineDisplacement;
if (SymGetLineFromAddr64(m_hProcess, sf.AddrPC.Offset,
&dwLineDisplacement, &lineInfo))
{
_tprintf(_T(" %s line %u"), lineInfo.FileName, lineInfo.LineNumber);
}
_tprintf(_T("\r\n"));
// Write out the variables, if desired
if (bWriteVariables)
{
// Use SymSetContext to get just the locals/params for this frame
IMAGEHLP_STACK_FRAME imagehlpStackFrame;
imagehlpStackFrame.InstructionOffset = sf.AddrPC.Offset;
SymSetContext(m_hProcess, &imagehlpStackFrame, 0);
// Enumerate the locals/parameters
SymEnumSymbols(m_hProcess, 0, 0, EnumerateSymbolsCallback, &sf);
_tprintf(_T("\r\n"));
}
}
}
//////////////////////////////////////////////////////////////////////////////
// The function invoked by SymEnumSymbols
//////////////////////////////////////////////////////////////////////////////
BOOL CALLBACK
WheatyExceptionReport::EnumerateSymbolsCallback(
PSYMBOL_INFO pSymInfo,
ULONG SymbolSize,
PVOID UserContext)
{
char szBuffer[2048];
__try
{
if (FormatSymbolValue(pSymInfo, (STACKFRAME*)UserContext,
szBuffer, sizeof(szBuffer)))
{ _tprintf(_T("\t%s\r\n"), szBuffer); }
}
__except(1)
{
_tprintf(_T("punting on symbol %s\r\n"), pSymInfo->Name);
}
return TRUE;
}
//////////////////////////////////////////////////////////////////////////////
// Given a SYMBOL_INFO representing a particular variable, displays its
// contents. If it's a user defined type, display the members and their
// values.
//////////////////////////////////////////////////////////////////////////////
bool WheatyExceptionReport::FormatSymbolValue(
PSYMBOL_INFO pSym,
STACKFRAME* sf,
char* pszBuffer,
unsigned cbBuffer)
{
char* pszCurrBuffer = pszBuffer;
// Indicate if the variable is a local or parameter
if (pSym->Flags & IMAGEHLP_SYMBOL_INFO_PARAMETER)
{ pszCurrBuffer += sprintf(pszCurrBuffer, "Parameter "); }
else if (pSym->Flags & IMAGEHLP_SYMBOL_INFO_LOCAL)
{ pszCurrBuffer += sprintf(pszCurrBuffer, "Local "); }
// If it's a function, don't do anything.
if (pSym->Tag == 5) // SymTagFunction from CVCONST.H from the DIA SDK
{ return false; }
DWORD_PTR pVariable = 0; // Will point to the variable's data in memory
if (pSym->Flags & IMAGEHLP_SYMBOL_INFO_REGRELATIVE)
{
// if ( pSym->Register == 8 ) // EBP is the value 8 (in DBGHELP 5.1)
{
// This may change!!!
pVariable = sf->AddrFrame.Offset;
pVariable += (DWORD_PTR)pSym->Address;
}
// else
// return false;
}
else if (pSym->Flags & IMAGEHLP_SYMBOL_INFO_REGISTER)
{
return false; // Don't try to report register variable
}
else
{
pVariable = (DWORD_PTR)pSym->Address; // It must be a global variable
}
// Determine if the variable is a user defined type (UDT). IF so, bHandled
// will return true.
bool bHandled;
pszCurrBuffer = DumpTypeIndex(pszCurrBuffer, pSym->ModBase, pSym->TypeIndex,
0, pVariable, bHandled, pSym->Name);
if (!bHandled)
{
// The symbol wasn't a UDT, so do basic, stupid formatting of the
// variable. Based on the size, we're assuming it's a char, WORD, or
// DWORD.
BasicType basicType = GetBasicType(pSym->TypeIndex, pSym->ModBase);
pszCurrBuffer += sprintf(pszCurrBuffer, rgBaseType[basicType]);
// Emit the variable name
pszCurrBuffer += sprintf(pszCurrBuffer, "\'%s\'", pSym->Name);
pszCurrBuffer = FormatOutputValue(pszCurrBuffer, basicType, pSym->Size,
(PVOID)pVariable);
}
return true;
}
//////////////////////////////////////////////////////////////////////////////
// If it's a user defined type (UDT), recurse through its members until we're
// at fundamental types. When he hit fundamental types, return
// bHandled = false, so that FormatSymbolValue() will format them.
//////////////////////////////////////////////////////////////////////////////
char* WheatyExceptionReport::DumpTypeIndex(
char* pszCurrBuffer,
DWORD64 modBase,
DWORD dwTypeIndex,
unsigned nestingLevel,
DWORD_PTR offset,
bool& bHandled,
char* Name)
{
bHandled = false;
// Get the name of the symbol. This will either be a Type name (if a UDT),
// or the structure member name.
WCHAR* pwszTypeName;
if (SymGetTypeInfo(m_hProcess, modBase, dwTypeIndex, TI_GET_SYMNAME,
&pwszTypeName))
{
pszCurrBuffer += sprintf(pszCurrBuffer, " %ls", pwszTypeName);
LocalFree(pwszTypeName);
}
// Determine how many children this type has.
DWORD dwChildrenCount = 0;
SymGetTypeInfo(m_hProcess, modBase, dwTypeIndex, TI_GET_CHILDRENCOUNT,
&dwChildrenCount);
if (!dwChildrenCount) // If no children, we're done
{ return pszCurrBuffer; }
// Prepare to get an array of "TypeIds", representing each of the children.
// SymGetTypeInfo(TI_FINDCHILDREN) expects more memory than just a
// TI_FINDCHILDREN_PARAMS struct has. Use derivation to accomplish this.
struct FINDCHILDREN : TI_FINDCHILDREN_PARAMS
{
ULONG MoreChildIds[1024];
FINDCHILDREN() {Count = sizeof(MoreChildIds) / sizeof(MoreChildIds[0]);}
} children;
children.Count = dwChildrenCount;
children.Start = 0;
// Get the array of TypeIds, one for each child type
if (!SymGetTypeInfo(m_hProcess, modBase, dwTypeIndex, TI_FINDCHILDREN,
&children))
{
return pszCurrBuffer;
}
// Append a line feed
pszCurrBuffer += sprintf(pszCurrBuffer, "\r\n");
// Iterate through each of the children
for (unsigned i = 0; i < dwChildrenCount; ++i)
{
// Add appropriate indentation level (since this routine is recursive)
for (unsigned j = 0; j <= nestingLevel + 1; ++j)
{ pszCurrBuffer += sprintf(pszCurrBuffer, "\t"); }
// Recurse for each of the child types
bool bHandled2;
BasicType basicType = GetBasicType(children.ChildId[i], modBase);
pszCurrBuffer += sprintf(pszCurrBuffer, rgBaseType[basicType]);
pszCurrBuffer = DumpTypeIndex(pszCurrBuffer, modBase,
children.ChildId[i], nestingLevel + 1,
offset, bHandled2, ""/*Name */);
// If the child wasn't a UDT, format it appropriately
if (!bHandled2)
{
// Get the offset of the child member, relative to its parent
DWORD dwMemberOffset;
SymGetTypeInfo(m_hProcess, modBase, children.ChildId[i],
TI_GET_OFFSET, &dwMemberOffset);
// Get the real "TypeId" of the child. We need this for the
// SymGetTypeInfo( TI_GET_TYPEID ) call below.
DWORD typeId;
SymGetTypeInfo(m_hProcess, modBase, children.ChildId[i],
TI_GET_TYPEID, &typeId);
// Get the size of the child member
ULONG64 length;
SymGetTypeInfo(m_hProcess, modBase, typeId, TI_GET_LENGTH, &length);
// Calculate the address of the member
DWORD_PTR dwFinalOffset = offset + dwMemberOffset;
// BasicType basicType = GetBasicType(children.ChildId[i], modBase );
//
// pszCurrBuffer += sprintf( pszCurrBuffer, rgBaseType[basicType]);
//
// Emit the variable name
// pszCurrBuffer += sprintf( pszCurrBuffer, "\'%s\'", Name );
pszCurrBuffer = FormatOutputValue(pszCurrBuffer, basicType,
length, (PVOID)dwFinalOffset);
pszCurrBuffer += sprintf(pszCurrBuffer, "\r\n");
}
}
bHandled = true;
return pszCurrBuffer;
}
char* WheatyExceptionReport::FormatOutputValue(char* pszCurrBuffer,
BasicType basicType,
DWORD64 length,
PVOID pAddress)
{
// Format appropriately (assuming it's a 1, 2, or 4 bytes (!!!)
if (length == 1)
{ pszCurrBuffer += sprintf(pszCurrBuffer, " = %X", *(PBYTE)pAddress); }
else if (length == 2)
{ pszCurrBuffer += sprintf(pszCurrBuffer, " = %X", *(PWORD)pAddress); }
else if (length == 4)
{
if (basicType == btFloat)
{
pszCurrBuffer += sprintf(pszCurrBuffer, " = %f", *(PFLOAT)pAddress);
}
else if (basicType == btChar)
{
if (!IsBadStringPtr(*(PSTR*)pAddress, 32))
{
pszCurrBuffer += sprintf(pszCurrBuffer, " = \"%.31s\"",
*(PDWORD)pAddress);
}
else
pszCurrBuffer += sprintf(pszCurrBuffer, " = %X",
*(PDWORD)pAddress);
}
else
{ pszCurrBuffer += sprintf(pszCurrBuffer, " = %X", *(PDWORD)pAddress); }
}
else if (length == 8)
{
if (basicType == btFloat)
{
pszCurrBuffer += sprintf(pszCurrBuffer, " = %lf",
*(double*)pAddress);
}
else
pszCurrBuffer += sprintf(pszCurrBuffer, " = %I64X",
*(DWORD64*)pAddress);
}
return pszCurrBuffer;
}
BasicType
WheatyExceptionReport::GetBasicType(DWORD typeIndex, DWORD64 modBase)
{
BasicType basicType;
if (SymGetTypeInfo(m_hProcess, modBase, typeIndex,
TI_GET_BASETYPE, &basicType))
{
return basicType;
}
// Get the real "TypeId" of the child. We need this for the
// SymGetTypeInfo( TI_GET_TYPEID ) call below.
DWORD typeId;
if (SymGetTypeInfo(m_hProcess, modBase, typeIndex, TI_GET_TYPEID, &typeId))
{
if (SymGetTypeInfo(m_hProcess, modBase, typeId, TI_GET_BASETYPE,
&basicType))
{
return basicType;
}
}
return btNoType;
}
//============================================================================
// Helper function that writes to the report file, and allows the user to use
// printf style formating
//============================================================================
int __cdecl WheatyExceptionReport::_tprintf(const TCHAR* format, ...)
{
TCHAR szBuff[1024];
int retValue;
DWORD cbWritten;
va_list argptr;
va_start(argptr, format);
retValue = vsprintf(szBuff, format, argptr);
va_end(argptr);
WriteFile(m_hReportFile, szBuff, retValue * sizeof(TCHAR), &cbWritten, 0);
return retValue;
}