r5sdk/r5dev/tier0/crashhandler.cpp

//=============================================================================//
//
// Purpose: Crash handler (overrides the game's implementation!)
//
//=============================================================================//
#include "core/stdafx.h"
#include "core/logdef.h"
#include "tier0/cpu.h"
#include "tier0/crashhandler.h"
#include "public/utility/binstream.h"

//-----------------------------------------------------------------------------
// Purpose: 
//-----------------------------------------------------------------------------
void CCrashHandler::Start()
{
	Lock();
	m_bExceptionHandled = true;
}

//-----------------------------------------------------------------------------
// Purpose: 
//-----------------------------------------------------------------------------
void CCrashHandler::End()
{
	m_bExceptionHandled = false;
	Unlock();
}

//-----------------------------------------------------------------------------
// Purpose: formats the crasher (module, address and exception)
//-----------------------------------------------------------------------------
void CCrashHandler::FormatCrash()
{
	m_svBuffer.append("crash:\n{\n");

	FormatExceptionAddress();
	FormatExceptionCode();

	m_svBuffer.append("}\n");
}

//-----------------------------------------------------------------------------
// Purpose: formats the captured callstack
//-----------------------------------------------------------------------------
void CCrashHandler::FormatCallstack()
{
	m_svBuffer.append("callstack:\n{\n");

	if (m_nCapturedFrames)
	{
		PEXCEPTION_RECORD pExceptionRecord = m_pExceptionPointers->ExceptionRecord;
		if (m_ppStackTrace[m_nCapturedFrames - 1] == pExceptionRecord->ExceptionAddress)
		{
			PCONTEXT pContextRecord = m_pExceptionPointers->ContextRecord;
			MEMORY_BASIC_INFORMATION mbi = { 0 };
			SIZE_T t = VirtualQuery((LPCVOID)pContextRecord->Rsp, &mbi, sizeof(LPCVOID));

			if (t >= sizeof(mbi)
				&& !(mbi.Protect & PAGE_NOACCESS)
				&& ((mbi.Protect & PAGE_READONLY) | PAGE_READWRITE)
				&& (mbi.State & MEM_COMMIT))
			{
				m_svBuffer.append("\t// call stack ended; possible return address?\n");
			}
		}
	}
	for (WORD i = 0; i < m_nCapturedFrames; i++)
	{
		FormatExceptionAddress(reinterpret_cast<LPCSTR>(m_ppStackTrace[i]));
	}

	m_svBuffer.append("}\n");
}

//-----------------------------------------------------------------------------
// Purpose: formats all the registers and their contents
//-----------------------------------------------------------------------------
void CCrashHandler::FormatRegisters()
{
	m_svBuffer.append("registers:\n{\n");
	PCONTEXT pContextRecord = m_pExceptionPointers->ContextRecord;

	FormatALU("rax", pContextRecord->Rax);
	FormatALU("rbx", pContextRecord->Rbx);
	FormatALU("rcx", pContextRecord->Rcx);
	FormatALU("rdx", pContextRecord->Rdx);
	FormatALU("rsp", pContextRecord->Rsp);
	FormatALU("rbp", pContextRecord->Rbp);
	FormatALU("rsi", pContextRecord->Rsi);
	FormatALU("rdi", pContextRecord->Rdi);
	FormatALU("r8 ", pContextRecord->R8);
	FormatALU("r9 ", pContextRecord->R9);
	FormatALU("r10", pContextRecord->R10);
	FormatALU("r11", pContextRecord->R11);
	FormatALU("r12", pContextRecord->R12);
	FormatALU("r13", pContextRecord->R13);
	FormatALU("r14", pContextRecord->R14);
	FormatALU("r15", pContextRecord->R15);
	FormatALU("rip", pContextRecord->Rip);

	FormatFPU("xmm0 ", &pContextRecord->Xmm0);
	FormatFPU("xmm1 ", &pContextRecord->Xmm1);
	FormatFPU("xmm2 ", &pContextRecord->Xmm2);
	FormatFPU("xmm3 ", &pContextRecord->Xmm3);
	FormatFPU("xmm4 ", &pContextRecord->Xmm4);
	FormatFPU("xmm5 ", &pContextRecord->Xmm5);
	FormatFPU("xmm6 ", &pContextRecord->Xmm6);
	FormatFPU("xmm7 ", &pContextRecord->Xmm7);
	FormatFPU("xmm8 ", &pContextRecord->Xmm8);
	FormatFPU("xmm9 ", &pContextRecord->Xmm9);
	FormatFPU("xmm10", &pContextRecord->Xmm10);
	FormatFPU("xmm11", &pContextRecord->Xmm11);
	FormatFPU("xmm12", &pContextRecord->Xmm12);
	FormatFPU("xmm13", &pContextRecord->Xmm13);
	FormatFPU("xmm14", &pContextRecord->Xmm14);
	FormatFPU("xmm15", &pContextRecord->Xmm15);

	m_svBuffer.append("}\n");
}

//-----------------------------------------------------------------------------
// Purpose: formats all loaded modules (verbose)
//-----------------------------------------------------------------------------
void CCrashHandler::FormatModules()
{
	m_svBuffer.append("modules:\n{\n");

	std::unique_ptr<HMODULE[]> hModule(new HMODULE[CRASHHANDLER_MAX_MODULES]);
	HANDLE hProcess = GetCurrentProcess();
	DWORD cbNeeded;

	BOOL result = K32EnumProcessModulesEx(hProcess, &*hModule.get(), CRASHHANDLER_MAX_MODULES, &cbNeeded, LIST_MODULES_ALL);
	if (result && cbNeeded <= CRASHHANDLER_MAX_MODULES && cbNeeded >> 3)
	{
		CHAR szModuleName[512];
		LPSTR pszModuleName;
		MODULEINFO modInfo;

		for (DWORD i = 0, j = cbNeeded >> 3; j; i++, j--)
		{
			DWORD m = GetModuleFileNameA(&*hModule.get()[i], szModuleName, sizeof(szModuleName));
			if ((m - 1) > (sizeof(szModuleName) - 2)) // Too small for buffer.
			{
				snprintf(szModuleName, sizeof(szModuleName), "module@%p", &*hModule.get()[i]);
				pszModuleName = szModuleName;
			}
			else
			{
				pszModuleName = strrchr(szModuleName, '\\') + 1;
			}

			K32GetModuleInformation(hProcess, &*hModule.get()[i], &modInfo, sizeof(modInfo));

			m_svBuffer.append(Format("\t%-15s: [%p, %p]\n", 
				pszModuleName, modInfo.lpBaseOfDll, (reinterpret_cast<uintptr_t>(modInfo.lpBaseOfDll) + modInfo.SizeOfImage)));
		}
	}

	m_svBuffer.append("}\n");
}

//-----------------------------------------------------------------------------
// Purpose: formats the system information
//-----------------------------------------------------------------------------
void CCrashHandler::FormatSystemInfo()
{
	m_svBuffer.append("system:\n{\n");

	const CPUInformation& pi = GetCPUInformation();

	m_svBuffer.append(Format("\tcpu_model = \"%s\"\n", pi.m_szProcessorBrand));
	m_svBuffer.append(Format("\tcpu_speed = %010lld // clock cycles\n", pi.m_Speed));

	for (DWORD i = 0; ; i++)
	{
		DISPLAY_DEVICE dd = { sizeof(dd), {0} };
		BOOL f = EnumDisplayDevices(NULL, i, &dd, EDD_GET_DEVICE_INTERFACE_NAME);
		if (!f)
		{
			break;
		}

		if (dd.StateFlags & DISPLAY_DEVICE_PRIMARY_DEVICE) // The primary device is the only relevant device.
		{
			char szDeviceName[128];
			wcstombs(szDeviceName, dd.DeviceString, sizeof(szDeviceName));
			m_svBuffer.append(Format("\tgpu_model = \"%s\"\n", szDeviceName));
			m_svBuffer.append(Format("\tgpu_flags = 0x%08X // primary device\n", dd.StateFlags));
		}
	}

	MEMORYSTATUSEX statex{};
	statex.dwLength = sizeof(statex);

	if (GlobalMemoryStatusEx(&statex))
	{
		m_svBuffer.append(Format("\tram_total = [%010d, %010d] // physical/virtual (MiB)\n", (statex.ullTotalPhys / 1024) / 1024, (statex.ullTotalVirtual / 1024) / 1024));
		m_svBuffer.append(Format("\tram_avail = [%010d, %010d] // physical/virtual (MiB)\n", (statex.ullAvailPhys / 1024) / 1024, (statex.ullAvailVirtual / 1024) / 1024));
	}

	m_svBuffer.append("}\n");
}

//-----------------------------------------------------------------------------
// Purpose: formats the build information
//-----------------------------------------------------------------------------
void CCrashHandler::FormatBuildInfo()
{
	m_svBuffer.append(Format("build_id: %u\n", g_SDKDll.m_pNTHeaders->FileHeader.TimeDateStamp));
}

//-----------------------------------------------------------------------------
// Purpose: formats the module, address and exception
//-----------------------------------------------------------------------------
void CCrashHandler::FormatExceptionAddress()
{
	FormatExceptionAddress(static_cast<LPCSTR>(m_pExceptionPointers->ExceptionRecord->ExceptionAddress));
}

//-----------------------------------------------------------------------------
// Purpose: formats the module, address and exception
// Input  : pExceptionAddress - 
//-----------------------------------------------------------------------------
void CCrashHandler::FormatExceptionAddress(LPCSTR pExceptionAddress)
{
	HMODULE hCrashedModule;
	if (!GetModuleHandleExA(GET_MODULE_HANDLE_EX_FLAG_FROM_ADDRESS | GET_MODULE_HANDLE_EX_FLAG_UNCHANGED_REFCOUNT, pExceptionAddress, &hCrashedModule))
	{
		m_svBuffer.append(Format("\t!!!unknown-module!!!: %p\n", pExceptionAddress));
		m_nCrashMsgFlags = 0; // Display the "unknown DLL or EXE" message.
		return;
	}

	LPCSTR pModuleBase = reinterpret_cast<LPCSTR>(pExceptionAddress - reinterpret_cast<LPCSTR>(hCrashedModule));

	CHAR szCrashedModuleFullName[512];
	if (GetModuleFileNameExA(GetCurrentProcess(), hCrashedModule, szCrashedModuleFullName, sizeof(szCrashedModuleFullName)) - 1 > 0x1FE)
	{
		m_svBuffer.append(Format("\tmodule@%p: %p\n", (void*)hCrashedModule, pModuleBase));
		m_nCrashMsgFlags = 2; // Display the "Apex crashed" message without additional information regarding the module.
		return;
	}

	// TODO: REMOVE EXT.
	const CHAR* szCrashedModuleName = strrchr(szCrashedModuleFullName, '\\') + 1;
	m_svBuffer.append(Format("\t%-15s: %p\n", szCrashedModuleName, pModuleBase));
	m_nCrashMsgFlags = 1; // Display the "Apex crashed in <module>" message.

	if (m_svCrashMsgInfo.empty()) // Only set it once to the crashing module.
	{
		m_svCrashMsgInfo = szCrashedModuleName;
	}
}

//-----------------------------------------------------------------------------
// Purpose: formats the exception code
//-----------------------------------------------------------------------------
void CCrashHandler::FormatExceptionCode()
{
	DWORD nExceptionCode = m_pExceptionPointers->ExceptionRecord->ExceptionCode;
	if (nExceptionCode > EXCEPTION_IN_PAGE_ERROR)
	{
		m_svBuffer.append(Format(ExceptionToString(), nExceptionCode));
	}
	else if (nExceptionCode >= EXCEPTION_ACCESS_VIOLATION)
	{
		const CHAR* pszException = "EXCEPTION_IN_PAGE_ERROR";
		if (nExceptionCode == EXCEPTION_ACCESS_VIOLATION)
		{
			pszException = "EXCEPTION_ACCESS_VIOLATION";
		}

		ULONG_PTR uExceptionInfo0 = m_pExceptionPointers->ExceptionRecord->ExceptionInformation[0];
		ULONG_PTR uExceptionInfo1 = m_pExceptionPointers->ExceptionRecord->ExceptionInformation[1];

		if (uExceptionInfo0)
		{
			if (uExceptionInfo0 == 1)
			{
				m_svBuffer.append(Format("\t%s(write): %p\n", pszException, uExceptionInfo1));
			}
			else if (uExceptionInfo0 == 8)
			{
				m_svBuffer.append(Format("\t%s(execute): %p\n", pszException, uExceptionInfo1));
			}
			else
			{
				m_svBuffer.append(Format("\t%s(unknown): %p\n", pszException, uExceptionInfo1));
			}
		}
		else
		{
			m_svBuffer.append(Format("\t%s(read): %p\n", pszException, uExceptionInfo1));
		}

		if (uExceptionInfo0 != 8)
		{
			if (IsPageAccessible())
			{
				FormatExceptionAddress();
			}
		}
	}
	else
	{
		m_svBuffer.append(Format(ExceptionToString(), nExceptionCode));
	}
}

//-----------------------------------------------------------------------------
// Purpose: formats the arithmetic logic register and its content
// Input  : *pszRegister - 
//			nContent - 
//-----------------------------------------------------------------------------
void CCrashHandler::FormatALU(const CHAR* pszRegister, DWORD64 nContent)
{
	if (nContent >= 1000000)
	{
		if (nContent > UINT_MAX)
		{
			m_svBuffer.append(Format("\t%s = 0x%016llX\n", pszRegister, nContent));
		}
		else
		{
			m_svBuffer.append(Format("\t%s = 0x%08X\n", pszRegister, nContent));
		}
	}
	else // Display as decimal.
	{
		m_svBuffer.append(Format("\t%s = %-15i\n", pszRegister, nContent));
		if (nContent >= 10)
		{
			const string svDesc = Format(" // 0x%08X\n", nContent);
			m_svBuffer.replace(m_svBuffer.length()-1, svDesc.size(), svDesc);
		}
	}
}

//-----------------------------------------------------------------------------
// Purpose: formats the floating point register and its content
// Input  : *pszRegister - 
//			*pxContent - 
//-----------------------------------------------------------------------------
void CCrashHandler::FormatFPU(const CHAR* pszRegister, M128A* pxContent)
{
	DWORD nVec[4] =
	{
		static_cast<DWORD>(pxContent->Low & UINT_MAX),
		static_cast<DWORD>(pxContent->Low >> 32),
		static_cast<DWORD>(pxContent->High & UINT_MAX),
		static_cast<DWORD>(pxContent->High >> 32),
	};

	m_svBuffer.append(Format("\t%s = [ [%.8g, %.8g, %.8g, %.8g]", pszRegister,
		*reinterpret_cast<FLOAT*>(&nVec[0]),
		*reinterpret_cast<FLOAT*>(&nVec[1]),
		*reinterpret_cast<FLOAT*>(&nVec[2]),
		*reinterpret_cast<FLOAT*>(&nVec[3])));

	const CHAR* pszVectorFormat = ", [%i, %i, %i, %i] ]\n";
	const LONG nHighest = abs(LONG(*MaxElementABS(std::begin(nVec), std::end(nVec))));

	if (nHighest >= 1000000)
	{
		pszVectorFormat = ", [0x%08X, 0x%08X, 0x%08X, 0x%08X] ]\n";
		m_svBuffer.append(Format(pszVectorFormat, nVec[0], nVec[1], nVec[2], nVec[3]));
	}
	else
	{
		m_svBuffer.append(Format(pszVectorFormat,
			static_cast<LONG>(nVec[0]), static_cast<LONG>(nVec[1]),
			static_cast<LONG>(nVec[2]), static_cast<LONG>(nVec[3])));
	}
}

//-----------------------------------------------------------------------------
// Purpose: returns the current exception code as string
// Output : exception code, "UNKNOWN_EXCEPTION" if exception code doesn't exist in this context
//-----------------------------------------------------------------------------
const CHAR* CCrashHandler::ExceptionToString(DWORD nExceptionCode) const
{
	switch (nExceptionCode)
	{
	case EXCEPTION_BREAKPOINT:               { return "\tEXCEPTION_BREAKPOINT"               ": %08X\n"; };
	case EXCEPTION_SINGLE_STEP:              { return "\tEXCEPTION_SINGLE_STEP"              ": %08X\n"; };
	case EXCEPTION_ACCESS_VIOLATION:         { return "\tEXCEPTION_ACCESS_VIOLATION"         ": %08X\n"; };
	case EXCEPTION_IN_PAGE_ERROR:            { return "\tEXCEPTION_IN_PAGE_ERROR"            ": %08X\n"; };
	case EXCEPTION_ARRAY_BOUNDS_EXCEEDED:    { return "\tEXCEPTION_ARRAY_BOUNDS_EXCEEDED"    ": %08X\n"; };
	case EXCEPTION_ILLEGAL_INSTRUCTION:      { return "\tEXCEPTION_ILLEGAL_INSTRUCTION"      ": %08X\n"; };
	case EXCEPTION_INVALID_DISPOSITION:      { return "\tEXCEPTION_INVALID_DISPOSITION"      ": %08X\n"; };
	case EXCEPTION_NONCONTINUABLE_EXCEPTION: { return "\tEXCEPTION_NONCONTINUABLE_EXCEPTION" ": %08X\n"; };
	case EXCEPTION_PRIV_INSTRUCTION:         { return "\tEXCEPTION_PRIV_INSTRUCTION"         ": %08X\n"; };
	case EXCEPTION_STACK_OVERFLOW:           { return "\tEXCEPTION_STACK_OVERFLOW"           ": %08X\n"; };
	case EXCEPTION_DATATYPE_MISALIGNMENT:    { return "\tEXCEPTION_DATATYPE_MISALIGNMENT"    ": %08X\n"; };
	case EXCEPTION_FLT_DENORMAL_OPERAND:     { return "\tEXCEPTION_FLT_DENORMAL_OPERAND"     ": %08X\n"; };
	case EXCEPTION_FLT_DIVIDE_BY_ZERO:       { return "\tEXCEPTION_FLT_DIVIDE_BY_ZERO"       ": %08X\n"; };
	case EXCEPTION_FLT_INEXACT_RESULT:       { return "\tEXCEPTION_FLT_INEXACT_RESULT"       ": %08X\n"; };
	case EXCEPTION_FLT_INVALID_OPERATION:    { return "\tEXCEPTION_FLT_INVALID_OPERATION"    ": %08X\n"; };
	case EXCEPTION_FLT_OVERFLOW:             { return "\tEXCEPTION_FLT_OVERFLOW"             ": %08X\n"; };
	case EXCEPTION_FLT_STACK_CHECK:          { return "\tEXCEPTION_FLT_STACK_CHECK"          ": %08X\n"; };
	case EXCEPTION_FLT_UNDERFLOW:            { return "\tEXCEPTION_FLT_UNDERFLOW"            ": %08X\n"; };
	case EXCEPTION_INT_DIVIDE_BY_ZERO:       { return "\tEXCEPTION_INT_DIVIDE_BY_ZERO"       ": %08X\n"; };
	case EXCEPTION_INT_OVERFLOW:             { return "\tEXCEPTION_INT_OVERFLOW"             ": %08X\n"; };
	default:                                 { return "\tUNKNOWN_EXCEPTION"                  ": %08X\n"; };
	}
}

//-----------------------------------------------------------------------------
// Purpose: returns the current exception code as string
//-----------------------------------------------------------------------------
const char* CCrashHandler::ExceptionToString() const
{
	return ExceptionToString(m_pExceptionPointers->ExceptionRecord->ExceptionCode);
}

//-----------------------------------------------------------------------------
// Purpose: tests if memory page is accessible
// Output : true if accessible, false otherwise
//-----------------------------------------------------------------------------
bool CCrashHandler::IsPageAccessible() const
{
	PCONTEXT pContextRecord = m_pExceptionPointers->ContextRecord;
	MEMORY_BASIC_INFORMATION mbi = { 0 };

	SIZE_T t = VirtualQuery((LPCVOID)pContextRecord->Rsp, &mbi, sizeof(LPCVOID));
	if (t < sizeof(mbi) || (mbi.Protect & PAGE_NOACCESS) || !((mbi.Protect & PAGE_NOACCESS) | PAGE_READWRITE))
	{
		return false;
	}
	else
	{
		return !(mbi.State & MEM_COMMIT);
	}
}

//-----------------------------------------------------------------------------
// Purpose: captures the callstack
//-----------------------------------------------------------------------------
void CCrashHandler::GetCallStack()
{
	m_nCapturedFrames = RtlCaptureStackBackTrace(2, NUM_FRAMES_TO_CAPTURE, m_ppStackTrace, NULL);
}

//-----------------------------------------------------------------------------
// Purpose: adds a whitelist exception address
//-----------------------------------------------------------------------------
void CCrashHandler::AddWhitelist(void* pWhitelist)
{
	m_WhiteList.insert(pWhitelist);
}

//-----------------------------------------------------------------------------
// Purpose: removes a whitelist exception address
//-----------------------------------------------------------------------------
void CCrashHandler::RemoveWhitelist(void* pWhitelist)
{
	m_WhiteList.erase(pWhitelist);
}

//-----------------------------------------------------------------------------
// Purpose: checks if callstack contains whitelisted addresses up to 'MAX_IMI_SEARCH' frames.
// Output : true is exist, false otherwise
//-----------------------------------------------------------------------------
bool CCrashHandler::HasWhitelist()
{
	for (WORD i = 0; i < NUM_FRAMES_TO_SEARCH; i++)
	{
		if (m_WhiteList.count(m_ppStackTrace[i]))
		{
			return true;
		}
	}
	return false;
}

//-----------------------------------------------------------------------------
// Purpose: writes the stack trace and minidump to the disk
//-----------------------------------------------------------------------------
void CCrashHandler::WriteFile()
{
	const string logDirectory = Format("%s\\%s.txt", g_LogSessionDirectory.c_str(), "apex_crash");
	CIOStream logFile;

	if (logFile.Open(logDirectory, CIOStream::Mode_t::WRITE))
	{
		logFile.WriteString(m_svBuffer);
	}

	const string dmpDirectory = Format("%s\\%s.dmp", g_LogSessionDirectory.c_str(), "minidump");
	HANDLE hDmpFile = CreateFileA(dmpDirectory.c_str(), GENERIC_WRITE, 0, 0, CREATE_NEW, FILE_ATTRIBUTE_NORMAL, 0);

	if (hDmpFile != INVALID_HANDLE_VALUE)
	{
		MINIDUMP_EXCEPTION_INFORMATION dumpExceptionInfo;
		dumpExceptionInfo.ThreadId = GetCurrentThreadId();
		dumpExceptionInfo.ExceptionPointers = m_pExceptionPointers;
		dumpExceptionInfo.ClientPointers = false;

		MiniDumpWriteDump(
			GetCurrentProcess(),
			GetCurrentProcessId(),
			hDmpFile, MiniDumpNormal,
			&dumpExceptionInfo, NULL, NULL);

		CloseHandle(hDmpFile);
	}
}

//-----------------------------------------------------------------------------
// Purpose: creates the crashmsg process displaying the error to the user
// the process has to be separate as the current process is getting killed
//-----------------------------------------------------------------------------
void CCrashHandler::CreateMessageProcess()
{
	if (m_bCrashMsgCreated)
	{
		return; // CrashMsg already displayed.
	}
	m_bCrashMsgCreated = true;

	PEXCEPTION_RECORD pExceptionRecord = m_pExceptionPointers->ExceptionRecord;
	PCONTEXT pContextRecord = m_pExceptionPointers->ContextRecord;

	if (pExceptionRecord->ExceptionCode == EXCEPTION_ACCESS_VIOLATION &&
		pExceptionRecord->ExceptionInformation[0] == 8 &&
		pExceptionRecord->ExceptionInformation[1] != pContextRecord->Rip)
	{
		m_svCrashMsgInfo = CRASHMESSAGE_MSG_EXECUTABLE" overclock";
	}
	else
	{
		m_svCrashMsgInfo = Format(CRASHMESSAGE_MSG_EXECUTABLE" crash %u \"%s\"", m_nCrashMsgFlags, m_svCrashMsgInfo.c_str());
	}

	PROCESS_INFORMATION processInfo;
	STARTUPINFOA startupInfo = { 0 };

	startupInfo.cb = sizeof(STARTUPINFOA);

	if (CreateProcessA(NULL, (LPSTR)m_svCrashMsgInfo.c_str(), NULL, NULL, TRUE, CREATE_NO_WINDOW, NULL, NULL, &startupInfo, &processInfo))
	{
		CloseHandle(processInfo.hProcess);
		CloseHandle(processInfo.hThread);
	}
}

//-----------------------------------------------------------------------------
// Purpose: 
// Input  : 
// Output : 
//-----------------------------------------------------------------------------
long __stdcall BottomLevelExceptionFilter(EXCEPTION_POINTERS* pExceptionInfo)
{
	g_CrashHandler->Start();
	g_CrashHandler->SetExceptionPointers(pExceptionInfo);

	// Let the higher level exception handlers deal with this particular exception.
	if (g_CrashHandler->ExceptionToString() == g_CrashHandler->ExceptionToString(0xFFFFFFFF))
	{
		g_CrashHandler->End();
		return EXCEPTION_CONTINUE_SEARCH;
	}

	// Don't run when a debugger is present.
	if (IsDebuggerPresent())
	{
		g_CrashHandler->End();
		return EXCEPTION_CONTINUE_SEARCH;
	}

	g_CrashHandler->GetCallStack();

	// Don't run filter when exception return address is in whitelist.
	// This is useful for when we want to use a different exception handler instead.
	if (g_CrashHandler->HasWhitelist())
	{
		g_CrashHandler->End();
		return EXCEPTION_CONTINUE_SEARCH;
	}

	// Kill on recursive call.
	if (g_CrashHandler->GetState())
	{
		// Shutdown SpdLog to flush all buffers.
		SpdLog_Shutdown();
		ExitProcess(1u);
	}

	g_CrashHandler->SetState(true);

	g_CrashHandler->FormatCrash();
	g_CrashHandler->FormatCallstack();
	g_CrashHandler->FormatRegisters();
	g_CrashHandler->FormatModules();
	g_CrashHandler->FormatSystemInfo();
	g_CrashHandler->FormatBuildInfo();

	g_CrashHandler->WriteFile();
	g_CrashHandler->CreateMessageProcess(); // Display the message to the user.

	// Don't end, just unlock the mutex so the next call kills the process.
	g_CrashHandler->Unlock();

	return EXCEPTION_EXECUTE_HANDLER;
}

//-----------------------------------------------------------------------------
// Purpose: 
//-----------------------------------------------------------------------------
void CCrashHandler::Init()
{
	m_hExceptionHandler = AddVectoredExceptionHandler(TRUE, BottomLevelExceptionFilter);
}

//-----------------------------------------------------------------------------
// Purpose: 
//-----------------------------------------------------------------------------
void CCrashHandler::Shutdown()
{
	if (m_hExceptionHandler)
	{
		RemoveVectoredExceptionHandler(m_hExceptionHandler);
		m_hExceptionHandler = nullptr;
	}
}

//-----------------------------------------------------------------------------
// Purpose: 
//-----------------------------------------------------------------------------
CCrashHandler::CCrashHandler()
	: m_ppStackTrace()
	, m_pExceptionPointers(nullptr)
	, m_nCapturedFrames(0)
	, m_nCrashMsgFlags(0)
	, m_bCallState(false)
	, m_bCrashMsgCreated(false)
	, m_bExceptionHandled(false)
{
	Init();
}

//-----------------------------------------------------------------------------
// Purpose: 
//-----------------------------------------------------------------------------
CCrashHandler::~CCrashHandler()
{
	Shutdown();
}

CCrashHandler* g_CrashHandler = new CCrashHandler();