llvm/lib/Support/CrashRecoveryContext.cpp - llvm-project - Git at Google

 //===--- CrashRecoveryContext.cpp - Crash Recovery ------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/Support/CrashRecoveryContext.h"
 #include "llvm/Config/llvm-config.h"
 #include "llvm/Support/ErrorHandling.h"
 #include "llvm/Support/ExitCodes.h"
 #include "llvm/Support/Signals.h"
 #include "llvm/Support/thread.h"
 #include <cassert>
 #include <mutex>
 #include <setjmp.h>

 using namespace llvm;

 namespace {

 struct CrashRecoveryContextImpl;
 static LLVM_THREAD_LOCAL const CrashRecoveryContextImpl *CurrentContext;

 struct CrashRecoveryContextImpl {
   // When threads are disabled, this links up all active
   // CrashRecoveryContextImpls.  When threads are enabled there's one thread
   // per CrashRecoveryContext and CurrentContext is a thread-local, so only one
   // CrashRecoveryContextImpl is active per thread and this is always null.
   const CrashRecoveryContextImpl *Next;

   CrashRecoveryContext *CRC;
   ::jmp_buf JumpBuffer;
   volatile unsigned Failed : 1;
   unsigned SwitchedThread : 1;
   unsigned ValidJumpBuffer : 1;

 public:
   CrashRecoveryContextImpl(CrashRecoveryContext *CRC) noexcept
       : CRC(CRC), Failed(false), SwitchedThread(false), ValidJumpBuffer(false) {
     Next = CurrentContext;
     CurrentContext = this;
   }
   ~CrashRecoveryContextImpl() {
     if (!SwitchedThread)
       CurrentContext = Next;
   }

   /// Called when the separate crash-recovery thread was finished, to
   /// indicate that we don't need to clear the thread-local CurrentContext.
   void setSwitchedThread() {
 #if defined(LLVM_ENABLE_THREADS) && LLVM_ENABLE_THREADS != 0
     SwitchedThread = true;
 #endif
   }

   // If the function ran by the CrashRecoveryContext crashes or fails, then
   // 'RetCode' represents the returned error code, as if it was returned by a
   // process. 'Context' represents the signal type on Unix; on Windows, it is
   // the ExceptionContext.
   void HandleCrash(int RetCode, uintptr_t Context) {
     // Eliminate the current context entry, to avoid re-entering in case the
     // cleanup code crashes.
     CurrentContext = Next;

     assert(!Failed && "Crash recovery context already failed!");
     Failed = true;

     if (CRC->DumpStackAndCleanupOnFailure)
       sys::CleanupOnSignal(Context);

     CRC->RetCode = RetCode;

     // Jump back to the RunSafely we were called under.
     if (ValidJumpBuffer)
       longjmp(JumpBuffer, 1);

     // Otherwise let the caller decide of the outcome of the crash. Currently
     // this occurs when using SEH on Windows with MSVC or clang-cl.
   }
 };

 std::mutex &getCrashRecoveryContextMutex() {
   static std::mutex CrashRecoveryContextMutex;
   return CrashRecoveryContextMutex;
 }

 static bool gCrashRecoveryEnabled = false;

 static LLVM_THREAD_LOCAL const CrashRecoveryContext *IsRecoveringFromCrash;

 } // namespace

 static void installExceptionOrSignalHandlers();
 static void uninstallExceptionOrSignalHandlers();

 CrashRecoveryContextCleanup::~CrashRecoveryContextCleanup() = default;

 CrashRecoveryContext::CrashRecoveryContext() {
   // On Windows, if abort() was previously triggered (and caught by a previous
   // CrashRecoveryContext) the Windows CRT removes our installed signal handler,
   // so we need to install it again.
   sys::DisableSystemDialogsOnCrash();
 }

 CrashRecoveryContext::~CrashRecoveryContext() {
   // Reclaim registered resources.
   CrashRecoveryContextCleanup *i = head;
   const CrashRecoveryContext *PC = IsRecoveringFromCrash;
   IsRecoveringFromCrash = this;
   while (i) {
     CrashRecoveryContextCleanup *tmp = i;
     i = tmp->next;
     tmp->cleanupFired = true;
     tmp->recoverResources();
     delete tmp;
   }
   IsRecoveringFromCrash = PC;

   CrashRecoveryContextImpl *CRCI = (CrashRecoveryContextImpl *) Impl;
   delete CRCI;
 }

 bool CrashRecoveryContext::isRecoveringFromCrash() {
   return IsRecoveringFromCrash != nullptr;
 }

 CrashRecoveryContext *CrashRecoveryContext::GetCurrent() {
   if (!gCrashRecoveryEnabled)
     return nullptr;

   const CrashRecoveryContextImpl *CRCI = CurrentContext;
   if (!CRCI)
     return nullptr;

   return CRCI->CRC;
 }

 void CrashRecoveryContext::Enable() {
   std::lock_guard<std::mutex> L(getCrashRecoveryContextMutex());
   // FIXME: Shouldn't this be a refcount or something?
   if (gCrashRecoveryEnabled)
     return;
   gCrashRecoveryEnabled = true;
   installExceptionOrSignalHandlers();
 }

 void CrashRecoveryContext::Disable() {
   std::lock_guard<std::mutex> L(getCrashRecoveryContextMutex());
   if (!gCrashRecoveryEnabled)
     return;
   gCrashRecoveryEnabled = false;
   uninstallExceptionOrSignalHandlers();
 }

 void CrashRecoveryContext::registerCleanup(CrashRecoveryContextCleanup *cleanup)
 {
   if (!cleanup)
     return;
   if (head)
     head->prev = cleanup;
   cleanup->next = head;
   head = cleanup;
 }

 void
 CrashRecoveryContext::unregisterCleanup(CrashRecoveryContextCleanup *cleanup) {
   if (!cleanup)
     return;
   if (cleanup == head) {
     head = cleanup->next;
     if (head)
       head->prev = nullptr;
   }
   else {
     cleanup->prev->next = cleanup->next;
     if (cleanup->next)
       cleanup->next->prev = cleanup->prev;
   }
   delete cleanup;
 }

 #if defined(_MSC_VER)

 #include <windows.h> // for GetExceptionInformation

 // If _MSC_VER is defined, we must have SEH. Use it if it's available. It's way
 // better than VEH. Vectored exception handling catches all exceptions happening
 // on the thread with installed exception handlers, so it can interfere with
 // internal exception handling of other libraries on that thread. SEH works
 // exactly as you would expect normal exception handling to work: it only
 // catches exceptions if they would bubble out from the stack frame with __try /
 // __except.

 static void installExceptionOrSignalHandlers() {}
 static void uninstallExceptionOrSignalHandlers() {}

 // We need this function because the call to GetExceptionInformation() can only
 // occur inside the __except evaluation block
 static int ExceptionFilter(_EXCEPTION_POINTERS *Except) {
   // Lookup the current thread local recovery object.
   const CrashRecoveryContextImpl *CRCI = CurrentContext;

   if (!CRCI) {
     // Something has gone horribly wrong, so let's just tell everyone
     // to keep searching
     CrashRecoveryContext::Disable();
     return EXCEPTION_CONTINUE_SEARCH;
   }

   int RetCode = (int)Except->ExceptionRecord->ExceptionCode;
   if ((RetCode & 0xF0000000) == 0xE0000000)
     RetCode &= ~0xF0000000; // this crash was generated by sys::Process::Exit

   // Handle the crash
   const_cast<CrashRecoveryContextImpl *>(CRCI)->HandleCrash(
       RetCode, reinterpret_cast<uintptr_t>(Except));

   return EXCEPTION_EXECUTE_HANDLER;
 }

 #if defined(__clang__) && defined(_M_IX86)
 // Work around PR44697.
 __attribute__((optnone))
 #endif
 bool CrashRecoveryContext::RunSafely(function_ref<void()> Fn) {
   if (!gCrashRecoveryEnabled) {
     Fn();
     return true;
   }
   assert(!Impl && "Crash recovery context already initialized!");
   Impl = new CrashRecoveryContextImpl(this);
   __try {
     Fn();
   } __except (ExceptionFilter(GetExceptionInformation())) {
     return false;
   }
   return true;
 }

 #else // !_MSC_VER

 #if defined(_WIN32)
 // This is a non-MSVC compiler, probably mingw gcc or clang without
 // -fms-extensions. Use vectored exception handling (VEH).
 //
 // On Windows, we can make use of vectored exception handling to catch most
 // crashing situations.  Note that this does mean we will be alerted of
 // exceptions *before* structured exception handling has the opportunity to
 // catch it. Unfortunately, this causes problems in practice with other code
 // running on threads with LLVM crash recovery contexts, so we would like to
 // eventually move away from VEH.
 //
 // Vectored works on a per-thread basis, which is an advantage over
 // SetUnhandledExceptionFilter. SetUnhandledExceptionFilter also doesn't have
 // any native support for chaining exception handlers, but VEH allows more than
 // one.
 //
 // The vectored exception handler functionality was added in Windows
 // XP, so if support for older versions of Windows is required,
 // it will have to be added.

 #include "llvm/Support/Windows/WindowsSupport.h"

 static LONG CALLBACK ExceptionHandler(PEXCEPTION_POINTERS ExceptionInfo)
 {
   // DBG_PRINTEXCEPTION_WIDE_C is not properly defined on all supported
   // compilers and platforms, so we define it manually.
   constexpr ULONG DbgPrintExceptionWideC = 0x4001000AL;
   switch (ExceptionInfo->ExceptionRecord->ExceptionCode)
   {
   case DBG_PRINTEXCEPTION_C:
   case DbgPrintExceptionWideC:
   case 0x406D1388:  // set debugger thread name
     return EXCEPTION_CONTINUE_EXECUTION;
   }

   // Lookup the current thread local recovery object.
   const CrashRecoveryContextImpl *CRCI = CurrentContext;

   if (!CRCI) {
     // Something has gone horribly wrong, so let's just tell everyone
     // to keep searching
     CrashRecoveryContext::Disable();
     return EXCEPTION_CONTINUE_SEARCH;
   }

   // TODO: We can capture the stack backtrace here and store it on the
   // implementation if we so choose.

   int RetCode = (int)ExceptionInfo->ExceptionRecord->ExceptionCode;
   if ((RetCode & 0xF0000000) == 0xE0000000)
     RetCode &= ~0xF0000000; // this crash was generated by sys::Process::Exit

   // Handle the crash
   const_cast<CrashRecoveryContextImpl *>(CRCI)->HandleCrash(
       RetCode, reinterpret_cast<uintptr_t>(ExceptionInfo));

   // Note that we don't actually get here because HandleCrash calls
   // longjmp, which means the HandleCrash function never returns.
   llvm_unreachable("Handled the crash, should have longjmp'ed out of here");
 }

 // Because the Enable and Disable calls are static, it means that
 // there may not actually be an Impl available, or even a current
 // CrashRecoveryContext at all.  So we make use of a thread-local
 // exception table.  The handles contained in here will either be
 // non-NULL, valid VEH handles, or NULL.
 static LLVM_THREAD_LOCAL const void* sCurrentExceptionHandle;

 static void installExceptionOrSignalHandlers() {
   // We can set up vectored exception handling now.  We will install our
   // handler as the front of the list, though there's no assurances that
   // it will remain at the front (another call could install itself before
   // our handler).  This 1) isn't likely, and 2) shouldn't cause problems.
   PVOID handle = ::AddVectoredExceptionHandler(1, ExceptionHandler);
   sCurrentExceptionHandle = handle;
 }

 static void uninstallExceptionOrSignalHandlers() {
   PVOID currentHandle = const_cast<PVOID>(sCurrentExceptionHandle);
   if (currentHandle) {
     // Now we can remove the vectored exception handler from the chain
     ::RemoveVectoredExceptionHandler(currentHandle);

     // Reset the handle in our thread-local set.
     sCurrentExceptionHandle = NULL;
   }
 }

 #else // !_WIN32

 // Generic POSIX implementation.
 //
 // This implementation relies on synchronous signals being delivered to the
 // current thread. We use a thread local object to keep track of the active
 // crash recovery context, and install signal handlers to invoke HandleCrash on
 // the active object.
 //
 // This implementation does not attempt to chain signal handlers in any
 // reliable fashion -- if we get a signal outside of a crash recovery context we
 // simply disable crash recovery and raise the signal again.

 #include <signal.h>

 static const int Signals[] =
     { SIGABRT, SIGBUS, SIGFPE, SIGILL, SIGSEGV, SIGTRAP };
 static const unsigned NumSignals = std::size(Signals);
 static struct sigaction PrevActions[NumSignals];

 static void CrashRecoverySignalHandler(int Signal) {
   // Lookup the current thread local recovery object.
   const CrashRecoveryContextImpl *CRCI = CurrentContext;

   if (!CRCI) {
     // We didn't find a crash recovery context -- this means either we got a
     // signal on a thread we didn't expect it on, the application got a signal
     // outside of a crash recovery context, or something else went horribly
     // wrong.
     //
     // Disable crash recovery and raise the signal again. The assumption here is
     // that the enclosing application will terminate soon, and we won't want to
     // attempt crash recovery again.
     //
     // This call of Disable isn't thread safe, but it doesn't actually matter.
     CrashRecoveryContext::Disable();
     raise(Signal);

     // The signal will be thrown once the signal mask is restored.
     return;
   }

   // Unblock the signal we received.
   sigset_t SigMask;
   sigemptyset(&SigMask);
   sigaddset(&SigMask, Signal);
   sigprocmask(SIG_UNBLOCK, &SigMask, nullptr);

   // Return the same error code as if the program crashed, as mentioned in the
   // section "Exit Status for Commands":
   // https://pubs.opengroup.org/onlinepubs/9699919799/xrat/V4_xcu_chap02.html
   int RetCode = 128 + Signal;

   // Don't consider a broken pipe as a crash (see clang/lib/Driver/Driver.cpp)
   if (Signal == SIGPIPE)
     RetCode = EX_IOERR;

   if (CRCI)
     const_cast<CrashRecoveryContextImpl *>(CRCI)->HandleCrash(RetCode, Signal);
 }

 static void installExceptionOrSignalHandlers() {
   // Setup the signal handler.
   struct sigaction Handler;
   Handler.sa_handler = CrashRecoverySignalHandler;
   Handler.sa_flags = 0;
   sigemptyset(&Handler.sa_mask);

   for (unsigned i = 0; i != NumSignals; ++i) {
     sigaction(Signals[i], &Handler, &PrevActions[i]);
   }
 }

 static void uninstallExceptionOrSignalHandlers() {
   // Restore the previous signal handlers.
   for (unsigned i = 0; i != NumSignals; ++i)
     sigaction(Signals[i], &PrevActions[i], nullptr);
 }

 #endif // !_WIN32

 bool CrashRecoveryContext::RunSafely(function_ref<void()> Fn) {
   // If crash recovery is disabled, do nothing.
   if (gCrashRecoveryEnabled) {
     assert(!Impl && "Crash recovery context already initialized!");
     CrashRecoveryContextImpl *CRCI = new CrashRecoveryContextImpl(this);
     Impl = CRCI;

     CRCI->ValidJumpBuffer = true;
     if (setjmp(CRCI->JumpBuffer) != 0) {
       return false;
     }
   }

   Fn();
   return true;
 }

 #endif // !_MSC_VER

 [[noreturn]] void CrashRecoveryContext::HandleExit(int RetCode) {
 #if defined(_WIN32)
   // Since the exception code is actually of NTSTATUS type, we use the
   // Microsoft-recommended 0xE prefix, to signify that this is a user error.
   // This value is a combination of the customer field (bit 29) and severity
   // field (bits 30-31) in the NTSTATUS specification.
   ::RaiseException(0xE0000000 | RetCode, 0, 0, NULL);
 #else
   // On Unix we don't need to raise an exception, we go directly to
   // HandleCrash(), then longjmp will unwind the stack for us.
   CrashRecoveryContextImpl *CRCI = (CrashRecoveryContextImpl *)Impl;
   assert(CRCI && "Crash recovery context never initialized!");
   CRCI->HandleCrash(RetCode, 0 /*no sig num*/);
 #endif
   llvm_unreachable("Most likely setjmp wasn't called!");
 }

 bool CrashRecoveryContext::isCrash(int RetCode) {
 #if defined(_WIN32)
   // On Windows, the code is interpreted as NTSTATUS. The two high bits
   // represent the severity. Values starting with 0x80000000 are reserved for
   // "warnings"; values of 0xC0000000 and up are for "errors". In practice, both
   // are interpreted as a non-continuable signal.
   unsigned Code = ((unsigned)RetCode & 0xF0000000) >> 28;
   if (Code != 0xC && Code != 8)
     return false;
 #else
   // On Unix, signals are represented by return codes of 128 or higher.
   // Exit code 128 is a reserved value and should not be raised as a signal.
   if (RetCode <= 128)
     return false;
 #endif
   return true;
 }

 bool CrashRecoveryContext::throwIfCrash(int RetCode) {
   if (!isCrash(RetCode))
     return false;
 #if defined(_WIN32)
   ::RaiseException(RetCode, 0, 0, NULL);
 #else
   llvm::sys::unregisterHandlers();
   raise(RetCode - 128);
 #endif
   return true;
 }

 // FIXME: Portability.
 static void setThreadBackgroundPriority() {
 #ifdef __APPLE__
   setpriority(PRIO_DARWIN_THREAD, 0, PRIO_DARWIN_BG);
 #endif
 }

 static bool hasThreadBackgroundPriority() {
 #ifdef __APPLE__
   return getpriority(PRIO_DARWIN_THREAD, 0) == 1;
 #else
   return false;
 #endif
 }

 namespace {
 struct RunSafelyOnThreadInfo {
   function_ref<void()> Fn;
   CrashRecoveryContext *CRC;
   bool UseBackgroundPriority;
   bool Result;
 };
 } // namespace

 static void RunSafelyOnThread_Dispatch(void *UserData) {
   RunSafelyOnThreadInfo *Info =
     reinterpret_cast<RunSafelyOnThreadInfo*>(UserData);

   if (Info->UseBackgroundPriority)
     setThreadBackgroundPriority();

   Info->Result = Info->CRC->RunSafely(Info->Fn);
 }
 bool CrashRecoveryContext::RunSafelyOnThread(function_ref<void()> Fn,
                                              unsigned RequestedStackSize) {
   bool UseBackgroundPriority = hasThreadBackgroundPriority();
   RunSafelyOnThreadInfo Info = { Fn, this, UseBackgroundPriority, false };
   llvm::thread Thread(RequestedStackSize == 0
                           ? std::nullopt
                           : std::optional<unsigned>(RequestedStackSize),
                       RunSafelyOnThread_Dispatch, &Info);
   Thread.join();

   if (CrashRecoveryContextImpl *CRC = (CrashRecoveryContextImpl *)Impl)
     CRC->setSwitchedThread();
   return Info.Result;
 }
	//===--- CrashRecoveryContext.cpp - Crash Recovery ------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/Support/CrashRecoveryContext.h"
	#include "llvm/Config/llvm-config.h"
	#include "llvm/Support/ErrorHandling.h"
	#include "llvm/Support/ExitCodes.h"
	#include "llvm/Support/Signals.h"
	#include "llvm/Support/thread.h"
	#include <cassert>
	#include <mutex>
	#include <setjmp.h>

	using namespace llvm;

	namespace {

	struct CrashRecoveryContextImpl;
	static LLVM_THREAD_LOCAL const CrashRecoveryContextImpl *CurrentContext;

	struct CrashRecoveryContextImpl {
	// When threads are disabled, this links up all active
	// CrashRecoveryContextImpls. When threads are enabled there's one thread
	// per CrashRecoveryContext and CurrentContext is a thread-local, so only one
	// CrashRecoveryContextImpl is active per thread and this is always null.
	const CrashRecoveryContextImpl *Next;

	CrashRecoveryContext *CRC;
	::jmp_buf JumpBuffer;
	volatile unsigned Failed : 1;
	unsigned SwitchedThread : 1;
	unsigned ValidJumpBuffer : 1;

	public:
	CrashRecoveryContextImpl(CrashRecoveryContext *CRC) noexcept
	: CRC(CRC), Failed(false), SwitchedThread(false), ValidJumpBuffer(false) {
	Next = CurrentContext;
	CurrentContext = this;
	}
	~CrashRecoveryContextImpl() {
	if (!SwitchedThread)
	CurrentContext = Next;
	}

	/// Called when the separate crash-recovery thread was finished, to
	/// indicate that we don't need to clear the thread-local CurrentContext.
	void setSwitchedThread() {
	#if defined(LLVM_ENABLE_THREADS) && LLVM_ENABLE_THREADS != 0
	SwitchedThread = true;
	#endif
	}

	// If the function ran by the CrashRecoveryContext crashes or fails, then
	// 'RetCode' represents the returned error code, as if it was returned by a
	// process. 'Context' represents the signal type on Unix; on Windows, it is
	// the ExceptionContext.
	void HandleCrash(int RetCode, uintptr_t Context) {
	// Eliminate the current context entry, to avoid re-entering in case the
	// cleanup code crashes.
	CurrentContext = Next;

	assert(!Failed && "Crash recovery context already failed!");
	Failed = true;

	if (CRC->DumpStackAndCleanupOnFailure)
	sys::CleanupOnSignal(Context);

	CRC->RetCode = RetCode;

	// Jump back to the RunSafely we were called under.
	if (ValidJumpBuffer)
	longjmp(JumpBuffer, 1);

	// Otherwise let the caller decide of the outcome of the crash. Currently
	// this occurs when using SEH on Windows with MSVC or clang-cl.
	}
	};

	std::mutex &getCrashRecoveryContextMutex() {
	static std::mutex CrashRecoveryContextMutex;
	return CrashRecoveryContextMutex;
	}

	static bool gCrashRecoveryEnabled = false;

	static LLVM_THREAD_LOCAL const CrashRecoveryContext *IsRecoveringFromCrash;

	} // namespace

	static void installExceptionOrSignalHandlers();
	static void uninstallExceptionOrSignalHandlers();

	CrashRecoveryContextCleanup::~CrashRecoveryContextCleanup() = default;

	CrashRecoveryContext::CrashRecoveryContext() {
	// On Windows, if abort() was previously triggered (and caught by a previous
	// CrashRecoveryContext) the Windows CRT removes our installed signal handler,
	// so we need to install it again.
	sys::DisableSystemDialogsOnCrash();
	}

	CrashRecoveryContext::~CrashRecoveryContext() {
	// Reclaim registered resources.
	CrashRecoveryContextCleanup *i = head;
	const CrashRecoveryContext *PC = IsRecoveringFromCrash;
	IsRecoveringFromCrash = this;
	while (i) {
	CrashRecoveryContextCleanup *tmp = i;
	i = tmp->next;
	tmp->cleanupFired = true;
	tmp->recoverResources();
	delete tmp;
	}
	IsRecoveringFromCrash = PC;

	CrashRecoveryContextImpl CRCI = (CrashRecoveryContextImpl ) Impl;
	delete CRCI;
	}

	bool CrashRecoveryContext::isRecoveringFromCrash() {
	return IsRecoveringFromCrash != nullptr;
	}

	CrashRecoveryContext *CrashRecoveryContext::GetCurrent() {
	if (!gCrashRecoveryEnabled)
	return nullptr;

	const CrashRecoveryContextImpl *CRCI = CurrentContext;
	if (!CRCI)
	return nullptr;

	return CRCI->CRC;
	}

	void CrashRecoveryContext::Enable() {
	std::lock_guard<std::mutex> L(getCrashRecoveryContextMutex());
	// FIXME: Shouldn't this be a refcount or something?
	if (gCrashRecoveryEnabled)
	return;
	gCrashRecoveryEnabled = true;
	installExceptionOrSignalHandlers();
	}

	void CrashRecoveryContext::Disable() {
	std::lock_guard<std::mutex> L(getCrashRecoveryContextMutex());
	if (!gCrashRecoveryEnabled)
	return;
	gCrashRecoveryEnabled = false;
	uninstallExceptionOrSignalHandlers();
	}

	void CrashRecoveryContext::registerCleanup(CrashRecoveryContextCleanup *cleanup)
	{
	if (!cleanup)
	return;
	if (head)
	head->prev = cleanup;
	cleanup->next = head;
	head = cleanup;
	}

	void
	CrashRecoveryContext::unregisterCleanup(CrashRecoveryContextCleanup *cleanup) {
	if (!cleanup)
	return;
	if (cleanup == head) {
	head = cleanup->next;
	if (head)
	head->prev = nullptr;
	}
	else {
	cleanup->prev->next = cleanup->next;
	if (cleanup->next)
	cleanup->next->prev = cleanup->prev;
	}
	delete cleanup;
	}

	#if defined(_MSC_VER)

	#include <windows.h> // for GetExceptionInformation

	// If _MSC_VER is defined, we must have SEH. Use it if it's available. It's way
	// better than VEH. Vectored exception handling catches all exceptions happening
	// on the thread with installed exception handlers, so it can interfere with
	// internal exception handling of other libraries on that thread. SEH works
	// exactly as you would expect normal exception handling to work: it only
	// catches exceptions if they would bubble out from the stack frame with __try /
	// __except.

	static void installExceptionOrSignalHandlers() {}
	static void uninstallExceptionOrSignalHandlers() {}

	// We need this function because the call to GetExceptionInformation() can only
	// occur inside the __except evaluation block
	static int ExceptionFilter(_EXCEPTION_POINTERS *Except) {
	// Lookup the current thread local recovery object.
	const CrashRecoveryContextImpl *CRCI = CurrentContext;

	if (!CRCI) {
	// Something has gone horribly wrong, so let's just tell everyone
	// to keep searching
	CrashRecoveryContext::Disable();
	return EXCEPTION_CONTINUE_SEARCH;
	}

	int RetCode = (int)Except->ExceptionRecord->ExceptionCode;
	if ((RetCode & 0xF0000000) == 0xE0000000)
	RetCode &= ~0xF0000000; // this crash was generated by sys::Process::Exit

	// Handle the crash
	const_cast<CrashRecoveryContextImpl *>(CRCI)->HandleCrash(
	RetCode, reinterpret_cast<uintptr_t>(Except));

	return EXCEPTION_EXECUTE_HANDLER;
	}

	#if defined(__clang__) && defined(_M_IX86)
	// Work around PR44697.
	__attribute__((optnone))
	#endif
	bool CrashRecoveryContext::RunSafely(function_ref<void()> Fn) {
	if (!gCrashRecoveryEnabled) {
	Fn();
	return true;
	}
	assert(!Impl && "Crash recovery context already initialized!");
	Impl = new CrashRecoveryContextImpl(this);
	__try {
	Fn();
	} __except (ExceptionFilter(GetExceptionInformation())) {
	return false;
	}
	return true;
	}

	#else // !_MSC_VER

	#if defined(_WIN32)
	// This is a non-MSVC compiler, probably mingw gcc or clang without
	// -fms-extensions. Use vectored exception handling (VEH).
	//
	// On Windows, we can make use of vectored exception handling to catch most
	// crashing situations. Note that this does mean we will be alerted of
	// exceptions before structured exception handling has the opportunity to
	// catch it. Unfortunately, this causes problems in practice with other code
	// running on threads with LLVM crash recovery contexts, so we would like to
	// eventually move away from VEH.
	//
	// Vectored works on a per-thread basis, which is an advantage over
	// SetUnhandledExceptionFilter. SetUnhandledExceptionFilter also doesn't have
	// any native support for chaining exception handlers, but VEH allows more than
	// one.
	//
	// The vectored exception handler functionality was added in Windows
	// XP, so if support for older versions of Windows is required,
	// it will have to be added.

	#include "llvm/Support/Windows/WindowsSupport.h"

	static LONG CALLBACK ExceptionHandler(PEXCEPTION_POINTERS ExceptionInfo)
	{
	// DBG_PRINTEXCEPTION_WIDE_C is not properly defined on all supported
	// compilers and platforms, so we define it manually.
	constexpr ULONG DbgPrintExceptionWideC = 0x4001000AL;
	switch (ExceptionInfo->ExceptionRecord->ExceptionCode)
	{
	case DBG_PRINTEXCEPTION_C:
	case DbgPrintExceptionWideC:
	case 0x406D1388: // set debugger thread name
	return EXCEPTION_CONTINUE_EXECUTION;
	}

	// Lookup the current thread local recovery object.
	const CrashRecoveryContextImpl *CRCI = CurrentContext;

	if (!CRCI) {
	// Something has gone horribly wrong, so let's just tell everyone
	// to keep searching
	CrashRecoveryContext::Disable();
	return EXCEPTION_CONTINUE_SEARCH;
	}

	// TODO: We can capture the stack backtrace here and store it on the
	// implementation if we so choose.

	int RetCode = (int)ExceptionInfo->ExceptionRecord->ExceptionCode;
	if ((RetCode & 0xF0000000) == 0xE0000000)
	RetCode &= ~0xF0000000; // this crash was generated by sys::Process::Exit

	// Handle the crash
	const_cast<CrashRecoveryContextImpl *>(CRCI)->HandleCrash(
	RetCode, reinterpret_cast<uintptr_t>(ExceptionInfo));

	// Note that we don't actually get here because HandleCrash calls
	// longjmp, which means the HandleCrash function never returns.
	llvm_unreachable("Handled the crash, should have longjmp'ed out of here");
	}

	// Because the Enable and Disable calls are static, it means that
	// there may not actually be an Impl available, or even a current
	// CrashRecoveryContext at all. So we make use of a thread-local
	// exception table. The handles contained in here will either be
	// non-NULL, valid VEH handles, or NULL.
	static LLVM_THREAD_LOCAL const void* sCurrentExceptionHandle;

	static void installExceptionOrSignalHandlers() {
	// We can set up vectored exception handling now. We will install our
	// handler as the front of the list, though there's no assurances that
	// it will remain at the front (another call could install itself before
	// our handler). This 1) isn't likely, and 2) shouldn't cause problems.
	PVOID handle = ::AddVectoredExceptionHandler(1, ExceptionHandler);
	sCurrentExceptionHandle = handle;
	}

	static void uninstallExceptionOrSignalHandlers() {
	PVOID currentHandle = const_cast<PVOID>(sCurrentExceptionHandle);
	if (currentHandle) {
	// Now we can remove the vectored exception handler from the chain
	::RemoveVectoredExceptionHandler(currentHandle);

	// Reset the handle in our thread-local set.
	sCurrentExceptionHandle = NULL;
	}
	}

	#else // !_WIN32

	// Generic POSIX implementation.
	//
	// This implementation relies on synchronous signals being delivered to the
	// current thread. We use a thread local object to keep track of the active
	// crash recovery context, and install signal handlers to invoke HandleCrash on
	// the active object.
	//
	// This implementation does not attempt to chain signal handlers in any
	// reliable fashion -- if we get a signal outside of a crash recovery context we
	// simply disable crash recovery and raise the signal again.

	#include <signal.h>

	static const int Signals[] =
	{ SIGABRT, SIGBUS, SIGFPE, SIGILL, SIGSEGV, SIGTRAP };
	static const unsigned NumSignals = std::size(Signals);
	static struct sigaction PrevActions[NumSignals];

	static void CrashRecoverySignalHandler(int Signal) {
	// Lookup the current thread local recovery object.
	const CrashRecoveryContextImpl *CRCI = CurrentContext;

	if (!CRCI) {
	// We didn't find a crash recovery context -- this means either we got a
	// signal on a thread we didn't expect it on, the application got a signal
	// outside of a crash recovery context, or something else went horribly
	// wrong.
	//
	// Disable crash recovery and raise the signal again. The assumption here is
	// that the enclosing application will terminate soon, and we won't want to
	// attempt crash recovery again.
	//
	// This call of Disable isn't thread safe, but it doesn't actually matter.
	CrashRecoveryContext::Disable();
	raise(Signal);

	// The signal will be thrown once the signal mask is restored.
	return;
	}

	// Unblock the signal we received.
	sigset_t SigMask;
	sigemptyset(&SigMask);
	sigaddset(&SigMask, Signal);
	sigprocmask(SIG_UNBLOCK, &SigMask, nullptr);

	// Return the same error code as if the program crashed, as mentioned in the
	// section "Exit Status for Commands":
	// https://pubs.opengroup.org/onlinepubs/9699919799/xrat/V4_xcu_chap02.html
	int RetCode = 128 + Signal;

	// Don't consider a broken pipe as a crash (see clang/lib/Driver/Driver.cpp)
	if (Signal == SIGPIPE)
	RetCode = EX_IOERR;

	if (CRCI)
	const_cast<CrashRecoveryContextImpl *>(CRCI)->HandleCrash(RetCode, Signal);
	}

	static void installExceptionOrSignalHandlers() {
	// Setup the signal handler.
	struct sigaction Handler;
	Handler.sa_handler = CrashRecoverySignalHandler;
	Handler.sa_flags = 0;
	sigemptyset(&Handler.sa_mask);

	for (unsigned i = 0; i != NumSignals; ++i) {
	sigaction(Signals[i], &Handler, &PrevActions[i]);
	}
	}

	static void uninstallExceptionOrSignalHandlers() {
	// Restore the previous signal handlers.
	for (unsigned i = 0; i != NumSignals; ++i)
	sigaction(Signals[i], &PrevActions[i], nullptr);
	}

	#endif // !_WIN32

	bool CrashRecoveryContext::RunSafely(function_ref<void()> Fn) {
	// If crash recovery is disabled, do nothing.
	if (gCrashRecoveryEnabled) {
	assert(!Impl && "Crash recovery context already initialized!");
	CrashRecoveryContextImpl *CRCI = new CrashRecoveryContextImpl(this);
	Impl = CRCI;

	CRCI->ValidJumpBuffer = true;
	if (setjmp(CRCI->JumpBuffer) != 0) {
	return false;
	}
	}

	Fn();
	return true;
	}

	#endif // !_MSC_VER

	[[noreturn]] void CrashRecoveryContext::HandleExit(int RetCode) {
	#if defined(_WIN32)
	// Since the exception code is actually of NTSTATUS type, we use the
	// Microsoft-recommended 0xE prefix, to signify that this is a user error.
	// This value is a combination of the customer field (bit 29) and severity
	// field (bits 30-31) in the NTSTATUS specification.
	::RaiseException(0xE0000000 \| RetCode, 0, 0, NULL);
	#else
	// On Unix we don't need to raise an exception, we go directly to
	// HandleCrash(), then longjmp will unwind the stack for us.
	CrashRecoveryContextImpl CRCI = (CrashRecoveryContextImpl )Impl;
	assert(CRCI && "Crash recovery context never initialized!");
	CRCI->HandleCrash(RetCode, 0 /no sig num/);
	#endif
	llvm_unreachable("Most likely setjmp wasn't called!");
	}

	bool CrashRecoveryContext::isCrash(int RetCode) {
	#if defined(_WIN32)
	// On Windows, the code is interpreted as NTSTATUS. The two high bits
	// represent the severity. Values starting with 0x80000000 are reserved for
	// "warnings"; values of 0xC0000000 and up are for "errors". In practice, both
	// are interpreted as a non-continuable signal.
	unsigned Code = ((unsigned)RetCode & 0xF0000000) >> 28;
	if (Code != 0xC && Code != 8)
	return false;
	#else
	// On Unix, signals are represented by return codes of 128 or higher.
	// Exit code 128 is a reserved value and should not be raised as a signal.
	if (RetCode <= 128)
	return false;
	#endif
	return true;
	}

	bool CrashRecoveryContext::throwIfCrash(int RetCode) {
	if (!isCrash(RetCode))
	return false;
	#if defined(_WIN32)
	::RaiseException(RetCode, 0, 0, NULL);
	#else
	llvm::sys::unregisterHandlers();
	raise(RetCode - 128);
	#endif
	return true;
	}

	// FIXME: Portability.
	static void setThreadBackgroundPriority() {
	#ifdef __APPLE__
	setpriority(PRIO_DARWIN_THREAD, 0, PRIO_DARWIN_BG);
	#endif
	}

	static bool hasThreadBackgroundPriority() {
	#ifdef __APPLE__
	return getpriority(PRIO_DARWIN_THREAD, 0) == 1;
	#else
	return false;
	#endif
	}

	namespace {
	struct RunSafelyOnThreadInfo {
	function_ref<void()> Fn;
	CrashRecoveryContext *CRC;
	bool UseBackgroundPriority;
	bool Result;
	};
	} // namespace

	static void RunSafelyOnThread_Dispatch(void *UserData) {
	RunSafelyOnThreadInfo *Info =
	reinterpret_cast<RunSafelyOnThreadInfo*>(UserData);

	if (Info->UseBackgroundPriority)
	setThreadBackgroundPriority();

	Info->Result = Info->CRC->RunSafely(Info->Fn);
	}
	bool CrashRecoveryContext::RunSafelyOnThread(function_ref<void()> Fn,
	unsigned RequestedStackSize) {
	bool UseBackgroundPriority = hasThreadBackgroundPriority();
	RunSafelyOnThreadInfo Info = { Fn, this, UseBackgroundPriority, false };
	llvm::thread Thread(RequestedStackSize == 0
	? std::nullopt
	: std::optional<unsigned>(RequestedStackSize),
	RunSafelyOnThread_Dispatch, &Info);
	Thread.join();

	if (CrashRecoveryContextImpl CRC = (CrashRecoveryContextImpl )Impl)
	CRC->setSwitchedThread();
	return Info.Result;
	}