//===- Signals.cpp - Generic Unix Signals Implementation -----*- C++ -*-===// // // 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 // //===----------------------------------------------------------------------===// // // This file defines some helpful functions for dealing with the possibility of // Unix signals occurring while your program is running. // //===----------------------------------------------------------------------===// // // This file is extremely careful to only do signal-safe things while in a // signal handler. In particular, memory allocation and acquiring a mutex // while in a signal handler should never occur. ManagedStatic isn't usable from // a signal handler for 2 reasons: // // 1. Creating a new one allocates. // 2. The signal handler could fire while llvm_shutdown is being processed, in // which case the ManagedStatic is in an unknown state because it could // already have been destroyed, or be in the process of being destroyed. // // Modifying the behavior of the signal handlers (such as registering new ones) // can acquire a mutex, but all this guarantees is that the signal handler // behavior is only modified by one thread at a time. A signal handler can still // fire while this occurs! // // Adding work to a signal handler requires lock-freedom (and assume atomics are // always lock-free) because the signal handler could fire while new work is // being added. // //===----------------------------------------------------------------------===// #include "Unix.h" #include "llvm/ADT/STLExtras.h" #include "llvm/Config/config.h" #include "llvm/Demangle/Demangle.h" #include "llvm/Support/ExitCodes.h" #include "llvm/Support/FileSystem.h" #include "llvm/Support/FileUtilities.h" #include "llvm/Support/Format.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/Mutex.h" #include "llvm/Support/Program.h" #include "llvm/Support/SaveAndRestore.h" #include "llvm/Support/raw_ostream.h" #include #include #ifdef HAVE_BACKTRACE #include BACKTRACE_HEADER // For backtrace(). #endif #if HAVE_SIGNAL_H #include #endif #if HAVE_SYS_STAT_H #include #endif #if HAVE_DLFCN_H #include #endif #if HAVE_MACH_MACH_H #include #endif #ifdef __APPLE__ #include #endif #if HAVE_LINK_H #include #endif #ifdef HAVE__UNWIND_BACKTRACE // FIXME: We should be able to use for any target that has an // _Unwind_Backtrace function, but on FreeBSD the configure test passes // despite the function not existing, and on Android, conflicts // with . #ifdef __GLIBC__ #include #else #undef HAVE__UNWIND_BACKTRACE #endif #endif using namespace llvm; static void SignalHandler(int Sig); // defined below. static void InfoSignalHandler(int Sig); // defined below. using SignalHandlerFunctionType = void (*)(); /// The function to call if ctrl-c is pressed. static std::atomic InterruptFunction = nullptr; static std::atomic InfoSignalFunction = nullptr; /// The function to call on SIGPIPE (one-time use only). static std::atomic OneShotPipeSignalFunction = nullptr; namespace { /// Signal-safe removal of files. /// Inserting and erasing from the list isn't signal-safe, but removal of files /// themselves is signal-safe. Memory is freed when the head is freed, deletion /// is therefore not signal-safe either. class FileToRemoveList { std::atomic Filename = nullptr; std::atomic Next = nullptr; FileToRemoveList() = default; // Not signal-safe. FileToRemoveList(const std::string &str) : Filename(strdup(str.c_str())) {} public: // Not signal-safe. ~FileToRemoveList() { if (FileToRemoveList *N = Next.exchange(nullptr)) delete N; if (char *F = Filename.exchange(nullptr)) free(F); } // Not signal-safe. static void insert(std::atomic &Head, const std::string &Filename) { // Insert the new file at the end of the list. FileToRemoveList *NewHead = new FileToRemoveList(Filename); std::atomic *InsertionPoint = &Head; FileToRemoveList *OldHead = nullptr; while (!InsertionPoint->compare_exchange_strong(OldHead, NewHead)) { InsertionPoint = &OldHead->Next; OldHead = nullptr; } } // Not signal-safe. static void erase(std::atomic &Head, const std::string &Filename) { // Use a lock to avoid concurrent erase: the comparison would access // free'd memory. static ManagedStatic> Lock; sys::SmartScopedLock Writer(*Lock); for (FileToRemoveList *Current = Head.load(); Current; Current = Current->Next.load()) { if (char *OldFilename = Current->Filename.load()) { if (OldFilename != Filename) continue; // Leave an empty filename. OldFilename = Current->Filename.exchange(nullptr); // The filename might have become null between the time we // compared it and we exchanged it. if (OldFilename) free(OldFilename); } } } // Signal-safe. static void removeAllFiles(std::atomic &Head) { // If cleanup were to occur while we're removing files we'd have a bad time. // Make sure we're OK by preventing cleanup from doing anything while we're // removing files. If cleanup races with us and we win we'll have a leak, // but we won't crash. FileToRemoveList *OldHead = Head.exchange(nullptr); for (FileToRemoveList *currentFile = OldHead; currentFile; currentFile = currentFile->Next.load()) { // If erasing was occuring while we're trying to remove files we'd look // at free'd data. Take away the path and put it back when done. if (char *path = currentFile->Filename.exchange(nullptr)) { // Get the status so we can determine if it's a file or directory. If we // can't stat the file, ignore it. struct stat buf; if (stat(path, &buf) != 0) continue; // If this is not a regular file, ignore it. We want to prevent removal // of special files like /dev/null, even if the compiler is being run // with the super-user permissions. if (!S_ISREG(buf.st_mode)) continue; // Otherwise, remove the file. We ignore any errors here as there is // nothing else we can do. unlink(path); // We're done removing the file, erasing can safely proceed. currentFile->Filename.exchange(path); } } // We're done removing files, cleanup can safely proceed. Head.exchange(OldHead); } }; static std::atomic FilesToRemove = nullptr; /// Clean up the list in a signal-friendly manner. /// Recall that signals can fire during llvm_shutdown. If this occurs we should /// either clean something up or nothing at all, but we shouldn't crash! struct FilesToRemoveCleanup { // Not signal-safe. ~FilesToRemoveCleanup() { FileToRemoveList *Head = FilesToRemove.exchange(nullptr); if (Head) delete Head; } }; } // namespace static StringRef Argv0; /// Signals that represent requested termination. There's no bug or failure, or /// if there is, it's not our direct responsibility. For whatever reason, our /// continued execution is no longer desirable. static const int IntSigs[] = {SIGHUP, SIGINT, SIGTERM, SIGUSR2}; /// Signals that represent that we have a bug, and our prompt termination has /// been ordered. static const int KillSigs[] = {SIGILL, SIGTRAP, SIGABRT, SIGFPE, SIGBUS, SIGSEGV, SIGQUIT #ifdef SIGSYS , SIGSYS #endif #ifdef SIGXCPU , SIGXCPU #endif #ifdef SIGXFSZ , SIGXFSZ #endif #ifdef SIGEMT , SIGEMT #endif }; /// Signals that represent requests for status. static const int InfoSigs[] = {SIGUSR1 #ifdef SIGINFO , SIGINFO #endif }; static const size_t NumSigs = std::size(IntSigs) + std::size(KillSigs) + std::size(InfoSigs) + 1 /* SIGPIPE */; static std::atomic NumRegisteredSignals = 0; static struct { struct sigaction SA; int SigNo; } RegisteredSignalInfo[NumSigs]; #if defined(HAVE_SIGALTSTACK) // Hold onto both the old and new alternate signal stack so that it's not // reported as a leak. We don't make any attempt to remove our alt signal // stack if we remove our signal handlers; that can't be done reliably if // someone else is also trying to do the same thing. static stack_t OldAltStack; LLVM_ATTRIBUTE_USED static void *NewAltStackPointer; static void CreateSigAltStack() { const size_t AltStackSize = MINSIGSTKSZ + 64 * 1024; // If we're executing on the alternate stack, or we already have an alternate // signal stack that we're happy with, there's nothing for us to do. Don't // reduce the size, some other part of the process might need a larger stack // than we do. if (sigaltstack(nullptr, &OldAltStack) != 0 || OldAltStack.ss_flags & SS_ONSTACK || (OldAltStack.ss_sp && OldAltStack.ss_size >= AltStackSize)) return; stack_t AltStack = {}; AltStack.ss_sp = static_cast(safe_malloc(AltStackSize)); NewAltStackPointer = AltStack.ss_sp; // Save to avoid reporting a leak. AltStack.ss_size = AltStackSize; if (sigaltstack(&AltStack, &OldAltStack) != 0) free(AltStack.ss_sp); } #else static void CreateSigAltStack() {} #endif static void RegisterHandlers() { // Not signal-safe. // The mutex prevents other threads from registering handlers while we're // doing it. We also have to protect the handlers and their count because // a signal handler could fire while we're registering handlers. static ManagedStatic> SignalHandlerRegistrationMutex; sys::SmartScopedLock Guard(*SignalHandlerRegistrationMutex); // If the handlers are already registered, we're done. if (NumRegisteredSignals.load() != 0) return; // Create an alternate stack for signal handling. This is necessary for us to // be able to reliably handle signals due to stack overflow. CreateSigAltStack(); enum class SignalKind { IsKill, IsInfo }; auto registerHandler = [&](int Signal, SignalKind Kind) { unsigned Index = NumRegisteredSignals.load(); assert(Index < std::size(RegisteredSignalInfo) && "Out of space for signal handlers!"); struct sigaction NewHandler; switch (Kind) { case SignalKind::IsKill: NewHandler.sa_handler = SignalHandler; NewHandler.sa_flags = SA_NODEFER | SA_RESETHAND | SA_ONSTACK; break; case SignalKind::IsInfo: NewHandler.sa_handler = InfoSignalHandler; NewHandler.sa_flags = SA_ONSTACK; break; } sigemptyset(&NewHandler.sa_mask); // Install the new handler, save the old one in RegisteredSignalInfo. sigaction(Signal, &NewHandler, &RegisteredSignalInfo[Index].SA); RegisteredSignalInfo[Index].SigNo = Signal; ++NumRegisteredSignals; }; for (auto S : IntSigs) registerHandler(S, SignalKind::IsKill); for (auto S : KillSigs) registerHandler(S, SignalKind::IsKill); if (OneShotPipeSignalFunction) registerHandler(SIGPIPE, SignalKind::IsKill); for (auto S : InfoSigs) registerHandler(S, SignalKind::IsInfo); } void sys::unregisterHandlers() { // Restore all of the signal handlers to how they were before we showed up. for (unsigned i = 0, e = NumRegisteredSignals.load(); i != e; ++i) { sigaction(RegisteredSignalInfo[i].SigNo, &RegisteredSignalInfo[i].SA, nullptr); --NumRegisteredSignals; } } /// Process the FilesToRemove list. static void RemoveFilesToRemove() { FileToRemoveList::removeAllFiles(FilesToRemove); } void sys::CleanupOnSignal(uintptr_t Context) { int Sig = (int)Context; if (llvm::is_contained(InfoSigs, Sig)) { InfoSignalHandler(Sig); return; } RemoveFilesToRemove(); if (llvm::is_contained(IntSigs, Sig) || Sig == SIGPIPE) return; llvm::sys::RunSignalHandlers(); } // The signal handler that runs. static void SignalHandler(int Sig) { // Restore the signal behavior to default, so that the program actually // crashes when we return and the signal reissues. This also ensures that if // we crash in our signal handler that the program will terminate immediately // instead of recursing in the signal handler. sys::unregisterHandlers(); // Unmask all potentially blocked kill signals. sigset_t SigMask; sigfillset(&SigMask); sigprocmask(SIG_UNBLOCK, &SigMask, nullptr); { RemoveFilesToRemove(); if (Sig == SIGPIPE) if (auto OldOneShotPipeFunction = OneShotPipeSignalFunction.exchange(nullptr)) return OldOneShotPipeFunction(); bool IsIntSig = llvm::is_contained(IntSigs, Sig); if (IsIntSig) if (auto OldInterruptFunction = InterruptFunction.exchange(nullptr)) return OldInterruptFunction(); if (Sig == SIGPIPE || IsIntSig) { raise(Sig); // Execute the default handler. return; } } // Otherwise if it is a fault (like SEGV) run any handler. llvm::sys::RunSignalHandlers(); #ifdef __s390__ // On S/390, certain signals are delivered with PSW Address pointing to // *after* the faulting instruction. Simply returning from the signal // handler would continue execution after that point, instead of // re-raising the signal. Raise the signal manually in those cases. if (Sig == SIGILL || Sig == SIGFPE || Sig == SIGTRAP) raise(Sig); #endif } static void InfoSignalHandler(int Sig) { SaveAndRestore SaveErrnoDuringASignalHandler(errno); if (SignalHandlerFunctionType CurrentInfoFunction = InfoSignalFunction) CurrentInfoFunction(); } void llvm::sys::RunInterruptHandlers() { RemoveFilesToRemove(); } void llvm::sys::SetInterruptFunction(void (*IF)()) { InterruptFunction.exchange(IF); RegisterHandlers(); } void llvm::sys::SetInfoSignalFunction(void (*Handler)()) { InfoSignalFunction.exchange(Handler); RegisterHandlers(); } void llvm::sys::SetOneShotPipeSignalFunction(void (*Handler)()) { OneShotPipeSignalFunction.exchange(Handler); RegisterHandlers(); } void llvm::sys::DefaultOneShotPipeSignalHandler() { // Send a special return code that drivers can check for, from sysexits.h. exit(EX_IOERR); } // The public API bool llvm::sys::RemoveFileOnSignal(StringRef Filename, std::string *ErrMsg) { // Ensure that cleanup will occur as soon as one file is added. static ManagedStatic FilesToRemoveCleanup; *FilesToRemoveCleanup; FileToRemoveList::insert(FilesToRemove, Filename.str()); RegisterHandlers(); return false; } // The public API void llvm::sys::DontRemoveFileOnSignal(StringRef Filename) { FileToRemoveList::erase(FilesToRemove, Filename.str()); } /// Add a function to be called when a signal is delivered to the process. The /// handler can have a cookie passed to it to identify what instance of the /// handler it is. void llvm::sys::AddSignalHandler(sys::SignalHandlerCallback FnPtr, void *Cookie) { // Signal-safe. insertSignalHandler(FnPtr, Cookie); RegisterHandlers(); } #if ENABLE_BACKTRACES && defined(HAVE_BACKTRACE) && HAVE_LINK_H && \ (defined(__linux__) || defined(__FreeBSD__) || \ defined(__FreeBSD_kernel__) || defined(__NetBSD__)) struct DlIteratePhdrData { void **StackTrace; int depth; bool first; const char **modules; intptr_t *offsets; const char *main_exec_name; }; static int dl_iterate_phdr_cb(dl_phdr_info *info, size_t size, void *arg) { DlIteratePhdrData *data = (DlIteratePhdrData *)arg; const char *name = data->first ? data->main_exec_name : info->dlpi_name; data->first = false; for (int i = 0; i < info->dlpi_phnum; i++) { const auto *phdr = &info->dlpi_phdr[i]; if (phdr->p_type != PT_LOAD) continue; intptr_t beg = info->dlpi_addr + phdr->p_vaddr; intptr_t end = beg + phdr->p_memsz; for (int j = 0; j < data->depth; j++) { if (data->modules[j]) continue; intptr_t addr = (intptr_t)data->StackTrace[j]; if (beg <= addr && addr < end) { data->modules[j] = name; data->offsets[j] = addr - info->dlpi_addr; } } } return 0; } /// If this is an ELF platform, we can find all loaded modules and their virtual /// addresses with dl_iterate_phdr. static bool findModulesAndOffsets(void **StackTrace, int Depth, const char **Modules, intptr_t *Offsets, const char *MainExecutableName, StringSaver &StrPool) { DlIteratePhdrData data = {StackTrace, Depth, true, Modules, Offsets, MainExecutableName}; dl_iterate_phdr(dl_iterate_phdr_cb, &data); return true; } class DSOMarkupPrinter { llvm::raw_ostream &OS; const char *MainExecutableName; size_t ModuleCount = 0; bool IsFirst = true; public: DSOMarkupPrinter(llvm::raw_ostream &OS, const char *MainExecutableName) : OS(OS), MainExecutableName(MainExecutableName) {} /// Print llvm-symbolizer markup describing the layout of the given DSO. void printDSOMarkup(dl_phdr_info *Info) { ArrayRef BuildID = findBuildID(Info); if (BuildID.empty()) return; OS << format("{{{module:%d:%s:elf:", ModuleCount, IsFirst ? MainExecutableName : Info->dlpi_name); for (uint8_t X : BuildID) OS << format("%02x", X); OS << "}}}\n"; for (int I = 0; I < Info->dlpi_phnum; I++) { const auto *Phdr = &Info->dlpi_phdr[I]; if (Phdr->p_type != PT_LOAD) continue; uintptr_t StartAddress = Info->dlpi_addr + Phdr->p_vaddr; uintptr_t ModuleRelativeAddress = Phdr->p_vaddr; std::array ModeStr = modeStrFromFlags(Phdr->p_flags); OS << format("{{{mmap:%#016x:%#x:load:%d:%s:%#016x}}}\n", StartAddress, Phdr->p_memsz, ModuleCount, &ModeStr[0], ModuleRelativeAddress); } IsFirst = false; ModuleCount++; } /// Callback for use with dl_iterate_phdr. The last dl_iterate_phdr argument /// must be a pointer to an instance of this class. static int printDSOMarkup(dl_phdr_info *Info, size_t Size, void *Arg) { static_cast(Arg)->printDSOMarkup(Info); return 0; } // Returns the build ID for the given DSO as an array of bytes. Returns an // empty array if none could be found. ArrayRef findBuildID(dl_phdr_info *Info) { for (int I = 0; I < Info->dlpi_phnum; I++) { const auto *Phdr = &Info->dlpi_phdr[I]; if (Phdr->p_type != PT_NOTE) continue; ArrayRef Notes( reinterpret_cast(Info->dlpi_addr + Phdr->p_vaddr), Phdr->p_memsz); while (Notes.size() > 12) { uint32_t NameSize = *reinterpret_cast(Notes.data()); Notes = Notes.drop_front(4); uint32_t DescSize = *reinterpret_cast(Notes.data()); Notes = Notes.drop_front(4); uint32_t Type = *reinterpret_cast(Notes.data()); Notes = Notes.drop_front(4); ArrayRef Name = Notes.take_front(NameSize); auto CurPos = reinterpret_cast(Notes.data()); uint32_t BytesUntilDesc = alignToPowerOf2(CurPos + NameSize, 4) - CurPos; if (BytesUntilDesc >= Notes.size()) break; Notes = Notes.drop_front(BytesUntilDesc); ArrayRef Desc = Notes.take_front(DescSize); CurPos = reinterpret_cast(Notes.data()); uint32_t BytesUntilNextNote = alignToPowerOf2(CurPos + DescSize, 4) - CurPos; if (BytesUntilNextNote > Notes.size()) break; Notes = Notes.drop_front(BytesUntilNextNote); if (Type == 3 /*NT_GNU_BUILD_ID*/ && Name.size() >= 3 && Name[0] == 'G' && Name[1] == 'N' && Name[2] == 'U') return Desc; } } return {}; } // Returns a symbolizer markup string describing the permissions on a DSO // with the given p_flags. std::array modeStrFromFlags(uint32_t Flags) { std::array Mode; char *Cur = &Mode[0]; if (Flags & PF_R) *Cur++ = 'r'; if (Flags & PF_W) *Cur++ = 'w'; if (Flags & PF_X) *Cur++ = 'x'; *Cur = '\0'; return Mode; } }; static bool printMarkupContext(llvm::raw_ostream &OS, const char *MainExecutableName) { OS << "{{{reset}}}\n"; DSOMarkupPrinter MP(OS, MainExecutableName); dl_iterate_phdr(DSOMarkupPrinter::printDSOMarkup, &MP); return true; } #elif ENABLE_BACKTRACES && defined(__APPLE__) && defined(__LP64__) static bool findModulesAndOffsets(void **StackTrace, int Depth, const char **Modules, intptr_t *Offsets, const char *MainExecutableName, StringSaver &StrPool) { uint32_t NumImgs = _dyld_image_count(); for (uint32_t ImageIndex = 0; ImageIndex < NumImgs; ImageIndex++) { const char *Name = _dyld_get_image_name(ImageIndex); intptr_t Slide = _dyld_get_image_vmaddr_slide(ImageIndex); auto *Header = (const struct mach_header_64 *)_dyld_get_image_header(ImageIndex); if (Header == NULL) continue; auto Cmd = (const struct load_command *)(&Header[1]); for (uint32_t CmdNum = 0; CmdNum < Header->ncmds; ++CmdNum) { uint32_t BaseCmd = Cmd->cmd & ~LC_REQ_DYLD; if (BaseCmd == LC_SEGMENT_64) { auto CmdSeg64 = (const struct segment_command_64 *)Cmd; for (int j = 0; j < Depth; j++) { if (Modules[j]) continue; intptr_t Addr = (intptr_t)StackTrace[j]; if ((intptr_t)CmdSeg64->vmaddr + Slide <= Addr && Addr < intptr_t(CmdSeg64->vmaddr + CmdSeg64->vmsize + Slide)) { Modules[j] = Name; Offsets[j] = Addr - Slide; } } } Cmd = (const load_command *)(((const char *)Cmd) + (Cmd->cmdsize)); } } return true; } static bool printMarkupContext(llvm::raw_ostream &OS, const char *MainExecutableName) { return false; } #else /// Backtraces are not enabled or we don't yet know how to find all loaded DSOs /// on this platform. static bool findModulesAndOffsets(void **StackTrace, int Depth, const char **Modules, intptr_t *Offsets, const char *MainExecutableName, StringSaver &StrPool) { return false; } static bool printMarkupContext(llvm::raw_ostream &OS, const char *MainExecutableName) { return false; } #endif // ENABLE_BACKTRACES && ... (findModulesAndOffsets variants) #if ENABLE_BACKTRACES && defined(HAVE__UNWIND_BACKTRACE) static int unwindBacktrace(void **StackTrace, int MaxEntries) { if (MaxEntries < 0) return 0; // Skip the first frame ('unwindBacktrace' itself). int Entries = -1; auto HandleFrame = [&](_Unwind_Context *Context) -> _Unwind_Reason_Code { // Apparently we need to detect reaching the end of the stack ourselves. void *IP = (void *)_Unwind_GetIP(Context); if (!IP) return _URC_END_OF_STACK; assert(Entries < MaxEntries && "recursively called after END_OF_STACK?"); if (Entries >= 0) StackTrace[Entries] = IP; if (++Entries == MaxEntries) return _URC_END_OF_STACK; return _URC_NO_REASON; }; _Unwind_Backtrace( [](_Unwind_Context *Context, void *Handler) { return (*static_cast(Handler))(Context); }, static_cast(&HandleFrame)); return std::max(Entries, 0); } #endif // In the case of a program crash or fault, print out a stack trace so that the // user has an indication of why and where we died. // // On glibc systems we have the 'backtrace' function, which works nicely, but // doesn't demangle symbols. void llvm::sys::PrintStackTrace(raw_ostream &OS, int Depth) { #if ENABLE_BACKTRACES static void *StackTrace[256]; int depth = 0; #if defined(HAVE_BACKTRACE) // Use backtrace() to output a backtrace on Linux systems with glibc. if (!depth) depth = backtrace(StackTrace, static_cast(std::size(StackTrace))); #endif #if defined(HAVE__UNWIND_BACKTRACE) // Try _Unwind_Backtrace() if backtrace() failed. if (!depth) depth = unwindBacktrace(StackTrace, static_cast(std::size(StackTrace))); #endif if (!depth) return; // If "Depth" is not provided by the caller, use the return value of // backtrace() for printing a symbolized stack trace. if (!Depth) Depth = depth; if (printMarkupStackTrace(Argv0, StackTrace, Depth, OS)) return; if (printSymbolizedStackTrace(Argv0, StackTrace, Depth, OS)) return; OS << "Stack dump without symbol names (ensure you have llvm-symbolizer in " "your PATH or set the environment var `LLVM_SYMBOLIZER_PATH` to point " "to it):\n"; #if HAVE_DLFCN_H && HAVE_DLADDR int width = 0; for (int i = 0; i < depth; ++i) { Dl_info dlinfo; dladdr(StackTrace[i], &dlinfo); const char *name = strrchr(dlinfo.dli_fname, '/'); int nwidth; if (!name) nwidth = strlen(dlinfo.dli_fname); else nwidth = strlen(name) - 1; if (nwidth > width) width = nwidth; } for (int i = 0; i < depth; ++i) { Dl_info dlinfo; dladdr(StackTrace[i], &dlinfo); OS << format("%-2d", i); const char *name = strrchr(dlinfo.dli_fname, '/'); if (!name) OS << format(" %-*s", width, dlinfo.dli_fname); else OS << format(" %-*s", width, name + 1); OS << format(" %#0*lx", (int)(sizeof(void *) * 2) + 2, (unsigned long)StackTrace[i]); if (dlinfo.dli_sname != nullptr) { OS << ' '; if (char *d = itaniumDemangle(dlinfo.dli_sname)) { OS << d; free(d); } else { OS << dlinfo.dli_sname; } OS << format(" + %tu", (static_cast(StackTrace[i]) - static_cast(dlinfo.dli_saddr))); } OS << '\n'; } #elif defined(HAVE_BACKTRACE) backtrace_symbols_fd(StackTrace, Depth, STDERR_FILENO); #endif #endif } static void PrintStackTraceSignalHandler(void *) { sys::PrintStackTrace(llvm::errs()); } void llvm::sys::DisableSystemDialogsOnCrash() {} /// When an error signal (such as SIGABRT or SIGSEGV) is delivered to the /// process, print a stack trace and then exit. void llvm::sys::PrintStackTraceOnErrorSignal(StringRef Argv0, bool DisableCrashReporting) { ::Argv0 = Argv0; AddSignalHandler(PrintStackTraceSignalHandler, nullptr); #if defined(__APPLE__) && ENABLE_CRASH_OVERRIDES // Environment variable to disable any kind of crash dialog. if (DisableCrashReporting || getenv("LLVM_DISABLE_CRASH_REPORT")) { mach_port_t self = mach_task_self(); exception_mask_t mask = EXC_MASK_CRASH; kern_return_t ret = task_set_exception_ports( self, mask, MACH_PORT_NULL, EXCEPTION_STATE_IDENTITY | MACH_EXCEPTION_CODES, THREAD_STATE_NONE); (void)ret; } #endif }