/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*- * vim: set shiftwidth=4 tabstop=8 autoindent cindent expandtab: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ /* API for getting a stack trace of the C/C++ stack on the current thread */ #include "mozilla/Assertions.h" #include "mozilla/IntegerPrintfMacros.h" #include "mozilla/StackWalk.h" #include "nsStackWalkPrivate.h" #include "nsStackWalk.h" using namespace mozilla; // The presence of this address is the stack must stop the stack walk. If // there is no such address, the structure will be {nullptr, true}. struct CriticalAddress { void* mAddr; bool mInit; }; static CriticalAddress gCriticalAddress; // for _Unwind_Backtrace from libcxxrt or libunwind // cxxabi.h from libcxxrt implicitly includes unwind.h first #if defined(HAVE__UNWIND_BACKTRACE) && !defined(_GNU_SOURCE) #define _GNU_SOURCE #endif #if defined(HAVE_DLOPEN) || defined(XP_MACOSX) #include #endif #define NSSTACKWALK_SUPPORTS_MACOSX \ (defined(XP_MACOSX) && \ (defined(__i386) || defined(__ppc__) || defined(HAVE__UNWIND_BACKTRACE))) #define NSSTACKWALK_SUPPORTS_LINUX \ (defined(linux) && \ ((defined(__GNUC__) && (defined(__i386) || defined(PPC))) || \ defined(HAVE__UNWIND_BACKTRACE))) #define NSSTACKWALK_SUPPORTS_SOLARIS \ (defined(__sun) && \ (defined(__sparc) || defined(sparc) || defined(__i386) || defined(i386))) #if NSSTACKWALK_SUPPORTS_MACOSX #include #include typedef void malloc_logger_t(uint32_t type, uintptr_t arg1, uintptr_t arg2, uintptr_t arg3, uintptr_t result, uint32_t num_hot_frames_to_skip); extern malloc_logger_t *malloc_logger; static void stack_callback(void *pc, void *sp, void *closure) { const char *name = reinterpret_cast(closure); Dl_info info; // On Leopard dladdr returns the wrong value for "new_sem_from_pool". The // stack shows up as having two pthread_cond_wait$UNIX2003 frames. The // correct one is the first that we find on our way up, so the // following check for gCriticalAddress.mAddr is critical. if (gCriticalAddress.mAddr || dladdr(pc, &info) == 0 || info.dli_sname == nullptr || strcmp(info.dli_sname, name) != 0) return; gCriticalAddress.mAddr = pc; } #ifdef DEBUG #define MAC_OS_X_VERSION_10_7_HEX 0x00001070 static int32_t OSXVersion() { static int32_t gOSXVersion = 0x0; if (gOSXVersion == 0x0) { OSErr err = ::Gestalt(gestaltSystemVersion, (SInt32*)&gOSXVersion); MOZ_ASSERT(err == noErr); } return gOSXVersion; } static bool OnLionOrLater() { return (OSXVersion() >= MAC_OS_X_VERSION_10_7_HEX); } #endif static void my_malloc_logger(uint32_t type, uintptr_t arg1, uintptr_t arg2, uintptr_t arg3, uintptr_t result, uint32_t num_hot_frames_to_skip) { static bool once = false; if (once) return; once = true; // On Leopard dladdr returns the wrong value for "new_sem_from_pool". The // stack shows up as having two pthread_cond_wait$UNIX2003 frames. const char *name = "new_sem_from_pool"; NS_StackWalk(stack_callback, /* skipFrames */ 0, /* maxFrames */ 0, const_cast(name), 0, nullptr); } // This is called from NS_LogInit() and from the stack walking functions, but // only the first call has any effect. We need to call this function from both // places because it must run before any mutexes are created, and also before // any objects whose refcounts we're logging are created. Running this // function during NS_LogInit() ensures that we meet the first criterion, and // running this function during the stack walking functions ensures we meet the // second criterion. void StackWalkInitCriticalAddress() { if(gCriticalAddress.mInit) return; gCriticalAddress.mInit = true; // We must not do work when 'new_sem_from_pool' calls realloc, since // it holds a non-reentrant spin-lock and we will quickly deadlock. // new_sem_from_pool is not directly accessible using dlsym, so // we force a situation where new_sem_from_pool is on the stack and // use dladdr to check the addresses. // malloc_logger can be set by external tools like 'Instruments' or 'leaks' malloc_logger_t *old_malloc_logger = malloc_logger; malloc_logger = my_malloc_logger; pthread_cond_t cond; int r = pthread_cond_init(&cond, 0); MOZ_ASSERT(r == 0); pthread_mutex_t mutex; r = pthread_mutex_init(&mutex,0); MOZ_ASSERT(r == 0); r = pthread_mutex_lock(&mutex); MOZ_ASSERT(r == 0); struct timespec abstime = {0, 1}; r = pthread_cond_timedwait_relative_np(&cond, &mutex, &abstime); // restore the previous malloc logger malloc_logger = old_malloc_logger; // On Lion, malloc is no longer called from pthread_cond_*wait*. This prevents // us from finding the address, but that is fine, since with no call to malloc // there is no critical address. MOZ_ASSERT(OnLionOrLater() || gCriticalAddress.mAddr != nullptr); MOZ_ASSERT(r == ETIMEDOUT); r = pthread_mutex_unlock(&mutex); MOZ_ASSERT(r == 0); r = pthread_mutex_destroy(&mutex); MOZ_ASSERT(r == 0); r = pthread_cond_destroy(&cond); MOZ_ASSERT(r == 0); } static bool IsCriticalAddress(void* aPC) { return gCriticalAddress.mAddr == aPC; } #else static bool IsCriticalAddress(void* aPC) { return false; } // We still initialize gCriticalAddress.mInit so that this code behaves // the same on all platforms. Otherwise a failure to init would be visible // only on OS X. void StackWalkInitCriticalAddress() { gCriticalAddress.mInit = true; } #endif #if defined(_WIN32) && (defined(_M_IX86) || defined(_M_AMD64) || defined(_M_IA64)) // WIN32 x86 stack walking code #include "nscore.h" #include #include #include #include #include "plstr.h" #include "mozilla/ArrayUtils.h" #include "nspr.h" #include // We need a way to know if we are building for WXP (or later), as if we are, we // need to use the newer 64-bit APIs. API_VERSION_NUMBER seems to fit the bill. // A value of 9 indicates we want to use the new APIs. #if API_VERSION_NUMBER < 9 #error Too old imagehlp.h #endif // Define these as static pointers so that we can load the DLL on the // fly (and not introduce a link-time dependency on it). Tip o' the // hat to Matt Pietrick for this idea. See: // // http://msdn.microsoft.com/library/periodic/period97/F1/D3/S245C6.htm // extern "C" { extern HANDLE hStackWalkMutex; bool EnsureSymInitialized(); bool EnsureWalkThreadReady(); struct WalkStackData { uint32_t skipFrames; HANDLE thread; bool walkCallingThread; HANDLE process; HANDLE eventStart; HANDLE eventEnd; void **pcs; uint32_t pc_size; uint32_t pc_count; uint32_t pc_max; void **sps; uint32_t sp_size; uint32_t sp_count; void *platformData; }; void PrintError(char *prefix, WalkStackData* data); unsigned int WINAPI WalkStackThread(void* data); void WalkStackMain64(struct WalkStackData* data); DWORD gStackWalkThread; CRITICAL_SECTION gDbgHelpCS; } // Routine to print an error message to standard error. void PrintError(const char *prefix) { LPVOID lpMsgBuf; DWORD lastErr = GetLastError(); FormatMessageA( FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS, nullptr, lastErr, MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT), // Default language (LPSTR) &lpMsgBuf, 0, nullptr ); fprintf(stderr, "### ERROR: %s: %s", prefix, lpMsgBuf ? lpMsgBuf : "(null)\n"); fflush(stderr); LocalFree(lpMsgBuf); } bool EnsureWalkThreadReady() { static bool walkThreadReady = false; static HANDLE stackWalkThread = nullptr; static HANDLE readyEvent = nullptr; if (walkThreadReady) return walkThreadReady; if (stackWalkThread == nullptr) { readyEvent = ::CreateEvent(nullptr, FALSE /* auto-reset*/, FALSE /* initially non-signaled */, nullptr); if (readyEvent == nullptr) { PrintError("CreateEvent"); return false; } unsigned int threadID; stackWalkThread = (HANDLE) _beginthreadex(nullptr, 0, WalkStackThread, (void*)readyEvent, 0, &threadID); if (stackWalkThread == nullptr) { PrintError("CreateThread"); ::CloseHandle(readyEvent); readyEvent = nullptr; return false; } gStackWalkThread = threadID; ::CloseHandle(stackWalkThread); } MOZ_ASSERT((stackWalkThread != nullptr && readyEvent != nullptr) || (stackWalkThread == nullptr && readyEvent == nullptr)); // The thread was created. Try to wait an arbitrary amount of time (1 second // should be enough) for its event loop to start before posting events to it. DWORD waitRet = ::WaitForSingleObject(readyEvent, 1000); if (waitRet == WAIT_TIMEOUT) { // We get a timeout if we're called during static initialization because // the thread will only start executing after we return so it couldn't // have signalled the event. If that is the case, give up for now and // try again next time we're called. return false; } ::CloseHandle(readyEvent); stackWalkThread = nullptr; readyEvent = nullptr; ::InitializeCriticalSection(&gDbgHelpCS); return walkThreadReady = true; } void WalkStackMain64(struct WalkStackData* data) { // Get the context information for the thread. That way we will // know where our sp, fp, pc, etc. are and can fill in the // STACKFRAME64 with the initial values. CONTEXT context; HANDLE myProcess = data->process; HANDLE myThread = data->thread; DWORD64 addr; DWORD64 spaddr; STACKFRAME64 frame64; // skip our own stack walking frames int skip = (data->walkCallingThread ? 3 : 0) + data->skipFrames; BOOL ok; // Get a context for the specified thread. if (!data->platformData) { memset(&context, 0, sizeof(CONTEXT)); context.ContextFlags = CONTEXT_FULL; if (!GetThreadContext(myThread, &context)) { if (data->walkCallingThread) { PrintError("GetThreadContext"); } return; } } else { context = *static_cast(data->platformData); } // Setup initial stack frame to walk from memset(&frame64, 0, sizeof(frame64)); #ifdef _M_IX86 frame64.AddrPC.Offset = context.Eip; frame64.AddrStack.Offset = context.Esp; frame64.AddrFrame.Offset = context.Ebp; #elif defined _M_AMD64 frame64.AddrPC.Offset = context.Rip; frame64.AddrStack.Offset = context.Rsp; frame64.AddrFrame.Offset = context.Rbp; #elif defined _M_IA64 frame64.AddrPC.Offset = context.StIIP; frame64.AddrStack.Offset = context.SP; frame64.AddrFrame.Offset = context.RsBSP; #else #error "Should not have compiled this code" #endif frame64.AddrPC.Mode = AddrModeFlat; frame64.AddrStack.Mode = AddrModeFlat; frame64.AddrFrame.Mode = AddrModeFlat; frame64.AddrReturn.Mode = AddrModeFlat; // Now walk the stack while (1) { // debug routines are not threadsafe, so grab the lock. EnterCriticalSection(&gDbgHelpCS); ok = StackWalk64( #ifdef _M_AMD64 IMAGE_FILE_MACHINE_AMD64, #elif defined _M_IA64 IMAGE_FILE_MACHINE_IA64, #elif defined _M_IX86 IMAGE_FILE_MACHINE_I386, #else #error "Should not have compiled this code" #endif myProcess, myThread, &frame64, &context, nullptr, SymFunctionTableAccess64, // function table access routine SymGetModuleBase64, // module base routine 0 ); LeaveCriticalSection(&gDbgHelpCS); if (ok) { addr = frame64.AddrPC.Offset; spaddr = frame64.AddrStack.Offset; } else { addr = 0; spaddr = 0; if (data->walkCallingThread) { PrintError("WalkStack64"); } } if (!ok || (addr == 0)) { break; } if (skip-- > 0) { continue; } if (data->pc_count < data->pc_size) data->pcs[data->pc_count] = (void*)addr; ++data->pc_count; if (data->sp_count < data->sp_size) data->sps[data->sp_count] = (void*)spaddr; ++data->sp_count; if (data->pc_max != 0 && data->pc_count == data->pc_max) break; if (frame64.AddrReturn.Offset == 0) break; } return; } unsigned int WINAPI WalkStackThread(void* aData) { BOOL msgRet; MSG msg; // Call PeekMessage to force creation of a message queue so that // other threads can safely post events to us. ::PeekMessage(&msg, nullptr, WM_USER, WM_USER, PM_NOREMOVE); // and tell the thread that created us that we're ready. HANDLE readyEvent = (HANDLE)aData; ::SetEvent(readyEvent); while ((msgRet = ::GetMessage(&msg, (HWND)-1, 0, 0)) != 0) { if (msgRet == -1) { PrintError("GetMessage"); } else { DWORD ret; struct WalkStackData *data = (WalkStackData *)msg.lParam; if (!data) continue; // Don't suspend the calling thread until it's waiting for // us; otherwise the number of frames on the stack could vary. ret = ::WaitForSingleObject(data->eventStart, INFINITE); if (ret != WAIT_OBJECT_0) PrintError("WaitForSingleObject"); // Suspend the calling thread, dump his stack, and then resume him. // He's currently waiting for us to finish so now should be a good time. ret = ::SuspendThread( data->thread ); if (ret == -1) { PrintError("ThreadSuspend"); } else { WalkStackMain64(data); ret = ::ResumeThread(data->thread); if (ret == -1) { PrintError("ThreadResume"); } } ::SetEvent(data->eventEnd); } } return 0; } /** * Walk the stack, translating PC's found into strings and recording the * chain in aBuffer. For this to work properly, the DLLs must be rebased * so that the address in the file agrees with the address in memory. * Otherwise StackWalk will return FALSE when it hits a frame in a DLL * whose in memory address doesn't match its in-file address. */ EXPORT_XPCOM_API(nsresult) NS_StackWalk(NS_WalkStackCallback aCallback, uint32_t aSkipFrames, uint32_t aMaxFrames, void *aClosure, uintptr_t aThread, void *aPlatformData) { StackWalkInitCriticalAddress(); static HANDLE myProcess = nullptr; HANDLE myThread; DWORD walkerReturn; struct WalkStackData data; if (!EnsureWalkThreadReady()) return NS_ERROR_FAILURE; HANDLE targetThread = ::GetCurrentThread(); data.walkCallingThread = true; if (aThread) { HANDLE threadToWalk = reinterpret_cast (aThread); // walkCallingThread indicates whether we are walking the caller's stack data.walkCallingThread = (threadToWalk == targetThread); targetThread = threadToWalk; } // We need to avoid calling fprintf and friends if we're walking the stack of // another thread, in order to avoid deadlocks. const bool shouldBeThreadSafe = !!aThread; // Have to duplicate handle to get a real handle. if (!myProcess) { if (!::DuplicateHandle(::GetCurrentProcess(), ::GetCurrentProcess(), ::GetCurrentProcess(), &myProcess, PROCESS_ALL_ACCESS, FALSE, 0)) { if (!shouldBeThreadSafe) { PrintError("DuplicateHandle (process)"); } return NS_ERROR_FAILURE; } } if (!::DuplicateHandle(::GetCurrentProcess(), targetThread, ::GetCurrentProcess(), &myThread, THREAD_ALL_ACCESS, FALSE, 0)) { if (!shouldBeThreadSafe) { PrintError("DuplicateHandle (thread)"); } return NS_ERROR_FAILURE; } data.skipFrames = aSkipFrames; data.thread = myThread; data.process = myProcess; void *local_pcs[1024]; data.pcs = local_pcs; data.pc_count = 0; data.pc_size = ArrayLength(local_pcs); data.pc_max = aMaxFrames; void *local_sps[1024]; data.sps = local_sps; data.sp_count = 0; data.sp_size = ArrayLength(local_sps); data.platformData = aPlatformData; if (aThread) { // If we're walking the stack of another thread, we don't need to // use a separate walker thread. WalkStackMain64(&data); if (data.pc_count > data.pc_size) { data.pcs = (void**) _alloca(data.pc_count * sizeof(void*)); data.pc_size = data.pc_count; data.pc_count = 0; data.sps = (void**) _alloca(data.sp_count * sizeof(void*)); data.sp_size = data.sp_count; data.sp_count = 0; WalkStackMain64(&data); } } else { data.eventStart = ::CreateEvent(nullptr, FALSE /* auto-reset*/, FALSE /* initially non-signaled */, nullptr); data.eventEnd = ::CreateEvent(nullptr, FALSE /* auto-reset*/, FALSE /* initially non-signaled */, nullptr); ::PostThreadMessage(gStackWalkThread, WM_USER, 0, (LPARAM)&data); walkerReturn = ::SignalObjectAndWait(data.eventStart, data.eventEnd, INFINITE, FALSE); if (walkerReturn != WAIT_OBJECT_0 && !shouldBeThreadSafe) PrintError("SignalObjectAndWait (1)"); if (data.pc_count > data.pc_size) { data.pcs = (void**) _alloca(data.pc_count * sizeof(void*)); data.pc_size = data.pc_count; data.pc_count = 0; data.sps = (void**) _alloca(data.sp_count * sizeof(void*)); data.sp_size = data.sp_count; data.sp_count = 0; ::PostThreadMessage(gStackWalkThread, WM_USER, 0, (LPARAM)&data); walkerReturn = ::SignalObjectAndWait(data.eventStart, data.eventEnd, INFINITE, FALSE); if (walkerReturn != WAIT_OBJECT_0 && !shouldBeThreadSafe) PrintError("SignalObjectAndWait (2)"); } ::CloseHandle(data.eventStart); ::CloseHandle(data.eventEnd); } ::CloseHandle(myThread); for (uint32_t i = 0; i < data.pc_count; ++i) (*aCallback)(data.pcs[i], data.sps[i], aClosure); return data.pc_count == 0 ? NS_ERROR_FAILURE : NS_OK; } static BOOL CALLBACK callbackEspecial64( PCSTR aModuleName, DWORD64 aModuleBase, ULONG aModuleSize, PVOID aUserContext) { BOOL retval = TRUE; DWORD64 addr = *(DWORD64*)aUserContext; /* * You'll want to control this if we are running on an * architecture where the addresses go the other direction. * Not sure this is even a realistic consideration. */ const BOOL addressIncreases = TRUE; /* * If it falls in side the known range, load the symbols. */ if (addressIncreases ? (addr >= aModuleBase && addr <= (aModuleBase + aModuleSize)) : (addr <= aModuleBase && addr >= (aModuleBase - aModuleSize)) ) { retval = !!SymLoadModule64(GetCurrentProcess(), nullptr, (PSTR)aModuleName, nullptr, aModuleBase, aModuleSize); if (!retval) PrintError("SymLoadModule64"); } return retval; } /* * SymGetModuleInfoEspecial * * Attempt to determine the module information. * Bug 112196 says this DLL may not have been loaded at the time * SymInitialize was called, and thus the module information * and symbol information is not available. * This code rectifies that problem. */ // New members were added to IMAGEHLP_MODULE64 (that show up in the // Platform SDK that ships with VC8, but not the Platform SDK that ships // with VC7.1, i.e., between DbgHelp 6.0 and 6.1), but we don't need to // use them, and it's useful to be able to function correctly with the // older library. (Stock Windows XP SP2 seems to ship with dbghelp.dll // version 5.1.) Since Platform SDK version need not correspond to // compiler version, and the version number in debughlp.h was NOT bumped // when these changes were made, ifdef based on a constant that was // added between these versions. #ifdef SSRVOPT_SETCONTEXT #define NS_IMAGEHLP_MODULE64_SIZE (((offsetof(IMAGEHLP_MODULE64, LoadedPdbName) + sizeof(DWORD64) - 1) / sizeof(DWORD64)) * sizeof(DWORD64)) #else #define NS_IMAGEHLP_MODULE64_SIZE sizeof(IMAGEHLP_MODULE64) #endif BOOL SymGetModuleInfoEspecial64(HANDLE aProcess, DWORD64 aAddr, PIMAGEHLP_MODULE64 aModuleInfo, PIMAGEHLP_LINE64 aLineInfo) { BOOL retval = FALSE; /* * Init the vars if we have em. */ aModuleInfo->SizeOfStruct = NS_IMAGEHLP_MODULE64_SIZE; if (nullptr != aLineInfo) { aLineInfo->SizeOfStruct = sizeof(IMAGEHLP_LINE64); } /* * Give it a go. * It may already be loaded. */ retval = SymGetModuleInfo64(aProcess, aAddr, aModuleInfo); if (FALSE == retval) { BOOL enumRes = FALSE; /* * Not loaded, here's the magic. * Go through all the modules. */ // Need to cast to PENUMLOADED_MODULES_CALLBACK64 because the // constness of the first parameter of // PENUMLOADED_MODULES_CALLBACK64 varies over SDK versions (from // non-const to const over time). See bug 391848 and bug // 415426. enumRes = EnumerateLoadedModules64(aProcess, (PENUMLOADED_MODULES_CALLBACK64)callbackEspecial64, (PVOID)&aAddr); if (FALSE != enumRes) { /* * One final go. * If it fails, then well, we have other problems. */ retval = SymGetModuleInfo64(aProcess, aAddr, aModuleInfo); } } /* * If we got module info, we may attempt line info as well. * We will not report failure if this does not work. */ if (FALSE != retval && nullptr != aLineInfo) { DWORD displacement = 0; BOOL lineRes = FALSE; lineRes = SymGetLineFromAddr64(aProcess, aAddr, &displacement, aLineInfo); if (!lineRes) { // Clear out aLineInfo to indicate that it's not valid memset(aLineInfo, 0, sizeof(*aLineInfo)); } } return retval; } bool EnsureSymInitialized() { static bool gInitialized = false; bool retStat; if (gInitialized) return gInitialized; if (!EnsureWalkThreadReady()) return false; SymSetOptions(SYMOPT_LOAD_LINES | SYMOPT_UNDNAME); retStat = SymInitialize(GetCurrentProcess(), nullptr, TRUE); if (!retStat) PrintError("SymInitialize"); gInitialized = retStat; /* XXX At some point we need to arrange to call SymCleanup */ return retStat; } EXPORT_XPCOM_API(nsresult) NS_DescribeCodeAddress(void *aPC, nsCodeAddressDetails *aDetails) { aDetails->library[0] = '\0'; aDetails->loffset = 0; aDetails->filename[0] = '\0'; aDetails->lineno = 0; aDetails->function[0] = '\0'; aDetails->foffset = 0; if (!EnsureSymInitialized()) return NS_ERROR_FAILURE; HANDLE myProcess = ::GetCurrentProcess(); BOOL ok; // debug routines are not threadsafe, so grab the lock. EnterCriticalSection(&gDbgHelpCS); // // Attempt to load module info before we attempt to resolve the symbol. // This just makes sure we get good info if available. // DWORD64 addr = (DWORD64)aPC; IMAGEHLP_MODULE64 modInfo; IMAGEHLP_LINE64 lineInfo; BOOL modInfoRes; modInfoRes = SymGetModuleInfoEspecial64(myProcess, addr, &modInfo, &lineInfo); if (modInfoRes) { PL_strncpyz(aDetails->library, modInfo.ModuleName, sizeof(aDetails->library)); aDetails->loffset = (char*) aPC - (char*) modInfo.BaseOfImage; if (lineInfo.FileName) { PL_strncpyz(aDetails->filename, lineInfo.FileName, sizeof(aDetails->filename)); aDetails->lineno = lineInfo.LineNumber; } } ULONG64 buffer[(sizeof(SYMBOL_INFO) + MAX_SYM_NAME*sizeof(TCHAR) + sizeof(ULONG64) - 1) / sizeof(ULONG64)]; PSYMBOL_INFO pSymbol = (PSYMBOL_INFO)buffer; pSymbol->SizeOfStruct = sizeof(SYMBOL_INFO); pSymbol->MaxNameLen = MAX_SYM_NAME; DWORD64 displacement; ok = SymFromAddr(myProcess, addr, &displacement, pSymbol); if (ok) { PL_strncpyz(aDetails->function, pSymbol->Name, sizeof(aDetails->function)); aDetails->foffset = static_cast(displacement); } LeaveCriticalSection(&gDbgHelpCS); // release our lock return NS_OK; } EXPORT_XPCOM_API(nsresult) NS_FormatCodeAddressDetails(void *aPC, const nsCodeAddressDetails *aDetails, char *aBuffer, uint32_t aBufferSize) { if (aDetails->function[0]) { _snprintf(aBuffer, aBufferSize, "%s+0x%08lX [%s +0x%016lX]", aDetails->function, aDetails->foffset, aDetails->library, aDetails->loffset); } else if (aDetails->library[0]) { _snprintf(aBuffer, aBufferSize, "UNKNOWN [%s +0x%016lX]", aDetails->library, aDetails->loffset); } else { _snprintf(aBuffer, aBufferSize, "UNKNOWN 0x%016lX", aPC); } aBuffer[aBufferSize - 1] = '\0'; uint32_t len = strlen(aBuffer); if (aDetails->filename[0]) { _snprintf(aBuffer + len, aBufferSize - len, " (%s, line %d)\n", aDetails->filename, aDetails->lineno); } else { aBuffer[len] = '\n'; if (++len != aBufferSize) aBuffer[len] = '\0'; } aBuffer[aBufferSize - 2] = '\n'; aBuffer[aBufferSize - 1] = '\0'; return NS_OK; } // WIN32 x86 stack walking code // i386 or PPC Linux stackwalking code or Solaris #elif HAVE_DLADDR && (HAVE__UNWIND_BACKTRACE || NSSTACKWALK_SUPPORTS_LINUX || NSSTACKWALK_SUPPORTS_SOLARIS || NSSTACKWALK_SUPPORTS_MACOSX) #include #include #include "nscore.h" #include #include "plstr.h" // On glibc 2.1, the Dl_info api defined in is only exposed // if __USE_GNU is defined. I suppose its some kind of standards // adherence thing. // #if (__GLIBC_MINOR__ >= 1) && !defined(__USE_GNU) #define __USE_GNU #endif // This thing is exported by libstdc++ // Yes, this is a gcc only hack #if defined(MOZ_DEMANGLE_SYMBOLS) #include #endif // MOZ_DEMANGLE_SYMBOLS void DemangleSymbol(const char * aSymbol, char * aBuffer, int aBufLen) { aBuffer[0] = '\0'; #if defined(MOZ_DEMANGLE_SYMBOLS) /* See demangle.h in the gcc source for the voodoo */ char * demangled = abi::__cxa_demangle(aSymbol,0,0,0); if (demangled) { PL_strncpyz(aBuffer,demangled,aBufLen); free(demangled); } #endif // MOZ_DEMANGLE_SYMBOLS } #if NSSTACKWALK_SUPPORTS_SOLARIS /* * Stack walking code for Solaris courtesy of Bart Smaalder's "memtrak". */ #include #include #include #include #include static int load_address ( void * pc, void * arg ); static struct bucket * newbucket ( void * pc ); static struct frame * cs_getmyframeptr ( void ); static void cs_walk_stack ( void * (*read_func)(char * address), struct frame * fp, int (*operate_func)(void *, void *, void *), void * usrarg ); static void cs_operate ( void (*operate_func)(void *, void *, void *), void * usrarg ); #ifndef STACK_BIAS #define STACK_BIAS 0 #endif /*STACK_BIAS*/ #define LOGSIZE 4096 /* type of demangling function */ typedef int demf_t(const char *, char *, size_t); static demf_t *demf; static int initialized = 0; #if defined(sparc) || defined(__sparc) #define FRAME_PTR_REGISTER REG_SP #endif #if defined(i386) || defined(__i386) #define FRAME_PTR_REGISTER EBP #endif struct bucket { void * pc; int index; struct bucket * next; }; struct my_user_args { NS_WalkStackCallback callback; uint32_t skipFrames; uint32_t maxFrames; uint32_t numFrames; void *closure; }; static void myinit(); #pragma init (myinit) static void myinit() { if (! initialized) { #ifndef __GNUC__ void *handle; const char *libdem = "libdemangle.so.1"; /* load libdemangle if we can and need to (only try this once) */ if ((handle = dlopen(libdem, RTLD_LAZY)) != nullptr) { demf = (demf_t *)dlsym(handle, "cplus_demangle"); /*lint !e611 */ /* * lint override above is to prevent lint from * complaining about "suspicious cast". */ } #endif /*__GNUC__*/ } initialized = 1; } static int load_address(void * pc, void * arg) { static struct bucket table[2048]; static mutex_t lock; struct bucket * ptr; struct my_user_args * args = (struct my_user_args *) arg; unsigned int val = NS_PTR_TO_INT32(pc); ptr = table + ((val >> 2)&2047); mutex_lock(&lock); while (ptr->next) { if (ptr->next->pc == pc) break; ptr = ptr->next; } int stop = 0; if (ptr->next) { mutex_unlock(&lock); } else { (args->callback)(pc, args->closure); args->numFrames++; if (args->maxFrames != 0 && args->numFrames == args->maxFrames) stop = 1; // causes us to stop getting frames ptr->next = newbucket(pc); mutex_unlock(&lock); } return stop; } static struct bucket * newbucket(void * pc) { struct bucket * ptr = (struct bucket *) malloc(sizeof (*ptr)); static int index; /* protected by lock in caller */ ptr->index = index++; ptr->next = nullptr; ptr->pc = pc; return (ptr); } static struct frame * csgetframeptr() { ucontext_t u; struct frame *fp; (void) getcontext(&u); fp = (struct frame *) ((char *)u.uc_mcontext.gregs[FRAME_PTR_REGISTER] + STACK_BIAS); /* make sure to return parents frame pointer.... */ return ((struct frame *)((ulong_t)fp->fr_savfp + STACK_BIAS)); } static void cswalkstack(struct frame *fp, int (*operate_func)(void *, void *, void *), void *usrarg) { while (fp != 0 && fp->fr_savpc != 0) { if (operate_func((void *)fp->fr_savpc, nullptr, usrarg) != 0) break; /* * watch out - libthread stacks look funny at the top * so they may not have their STACK_BIAS set */ fp = (struct frame *)((ulong_t)fp->fr_savfp + (fp->fr_savfp?(ulong_t)STACK_BIAS:0)); } } static void cs_operate(int (*operate_func)(void *, void *, void *), void * usrarg) { cswalkstack(csgetframeptr(), operate_func, usrarg); } EXPORT_XPCOM_API(nsresult) NS_StackWalk(NS_WalkStackCallback aCallback, uint32_t aSkipFrames, uint32_t aMaxFrames, void *aClosure, uintptr_t aThread, void *aPlatformData) { MOZ_ASSERT(!aThread); MOZ_ASSERT(!aPlatformData); struct my_user_args args; StackWalkInitCriticalAddress(); if (!initialized) myinit(); args.callback = aCallback; args.skipFrames = aSkipFrames; /* XXX Not handled! */ args.maxFrames = aMaxFrames; args.numFrames = 0; args.closure = aClosure; cs_operate(load_address, &args); return args.numFrames == 0 ? NS_ERROR_FAILURE : NS_OK; } EXPORT_XPCOM_API(nsresult) NS_DescribeCodeAddress(void *aPC, nsCodeAddressDetails *aDetails) { aDetails->library[0] = '\0'; aDetails->loffset = 0; aDetails->filename[0] = '\0'; aDetails->lineno = 0; aDetails->function[0] = '\0'; aDetails->foffset = 0; char dembuff[4096]; Dl_info info; if (dladdr(aPC, & info)) { if (info.dli_fname) { PL_strncpyz(aDetails->library, info.dli_fname, sizeof(aDetails->library)); aDetails->loffset = (char*)aPC - (char*)info.dli_fbase; } if (info.dli_sname) { aDetails->foffset = (char*)aPC - (char*)info.dli_saddr; #ifdef __GNUC__ DemangleSymbol(info.dli_sname, dembuff, sizeof(dembuff)); #else if (!demf || demf(info.dli_sname, dembuff, sizeof (dembuff))) dembuff[0] = 0; #endif /*__GNUC__*/ PL_strncpyz(aDetails->function, (dembuff[0] != '\0') ? dembuff : info.dli_sname, sizeof(aDetails->function)); } } return NS_OK; } EXPORT_XPCOM_API(nsresult) NS_FormatCodeAddressDetails(void *aPC, const nsCodeAddressDetails *aDetails, char *aBuffer, uint32_t aBufferSize) { snprintf(aBuffer, aBufferSize, "%p %s:%s+0x%lx\n", aPC, aDetails->library[0] ? aDetails->library : "??", aDetails->function[0] ? aDetails->function : "??", aDetails->foffset); return NS_OK; } #else // not __sun-specific #if __GLIBC__ > 2 || __GLIBC_MINOR > 1 #define HAVE___LIBC_STACK_END 1 #else #define HAVE___LIBC_STACK_END 0 #endif #if HAVE___LIBC_STACK_END extern void *__libc_stack_end; // from ld-linux.so #endif namespace mozilla { nsresult FramePointerStackWalk(NS_WalkStackCallback aCallback, uint32_t aSkipFrames, uint32_t aMaxFrames, void *aClosure, void **bp, void *aStackEnd) { // Stack walking code courtesy Kipp's "leaky". int32_t skip = aSkipFrames; uint32_t numFrames = 0; while (1) { void **next = (void**)*bp; // bp may not be a frame pointer on i386 if code was compiled with // -fomit-frame-pointer, so do some sanity checks. // (bp should be a frame pointer on ppc(64) but checking anyway may help // a little if the stack has been corrupted.) // We don't need to check against the begining of the stack because // we can assume that bp > sp if (next <= bp || next > aStackEnd || (long(next) & 3)) { break; } #if (defined(__ppc__) && defined(XP_MACOSX)) || defined(__powerpc64__) // ppc mac or powerpc64 linux void *pc = *(bp+2); bp += 3; #else // i386 or powerpc32 linux void *pc = *(bp+1); bp += 2; #endif if (IsCriticalAddress(pc)) { printf("Aborting stack trace, PC is critical\n"); return NS_ERROR_UNEXPECTED; } if (--skip < 0) { // Assume that the SP points to the BP of the function // it called. We can't know the exact location of the SP // but this should be sufficient for our use the SP // to order elements on the stack. (*aCallback)(pc, bp, aClosure); numFrames++; if (aMaxFrames != 0 && numFrames == aMaxFrames) break; } bp = next; } return numFrames == 0 ? NS_ERROR_FAILURE : NS_OK; } } #define X86_OR_PPC (defined(__i386) || defined(PPC) || defined(__ppc__)) #if X86_OR_PPC && (NSSTACKWALK_SUPPORTS_MACOSX || NSSTACKWALK_SUPPORTS_LINUX) // i386 or PPC Linux or Mac stackwalking code EXPORT_XPCOM_API(nsresult) NS_StackWalk(NS_WalkStackCallback aCallback, uint32_t aSkipFrames, uint32_t aMaxFrames, void *aClosure, uintptr_t aThread, void *aPlatformData) { MOZ_ASSERT(!aThread); MOZ_ASSERT(!aPlatformData); StackWalkInitCriticalAddress(); // Get the frame pointer void **bp; #if defined(__i386) __asm__( "movl %%ebp, %0" : "=g"(bp)); #else // It would be nice if this worked uniformly, but at least on i386 and // x86_64, it stopped working with gcc 4.1, because it points to the // end of the saved registers instead of the start. bp = (void**) __builtin_frame_address(0); #endif void *stackEnd; #if HAVE___LIBC_STACK_END stackEnd = __libc_stack_end; #else stackEnd = reinterpret_cast(-1); #endif return FramePointerStackWalk(aCallback, aSkipFrames, aMaxFrames, aClosure, bp, stackEnd); } #elif defined(HAVE__UNWIND_BACKTRACE) // libgcc_s.so symbols _Unwind_Backtrace@@GCC_3.3 and _Unwind_GetIP@@GCC_3.0 #include struct unwind_info { NS_WalkStackCallback callback; int skip; int maxFrames; int numFrames; bool isCriticalAbort; void *closure; }; static _Unwind_Reason_Code unwind_callback (struct _Unwind_Context *context, void *closure) { unwind_info *info = static_cast(closure); void *pc = reinterpret_cast(_Unwind_GetIP(context)); // TODO Use something like '_Unwind_GetGR()' to get the stack pointer. if (IsCriticalAddress(pc)) { printf("Aborting stack trace, PC is critical\n"); info->isCriticalAbort = true; // We just want to stop the walk, so any error code will do. Using // _URC_NORMAL_STOP would probably be the most accurate, but it is not // defined on Android for ARM. return _URC_FOREIGN_EXCEPTION_CAUGHT; } if (--info->skip < 0) { (*info->callback)(pc, nullptr, info->closure); info->numFrames++; if (info->maxFrames != 0 && info->numFrames == info->maxFrames) { // Again, any error code that stops the walk will do. return _URC_FOREIGN_EXCEPTION_CAUGHT; } } return _URC_NO_REASON; } EXPORT_XPCOM_API(nsresult) NS_StackWalk(NS_WalkStackCallback aCallback, uint32_t aSkipFrames, uint32_t aMaxFrames, void *aClosure, uintptr_t aThread, void *aPlatformData) { MOZ_ASSERT(!aThread); MOZ_ASSERT(!aPlatformData); StackWalkInitCriticalAddress(); unwind_info info; info.callback = aCallback; info.skip = aSkipFrames + 1; info.maxFrames = aMaxFrames; info.numFrames = 0; info.isCriticalAbort = false; info.closure = aClosure; (void)_Unwind_Backtrace(unwind_callback, &info); // We ignore the return value from _Unwind_Backtrace and instead determine // the outcome from |info|. There are two main reasons for this: // - On ARM/Android bionic's _Unwind_Backtrace usually (always?) returns // _URC_FAILURE. See // https://bugzilla.mozilla.org/show_bug.cgi?id=717853#c110. // - If aMaxFrames != 0, we want to stop early, and the only way to do that // is to make unwind_callback return something other than _URC_NO_REASON, // which causes _Unwind_Backtrace to return a non-success code. if (info.isCriticalAbort) return NS_ERROR_UNEXPECTED; return info.numFrames == 0 ? NS_ERROR_FAILURE : NS_OK; } #endif EXPORT_XPCOM_API(nsresult) NS_DescribeCodeAddress(void *aPC, nsCodeAddressDetails *aDetails) { aDetails->library[0] = '\0'; aDetails->loffset = 0; aDetails->filename[0] = '\0'; aDetails->lineno = 0; aDetails->function[0] = '\0'; aDetails->foffset = 0; Dl_info info; int ok = dladdr(aPC, &info); if (!ok) { return NS_OK; } PL_strncpyz(aDetails->library, info.dli_fname, sizeof(aDetails->library)); aDetails->loffset = (char*)aPC - (char*)info.dli_fbase; const char * symbol = info.dli_sname; if (!symbol || symbol[0] == '\0') { return NS_OK; } DemangleSymbol(symbol, aDetails->function, sizeof(aDetails->function)); if (aDetails->function[0] == '\0') { // Just use the mangled symbol if demangling failed. PL_strncpyz(aDetails->function, symbol, sizeof(aDetails->function)); } aDetails->foffset = (char*)aPC - (char*)info.dli_saddr; return NS_OK; } EXPORT_XPCOM_API(nsresult) NS_FormatCodeAddressDetails(void *aPC, const nsCodeAddressDetails *aDetails, char *aBuffer, uint32_t aBufferSize) { if (!aDetails->library[0]) { snprintf(aBuffer, aBufferSize, "UNKNOWN %p\n", aPC); } else if (!aDetails->function[0]) { snprintf(aBuffer, aBufferSize, "UNKNOWN [%s +0x%08" PRIXPTR "]\n", aDetails->library, aDetails->loffset); } else { snprintf(aBuffer, aBufferSize, "%s+0x%08" PRIXPTR " [%s +0x%08" PRIXPTR "]\n", aDetails->function, aDetails->foffset, aDetails->library, aDetails->loffset); } return NS_OK; } #endif #else // unsupported platform. EXPORT_XPCOM_API(nsresult) NS_StackWalk(NS_WalkStackCallback aCallback, uint32_t aSkipFrames, uint32_t aMaxFrames, void *aClosure, uintptr_t aThread, void *aPlatformData) { MOZ_ASSERT(!aThread); MOZ_ASSERT(!aPlatformData); return NS_ERROR_NOT_IMPLEMENTED; } namespace mozilla { nsresult FramePointerStackWalk(NS_WalkStackCallback aCallback, uint32_t aSkipFrames, void *aClosure, void **bp) { return NS_ERROR_NOT_IMPLEMENTED; } } EXPORT_XPCOM_API(nsresult) NS_DescribeCodeAddress(void *aPC, nsCodeAddressDetails *aDetails) { aDetails->library[0] = '\0'; aDetails->loffset = 0; aDetails->filename[0] = '\0'; aDetails->lineno = 0; aDetails->function[0] = '\0'; aDetails->foffset = 0; return NS_ERROR_NOT_IMPLEMENTED; } EXPORT_XPCOM_API(nsresult) NS_FormatCodeAddressDetails(void *aPC, const nsCodeAddressDetails *aDetails, char *aBuffer, uint32_t aBufferSize) { aBuffer[0] = '\0'; return NS_ERROR_NOT_IMPLEMENTED; } #endif