//===--- Errors.cpp - Error reporting utilities ---------------------------===// // // This source file is part of the Swift.org open source project // // Copyright (c) 2014 - 2017 Apple Inc. and the Swift project authors // Licensed under Apache License v2.0 with Runtime Library Exception // // See https://swift.org/LICENSE.txt for license information // See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors // //===----------------------------------------------------------------------===// // // Utilities for reporting errors to stderr, system console, and crash logs. // //===----------------------------------------------------------------------===// #if defined(__CYGWIN__) || defined(__ANDROID__) || defined(_WIN32) # define SWIFT_SUPPORTS_BACKTRACE_REPORTING 0 #else # define SWIFT_SUPPORTS_BACKTRACE_REPORTING 1 #endif #include #include #include #include #if defined(_WIN32) #include #else #include #endif #include #include "ImageInspection.h" #include "swift/Runtime/Debug.h" #include "swift/Runtime/Mutex.h" #include "swift/Demangling/Demangle.h" #include "swift/Basic/LLVM.h" #include "llvm/ADT/StringRef.h" #if !defined(_MSC_VER) #include #endif #if SWIFT_SUPPORTS_BACKTRACE_REPORTING // execinfo.h is not available on Android. Checks in this file ensure that // fatalError behaves as expected, but without stack traces. #include #endif #if defined(__APPLE__) #include #elif defined(__ANDROID__) #include #endif namespace FatalErrorFlags { enum: uint32_t { ReportBacktrace = 1 << 0 }; } // end namespace FatalErrorFlags using namespace swift; static bool getSymbolNameAddr(llvm::StringRef libraryName, SymbolInfo syminfo, std::string &symbolName, uintptr_t &addrOut) { // If we failed to find a symbol and thus dlinfo->dli_sname is nullptr, we // need to use the hex address. bool hasUnavailableAddress = syminfo.symbolName == nullptr; if (hasUnavailableAddress) { return false; } // Ok, now we know that we have some sort of "real" name. Set the outAddr. addrOut = uintptr_t(syminfo.symbolAddress); // First lets try to demangle using cxxabi. If this fails, we will try to // demangle with swift. We are taking advantage of __cxa_demangle actually // providing failure status instead of just returning the original string like // swift demangle. int status; char *demangled = abi::__cxa_demangle(syminfo.symbolName, 0, 0, &status); if (status == 0) { assert(demangled != nullptr && "If __cxa_demangle succeeds, demangled " "should never be nullptr"); symbolName += demangled; free(demangled); return true; } assert(demangled == nullptr && "If __cxa_demangle fails, demangled should " "be a nullptr"); // Otherwise, try to demangle with swift. If swift fails to demangle, it will // just pass through the original output. symbolName = demangleSymbolAsString( syminfo.symbolName, strlen(syminfo.symbolName), Demangle::DemangleOptions::SimplifiedUIDemangleOptions()); return true; } void swift::dumpStackTraceEntry(unsigned index, void *framePC, bool shortOutput) { #if SWIFT_SUPPORTS_BACKTRACE_REPORTING SymbolInfo syminfo; // 0 is failure for lookupSymbol if (0 == lookupSymbol(framePC, &syminfo)) { return; } // If lookupSymbol succeeded then fileName is non-null. Thus, we find the // library name here. StringRef libraryName = StringRef(syminfo.fileName).rsplit('/').second; // Next we get the symbol name that we are going to use in our backtrace. std::string symbolName; // We initialize symbolAddr to framePC so that if we succeed in finding the // symbol, we get the offset in the function and if we fail to find the symbol // we just get HexAddr + 0. uintptr_t symbolAddr = uintptr_t(framePC); bool foundSymbol = getSymbolNameAddr(libraryName, syminfo, symbolName, symbolAddr); ptrdiff_t offset = 0; if (foundSymbol) { offset = ptrdiff_t(uintptr_t(framePC) - symbolAddr); } else { offset = ptrdiff_t(uintptr_t(framePC) - uintptr_t(syminfo.baseAddress)); symbolAddr = uintptr_t(framePC); symbolName = ""; } // We do not use %p here for our pointers since the format is implementation // defined. This makes it logically impossible to check the output. Forcing // hexadecimal solves this issue. // If the symbol is not available, we print out + offset // from the base address of where the image containing framePC is mapped. // This gives enough info to reconstruct identical debugging target after // this process terminates. if (shortOutput) { fprintf(stderr, "%s`%s + %td", libraryName.data(), symbolName.c_str(), offset); } else { constexpr const char *format = "%-4u %-34s 0x%0.16lx %s + %td\n"; fprintf(stderr, format, index, libraryName.data(), symbolAddr, symbolName.c_str(), offset); } #else if (shortOutput) { fprintf(stderr, ""); } else { constexpr const char *format = "%-4u 0x%0.16lx\n"; fprintf(stderr, format, index, framePC); } #endif } LLVM_ATTRIBUTE_NOINLINE void swift::printCurrentBacktrace(unsigned framesToSkip) { #if SWIFT_SUPPORTS_BACKTRACE_REPORTING constexpr unsigned maxSupportedStackDepth = 128; void *addrs[maxSupportedStackDepth]; int symbolCount = backtrace(addrs, maxSupportedStackDepth); for (int i = framesToSkip; i < symbolCount; ++i) { dumpStackTraceEntry(i - framesToSkip, addrs[i]); } #else fprintf(stderr, "\n"); #endif } #ifdef SWIFT_HAVE_CRASHREPORTERCLIENT #include // Instead of linking to CrashReporterClient.a (because it complicates the // build system), define the only symbol from that static archive ourselves. // // The layout of this struct is CrashReporter ABI, so there are no ABI concerns // here. extern "C" { LLVM_LIBRARY_VISIBILITY struct crashreporter_annotations_t gCRAnnotations __attribute__((__section__("__DATA," CRASHREPORTER_ANNOTATIONS_SECTION))) = { CRASHREPORTER_ANNOTATIONS_VERSION, 0, 0, 0, 0, 0, 0, 0}; } // Report a message to any forthcoming crash log. static void reportOnCrash(uint32_t flags, const char *message) { // We must use an "unsafe" mutex in this pathway since the normal "safe" // mutex calls fatalError when an error is detected and fatalError ends up // calling us. In other words we could get infinite recursion if the // mutex errors. static swift::StaticUnsafeMutex crashlogLock; crashlogLock.lock(); char *oldMessage = (char *)CRGetCrashLogMessage(); char *newMessage; if (oldMessage) { asprintf(&newMessage, "%s%s", oldMessage, message); if (malloc_size(oldMessage)) free(oldMessage); } else { newMessage = strdup(message); } CRSetCrashLogMessage(newMessage); crashlogLock.unlock(); } #else static void reportOnCrash(uint32_t flags, const char *message) { // empty } #endif // Report a message to system console and stderr. static void reportNow(uint32_t flags, const char *message) { #if defined(_WIN32) #define STDERR_FILENO 2 _write(STDERR_FILENO, message, strlen(message)); #else write(STDERR_FILENO, message, strlen(message)); #endif #if defined(__APPLE__) asl_log(nullptr, nullptr, ASL_LEVEL_ERR, "%s", message); #elif defined(__ANDROID__) __android_log_print(ANDROID_LOG_FATAL, "SwiftRuntime", "%s", message); #endif #if SWIFT_SUPPORTS_BACKTRACE_REPORTING if (flags & FatalErrorFlags::ReportBacktrace) { fputs("Current stack trace:\n", stderr); printCurrentBacktrace(); } #endif } /// Report a fatal error to system console, stderr, and crash logs. /// Does not crash by itself. void swift::swift_reportError(uint32_t flags, const char *message) { #if NDEBUG flags &= ~FatalErrorFlags::ReportBacktrace; #endif reportNow(flags, message); reportOnCrash(flags, message); } static int swift_vasprintf(char **strp, const char *fmt, va_list ap) { #if defined(_WIN32) int len = _vscprintf(fmt, ap); if (len < 0) return -1; char *buffer = reinterpret_cast(malloc(len + 1)); if (!buffer) return -1; int result = vsprintf(buffer, fmt, ap); if (result < 0) { free(buffer); return -1; } *strp = buffer; return result; #else return vasprintf(strp, fmt, ap); #endif } // Report a fatal error to system console, stderr, and crash logs, then abort. LLVM_ATTRIBUTE_NORETURN void swift::fatalError(uint32_t flags, const char *format, ...) { va_list args; va_start(args, format); char *log; swift_vasprintf(&log, format, args); swift_reportError(flags, log); abort(); } // Report a warning to system console and stderr. void swift::warning(uint32_t flags, const char *format, ...) { va_list args; va_start(args, format); char *log; swift_vasprintf(&log, format, args); reportNow(flags, log); free(log); } // Crash when a deleted method is called by accident. SWIFT_RUNTIME_EXPORT LLVM_ATTRIBUTE_NORETURN void swift_deletedMethodError() { swift::fatalError(/* flags = */ 0, "fatal error: call of deleted method\n"); } // Crash due to a retain count overflow. // FIXME: can't pass the object's address from InlineRefCounts without hacks void swift::swift_abortRetainOverflow() { swift::fatalError(FatalErrorFlags::ReportBacktrace, "fatal error: object was retained too many times"); } // Crash due to retain of a dead unowned reference. // FIXME: can't pass the object's address from InlineRefCounts without hacks void swift::swift_abortRetainUnowned(const void *object) { if (object) { swift::fatalError(FatalErrorFlags::ReportBacktrace, "fatal error: attempted to read an unowned reference but " "object %p was already deallocated", object); } else { swift::fatalError(FatalErrorFlags::ReportBacktrace, "fatal error: attempted to read an unowned reference but " "the object was already deallocated"); } }