//===-- sanitizer_common_libcdep.cc ---------------------------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file is shared between AddressSanitizer and ThreadSanitizer // run-time libraries. //===----------------------------------------------------------------------===// #include "sanitizer_common.h" #include "sanitizer_allocator_interface.h" #include "sanitizer_file.h" #include "sanitizer_flags.h" #include "sanitizer_procmaps.h" #include "sanitizer_report_decorator.h" #include "sanitizer_stackdepot.h" #include "sanitizer_stacktrace.h" #include "sanitizer_symbolizer.h" #if SANITIZER_POSIX #include "sanitizer_posix.h" #endif namespace __sanitizer { #if !SANITIZER_FUCHSIA bool ReportFile::SupportsColors() { SpinMutexLock l(mu); ReopenIfNecessary(); return SupportsColoredOutput(fd); } static INLINE bool ReportSupportsColors() { return report_file.SupportsColors(); } #else // SANITIZER_FUCHSIA // Fuchsia's logs always go through post-processing that handles colorization. static INLINE bool ReportSupportsColors() { return true; } #endif // !SANITIZER_FUCHSIA bool ColorizeReports() { // FIXME: Add proper Windows support to AnsiColorDecorator and re-enable color // printing on Windows. if (SANITIZER_WINDOWS) return false; const char *flag = common_flags()->color; return internal_strcmp(flag, "always") == 0 || (internal_strcmp(flag, "auto") == 0 && ReportSupportsColors()); } static void (*sandboxing_callback)(); void SetSandboxingCallback(void (*f)()) { sandboxing_callback = f; } void ReportErrorSummary(const char *error_type, const StackTrace *stack, const char *alt_tool_name) { #if !SANITIZER_GO if (!common_flags()->print_summary) return; if (stack->size == 0) { ReportErrorSummary(error_type); return; } // Currently, we include the first stack frame into the report summary. // Maybe sometimes we need to choose another frame (e.g. skip memcpy/etc). uptr pc = StackTrace::GetPreviousInstructionPc(stack->trace[0]); SymbolizedStack *frame = Symbolizer::GetOrInit()->SymbolizePC(pc); ReportErrorSummary(error_type, frame->info, alt_tool_name); frame->ClearAll(); #endif } static void (*SoftRssLimitExceededCallback)(bool exceeded); void SetSoftRssLimitExceededCallback(void (*Callback)(bool exceeded)) { CHECK_EQ(SoftRssLimitExceededCallback, nullptr); SoftRssLimitExceededCallback = Callback; } #if SANITIZER_LINUX && !SANITIZER_GO void BackgroundThread(void *arg) { uptr hard_rss_limit_mb = common_flags()->hard_rss_limit_mb; uptr soft_rss_limit_mb = common_flags()->soft_rss_limit_mb; bool heap_profile = common_flags()->heap_profile; uptr prev_reported_rss = 0; uptr prev_reported_stack_depot_size = 0; bool reached_soft_rss_limit = false; uptr rss_during_last_reported_profile = 0; while (true) { SleepForMillis(100); uptr current_rss_mb = GetRSS() >> 20; if (Verbosity()) { // If RSS has grown 10% since last time, print some information. if (prev_reported_rss * 11 / 10 < current_rss_mb) { Printf("%s: RSS: %zdMb\n", SanitizerToolName, current_rss_mb); prev_reported_rss = current_rss_mb; } // If stack depot has grown 10% since last time, print it too. StackDepotStats *stack_depot_stats = StackDepotGetStats(); if (prev_reported_stack_depot_size * 11 / 10 < stack_depot_stats->allocated) { Printf("%s: StackDepot: %zd ids; %zdM allocated\n", SanitizerToolName, stack_depot_stats->n_uniq_ids, stack_depot_stats->allocated >> 20); prev_reported_stack_depot_size = stack_depot_stats->allocated; } } // Check RSS against the limit. if (hard_rss_limit_mb && hard_rss_limit_mb < current_rss_mb) { Report("%s: hard rss limit exhausted (%zdMb vs %zdMb)\n", SanitizerToolName, hard_rss_limit_mb, current_rss_mb); DumpProcessMap(); Die(); } if (soft_rss_limit_mb) { if (soft_rss_limit_mb < current_rss_mb && !reached_soft_rss_limit) { reached_soft_rss_limit = true; Report("%s: soft rss limit exhausted (%zdMb vs %zdMb)\n", SanitizerToolName, soft_rss_limit_mb, current_rss_mb); if (SoftRssLimitExceededCallback) SoftRssLimitExceededCallback(true); } else if (soft_rss_limit_mb >= current_rss_mb && reached_soft_rss_limit) { reached_soft_rss_limit = false; if (SoftRssLimitExceededCallback) SoftRssLimitExceededCallback(false); } } if (heap_profile && current_rss_mb > rss_during_last_reported_profile * 1.1) { Printf("\n\nHEAP PROFILE at RSS %zdMb\n", current_rss_mb); __sanitizer_print_memory_profile(90, 20); rss_during_last_reported_profile = current_rss_mb; } } } #endif #if !SANITIZER_FUCHSIA && !SANITIZER_GO void StartReportDeadlySignal() { // Write the first message using fd=2, just in case. // It may actually fail to write in case stderr is closed. CatastrophicErrorWrite(SanitizerToolName, internal_strlen(SanitizerToolName)); static const char kDeadlySignal[] = ":DEADLYSIGNAL\n"; CatastrophicErrorWrite(kDeadlySignal, sizeof(kDeadlySignal) - 1); } static void MaybeReportNonExecRegion(uptr pc) { #if SANITIZER_FREEBSD || SANITIZER_LINUX || SANITIZER_NETBSD MemoryMappingLayout proc_maps(/*cache_enabled*/ true); MemoryMappedSegment segment; while (proc_maps.Next(&segment)) { if (pc >= segment.start && pc < segment.end && !segment.IsExecutable()) Report("Hint: PC is at a non-executable region. Maybe a wild jump?\n"); } #endif } static void PrintMemoryByte(InternalScopedString *str, const char *before, u8 byte) { SanitizerCommonDecorator d; str->append("%s%s%x%x%s ", before, d.MemoryByte(), byte >> 4, byte & 15, d.Default()); } static void MaybeDumpInstructionBytes(uptr pc) { if (!common_flags()->dump_instruction_bytes || (pc < GetPageSizeCached())) return; InternalScopedString str(1024); str.append("First 16 instruction bytes at pc: "); if (IsAccessibleMemoryRange(pc, 16)) { for (int i = 0; i < 16; ++i) { PrintMemoryByte(&str, "", ((u8 *)pc)[i]); } str.append("\n"); } else { str.append("unaccessible\n"); } Report("%s", str.data()); } static void MaybeDumpRegisters(void *context) { if (!common_flags()->dump_registers) return; SignalContext::DumpAllRegisters(context); } static void ReportStackOverflowImpl(const SignalContext &sig, u32 tid, UnwindSignalStackCallbackType unwind, const void *unwind_context) { SanitizerCommonDecorator d; Printf("%s", d.Warning()); static const char kDescription[] = "stack-overflow"; Report("ERROR: %s: %s on address %p (pc %p bp %p sp %p T%d)\n", SanitizerToolName, kDescription, (void *)sig.addr, (void *)sig.pc, (void *)sig.bp, (void *)sig.sp, tid); Printf("%s", d.Default()); InternalScopedBuffer stack_buffer(1); BufferedStackTrace *stack = stack_buffer.data(); stack->Reset(); unwind(sig, unwind_context, stack); stack->Print(); ReportErrorSummary(kDescription, stack); } static void ReportDeadlySignalImpl(const SignalContext &sig, u32 tid, UnwindSignalStackCallbackType unwind, const void *unwind_context) { SanitizerCommonDecorator d; Printf("%s", d.Warning()); const char *description = sig.Describe(); Report("ERROR: %s: %s on unknown address %p (pc %p bp %p sp %p T%d)\n", SanitizerToolName, description, (void *)sig.addr, (void *)sig.pc, (void *)sig.bp, (void *)sig.sp, tid); Printf("%s", d.Default()); if (sig.pc < GetPageSizeCached()) Report("Hint: pc points to the zero page.\n"); if (sig.is_memory_access) { const char *access_type = sig.write_flag == SignalContext::WRITE ? "WRITE" : (sig.write_flag == SignalContext::READ ? "READ" : "UNKNOWN"); Report("The signal is caused by a %s memory access.\n", access_type); if (sig.addr < GetPageSizeCached()) Report("Hint: address points to the zero page.\n"); } MaybeReportNonExecRegion(sig.pc); InternalScopedBuffer stack_buffer(1); BufferedStackTrace *stack = stack_buffer.data(); stack->Reset(); unwind(sig, unwind_context, stack); stack->Print(); MaybeDumpInstructionBytes(sig.pc); MaybeDumpRegisters(sig.context); Printf("%s can not provide additional info.\n", SanitizerToolName); ReportErrorSummary(description, stack); } void ReportDeadlySignal(const SignalContext &sig, u32 tid, UnwindSignalStackCallbackType unwind, const void *unwind_context) { if (sig.IsStackOverflow()) ReportStackOverflowImpl(sig, tid, unwind, unwind_context); else ReportDeadlySignalImpl(sig, tid, unwind, unwind_context); } void HandleDeadlySignal(void *siginfo, void *context, u32 tid, UnwindSignalStackCallbackType unwind, const void *unwind_context) { StartReportDeadlySignal(); ScopedErrorReportLock rl; SignalContext sig(siginfo, context); ReportDeadlySignal(sig, tid, unwind, unwind_context); Report("ABORTING\n"); Die(); } #endif // !SANITIZER_FUCHSIA && !SANITIZER_GO void WriteToSyslog(const char *msg) { InternalScopedString msg_copy(kErrorMessageBufferSize); msg_copy.append("%s", msg); char *p = msg_copy.data(); char *q; // Print one line at a time. // syslog, at least on Android, has an implicit message length limit. do { q = internal_strchr(p, '\n'); if (q) *q = '\0'; WriteOneLineToSyslog(p); if (q) p = q + 1; } while (q); } void MaybeStartBackgroudThread() { #if SANITIZER_LINUX && \ !SANITIZER_GO // Need to implement/test on other platforms. // Start the background thread if one of the rss limits is given. if (!common_flags()->hard_rss_limit_mb && !common_flags()->soft_rss_limit_mb && !common_flags()->heap_profile) return; if (!&real_pthread_create) return; // Can't spawn the thread anyway. internal_start_thread(BackgroundThread, nullptr); #endif } static atomic_uintptr_t reporting_thread = {0}; static StaticSpinMutex CommonSanitizerReportMutex; ScopedErrorReportLock::ScopedErrorReportLock() { uptr current = GetThreadSelf(); for (;;) { uptr expected = 0; if (atomic_compare_exchange_strong(&reporting_thread, &expected, current, memory_order_relaxed)) { // We've claimed reporting_thread so proceed. CommonSanitizerReportMutex.Lock(); return; } if (expected == current) { // This is either asynch signal or nested error during error reporting. // Fail simple to avoid deadlocks in Report(). // Can't use Report() here because of potential deadlocks in nested // signal handlers. CatastrophicErrorWrite(SanitizerToolName, internal_strlen(SanitizerToolName)); static const char msg[] = ": nested bug in the same thread, aborting.\n"; CatastrophicErrorWrite(msg, sizeof(msg) - 1); internal__exit(common_flags()->exitcode); } internal_sched_yield(); } } ScopedErrorReportLock::~ScopedErrorReportLock() { CommonSanitizerReportMutex.Unlock(); atomic_store_relaxed(&reporting_thread, 0); } void ScopedErrorReportLock::CheckLocked() { CommonSanitizerReportMutex.CheckLocked(); } } // namespace __sanitizer SANITIZER_INTERFACE_WEAK_DEF(void, __sanitizer_sandbox_on_notify, __sanitizer_sandbox_arguments *args) { __sanitizer::PrepareForSandboxing(args); if (__sanitizer::sandboxing_callback) __sanitizer::sandboxing_callback(); }