//===-- asan_report.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 a part of AddressSanitizer, an address sanity checker. // // This file contains error reporting code. //===----------------------------------------------------------------------===// #include "asan_flags.h" #include "asan_internal.h" #include "asan_mapping.h" #include "asan_report.h" #include "asan_scariness_score.h" #include "asan_stack.h" #include "asan_thread.h" #include "sanitizer_common/sanitizer_common.h" #include "sanitizer_common/sanitizer_flags.h" #include "sanitizer_common/sanitizer_report_decorator.h" #include "sanitizer_common/sanitizer_stackdepot.h" #include "sanitizer_common/sanitizer_symbolizer.h" namespace __asan { // -------------------- User-specified callbacks ----------------- {{{1 static void (*error_report_callback)(const char*); static char *error_message_buffer = nullptr; static uptr error_message_buffer_pos = 0; static BlockingMutex error_message_buf_mutex(LINKER_INITIALIZED); static const unsigned kAsanBuggyPcPoolSize = 25; static __sanitizer::atomic_uintptr_t AsanBuggyPcPool[kAsanBuggyPcPoolSize]; struct ReportData { uptr pc; uptr sp; uptr bp; uptr addr; bool is_write; uptr access_size; const char *description; }; static bool report_happened = false; static ReportData report_data = {}; void AppendToErrorMessageBuffer(const char *buffer) { BlockingMutexLock l(&error_message_buf_mutex); if (!error_message_buffer) { error_message_buffer = (char*)MmapOrDieQuietly(kErrorMessageBufferSize, __func__); error_message_buffer_pos = 0; } uptr length = internal_strlen(buffer); RAW_CHECK(kErrorMessageBufferSize >= error_message_buffer_pos); uptr remaining = kErrorMessageBufferSize - error_message_buffer_pos; internal_strncpy(error_message_buffer + error_message_buffer_pos, buffer, remaining); error_message_buffer[kErrorMessageBufferSize - 1] = '\0'; // FIXME: reallocate the buffer instead of truncating the message. error_message_buffer_pos += Min(remaining, length); } // ---------------------- Decorator ------------------------------ {{{1 class Decorator: public __sanitizer::SanitizerCommonDecorator { public: Decorator() : SanitizerCommonDecorator() { } const char *Access() { return Blue(); } const char *EndAccess() { return Default(); } const char *Location() { return Green(); } const char *EndLocation() { return Default(); } const char *Allocation() { return Magenta(); } const char *EndAllocation() { return Default(); } const char *ShadowByte(u8 byte) { switch (byte) { case kAsanHeapLeftRedzoneMagic: case kAsanHeapRightRedzoneMagic: case kAsanArrayCookieMagic: return Red(); case kAsanHeapFreeMagic: return Magenta(); case kAsanStackLeftRedzoneMagic: case kAsanStackMidRedzoneMagic: case kAsanStackRightRedzoneMagic: case kAsanStackPartialRedzoneMagic: return Red(); case kAsanStackAfterReturnMagic: return Magenta(); case kAsanInitializationOrderMagic: return Cyan(); case kAsanUserPoisonedMemoryMagic: case kAsanContiguousContainerOOBMagic: case kAsanAllocaLeftMagic: case kAsanAllocaRightMagic: return Blue(); case kAsanStackUseAfterScopeMagic: return Magenta(); case kAsanGlobalRedzoneMagic: return Red(); case kAsanInternalHeapMagic: return Yellow(); case kAsanIntraObjectRedzone: return Yellow(); default: return Default(); } } const char *EndShadowByte() { return Default(); } const char *MemoryByte() { return Magenta(); } const char *EndMemoryByte() { return Default(); } }; // ---------------------- Helper functions ----------------------- {{{1 static void PrintMemoryByte(InternalScopedString *str, const char *before, u8 byte, bool in_shadow, const char *after = "\n") { Decorator d; str->append("%s%s%x%x%s%s", before, in_shadow ? d.ShadowByte(byte) : d.MemoryByte(), byte >> 4, byte & 15, in_shadow ? d.EndShadowByte() : d.EndMemoryByte(), after); } static void PrintShadowByte(InternalScopedString *str, const char *before, u8 byte, const char *after = "\n") { PrintMemoryByte(str, before, byte, /*in_shadow*/true, after); } static void PrintShadowBytes(InternalScopedString *str, const char *before, u8 *bytes, u8 *guilty, uptr n) { Decorator d; if (before) str->append("%s%p:", before, bytes); for (uptr i = 0; i < n; i++) { u8 *p = bytes + i; const char *before = p == guilty ? "[" : (p - 1 == guilty && i != 0) ? "" : " "; const char *after = p == guilty ? "]" : ""; PrintShadowByte(str, before, *p, after); } str->append("\n"); } static void PrintLegend(InternalScopedString *str) { str->append( "Shadow byte legend (one shadow byte represents %d " "application bytes):\n", (int)SHADOW_GRANULARITY); PrintShadowByte(str, " Addressable: ", 0); str->append(" Partially addressable: "); for (u8 i = 1; i < SHADOW_GRANULARITY; i++) PrintShadowByte(str, "", i, " "); str->append("\n"); PrintShadowByte(str, " Heap left redzone: ", kAsanHeapLeftRedzoneMagic); PrintShadowByte(str, " Heap right redzone: ", kAsanHeapRightRedzoneMagic); PrintShadowByte(str, " Freed heap region: ", kAsanHeapFreeMagic); PrintShadowByte(str, " Stack left redzone: ", kAsanStackLeftRedzoneMagic); PrintShadowByte(str, " Stack mid redzone: ", kAsanStackMidRedzoneMagic); PrintShadowByte(str, " Stack right redzone: ", kAsanStackRightRedzoneMagic); PrintShadowByte(str, " Stack partial redzone: ", kAsanStackPartialRedzoneMagic); PrintShadowByte(str, " Stack after return: ", kAsanStackAfterReturnMagic); PrintShadowByte(str, " Stack use after scope: ", kAsanStackUseAfterScopeMagic); PrintShadowByte(str, " Global redzone: ", kAsanGlobalRedzoneMagic); PrintShadowByte(str, " Global init order: ", kAsanInitializationOrderMagic); PrintShadowByte(str, " Poisoned by user: ", kAsanUserPoisonedMemoryMagic); PrintShadowByte(str, " Container overflow: ", kAsanContiguousContainerOOBMagic); PrintShadowByte(str, " Array cookie: ", kAsanArrayCookieMagic); PrintShadowByte(str, " Intra object redzone: ", kAsanIntraObjectRedzone); PrintShadowByte(str, " ASan internal: ", kAsanInternalHeapMagic); PrintShadowByte(str, " Left alloca redzone: ", kAsanAllocaLeftMagic); PrintShadowByte(str, " Right alloca redzone: ", kAsanAllocaRightMagic); } void MaybeDumpInstructionBytes(uptr pc) { if (!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], /*in_shadow*/false, " "); } str.append("\n"); } else { str.append("unaccessible\n"); } Report("%s", str.data()); } static void PrintShadowMemoryForAddress(uptr addr) { if (!AddrIsInMem(addr)) return; uptr shadow_addr = MemToShadow(addr); const uptr n_bytes_per_row = 16; uptr aligned_shadow = shadow_addr & ~(n_bytes_per_row - 1); InternalScopedString str(4096 * 8); str.append("Shadow bytes around the buggy address:\n"); for (int i = -5; i <= 5; i++) { const char *prefix = (i == 0) ? "=>" : " "; PrintShadowBytes(&str, prefix, (u8 *)(aligned_shadow + i * n_bytes_per_row), (u8 *)shadow_addr, n_bytes_per_row); } if (flags()->print_legend) PrintLegend(&str); Printf("%s", str.data()); } static void PrintZoneForPointer(uptr ptr, uptr zone_ptr, const char *zone_name) { if (zone_ptr) { if (zone_name) { Printf("malloc_zone_from_ptr(%p) = %p, which is %s\n", ptr, zone_ptr, zone_name); } else { Printf("malloc_zone_from_ptr(%p) = %p, which doesn't have a name\n", ptr, zone_ptr); } } else { Printf("malloc_zone_from_ptr(%p) = 0\n", ptr); } } static void DescribeThread(AsanThread *t) { if (t) DescribeThread(t->context()); } // ---------------------- Address Descriptions ------------------- {{{1 static bool IsASCII(unsigned char c) { return /*0x00 <= c &&*/ c <= 0x7F; } static const char *MaybeDemangleGlobalName(const char *name) { // We can spoil names of globals with C linkage, so use an heuristic // approach to check if the name should be demangled. bool should_demangle = false; if (name[0] == '_' && name[1] == 'Z') should_demangle = true; else if (SANITIZER_WINDOWS && name[0] == '\01' && name[1] == '?') should_demangle = true; return should_demangle ? Symbolizer::GetOrInit()->Demangle(name) : name; } // Check if the global is a zero-terminated ASCII string. If so, print it. static void PrintGlobalNameIfASCII(InternalScopedString *str, const __asan_global &g) { for (uptr p = g.beg; p < g.beg + g.size - 1; p++) { unsigned char c = *(unsigned char*)p; if (c == '\0' || !IsASCII(c)) return; } if (*(char*)(g.beg + g.size - 1) != '\0') return; str->append(" '%s' is ascii string '%s'\n", MaybeDemangleGlobalName(g.name), (char *)g.beg); } static const char *GlobalFilename(const __asan_global &g) { const char *res = g.module_name; // Prefer the filename from source location, if is available. if (g.location) res = g.location->filename; CHECK(res); return res; } static void PrintGlobalLocation(InternalScopedString *str, const __asan_global &g) { str->append("%s", GlobalFilename(g)); if (!g.location) return; if (g.location->line_no) str->append(":%d", g.location->line_no); if (g.location->column_no) str->append(":%d", g.location->column_no); } static void DescribeAddressRelativeToGlobal(uptr addr, uptr size, const __asan_global &g) { InternalScopedString str(4096); Decorator d; str.append("%s", d.Location()); if (addr < g.beg) { str.append("%p is located %zd bytes to the left", (void *)addr, g.beg - addr); } else if (addr + size > g.beg + g.size) { if (addr < g.beg + g.size) addr = g.beg + g.size; str.append("%p is located %zd bytes to the right", (void *)addr, addr - (g.beg + g.size)); } else { // Can it happen? str.append("%p is located %zd bytes inside", (void *)addr, addr - g.beg); } str.append(" of global variable '%s' defined in '", MaybeDemangleGlobalName(g.name)); PrintGlobalLocation(&str, g); str.append("' (0x%zx) of size %zu\n", g.beg, g.size); str.append("%s", d.EndLocation()); PrintGlobalNameIfASCII(&str, g); Printf("%s", str.data()); } static bool DescribeAddressIfGlobal(uptr addr, uptr size, const char *bug_type) { // Assume address is close to at most four globals. const int kMaxGlobalsInReport = 4; __asan_global globals[kMaxGlobalsInReport]; u32 reg_sites[kMaxGlobalsInReport]; int globals_num = GetGlobalsForAddress(addr, globals, reg_sites, ARRAY_SIZE(globals)); if (globals_num == 0) return false; for (int i = 0; i < globals_num; i++) { DescribeAddressRelativeToGlobal(addr, size, globals[i]); if (0 == internal_strcmp(bug_type, "initialization-order-fiasco") && reg_sites[i]) { Printf(" registered at:\n"); StackDepotGet(reg_sites[i]).Print(); } } return true; } bool DescribeAddressIfShadow(uptr addr, AddressDescription *descr, bool print) { if (AddrIsInMem(addr)) return false; const char *area_type = nullptr; if (AddrIsInShadowGap(addr)) area_type = "shadow gap"; else if (AddrIsInHighShadow(addr)) area_type = "high shadow"; else if (AddrIsInLowShadow(addr)) area_type = "low shadow"; if (area_type != nullptr) { if (print) { Printf("Address %p is located in the %s area.\n", addr, area_type); } else { CHECK(descr); descr->region_kind = area_type; } return true; } CHECK(0 && "Address is not in memory and not in shadow?"); return false; } // Return " (thread_name) " or an empty string if the name is empty. const char *ThreadNameWithParenthesis(AsanThreadContext *t, char buff[], uptr buff_len) { const char *name = t->name; if (name[0] == '\0') return ""; buff[0] = 0; internal_strncat(buff, " (", 3); internal_strncat(buff, name, buff_len - 4); internal_strncat(buff, ")", 2); return buff; } const char *ThreadNameWithParenthesis(u32 tid, char buff[], uptr buff_len) { if (tid == kInvalidTid) return ""; asanThreadRegistry().CheckLocked(); AsanThreadContext *t = GetThreadContextByTidLocked(tid); return ThreadNameWithParenthesis(t, buff, buff_len); } static void PrintAccessAndVarIntersection(const StackVarDescr &var, uptr addr, uptr access_size, uptr prev_var_end, uptr next_var_beg) { uptr var_end = var.beg + var.size; uptr addr_end = addr + access_size; const char *pos_descr = nullptr; // If the variable [var.beg, var_end) is the nearest variable to the // current memory access, indicate it in the log. if (addr >= var.beg) { if (addr_end <= var_end) pos_descr = "is inside"; // May happen if this is a use-after-return. else if (addr < var_end) pos_descr = "partially overflows"; else if (addr_end <= next_var_beg && next_var_beg - addr_end >= addr - var_end) pos_descr = "overflows"; } else { if (addr_end > var.beg) pos_descr = "partially underflows"; else if (addr >= prev_var_end && addr - prev_var_end >= var.beg - addr_end) pos_descr = "underflows"; } InternalScopedString str(1024); str.append(" [%zd, %zd)", var.beg, var_end); // Render variable name. str.append(" '"); for (uptr i = 0; i < var.name_len; ++i) { str.append("%c", var.name_pos[i]); } str.append("'"); if (pos_descr) { Decorator d; // FIXME: we may want to also print the size of the access here, // but in case of accesses generated by memset it may be confusing. str.append("%s <== Memory access at offset %zd %s this variable%s\n", d.Location(), addr, pos_descr, d.EndLocation()); } else { str.append("\n"); } Printf("%s", str.data()); } bool ParseFrameDescription(const char *frame_descr, InternalMmapVector<StackVarDescr> *vars) { CHECK(frame_descr); char *p; // This string is created by the compiler and has the following form: // "n alloc_1 alloc_2 ... alloc_n" // where alloc_i looks like "offset size len ObjectName". uptr n_objects = (uptr)internal_simple_strtoll(frame_descr, &p, 10); if (n_objects == 0) return false; for (uptr i = 0; i < n_objects; i++) { uptr beg = (uptr)internal_simple_strtoll(p, &p, 10); uptr size = (uptr)internal_simple_strtoll(p, &p, 10); uptr len = (uptr)internal_simple_strtoll(p, &p, 10); if (beg == 0 || size == 0 || *p != ' ') { return false; } p++; StackVarDescr var = {beg, size, p, len}; vars->push_back(var); p += len; } return true; } bool DescribeAddressIfStack(uptr addr, uptr access_size) { AsanThread *t = FindThreadByStackAddress(addr); if (!t) return false; Decorator d; char tname[128]; Printf("%s", d.Location()); Printf("Address %p is located in stack of thread T%d%s", addr, t->tid(), ThreadNameWithParenthesis(t->tid(), tname, sizeof(tname))); // Try to fetch precise stack frame for this access. AsanThread::StackFrameAccess access; if (!t->GetStackFrameAccessByAddr(addr, &access)) { Printf("%s\n", d.EndLocation()); return true; } Printf(" at offset %zu in frame%s\n", access.offset, d.EndLocation()); // Now we print the frame where the alloca has happened. // We print this frame as a stack trace with one element. // The symbolizer may print more than one frame if inlining was involved. // The frame numbers may be different than those in the stack trace printed // previously. That's unfortunate, but I have no better solution, // especially given that the alloca may be from entirely different place // (e.g. use-after-scope, or different thread's stack). #if SANITIZER_PPC64V1 // On PowerPC64 ELFv1, the address of a function actually points to a // three-doubleword data structure with the first field containing // the address of the function's code. access.frame_pc = *reinterpret_cast<uptr *>(access.frame_pc); #endif access.frame_pc += 16; Printf("%s", d.EndLocation()); StackTrace alloca_stack(&access.frame_pc, 1); alloca_stack.Print(); InternalMmapVector<StackVarDescr> vars(16); if (!ParseFrameDescription(access.frame_descr, &vars)) { Printf("AddressSanitizer can't parse the stack frame " "descriptor: |%s|\n", access.frame_descr); // 'addr' is a stack address, so return true even if we can't parse frame return true; } uptr n_objects = vars.size(); // Report the number of stack objects. Printf(" This frame has %zu object(s):\n", n_objects); // Report all objects in this frame. for (uptr i = 0; i < n_objects; i++) { uptr prev_var_end = i ? vars[i - 1].beg + vars[i - 1].size : 0; uptr next_var_beg = i + 1 < n_objects ? vars[i + 1].beg : ~(0UL); PrintAccessAndVarIntersection(vars[i], access.offset, access_size, prev_var_end, next_var_beg); } Printf("HINT: this may be a false positive if your program uses " "some custom stack unwind mechanism or swapcontext\n"); if (SANITIZER_WINDOWS) Printf(" (longjmp, SEH and C++ exceptions *are* supported)\n"); else Printf(" (longjmp and C++ exceptions *are* supported)\n"); DescribeThread(t); return true; } static void DescribeAccessToHeapChunk(AsanChunkView chunk, uptr addr, uptr access_size) { sptr offset; Decorator d; InternalScopedString str(4096); str.append("%s", d.Location()); if (chunk.AddrIsAtLeft(addr, access_size, &offset)) { str.append("%p is located %zd bytes to the left of", (void *)addr, offset); } else if (chunk.AddrIsAtRight(addr, access_size, &offset)) { if (offset < 0) { addr -= offset; offset = 0; } str.append("%p is located %zd bytes to the right of", (void *)addr, offset); } else if (chunk.AddrIsInside(addr, access_size, &offset)) { str.append("%p is located %zd bytes inside of", (void*)addr, offset); } else { str.append("%p is located somewhere around (this is AddressSanitizer bug!)", (void *)addr); } str.append(" %zu-byte region [%p,%p)\n", chunk.UsedSize(), (void *)(chunk.Beg()), (void *)(chunk.End())); str.append("%s", d.EndLocation()); Printf("%s", str.data()); } void DescribeHeapAddress(uptr addr, uptr access_size) { AsanChunkView chunk = FindHeapChunkByAddress(addr); if (!chunk.IsValid()) { Printf("AddressSanitizer can not describe address in more detail " "(wild memory access suspected).\n"); return; } DescribeAccessToHeapChunk(chunk, addr, access_size); CHECK(chunk.AllocTid() != kInvalidTid); asanThreadRegistry().CheckLocked(); AsanThreadContext *alloc_thread = GetThreadContextByTidLocked(chunk.AllocTid()); StackTrace alloc_stack = chunk.GetAllocStack(); char tname[128]; Decorator d; AsanThreadContext *free_thread = nullptr; if (chunk.FreeTid() != kInvalidTid) { free_thread = GetThreadContextByTidLocked(chunk.FreeTid()); Printf("%sfreed by thread T%d%s here:%s\n", d.Allocation(), free_thread->tid, ThreadNameWithParenthesis(free_thread, tname, sizeof(tname)), d.EndAllocation()); StackTrace free_stack = chunk.GetFreeStack(); free_stack.Print(); Printf("%spreviously allocated by thread T%d%s here:%s\n", d.Allocation(), alloc_thread->tid, ThreadNameWithParenthesis(alloc_thread, tname, sizeof(tname)), d.EndAllocation()); } else { Printf("%sallocated by thread T%d%s here:%s\n", d.Allocation(), alloc_thread->tid, ThreadNameWithParenthesis(alloc_thread, tname, sizeof(tname)), d.EndAllocation()); } alloc_stack.Print(); DescribeThread(GetCurrentThread()); if (free_thread) DescribeThread(free_thread); DescribeThread(alloc_thread); } static void DescribeAddress(uptr addr, uptr access_size, const char *bug_type) { // Check if this is shadow or shadow gap. if (DescribeAddressIfShadow(addr)) return; CHECK(AddrIsInMem(addr)); if (DescribeAddressIfGlobal(addr, access_size, bug_type)) return; if (DescribeAddressIfStack(addr, access_size)) return; // Assume it is a heap address. DescribeHeapAddress(addr, access_size); } // ------------------- Thread description -------------------- {{{1 void DescribeThread(AsanThreadContext *context) { CHECK(context); asanThreadRegistry().CheckLocked(); // No need to announce the main thread. if (context->tid == 0 || context->announced) { return; } context->announced = true; char tname[128]; InternalScopedString str(1024); str.append("Thread T%d%s", context->tid, ThreadNameWithParenthesis(context->tid, tname, sizeof(tname))); if (context->parent_tid == kInvalidTid) { str.append(" created by unknown thread\n"); Printf("%s", str.data()); return; } str.append( " created by T%d%s here:\n", context->parent_tid, ThreadNameWithParenthesis(context->parent_tid, tname, sizeof(tname))); Printf("%s", str.data()); StackDepotGet(context->stack_id).Print(); // Recursively described parent thread if needed. if (flags()->print_full_thread_history) { AsanThreadContext *parent_context = GetThreadContextByTidLocked(context->parent_tid); DescribeThread(parent_context); } } // -------------------- Different kinds of reports ----------------- {{{1 // Use ScopedInErrorReport to run common actions just before and // immediately after printing error report. class ScopedInErrorReport { public: explicit ScopedInErrorReport(ReportData *report = nullptr, bool fatal = false) { halt_on_error_ = fatal || flags()->halt_on_error; if (lock_.TryLock()) { StartReporting(report); return; } // ASan found two bugs in different threads simultaneously. u32 current_tid = GetCurrentTidOrInvalid(); if (reporting_thread_tid_ == current_tid || reporting_thread_tid_ == kInvalidTid) { // 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. const char msg[] = "AddressSanitizer: nested bug in the same thread, " "aborting.\n"; WriteToFile(kStderrFd, msg, sizeof(msg)); internal__exit(common_flags()->exitcode); } if (halt_on_error_) { // Do not print more than one report, otherwise they will mix up. // Error reporting functions shouldn't return at this situation, as // they are effectively no-returns. Report("AddressSanitizer: while reporting a bug found another one. " "Ignoring.\n"); // Sleep long enough to make sure that the thread which started // to print an error report will finish doing it. SleepForSeconds(Max(100, flags()->sleep_before_dying + 1)); // If we're still not dead for some reason, use raw _exit() instead of // Die() to bypass any additional checks. internal__exit(common_flags()->exitcode); } else { // The other thread will eventually finish reporting // so it's safe to wait lock_.Lock(); } StartReporting(report); } ~ScopedInErrorReport() { // Make sure the current thread is announced. DescribeThread(GetCurrentThread()); // We may want to grab this lock again when printing stats. asanThreadRegistry().Unlock(); // Print memory stats. if (flags()->print_stats) __asan_print_accumulated_stats(); if (common_flags()->print_cmdline) PrintCmdline(); // Copy the message buffer so that we could start logging without holding a // lock that gets aquired during printing. InternalScopedBuffer<char> buffer_copy(kErrorMessageBufferSize); { BlockingMutexLock l(&error_message_buf_mutex); internal_memcpy(buffer_copy.data(), error_message_buffer, kErrorMessageBufferSize); } LogFullErrorReport(buffer_copy.data()); if (error_report_callback) { error_report_callback(buffer_copy.data()); } CommonSanitizerReportMutex.Unlock(); reporting_thread_tid_ = kInvalidTid; lock_.Unlock(); if (halt_on_error_) { Report("ABORTING\n"); Die(); } } private: void StartReporting(ReportData *report) { if (report) report_data = *report; report_happened = true; ASAN_ON_ERROR(); // Make sure the registry and sanitizer report mutexes are locked while // we're printing an error report. // We can lock them only here to avoid self-deadlock in case of // recursive reports. asanThreadRegistry().Lock(); CommonSanitizerReportMutex.Lock(); reporting_thread_tid_ = GetCurrentTidOrInvalid(); Printf("====================================================" "=============\n"); } static StaticSpinMutex lock_; static u32 reporting_thread_tid_; bool halt_on_error_; }; StaticSpinMutex ScopedInErrorReport::lock_; u32 ScopedInErrorReport::reporting_thread_tid_ = kInvalidTid; void ReportStackOverflow(const SignalContext &sig) { ScopedInErrorReport in_report(/*report*/ nullptr, /*fatal*/ true); Decorator d; Printf("%s", d.Warning()); Report( "ERROR: AddressSanitizer: stack-overflow on address %p" " (pc %p bp %p sp %p T%d)\n", (void *)sig.addr, (void *)sig.pc, (void *)sig.bp, (void *)sig.sp, GetCurrentTidOrInvalid()); Printf("%s", d.EndWarning()); ScarinessScore::PrintSimple(10, "stack-overflow"); GET_STACK_TRACE_SIGNAL(sig); stack.Print(); ReportErrorSummary("stack-overflow", &stack); } void ReportDeadlySignal(const char *description, const SignalContext &sig) { ScopedInErrorReport in_report(/*report*/ nullptr, /*fatal*/ true); Decorator d; Printf("%s", d.Warning()); Report( "ERROR: AddressSanitizer: %s on unknown address %p" " (pc %p bp %p sp %p T%d)\n", description, (void *)sig.addr, (void *)sig.pc, (void *)sig.bp, (void *)sig.sp, GetCurrentTidOrInvalid()); Printf("%s", d.EndWarning()); ScarinessScore SS; 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"); SS.Scare(10, "null-deref"); } else if (sig.addr == sig.pc) { SS.Scare(60, "wild-jump"); } else if (sig.write_flag == SignalContext::WRITE) { SS.Scare(30, "wild-addr-write"); } else if (sig.write_flag == SignalContext::READ) { SS.Scare(20, "wild-addr-read"); } else { SS.Scare(25, "wild-addr"); } } else { SS.Scare(10, "signal"); } SS.Print(); GET_STACK_TRACE_SIGNAL(sig); stack.Print(); MaybeDumpInstructionBytes(sig.pc); Printf("AddressSanitizer can not provide additional info.\n"); ReportErrorSummary(description, &stack); } void ReportDoubleFree(uptr addr, BufferedStackTrace *free_stack) { ScopedInErrorReport in_report; Decorator d; Printf("%s", d.Warning()); char tname[128]; u32 curr_tid = GetCurrentTidOrInvalid(); Report("ERROR: AddressSanitizer: attempting double-free on %p in " "thread T%d%s:\n", addr, curr_tid, ThreadNameWithParenthesis(curr_tid, tname, sizeof(tname))); Printf("%s", d.EndWarning()); CHECK_GT(free_stack->size, 0); ScarinessScore::PrintSimple(42, "double-free"); GET_STACK_TRACE_FATAL(free_stack->trace[0], free_stack->top_frame_bp); stack.Print(); DescribeHeapAddress(addr, 1); ReportErrorSummary("double-free", &stack); } void ReportNewDeleteSizeMismatch(uptr addr, uptr alloc_size, uptr delete_size, BufferedStackTrace *free_stack) { ScopedInErrorReport in_report; Decorator d; Printf("%s", d.Warning()); char tname[128]; u32 curr_tid = GetCurrentTidOrInvalid(); Report("ERROR: AddressSanitizer: new-delete-type-mismatch on %p in " "thread T%d%s:\n", addr, curr_tid, ThreadNameWithParenthesis(curr_tid, tname, sizeof(tname))); Printf("%s object passed to delete has wrong type:\n", d.EndWarning()); Printf(" size of the allocated type: %zd bytes;\n" " size of the deallocated type: %zd bytes.\n", alloc_size, delete_size); CHECK_GT(free_stack->size, 0); ScarinessScore::PrintSimple(10, "new-delete-type-mismatch"); GET_STACK_TRACE_FATAL(free_stack->trace[0], free_stack->top_frame_bp); stack.Print(); DescribeHeapAddress(addr, 1); ReportErrorSummary("new-delete-type-mismatch", &stack); Report("HINT: if you don't care about these errors you may set " "ASAN_OPTIONS=new_delete_type_mismatch=0\n"); } void ReportFreeNotMalloced(uptr addr, BufferedStackTrace *free_stack) { ScopedInErrorReport in_report; Decorator d; Printf("%s", d.Warning()); char tname[128]; u32 curr_tid = GetCurrentTidOrInvalid(); Report("ERROR: AddressSanitizer: attempting free on address " "which was not malloc()-ed: %p in thread T%d%s\n", addr, curr_tid, ThreadNameWithParenthesis(curr_tid, tname, sizeof(tname))); Printf("%s", d.EndWarning()); CHECK_GT(free_stack->size, 0); ScarinessScore::PrintSimple(40, "bad-free"); GET_STACK_TRACE_FATAL(free_stack->trace[0], free_stack->top_frame_bp); stack.Print(); DescribeHeapAddress(addr, 1); ReportErrorSummary("bad-free", &stack); } void ReportAllocTypeMismatch(uptr addr, BufferedStackTrace *free_stack, AllocType alloc_type, AllocType dealloc_type) { static const char *alloc_names[] = {"INVALID", "malloc", "operator new", "operator new []"}; static const char *dealloc_names[] = {"INVALID", "free", "operator delete", "operator delete []"}; CHECK_NE(alloc_type, dealloc_type); ScopedInErrorReport in_report; Decorator d; Printf("%s", d.Warning()); Report("ERROR: AddressSanitizer: alloc-dealloc-mismatch (%s vs %s) on %p\n", alloc_names[alloc_type], dealloc_names[dealloc_type], addr); Printf("%s", d.EndWarning()); CHECK_GT(free_stack->size, 0); ScarinessScore::PrintSimple(10, "alloc-dealloc-mismatch"); GET_STACK_TRACE_FATAL(free_stack->trace[0], free_stack->top_frame_bp); stack.Print(); DescribeHeapAddress(addr, 1); ReportErrorSummary("alloc-dealloc-mismatch", &stack); Report("HINT: if you don't care about these errors you may set " "ASAN_OPTIONS=alloc_dealloc_mismatch=0\n"); } void ReportMallocUsableSizeNotOwned(uptr addr, BufferedStackTrace *stack) { ScopedInErrorReport in_report; Decorator d; Printf("%s", d.Warning()); Report("ERROR: AddressSanitizer: attempting to call " "malloc_usable_size() for pointer which is " "not owned: %p\n", addr); Printf("%s", d.EndWarning()); stack->Print(); DescribeHeapAddress(addr, 1); ReportErrorSummary("bad-malloc_usable_size", stack); } void ReportSanitizerGetAllocatedSizeNotOwned(uptr addr, BufferedStackTrace *stack) { ScopedInErrorReport in_report; Decorator d; Printf("%s", d.Warning()); Report("ERROR: AddressSanitizer: attempting to call " "__sanitizer_get_allocated_size() for pointer which is " "not owned: %p\n", addr); Printf("%s", d.EndWarning()); stack->Print(); DescribeHeapAddress(addr, 1); ReportErrorSummary("bad-__sanitizer_get_allocated_size", stack); } void ReportStringFunctionMemoryRangesOverlap(const char *function, const char *offset1, uptr length1, const char *offset2, uptr length2, BufferedStackTrace *stack) { ScopedInErrorReport in_report; Decorator d; char bug_type[100]; internal_snprintf(bug_type, sizeof(bug_type), "%s-param-overlap", function); Printf("%s", d.Warning()); Report("ERROR: AddressSanitizer: %s: " "memory ranges [%p,%p) and [%p, %p) overlap\n", \ bug_type, offset1, offset1 + length1, offset2, offset2 + length2); Printf("%s", d.EndWarning()); ScarinessScore::PrintSimple(10, bug_type); stack->Print(); DescribeAddress((uptr)offset1, length1, bug_type); DescribeAddress((uptr)offset2, length2, bug_type); ReportErrorSummary(bug_type, stack); } void ReportStringFunctionSizeOverflow(uptr offset, uptr size, BufferedStackTrace *stack) { ScopedInErrorReport in_report; Decorator d; const char *bug_type = "negative-size-param"; Printf("%s", d.Warning()); Report("ERROR: AddressSanitizer: %s: (size=%zd)\n", bug_type, size); Printf("%s", d.EndWarning()); ScarinessScore::PrintSimple(10, bug_type); stack->Print(); DescribeAddress(offset, size, bug_type); ReportErrorSummary(bug_type, stack); } void ReportBadParamsToAnnotateContiguousContainer(uptr beg, uptr end, uptr old_mid, uptr new_mid, BufferedStackTrace *stack) { ScopedInErrorReport in_report; Report("ERROR: AddressSanitizer: bad parameters to " "__sanitizer_annotate_contiguous_container:\n" " beg : %p\n" " end : %p\n" " old_mid : %p\n" " new_mid : %p\n", beg, end, old_mid, new_mid); uptr granularity = SHADOW_GRANULARITY; if (!IsAligned(beg, granularity)) Report("ERROR: beg is not aligned by %d\n", granularity); stack->Print(); ReportErrorSummary("bad-__sanitizer_annotate_contiguous_container", stack); } void ReportODRViolation(const __asan_global *g1, u32 stack_id1, const __asan_global *g2, u32 stack_id2) { ScopedInErrorReport in_report; Decorator d; Printf("%s", d.Warning()); Report("ERROR: AddressSanitizer: odr-violation (%p):\n", g1->beg); Printf("%s", d.EndWarning()); InternalScopedString g1_loc(256), g2_loc(256); PrintGlobalLocation(&g1_loc, *g1); PrintGlobalLocation(&g2_loc, *g2); Printf(" [1] size=%zd '%s' %s\n", g1->size, MaybeDemangleGlobalName(g1->name), g1_loc.data()); Printf(" [2] size=%zd '%s' %s\n", g2->size, MaybeDemangleGlobalName(g2->name), g2_loc.data()); if (stack_id1 && stack_id2) { Printf("These globals were registered at these points:\n"); Printf(" [1]:\n"); StackDepotGet(stack_id1).Print(); Printf(" [2]:\n"); StackDepotGet(stack_id2).Print(); } Report("HINT: if you don't care about these errors you may set " "ASAN_OPTIONS=detect_odr_violation=0\n"); InternalScopedString error_msg(256); error_msg.append("odr-violation: global '%s' at %s", MaybeDemangleGlobalName(g1->name), g1_loc.data()); ReportErrorSummary(error_msg.data()); } // ----------------------- CheckForInvalidPointerPair ----------- {{{1 static NOINLINE void ReportInvalidPointerPair(uptr pc, uptr bp, uptr sp, uptr a1, uptr a2) { ScopedInErrorReport in_report; const char *bug_type = "invalid-pointer-pair"; Decorator d; Printf("%s", d.Warning()); Report("ERROR: AddressSanitizer: invalid-pointer-pair: %p %p\n", a1, a2); Printf("%s", d.EndWarning()); GET_STACK_TRACE_FATAL(pc, bp); stack.Print(); DescribeAddress(a1, 1, bug_type); DescribeAddress(a2, 1, bug_type); ReportErrorSummary(bug_type, &stack); } static INLINE void CheckForInvalidPointerPair(void *p1, void *p2) { if (!flags()->detect_invalid_pointer_pairs) return; uptr a1 = reinterpret_cast<uptr>(p1); uptr a2 = reinterpret_cast<uptr>(p2); AsanChunkView chunk1 = FindHeapChunkByAddress(a1); AsanChunkView chunk2 = FindHeapChunkByAddress(a2); bool valid1 = chunk1.IsAllocated(); bool valid2 = chunk2.IsAllocated(); if (!valid1 || !valid2 || !chunk1.Eq(chunk2)) { GET_CALLER_PC_BP_SP; return ReportInvalidPointerPair(pc, bp, sp, a1, a2); } } // ----------------------- Mac-specific reports ----------------- {{{1 void ReportMacMzReallocUnknown(uptr addr, uptr zone_ptr, const char *zone_name, BufferedStackTrace *stack) { ScopedInErrorReport in_report; Printf("mz_realloc(%p) -- attempting to realloc unallocated memory.\n" "This is an unrecoverable problem, exiting now.\n", addr); PrintZoneForPointer(addr, zone_ptr, zone_name); stack->Print(); DescribeHeapAddress(addr, 1); } // -------------- SuppressErrorReport -------------- {{{1 // Avoid error reports duplicating for ASan recover mode. static bool SuppressErrorReport(uptr pc) { if (!common_flags()->suppress_equal_pcs) return false; for (unsigned i = 0; i < kAsanBuggyPcPoolSize; i++) { uptr cmp = atomic_load_relaxed(&AsanBuggyPcPool[i]); if (cmp == 0 && atomic_compare_exchange_strong(&AsanBuggyPcPool[i], &cmp, pc, memory_order_relaxed)) return false; if (cmp == pc) return true; } Die(); } static void PrintContainerOverflowHint() { Printf("HINT: if you don't care about these errors you may set " "ASAN_OPTIONS=detect_container_overflow=0.\n" "If you suspect a false positive see also: " "https://github.com/google/sanitizers/wiki/" "AddressSanitizerContainerOverflow.\n"); } static bool AdjacentShadowValuesAreFullyPoisoned(u8 *s) { return s[-1] > 127 && s[1] > 127; } void ReportGenericError(uptr pc, uptr bp, uptr sp, uptr addr, bool is_write, uptr access_size, u32 exp, bool fatal) { if (!fatal && SuppressErrorReport(pc)) return; ENABLE_FRAME_POINTER; ScarinessScore SS; if (access_size) { if (access_size <= 9) { char desr[] = "?-byte"; desr[0] = '0' + access_size; SS.Scare(access_size + access_size / 2, desr); } else if (access_size >= 10) { SS.Scare(15, "multi-byte"); } is_write ? SS.Scare(20, "write") : SS.Scare(1, "read"); } // Optimization experiments. // The experiments can be used to evaluate potential optimizations that remove // instrumentation (assess false negatives). Instead of completely removing // some instrumentation, compiler can emit special calls into runtime // (e.g. __asan_report_exp_load1 instead of __asan_report_load1) and pass // mask of experiments (exp). // The reaction to a non-zero value of exp is to be defined. (void)exp; // Determine the error type. const char *bug_descr = "unknown-crash"; u8 shadow_val = 0; if (AddrIsInMem(addr)) { u8 *shadow_addr = (u8*)MemToShadow(addr); // If we are accessing 16 bytes, look at the second shadow byte. if (*shadow_addr == 0 && access_size > SHADOW_GRANULARITY) shadow_addr++; // If we are in the partial right redzone, look at the next shadow byte. if (*shadow_addr > 0 && *shadow_addr < 128) shadow_addr++; bool far_from_bounds = false; shadow_val = *shadow_addr; int bug_type_score = 0; // For use-after-frees reads are almost as bad as writes. int read_after_free_bonus = 0; switch (shadow_val) { case kAsanHeapLeftRedzoneMagic: case kAsanHeapRightRedzoneMagic: case kAsanArrayCookieMagic: bug_descr = "heap-buffer-overflow"; bug_type_score = 10; far_from_bounds = AdjacentShadowValuesAreFullyPoisoned(shadow_addr); break; case kAsanHeapFreeMagic: bug_descr = "heap-use-after-free"; bug_type_score = 20; if (!is_write) read_after_free_bonus = 18; break; case kAsanStackLeftRedzoneMagic: bug_descr = "stack-buffer-underflow"; bug_type_score = 25; far_from_bounds = AdjacentShadowValuesAreFullyPoisoned(shadow_addr); break; case kAsanInitializationOrderMagic: bug_descr = "initialization-order-fiasco"; bug_type_score = 1; break; case kAsanStackMidRedzoneMagic: case kAsanStackRightRedzoneMagic: case kAsanStackPartialRedzoneMagic: bug_descr = "stack-buffer-overflow"; bug_type_score = 25; far_from_bounds = AdjacentShadowValuesAreFullyPoisoned(shadow_addr); break; case kAsanStackAfterReturnMagic: bug_descr = "stack-use-after-return"; bug_type_score = 30; if (!is_write) read_after_free_bonus = 18; break; case kAsanUserPoisonedMemoryMagic: bug_descr = "use-after-poison"; bug_type_score = 20; break; case kAsanContiguousContainerOOBMagic: bug_descr = "container-overflow"; bug_type_score = 10; break; case kAsanStackUseAfterScopeMagic: bug_descr = "stack-use-after-scope"; bug_type_score = 10; break; case kAsanGlobalRedzoneMagic: bug_descr = "global-buffer-overflow"; bug_type_score = 10; far_from_bounds = AdjacentShadowValuesAreFullyPoisoned(shadow_addr); break; case kAsanIntraObjectRedzone: bug_descr = "intra-object-overflow"; bug_type_score = 10; break; case kAsanAllocaLeftMagic: case kAsanAllocaRightMagic: bug_descr = "dynamic-stack-buffer-overflow"; bug_type_score = 25; far_from_bounds = AdjacentShadowValuesAreFullyPoisoned(shadow_addr); break; } SS.Scare(bug_type_score + read_after_free_bonus, bug_descr); if (far_from_bounds) SS.Scare(10, "far-from-bounds"); } ReportData report = { pc, sp, bp, addr, (bool)is_write, access_size, bug_descr }; ScopedInErrorReport in_report(&report, fatal); Decorator d; Printf("%s", d.Warning()); Report("ERROR: AddressSanitizer: %s on address " "%p at pc %p bp %p sp %p\n", bug_descr, (void*)addr, pc, bp, sp); Printf("%s", d.EndWarning()); u32 curr_tid = GetCurrentTidOrInvalid(); char tname[128]; Printf("%s%s of size %zu at %p thread T%d%s%s\n", d.Access(), access_size ? (is_write ? "WRITE" : "READ") : "ACCESS", access_size, (void*)addr, curr_tid, ThreadNameWithParenthesis(curr_tid, tname, sizeof(tname)), d.EndAccess()); SS.Print(); GET_STACK_TRACE_FATAL(pc, bp); stack.Print(); DescribeAddress(addr, access_size, bug_descr); if (shadow_val == kAsanContiguousContainerOOBMagic) PrintContainerOverflowHint(); ReportErrorSummary(bug_descr, &stack); PrintShadowMemoryForAddress(addr); } } // namespace __asan // --------------------------- Interface --------------------- {{{1 using namespace __asan; // NOLINT void __asan_report_error(uptr pc, uptr bp, uptr sp, uptr addr, int is_write, uptr access_size, u32 exp) { ENABLE_FRAME_POINTER; bool fatal = flags()->halt_on_error; ReportGenericError(pc, bp, sp, addr, is_write, access_size, exp, fatal); } void NOINLINE __asan_set_error_report_callback(void (*callback)(const char*)) { BlockingMutexLock l(&error_message_buf_mutex); error_report_callback = callback; } void __asan_describe_address(uptr addr) { // Thread registry must be locked while we're describing an address. asanThreadRegistry().Lock(); DescribeAddress(addr, 1, ""); asanThreadRegistry().Unlock(); } int __asan_report_present() { return report_happened ? 1 : 0; } uptr __asan_get_report_pc() { return report_data.pc; } uptr __asan_get_report_bp() { return report_data.bp; } uptr __asan_get_report_sp() { return report_data.sp; } uptr __asan_get_report_address() { return report_data.addr; } int __asan_get_report_access_type() { return report_data.is_write ? 1 : 0; } uptr __asan_get_report_access_size() { return report_data.access_size; } const char *__asan_get_report_description() { return report_data.description; } extern "C" { SANITIZER_INTERFACE_ATTRIBUTE void __sanitizer_ptr_sub(void *a, void *b) { CheckForInvalidPointerPair(a, b); } SANITIZER_INTERFACE_ATTRIBUTE void __sanitizer_ptr_cmp(void *a, void *b) { CheckForInvalidPointerPair(a, b); } } // extern "C" #if !SANITIZER_SUPPORTS_WEAK_HOOKS // Provide default implementation of __asan_on_error that does nothing // and may be overriden by user. SANITIZER_INTERFACE_ATTRIBUTE SANITIZER_WEAK_ATTRIBUTE NOINLINE void __asan_on_error() {} #endif