lib/hwasan/hwasan.cc - toolchain/compiler-rt - Git at Google

 //===-- hwasan.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 HWAddressSanitizer.
 //
 // HWAddressSanitizer runtime.
 //===----------------------------------------------------------------------===//

 #include "hwasan.h"
 #include "hwasan_mapping.h"
 #include "hwasan_poisoning.h"
 #include "hwasan_report.h"
 #include "hwasan_thread.h"
 #include "hwasan_thread_list.h"
 #include "sanitizer_common/sanitizer_atomic.h"
 #include "sanitizer_common/sanitizer_common.h"
 #include "sanitizer_common/sanitizer_flags.h"
 #include "sanitizer_common/sanitizer_flag_parser.h"
 #include "sanitizer_common/sanitizer_libc.h"
 #include "sanitizer_common/sanitizer_procmaps.h"
 #include "sanitizer_common/sanitizer_stacktrace.h"
 #include "sanitizer_common/sanitizer_symbolizer.h"
 #include "sanitizer_common/sanitizer_stackdepot.h"
 #include "ubsan/ubsan_flags.h"
 #include "ubsan/ubsan_init.h"

 // ACHTUNG! No system header includes in this file.

 using namespace __sanitizer;

 namespace __hwasan {

 void EnterSymbolizer() {
   Thread *t = GetCurrentThread();
   CHECK(t);
   t->EnterSymbolizer();
 }
 void ExitSymbolizer() {
   Thread *t = GetCurrentThread();
   CHECK(t);
   t->LeaveSymbolizer();
 }
 bool IsInSymbolizer() {
   Thread *t = GetCurrentThread();
   return t && t->InSymbolizer();
 }

 static Flags hwasan_flags;

 Flags *flags() {
   return &hwasan_flags;
 }

 int hwasan_inited = 0;
 int hwasan_shadow_inited = 0;
 bool hwasan_init_is_running;

 int hwasan_report_count = 0;

 void Flags::SetDefaults() {
 #define HWASAN_FLAG(Type, Name, DefaultValue, Description) Name = DefaultValue;
 #include "hwasan_flags.inc"
 #undef HWASAN_FLAG
 }

 static void RegisterHwasanFlags(FlagParser *parser, Flags *f) {
 #define HWASAN_FLAG(Type, Name, DefaultValue, Description) \
   RegisterFlag(parser, #Name, Description, &f->Name);
 #include "hwasan_flags.inc"
 #undef HWASAN_FLAG
 }

 static void InitializeFlags() {
   SetCommonFlagsDefaults();
   {
     CommonFlags cf;
     cf.CopyFrom(*common_flags());
     cf.external_symbolizer_path = GetEnv("HWASAN_SYMBOLIZER_PATH");
     cf.malloc_context_size = 20;
     cf.handle_ioctl = true;
     // FIXME: test and enable.
     cf.check_printf = false;
     cf.intercept_tls_get_addr = true;
     cf.exitcode = 99;
     // Sigtrap is used in error reporting.
     cf.handle_sigtrap = kHandleSignalExclusive;

 #if SANITIZER_ANDROID
     // Let platform handle other signals. It is better at reporting them then we
     // are.
     cf.handle_segv = kHandleSignalNo;
     cf.handle_sigbus = kHandleSignalNo;
     cf.handle_abort = kHandleSignalNo;
     cf.handle_sigill = kHandleSignalNo;
     cf.handle_sigfpe = kHandleSignalNo;
 #endif
     OverrideCommonFlags(cf);
   }

   Flags *f = flags();
   f->SetDefaults();

   FlagParser parser;
   RegisterHwasanFlags(&parser, f);
   RegisterCommonFlags(&parser);

 #if HWASAN_CONTAINS_UBSAN
   __ubsan::Flags *uf = __ubsan::flags();
   uf->SetDefaults();

   FlagParser ubsan_parser;
   __ubsan::RegisterUbsanFlags(&ubsan_parser, uf);
   RegisterCommonFlags(&ubsan_parser);
 #endif

   // Override from user-specified string.
   if (__hwasan_default_options)
     parser.ParseString(__hwasan_default_options());
 #if HWASAN_CONTAINS_UBSAN
   const char *ubsan_default_options = __ubsan::MaybeCallUbsanDefaultOptions();
   ubsan_parser.ParseString(ubsan_default_options);
 #endif

   const char *hwasan_options = GetEnv("HWASAN_OPTIONS");
   parser.ParseString(hwasan_options);
 #if HWASAN_CONTAINS_UBSAN
   ubsan_parser.ParseString(GetEnv("UBSAN_OPTIONS"));
 #endif
   VPrintf(1, "HWASAN_OPTIONS: %s\n",
           hwasan_options ? hwasan_options : "<empty>");

   InitializeCommonFlags();

   if (Verbosity()) ReportUnrecognizedFlags();

   if (common_flags()->help) parser.PrintFlagDescriptions();
 }

 void GetStackTrace(BufferedStackTrace *stack, uptr max_s, uptr pc, uptr bp,
                    void *context, bool request_fast_unwind) {
   Thread *t = GetCurrentThread();
   if (!t) {
     // the thread is still being created.
     stack->size = 0;
     return;
   }
   if (!StackTrace::WillUseFastUnwind(request_fast_unwind)) {
     // Block reports from our interceptors during _Unwind_Backtrace.
     SymbolizerScope sym_scope;
     return stack->Unwind(max_s, pc, bp, context, 0, 0, request_fast_unwind);
   }
   stack->Unwind(max_s, pc, bp, context, t->stack_top(), t->stack_bottom(),
                 request_fast_unwind);
 }

 static void HWAsanCheckFailed(const char *file, int line, const char *cond,
                               u64 v1, u64 v2) {
   Report("HWAddressSanitizer CHECK failed: %s:%d \"%s\" (0x%zx, 0x%zx)\n", file,
          line, cond, (uptr)v1, (uptr)v2);
   PRINT_CURRENT_STACK_CHECK();
   Die();
 }

 static constexpr uptr kMemoryUsageBufferSize = 4096;

 static void HwasanFormatMemoryUsage(InternalScopedString &s) {
   HwasanThreadList &thread_list = hwasanThreadList();
   auto thread_stats = thread_list.GetThreadStats();
   auto *sds = StackDepotGetStats();
   AllocatorStatCounters asc;
   GetAllocatorStats(asc);
   s.append(
       "HWASAN pid: %d rss: %zd threads: %zd stacks: %zd"
       " thr_aux: %zd stack_depot: %zd uniq_stacks: %zd"
       " heap: %zd",
       internal_getpid(), GetRSS(), thread_stats.n_live_threads,
       thread_stats.total_stack_size,
       thread_stats.n_live_threads * thread_list.MemoryUsedPerThread(),
       sds->allocated, sds->n_uniq_ids, asc[AllocatorStatMapped]);
 }

 #if SANITIZER_ANDROID
 static char *memory_usage_buffer = nullptr;

 #define PR_SET_VMA 0x53564d41
 #define PR_SET_VMA_ANON_NAME 0

 static void InitMemoryUsage() {
   memory_usage_buffer =
       (char *)MmapOrDie(kMemoryUsageBufferSize, "memory usage string");
   CHECK(memory_usage_buffer);
   memory_usage_buffer[0] = '\0';
   CHECK(internal_prctl(PR_SET_VMA, PR_SET_VMA_ANON_NAME,
                        (uptr)memory_usage_buffer, kMemoryUsageBufferSize,
                        (uptr)memory_usage_buffer) == 0);
 }

 void UpdateMemoryUsage() {
   if (!flags()->export_memory_stats)
     return;
   if (!memory_usage_buffer)
     InitMemoryUsage();
   InternalScopedString s(kMemoryUsageBufferSize);
   HwasanFormatMemoryUsage(s);
   internal_strncpy(memory_usage_buffer, s.data(), kMemoryUsageBufferSize - 1);
   memory_usage_buffer[kMemoryUsageBufferSize - 1] = '\0';
 }
 #else
 void UpdateMemoryUsage() {}
 #endif

 struct FrameDescription {
   uptr PC;
   const char *Descr;
 };

 struct FrameDescriptionArray {
   FrameDescription *beg, *end;
 };

 static InternalMmapVectorNoCtor<FrameDescriptionArray> AllFrames;

 void InitFrameDescriptors(uptr b, uptr e) {
   FrameDescription *beg = reinterpret_cast<FrameDescription *>(b);
   FrameDescription *end = reinterpret_cast<FrameDescription *>(e);
   if (beg == end)
     return;
   AllFrames.push_back({beg, end});
   if (Verbosity())
     for (FrameDescription *frame_descr = beg; frame_descr < end; frame_descr++)
       Printf("Frame: %p %s\n", frame_descr->PC, frame_descr->Descr);
 }

 const char *GetStackFrameDescr(uptr pc) {
   for (uptr i = 0, n = AllFrames.size(); i < n; i++)
     for (auto p = AllFrames[i].beg; p < AllFrames[i].end; p++)
       if (p->PC == pc)
         return p->Descr;
   return nullptr;
 }

 } // namespace __hwasan

 // Interface.

 using namespace __hwasan;

 uptr __hwasan_shadow_memory_dynamic_address;  // Global interface symbol.

 void __hwasan_shadow_init() {
   if (hwasan_shadow_inited) return;
   if (!InitShadow()) {
     Printf("FATAL: HWAddressSanitizer cannot mmap the shadow memory.\n");
     DumpProcessMap();
     Die();
   }
   hwasan_shadow_inited = 1;
 }

 void __hwasan_init_frames(uptr beg, uptr end) {
   InitFrameDescriptors(beg, end);
 }

 void __hwasan_init() {
   CHECK(!hwasan_init_is_running);
   if (hwasan_inited) return;
   hwasan_init_is_running = 1;
   SanitizerToolName = "HWAddressSanitizer";

   InitTlsSize();

   CacheBinaryName();
   InitializeFlags();

   // Install tool-specific callbacks in sanitizer_common.
   SetCheckFailedCallback(HWAsanCheckFailed);

   __sanitizer_set_report_path(common_flags()->log_path);

   AndroidTestTlsSlot();

   DisableCoreDumperIfNecessary();

   __hwasan_shadow_init();

   InitThreads();
   hwasanThreadList().CreateCurrentThread();

   MadviseShadow();

   SetPrintfAndReportCallback(AppendToErrorMessageBuffer);
   // This may call libc -> needs initialized shadow.
   AndroidLogInit();

   InitializeInterceptors();
   InstallDeadlySignalHandlers(HwasanOnDeadlySignal);
   InstallAtExitHandler(); // Needs __cxa_atexit interceptor.

   Symbolizer::GetOrInit()->AddHooks(EnterSymbolizer, ExitSymbolizer);

   InitializeCoverage(common_flags()->coverage, common_flags()->coverage_dir);

   HwasanTSDInit();
   HwasanTSDThreadInit();

   HwasanAllocatorInit();

 #if HWASAN_CONTAINS_UBSAN
   __ubsan::InitAsPlugin();
 #endif

   VPrintf(1, "HWAddressSanitizer init done\n");

   hwasan_init_is_running = 0;
   hwasan_inited = 1;
 }

 void __hwasan_print_shadow(const void *p, uptr sz) {
   uptr ptr_raw = UntagAddr(reinterpret_cast<uptr>(p));
   uptr shadow_first = MemToShadow(ptr_raw);
   uptr shadow_last = MemToShadow(ptr_raw + sz - 1);
   Printf("HWASan shadow map for %zx .. %zx (pointer tag %x)\n", ptr_raw,
          ptr_raw + sz, GetTagFromPointer((uptr)p));
   for (uptr s = shadow_first; s <= shadow_last; ++s)
     Printf("  %zx: %x\n", ShadowToMem(s), *(tag_t *)s);
 }

 sptr __hwasan_test_shadow(const void *p, uptr sz) {
   if (sz == 0)
     return -1;
   tag_t ptr_tag = GetTagFromPointer((uptr)p);
   if (ptr_tag == 0)
     return -1;
   uptr ptr_raw = UntagAddr(reinterpret_cast<uptr>(p));
   uptr shadow_first = MemToShadow(ptr_raw);
   uptr shadow_last = MemToShadow(ptr_raw + sz - 1);
   for (uptr s = shadow_first; s <= shadow_last; ++s)
     if (*(tag_t*)s != ptr_tag)
       return ShadowToMem(s) - ptr_raw;
   return -1;
 }

 u16 __sanitizer_unaligned_load16(const uu16 *p) {
   return *p;
 }
 u32 __sanitizer_unaligned_load32(const uu32 *p) {
   return *p;
 }
 u64 __sanitizer_unaligned_load64(const uu64 *p) {
   return *p;
 }
 void __sanitizer_unaligned_store16(uu16 *p, u16 x) {
   *p = x;
 }
 void __sanitizer_unaligned_store32(uu32 *p, u32 x) {
   *p = x;
 }
 void __sanitizer_unaligned_store64(uu64 *p, u64 x) {
   *p = x;
 }

 template<unsigned X>
 __attribute__((always_inline))
 static void SigTrap(uptr p) {
 #if defined(__aarch64__)
   (void)p;
   // 0x900 is added to do not interfere with the kernel use of lower values of
   // brk immediate.
   // FIXME: Add a constraint to put the pointer into x0, the same as x86 branch.
   asm("brk %0\n\t" ::"n"(0x900 + X));
 #elif defined(__x86_64__)
   // INT3 + NOP DWORD ptr [EAX + X] to pass X to our signal handler, 5 bytes
   // total. The pointer is passed via rdi.
   // 0x40 is added as a safeguard, to help distinguish our trap from others and
   // to avoid 0 offsets in the command (otherwise it'll be reduced to a
   // different nop command, the three bytes one).
   asm volatile(
       "int3\n"
       "nopl %c0(%%rax)\n"
       :: "n"(0x40 + X), "D"(p));
 #else
   // FIXME: not always sigill.
   __builtin_trap();
 #endif
   // __builtin_unreachable();
 }

 enum class ErrorAction { Abort, Recover };
 enum class AccessType { Load, Store };

 template <ErrorAction EA, AccessType AT, unsigned LogSize>
 __attribute__((always_inline, nodebug)) static void CheckAddress(uptr p) {
   tag_t ptr_tag = GetTagFromPointer(p);
   uptr ptr_raw = p & ~kAddressTagMask;
   tag_t mem_tag = *(tag_t *)MemToShadow(ptr_raw);
   if (UNLIKELY(ptr_tag != mem_tag)) {
     SigTrap<0x20 * (EA == ErrorAction::Recover) +
            0x10 * (AT == AccessType::Store) + LogSize>(p);
     if (EA == ErrorAction::Abort) __builtin_unreachable();
   }
 }

 template <ErrorAction EA, AccessType AT>
 __attribute__((always_inline, nodebug)) static void CheckAddressSized(uptr p,
                                                                       uptr sz) {
   CHECK_NE(0, sz);
   tag_t ptr_tag = GetTagFromPointer(p);
   uptr ptr_raw = p & ~kAddressTagMask;
   tag_t *shadow_first = (tag_t *)MemToShadow(ptr_raw);
   tag_t *shadow_last = (tag_t *)MemToShadow(ptr_raw + sz - 1);
   for (tag_t *t = shadow_first; t <= shadow_last; ++t)
     if (UNLIKELY(ptr_tag != *t)) {
       SigTrap<0x20 * (EA == ErrorAction::Recover) +
              0x10 * (AT == AccessType::Store) + 0xf>(p);
       if (EA == ErrorAction::Abort) __builtin_unreachable();
     }
 }

 void __hwasan_loadN(uptr p, uptr sz) {
   CheckAddressSized<ErrorAction::Abort, AccessType::Load>(p, sz);
 }
 void __hwasan_load1(uptr p) {
   CheckAddress<ErrorAction::Abort, AccessType::Load, 0>(p);
 }
 void __hwasan_load2(uptr p) {
   CheckAddress<ErrorAction::Abort, AccessType::Load, 1>(p);
 }
 void __hwasan_load4(uptr p) {
   CheckAddress<ErrorAction::Abort, AccessType::Load, 2>(p);
 }
 void __hwasan_load8(uptr p) {
   CheckAddress<ErrorAction::Abort, AccessType::Load, 3>(p);
 }
 void __hwasan_load16(uptr p) {
   CheckAddress<ErrorAction::Abort, AccessType::Load, 4>(p);
 }

 void __hwasan_loadN_noabort(uptr p, uptr sz) {
   CheckAddressSized<ErrorAction::Recover, AccessType::Load>(p, sz);
 }
 void __hwasan_load1_noabort(uptr p) {
   CheckAddress<ErrorAction::Recover, AccessType::Load, 0>(p);
 }
 void __hwasan_load2_noabort(uptr p) {
   CheckAddress<ErrorAction::Recover, AccessType::Load, 1>(p);
 }
 void __hwasan_load4_noabort(uptr p) {
   CheckAddress<ErrorAction::Recover, AccessType::Load, 2>(p);
 }
 void __hwasan_load8_noabort(uptr p) {
   CheckAddress<ErrorAction::Recover, AccessType::Load, 3>(p);
 }
 void __hwasan_load16_noabort(uptr p) {
   CheckAddress<ErrorAction::Recover, AccessType::Load, 4>(p);
 }

 void __hwasan_storeN(uptr p, uptr sz) {
   CheckAddressSized<ErrorAction::Abort, AccessType::Store>(p, sz);
 }
 void __hwasan_store1(uptr p) {
   CheckAddress<ErrorAction::Abort, AccessType::Store, 0>(p);
 }
 void __hwasan_store2(uptr p) {
   CheckAddress<ErrorAction::Abort, AccessType::Store, 1>(p);
 }
 void __hwasan_store4(uptr p) {
   CheckAddress<ErrorAction::Abort, AccessType::Store, 2>(p);
 }
 void __hwasan_store8(uptr p) {
   CheckAddress<ErrorAction::Abort, AccessType::Store, 3>(p);
 }
 void __hwasan_store16(uptr p) {
   CheckAddress<ErrorAction::Abort, AccessType::Store, 4>(p);
 }

 void __hwasan_storeN_noabort(uptr p, uptr sz) {
   CheckAddressSized<ErrorAction::Recover, AccessType::Store>(p, sz);
 }
 void __hwasan_store1_noabort(uptr p) {
   CheckAddress<ErrorAction::Recover, AccessType::Store, 0>(p);
 }
 void __hwasan_store2_noabort(uptr p) {
   CheckAddress<ErrorAction::Recover, AccessType::Store, 1>(p);
 }
 void __hwasan_store4_noabort(uptr p) {
   CheckAddress<ErrorAction::Recover, AccessType::Store, 2>(p);
 }
 void __hwasan_store8_noabort(uptr p) {
   CheckAddress<ErrorAction::Recover, AccessType::Store, 3>(p);
 }
 void __hwasan_store16_noabort(uptr p) {
   CheckAddress<ErrorAction::Recover, AccessType::Store, 4>(p);
 }

 void __hwasan_tag_memory(uptr p, u8 tag, uptr sz) {
   TagMemoryAligned(p, sz, tag);
 }

 uptr __hwasan_tag_pointer(uptr p, u8 tag) {
   return AddTagToPointer(p, tag);
 }

 void __hwasan_handle_longjmp(const void *sp_dst) {
   uptr dst = (uptr)sp_dst;
   // HWASan does not support tagged SP.
   CHECK(GetTagFromPointer(dst) == 0);

   uptr sp = (uptr)__builtin_frame_address(0);
   static const uptr kMaxExpectedCleanupSize = 64 << 20;  // 64M
   if (dst < sp || dst - sp > kMaxExpectedCleanupSize) {
     Report(
         "WARNING: HWASan is ignoring requested __hwasan_handle_longjmp: "
         "stack top: %p; target %p; distance: %p (%zd)\n"
         "False positive error reports may follow\n",
         (void *)sp, (void *)dst, dst - sp);
     return;
   }
   TagMemory(sp, dst - sp, 0);
 }

 void __hwasan_print_memory_usage() {
   InternalScopedString s(kMemoryUsageBufferSize);
   HwasanFormatMemoryUsage(s);
   Printf("%s\n", s.data());
 }

 static const u8 kFallbackTag = 0xBB;

 u8 __hwasan_generate_tag() {
   Thread *t = GetCurrentThread();
   if (!t) return kFallbackTag;
   return t->GenerateRandomTag();
 }

 #if !SANITIZER_SUPPORTS_WEAK_HOOKS
 extern "C" {
 SANITIZER_INTERFACE_ATTRIBUTE SANITIZER_WEAK_ATTRIBUTE
 const char* __hwasan_default_options() { return ""; }
 }  // extern "C"
 #endif

 extern "C" {
 SANITIZER_INTERFACE_ATTRIBUTE
 void __sanitizer_print_stack_trace() {
   GET_FATAL_STACK_TRACE_PC_BP(StackTrace::GetCurrentPc(), GET_CURRENT_FRAME());
   stack.Print();
 }
 } // extern "C"
	//===-- hwasan.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 HWAddressSanitizer.
	//
	// HWAddressSanitizer runtime.
	//===----------------------------------------------------------------------===//

	#include "hwasan.h"
	#include "hwasan_mapping.h"
	#include "hwasan_poisoning.h"
	#include "hwasan_report.h"
	#include "hwasan_thread.h"
	#include "hwasan_thread_list.h"
	#include "sanitizer_common/sanitizer_atomic.h"
	#include "sanitizer_common/sanitizer_common.h"
	#include "sanitizer_common/sanitizer_flags.h"
	#include "sanitizer_common/sanitizer_flag_parser.h"
	#include "sanitizer_common/sanitizer_libc.h"
	#include "sanitizer_common/sanitizer_procmaps.h"
	#include "sanitizer_common/sanitizer_stacktrace.h"
	#include "sanitizer_common/sanitizer_symbolizer.h"
	#include "sanitizer_common/sanitizer_stackdepot.h"
	#include "ubsan/ubsan_flags.h"
	#include "ubsan/ubsan_init.h"

	// ACHTUNG! No system header includes in this file.

	using namespace __sanitizer;

	namespace __hwasan {

	void EnterSymbolizer() {
	Thread *t = GetCurrentThread();
	CHECK(t);
	t->EnterSymbolizer();
	}
	void ExitSymbolizer() {
	Thread *t = GetCurrentThread();
	CHECK(t);
	t->LeaveSymbolizer();
	}
	bool IsInSymbolizer() {
	Thread *t = GetCurrentThread();
	return t && t->InSymbolizer();
	}

	static Flags hwasan_flags;

	Flags *flags() {
	return &hwasan_flags;
	}

	int hwasan_inited = 0;
	int hwasan_shadow_inited = 0;
	bool hwasan_init_is_running;

	int hwasan_report_count = 0;

	void Flags::SetDefaults() {
	#define HWASAN_FLAG(Type, Name, DefaultValue, Description) Name = DefaultValue;
	#include "hwasan_flags.inc"
	#undef HWASAN_FLAG
	}

	static void RegisterHwasanFlags(FlagParser parser, Flags f) {
	#define HWASAN_FLAG(Type, Name, DefaultValue, Description) \
	RegisterFlag(parser, #Name, Description, &f->Name);
	#include "hwasan_flags.inc"
	#undef HWASAN_FLAG
	}

	static void InitializeFlags() {
	SetCommonFlagsDefaults();
	{
	CommonFlags cf;
	cf.CopyFrom(*common_flags());
	cf.external_symbolizer_path = GetEnv("HWASAN_SYMBOLIZER_PATH");
	cf.malloc_context_size = 20;
	cf.handle_ioctl = true;
	// FIXME: test and enable.
	cf.check_printf = false;
	cf.intercept_tls_get_addr = true;
	cf.exitcode = 99;
	// Sigtrap is used in error reporting.
	cf.handle_sigtrap = kHandleSignalExclusive;

	#if SANITIZER_ANDROID
	// Let platform handle other signals. It is better at reporting them then we
	// are.
	cf.handle_segv = kHandleSignalNo;
	cf.handle_sigbus = kHandleSignalNo;
	cf.handle_abort = kHandleSignalNo;
	cf.handle_sigill = kHandleSignalNo;
	cf.handle_sigfpe = kHandleSignalNo;
	#endif
	OverrideCommonFlags(cf);
	}

	Flags *f = flags();
	f->SetDefaults();

	FlagParser parser;
	RegisterHwasanFlags(&parser, f);
	RegisterCommonFlags(&parser);

	#if HWASAN_CONTAINS_UBSAN
	__ubsan::Flags *uf = __ubsan::flags();
	uf->SetDefaults();

	FlagParser ubsan_parser;
	__ubsan::RegisterUbsanFlags(&ubsan_parser, uf);
	RegisterCommonFlags(&ubsan_parser);
	#endif

	// Override from user-specified string.
	if (__hwasan_default_options)
	parser.ParseString(__hwasan_default_options());
	#if HWASAN_CONTAINS_UBSAN
	const char *ubsan_default_options = __ubsan::MaybeCallUbsanDefaultOptions();
	ubsan_parser.ParseString(ubsan_default_options);
	#endif

	const char *hwasan_options = GetEnv("HWASAN_OPTIONS");
	parser.ParseString(hwasan_options);
	#if HWASAN_CONTAINS_UBSAN
	ubsan_parser.ParseString(GetEnv("UBSAN_OPTIONS"));
	#endif
	VPrintf(1, "HWASAN_OPTIONS: %s\n",
	hwasan_options ? hwasan_options : "<empty>");

	InitializeCommonFlags();

	if (Verbosity()) ReportUnrecognizedFlags();

	if (common_flags()->help) parser.PrintFlagDescriptions();
	}

	void GetStackTrace(BufferedStackTrace *stack, uptr max_s, uptr pc, uptr bp,
	void *context, bool request_fast_unwind) {
	Thread *t = GetCurrentThread();
	if (!t) {
	// the thread is still being created.
	stack->size = 0;
	return;
	}
	if (!StackTrace::WillUseFastUnwind(request_fast_unwind)) {
	// Block reports from our interceptors during _Unwind_Backtrace.
	SymbolizerScope sym_scope;
	return stack->Unwind(max_s, pc, bp, context, 0, 0, request_fast_unwind);
	}
	stack->Unwind(max_s, pc, bp, context, t->stack_top(), t->stack_bottom(),
	request_fast_unwind);
	}

	static void HWAsanCheckFailed(const char file, int line, const char cond,
	u64 v1, u64 v2) {
	Report("HWAddressSanitizer CHECK failed: %s:%d \"%s\" (0x%zx, 0x%zx)\n", file,
	line, cond, (uptr)v1, (uptr)v2);
	PRINT_CURRENT_STACK_CHECK();
	Die();
	}

	static constexpr uptr kMemoryUsageBufferSize = 4096;

	static void HwasanFormatMemoryUsage(InternalScopedString &s) {
	HwasanThreadList &thread_list = hwasanThreadList();
	auto thread_stats = thread_list.GetThreadStats();
	auto *sds = StackDepotGetStats();
	AllocatorStatCounters asc;
	GetAllocatorStats(asc);
	s.append(
	"HWASAN pid: %d rss: %zd threads: %zd stacks: %zd"
	" thr_aux: %zd stack_depot: %zd uniq_stacks: %zd"
	" heap: %zd",
	internal_getpid(), GetRSS(), thread_stats.n_live_threads,
	thread_stats.total_stack_size,
	thread_stats.n_live_threads * thread_list.MemoryUsedPerThread(),
	sds->allocated, sds->n_uniq_ids, asc[AllocatorStatMapped]);
	}

	#if SANITIZER_ANDROID
	static char *memory_usage_buffer = nullptr;

	#define PR_SET_VMA 0x53564d41
	#define PR_SET_VMA_ANON_NAME 0

	static void InitMemoryUsage() {
	memory_usage_buffer =
	(char *)MmapOrDie(kMemoryUsageBufferSize, "memory usage string");
	CHECK(memory_usage_buffer);
	memory_usage_buffer[0] = '\0';
	CHECK(internal_prctl(PR_SET_VMA, PR_SET_VMA_ANON_NAME,
	(uptr)memory_usage_buffer, kMemoryUsageBufferSize,
	(uptr)memory_usage_buffer) == 0);
	}

	void UpdateMemoryUsage() {
	if (!flags()->export_memory_stats)
	return;
	if (!memory_usage_buffer)
	InitMemoryUsage();
	InternalScopedString s(kMemoryUsageBufferSize);
	HwasanFormatMemoryUsage(s);
	internal_strncpy(memory_usage_buffer, s.data(), kMemoryUsageBufferSize - 1);
	memory_usage_buffer[kMemoryUsageBufferSize - 1] = '\0';
	}
	#else
	void UpdateMemoryUsage() {}
	#endif

	struct FrameDescription {
	uptr PC;
	const char *Descr;
	};

	struct FrameDescriptionArray {
	FrameDescription beg, end;
	};

	static InternalMmapVectorNoCtor<FrameDescriptionArray> AllFrames;

	void InitFrameDescriptors(uptr b, uptr e) {
	FrameDescription beg = reinterpret_cast<FrameDescription >(b);
	FrameDescription end = reinterpret_cast<FrameDescription >(e);
	if (beg == end)
	return;
	AllFrames.push_back({beg, end});
	if (Verbosity())
	for (FrameDescription *frame_descr = beg; frame_descr < end; frame_descr++)
	Printf("Frame: %p %s\n", frame_descr->PC, frame_descr->Descr);
	}

	const char *GetStackFrameDescr(uptr pc) {
	for (uptr i = 0, n = AllFrames.size(); i < n; i++)
	for (auto p = AllFrames[i].beg; p < AllFrames[i].end; p++)
	if (p->PC == pc)
	return p->Descr;
	return nullptr;
	}

	} // namespace __hwasan

	// Interface.

	using namespace __hwasan;

	uptr __hwasan_shadow_memory_dynamic_address; // Global interface symbol.

	void __hwasan_shadow_init() {
	if (hwasan_shadow_inited) return;
	if (!InitShadow()) {
	Printf("FATAL: HWAddressSanitizer cannot mmap the shadow memory.\n");
	DumpProcessMap();
	Die();
	}
	hwasan_shadow_inited = 1;
	}

	void __hwasan_init_frames(uptr beg, uptr end) {
	InitFrameDescriptors(beg, end);
	}

	void __hwasan_init() {
	CHECK(!hwasan_init_is_running);
	if (hwasan_inited) return;
	hwasan_init_is_running = 1;
	SanitizerToolName = "HWAddressSanitizer";

	InitTlsSize();

	CacheBinaryName();
	InitializeFlags();

	// Install tool-specific callbacks in sanitizer_common.
	SetCheckFailedCallback(HWAsanCheckFailed);

	__sanitizer_set_report_path(common_flags()->log_path);

	AndroidTestTlsSlot();

	DisableCoreDumperIfNecessary();

	__hwasan_shadow_init();

	InitThreads();
	hwasanThreadList().CreateCurrentThread();

	MadviseShadow();

	SetPrintfAndReportCallback(AppendToErrorMessageBuffer);
	// This may call libc -> needs initialized shadow.
	AndroidLogInit();

	InitializeInterceptors();
	InstallDeadlySignalHandlers(HwasanOnDeadlySignal);
	InstallAtExitHandler(); // Needs __cxa_atexit interceptor.

	Symbolizer::GetOrInit()->AddHooks(EnterSymbolizer, ExitSymbolizer);

	InitializeCoverage(common_flags()->coverage, common_flags()->coverage_dir);

	HwasanTSDInit();
	HwasanTSDThreadInit();

	HwasanAllocatorInit();

	#if HWASAN_CONTAINS_UBSAN
	__ubsan::InitAsPlugin();
	#endif

	VPrintf(1, "HWAddressSanitizer init done\n");

	hwasan_init_is_running = 0;
	hwasan_inited = 1;
	}

	void __hwasan_print_shadow(const void *p, uptr sz) {
	uptr ptr_raw = UntagAddr(reinterpret_cast<uptr>(p));
	uptr shadow_first = MemToShadow(ptr_raw);
	uptr shadow_last = MemToShadow(ptr_raw + sz - 1);
	Printf("HWASan shadow map for %zx .. %zx (pointer tag %x)\n", ptr_raw,
	ptr_raw + sz, GetTagFromPointer((uptr)p));
	for (uptr s = shadow_first; s <= shadow_last; ++s)
	Printf(" %zx: %x\n", ShadowToMem(s), (tag_t )s);
	}

	sptr __hwasan_test_shadow(const void *p, uptr sz) {
	if (sz == 0)
	return -1;
	tag_t ptr_tag = GetTagFromPointer((uptr)p);
	if (ptr_tag == 0)
	return -1;
	uptr ptr_raw = UntagAddr(reinterpret_cast<uptr>(p));
	uptr shadow_first = MemToShadow(ptr_raw);
	uptr shadow_last = MemToShadow(ptr_raw + sz - 1);
	for (uptr s = shadow_first; s <= shadow_last; ++s)
	if ((tag_t)s != ptr_tag)
	return ShadowToMem(s) - ptr_raw;
	return -1;
	}

	u16 __sanitizer_unaligned_load16(const uu16 *p) {
	return *p;
	}
	u32 __sanitizer_unaligned_load32(const uu32 *p) {
	return *p;
	}
	u64 __sanitizer_unaligned_load64(const uu64 *p) {
	return *p;
	}
	void __sanitizer_unaligned_store16(uu16 *p, u16 x) {
	*p = x;
	}
	void __sanitizer_unaligned_store32(uu32 *p, u32 x) {
	*p = x;
	}
	void __sanitizer_unaligned_store64(uu64 *p, u64 x) {
	*p = x;
	}

	template<unsigned X>
	__attribute__((always_inline))
	static void SigTrap(uptr p) {
	#if defined(__aarch64__)
	(void)p;
	// 0x900 is added to do not interfere with the kernel use of lower values of
	// brk immediate.
	// FIXME: Add a constraint to put the pointer into x0, the same as x86 branch.
	asm("brk %0\n\t" ::"n"(0x900 + X));
	#elif defined(__x86_64__)
	// INT3 + NOP DWORD ptr [EAX + X] to pass X to our signal handler, 5 bytes
	// total. The pointer is passed via rdi.
	// 0x40 is added as a safeguard, to help distinguish our trap from others and
	// to avoid 0 offsets in the command (otherwise it'll be reduced to a
	// different nop command, the three bytes one).
	asm volatile(
	"int3\n"
	"nopl %c0(%%rax)\n"
	:: "n"(0x40 + X), "D"(p));
	#else
	// FIXME: not always sigill.
	__builtin_trap();
	#endif
	// __builtin_unreachable();
	}

	enum class ErrorAction { Abort, Recover };
	enum class AccessType { Load, Store };

	template <ErrorAction EA, AccessType AT, unsigned LogSize>
	__attribute__((always_inline, nodebug)) static void CheckAddress(uptr p) {
	tag_t ptr_tag = GetTagFromPointer(p);
	uptr ptr_raw = p & ~kAddressTagMask;
	tag_t mem_tag = (tag_t )MemToShadow(ptr_raw);
	if (UNLIKELY(ptr_tag != mem_tag)) {
	SigTrap<0x20 * (EA == ErrorAction::Recover) +
	0x10 * (AT == AccessType::Store) + LogSize>(p);
	if (EA == ErrorAction::Abort) __builtin_unreachable();
	}
	}

	template <ErrorAction EA, AccessType AT>
	__attribute__((always_inline, nodebug)) static void CheckAddressSized(uptr p,
	uptr sz) {
	CHECK_NE(0, sz);
	tag_t ptr_tag = GetTagFromPointer(p);
	uptr ptr_raw = p & ~kAddressTagMask;
	tag_t shadow_first = (tag_t )MemToShadow(ptr_raw);
	tag_t shadow_last = (tag_t )MemToShadow(ptr_raw + sz - 1);
	for (tag_t *t = shadow_first; t <= shadow_last; ++t)
	if (UNLIKELY(ptr_tag != *t)) {
	SigTrap<0x20 * (EA == ErrorAction::Recover) +
	0x10 * (AT == AccessType::Store) + 0xf>(p);
	if (EA == ErrorAction::Abort) __builtin_unreachable();
	}
	}

	void __hwasan_loadN(uptr p, uptr sz) {
	CheckAddressSized<ErrorAction::Abort, AccessType::Load>(p, sz);
	}
	void __hwasan_load1(uptr p) {
	CheckAddress<ErrorAction::Abort, AccessType::Load, 0>(p);
	}
	void __hwasan_load2(uptr p) {
	CheckAddress<ErrorAction::Abort, AccessType::Load, 1>(p);
	}
	void __hwasan_load4(uptr p) {
	CheckAddress<ErrorAction::Abort, AccessType::Load, 2>(p);
	}
	void __hwasan_load8(uptr p) {
	CheckAddress<ErrorAction::Abort, AccessType::Load, 3>(p);
	}
	void __hwasan_load16(uptr p) {
	CheckAddress<ErrorAction::Abort, AccessType::Load, 4>(p);
	}

	void __hwasan_loadN_noabort(uptr p, uptr sz) {
	CheckAddressSized<ErrorAction::Recover, AccessType::Load>(p, sz);
	}
	void __hwasan_load1_noabort(uptr p) {
	CheckAddress<ErrorAction::Recover, AccessType::Load, 0>(p);
	}
	void __hwasan_load2_noabort(uptr p) {
	CheckAddress<ErrorAction::Recover, AccessType::Load, 1>(p);
	}
	void __hwasan_load4_noabort(uptr p) {
	CheckAddress<ErrorAction::Recover, AccessType::Load, 2>(p);
	}
	void __hwasan_load8_noabort(uptr p) {
	CheckAddress<ErrorAction::Recover, AccessType::Load, 3>(p);
	}
	void __hwasan_load16_noabort(uptr p) {
	CheckAddress<ErrorAction::Recover, AccessType::Load, 4>(p);
	}

	void __hwasan_storeN(uptr p, uptr sz) {
	CheckAddressSized<ErrorAction::Abort, AccessType::Store>(p, sz);
	}
	void __hwasan_store1(uptr p) {
	CheckAddress<ErrorAction::Abort, AccessType::Store, 0>(p);
	}
	void __hwasan_store2(uptr p) {
	CheckAddress<ErrorAction::Abort, AccessType::Store, 1>(p);
	}
	void __hwasan_store4(uptr p) {
	CheckAddress<ErrorAction::Abort, AccessType::Store, 2>(p);
	}
	void __hwasan_store8(uptr p) {
	CheckAddress<ErrorAction::Abort, AccessType::Store, 3>(p);
	}
	void __hwasan_store16(uptr p) {
	CheckAddress<ErrorAction::Abort, AccessType::Store, 4>(p);
	}

	void __hwasan_storeN_noabort(uptr p, uptr sz) {
	CheckAddressSized<ErrorAction::Recover, AccessType::Store>(p, sz);
	}
	void __hwasan_store1_noabort(uptr p) {
	CheckAddress<ErrorAction::Recover, AccessType::Store, 0>(p);
	}
	void __hwasan_store2_noabort(uptr p) {
	CheckAddress<ErrorAction::Recover, AccessType::Store, 1>(p);
	}
	void __hwasan_store4_noabort(uptr p) {
	CheckAddress<ErrorAction::Recover, AccessType::Store, 2>(p);
	}
	void __hwasan_store8_noabort(uptr p) {
	CheckAddress<ErrorAction::Recover, AccessType::Store, 3>(p);
	}
	void __hwasan_store16_noabort(uptr p) {
	CheckAddress<ErrorAction::Recover, AccessType::Store, 4>(p);
	}

	void __hwasan_tag_memory(uptr p, u8 tag, uptr sz) {
	TagMemoryAligned(p, sz, tag);
	}

	uptr __hwasan_tag_pointer(uptr p, u8 tag) {
	return AddTagToPointer(p, tag);
	}

	void __hwasan_handle_longjmp(const void *sp_dst) {
	uptr dst = (uptr)sp_dst;
	// HWASan does not support tagged SP.
	CHECK(GetTagFromPointer(dst) == 0);

	uptr sp = (uptr)__builtin_frame_address(0);
	static const uptr kMaxExpectedCleanupSize = 64 << 20; // 64M
	if (dst < sp \|\| dst - sp > kMaxExpectedCleanupSize) {
	Report(
	"WARNING: HWASan is ignoring requested __hwasan_handle_longjmp: "
	"stack top: %p; target %p; distance: %p (%zd)\n"
	"False positive error reports may follow\n",
	(void )sp, (void )dst, dst - sp);
	return;
	}
	TagMemory(sp, dst - sp, 0);
	}

	void __hwasan_print_memory_usage() {
	InternalScopedString s(kMemoryUsageBufferSize);
	HwasanFormatMemoryUsage(s);
	Printf("%s\n", s.data());
	}

	static const u8 kFallbackTag = 0xBB;

	u8 __hwasan_generate_tag() {
	Thread *t = GetCurrentThread();
	if (!t) return kFallbackTag;
	return t->GenerateRandomTag();
	}

	#if !SANITIZER_SUPPORTS_WEAK_HOOKS
	extern "C" {
	SANITIZER_INTERFACE_ATTRIBUTE SANITIZER_WEAK_ATTRIBUTE
	const char* __hwasan_default_options() { return ""; }
	} // extern "C"
	#endif

	extern "C" {
	SANITIZER_INTERFACE_ATTRIBUTE
	void __sanitizer_print_stack_trace() {
	GET_FATAL_STACK_TRACE_PC_BP(StackTrace::GetCurrentPc(), GET_CURRENT_FRAME());
	stack.Print();
	}
	} // extern "C"