compiler-rt/lib/asan/asan_rtl.cc - external/github.com/llvm/llvm-project.git - Git at Google

 //===-- asan_rtl.cc ---------------------------------------------*- C++ -*-===//
 //
 //                     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.
 //
 // Main file of the ASan run-time library.
 //===----------------------------------------------------------------------===//
 #include "asan_allocator.h"
 #include "asan_interceptors.h"
 #include "asan_interface.h"
 #include "asan_internal.h"
 #include "asan_lock.h"
 #include "asan_mapping.h"
 #include "asan_procmaps.h"
 #include "asan_stack.h"
 #include "asan_stats.h"
 #include "asan_thread.h"
 #include "asan_thread_registry.h"

 namespace __asan {

 // -------------------------- Flags ------------------------- {{{1
 static const size_t kMallocContextSize = 30;
 static int    FLAG_atexit;

 size_t FLAG_redzone;  // power of two, >= 32
 size_t FLAG_quarantine_size;
 int    FLAG_demangle;
 bool   FLAG_symbolize;
 int    FLAG_v;
 int    FLAG_debug;
 bool   FLAG_poison_shadow;
 int    FLAG_report_globals;
 size_t FLAG_malloc_context_size = kMallocContextSize;
 uintptr_t FLAG_large_malloc;
 bool   FLAG_handle_segv;
 bool   FLAG_replace_str;
 bool   FLAG_replace_intrin;
 bool   FLAG_replace_cfallocator;  // Used on Mac only.
 size_t FLAG_max_malloc_fill_size = 0;
 bool   FLAG_use_fake_stack;
 int    FLAG_exitcode = EXIT_FAILURE;
 bool   FLAG_allow_user_poisoning;
 int    FLAG_sleep_before_dying;

 // -------------------------- Globals --------------------- {{{1
 int asan_inited;
 bool asan_init_is_running;

 // -------------------------- Misc ---------------- {{{1
 void ShowStatsAndAbort() {
   __asan_print_accumulated_stats();
   AsanDie();
 }

 static void PrintBytes(const char *before, uintptr_t *a) {
   uint8_t *bytes = (uint8_t*)a;
   size_t byte_num = (__WORDSIZE) / 8;
   Printf("%s%p:", before, (uintptr_t)a);
   for (size_t i = 0; i < byte_num; i++) {
     Printf(" %lx%lx", bytes[i] >> 4, bytes[i] & 15);
   }
   Printf("\n");
 }

 size_t ReadFileToBuffer(const char *file_name, char **buff,
                          size_t *buff_size, size_t max_len) {
   const size_t kMinFileLen = kPageSize;
   size_t read_len = 0;
   *buff = 0;
   *buff_size = 0;
   // The files we usually open are not seekable, so try different buffer sizes.
   for (size_t size = kMinFileLen; size <= max_len; size *= 2) {
     int fd = AsanOpenReadonly(file_name);
     if (fd < 0) return -1;
     AsanUnmapOrDie(*buff, *buff_size);
     *buff = (char*)AsanMmapSomewhereOrDie(size, __FUNCTION__);
     *buff_size = size;
     // Read up to one page at a time.
     read_len = 0;
     bool reached_eof = false;
     while (read_len + kPageSize <= size) {
       size_t just_read = AsanRead(fd, *buff + read_len, kPageSize);
       if (just_read == 0) {
         reached_eof = true;
         break;
       }
       read_len += just_read;
     }
     AsanClose(fd);
     if (reached_eof)  // We've read the whole file.
       break;
   }
   return read_len;
 }

 // ---------------------- mmap -------------------- {{{1
 void OutOfMemoryMessageAndDie(const char *mem_type, size_t size) {
   Report("ERROR: AddressSanitizer failed to allocate "
          "0x%lx (%ld) bytes of %s\n",
          size, size, mem_type);
   PRINT_CURRENT_STACK();
   ShowStatsAndAbort();
 }

 // Reserve memory range [beg, end].
 static void ReserveShadowMemoryRange(uintptr_t beg, uintptr_t end) {
   CHECK((beg % kPageSize) == 0);
   CHECK(((end + 1) % kPageSize) == 0);
   size_t size = end - beg + 1;
   void *res = AsanMmapFixedNoReserve(beg, size);
   CHECK(res == (void*)beg && "ReserveShadowMemoryRange failed");
 }

 // ---------------------- LowLevelAllocator ------------- {{{1
 void *LowLevelAllocator::Allocate(size_t size) {
   CHECK((size & (size - 1)) == 0 && "size must be a power of two");
   if (allocated_end_ - allocated_current_ < size) {
     size_t size_to_allocate = Max(size, kPageSize);
     allocated_current_ =
         (char*)AsanMmapSomewhereOrDie(size_to_allocate, __FUNCTION__);
     allocated_end_ = allocated_current_ + size_to_allocate;
     PoisonShadow((uintptr_t)allocated_current_, size_to_allocate,
                  kAsanInternalHeapMagic);
   }
   CHECK(allocated_end_ - allocated_current_ >= size);
   void *res = allocated_current_;
   allocated_current_ += size;
   return res;
 }

 // ---------------------- DescribeAddress -------------------- {{{1
 static bool DescribeStackAddress(uintptr_t addr, uintptr_t access_size) {
   AsanThread *t = asanThreadRegistry().FindThreadByStackAddress(addr);
   if (!t) return false;
   const intptr_t kBufSize = 4095;
   char buf[kBufSize];
   uintptr_t offset = 0;
   const char *frame_descr = t->GetFrameNameByAddr(addr, &offset);
   // This string is created by the compiler and has the following form:
   // "FunctioName n alloc_1 alloc_2 ... alloc_n"
   // where alloc_i looks like "offset size len ObjectName ".
   CHECK(frame_descr);
   // Report the function name and the offset.
   const char *name_end = real_strchr(frame_descr, ' ');
   CHECK(name_end);
   buf[0] = 0;
   internal_strncat(buf, frame_descr,
                    Min(kBufSize,
                        static_cast<intptr_t>(name_end - frame_descr)));
   Printf("Address %p is located at offset %ld "
          "in frame <%s> of T%d's stack:\n",
          addr, offset, buf, t->tid());
   // Report the number of stack objects.
   char *p;
   size_t n_objects = strtol(name_end, &p, 10);
   CHECK(n_objects > 0);
   Printf("  This frame has %ld object(s):\n", n_objects);
   // Report all objects in this frame.
   for (size_t i = 0; i < n_objects; i++) {
     size_t beg, size;
     intptr_t len;
     beg  = strtol(p, &p, 10);
     size = strtol(p, &p, 10);
     len  = strtol(p, &p, 10);
     if (beg <= 0 || size <= 0 || len < 0 || *p != ' ') {
       Printf("AddressSanitizer can't parse the stack frame descriptor: |%s|\n",
              frame_descr);
       break;
     }
     p++;
     buf[0] = 0;
     internal_strncat(buf, p, Min(kBufSize, len));
     p += len;
     Printf("    [%ld, %ld) '%s'\n", beg, beg + size, buf);
   }
   Printf("HINT: this may be a false positive if your program uses "
          "some custom stack unwind mechanism\n"
          "      (longjmp and C++ exceptions *are* supported)\n");
   t->summary()->Announce();
   return true;
 }

 static NOINLINE void DescribeAddress(uintptr_t addr, uintptr_t access_size) {
   // Check if this is a global.
   if (DescribeAddrIfGlobal(addr))
     return;

   if (DescribeStackAddress(addr, access_size))
     return;

   // finally, check if this is a heap.
   DescribeHeapAddress(addr, access_size);
 }

 // -------------------------- Run-time entry ------------------- {{{1
 // exported functions
 #define ASAN_REPORT_ERROR(type, is_write, size)                     \
 NOINLINE ASAN_INTERFACE_ATTRIBUTE                                   \
 extern "C" void __asan_report_ ## type ## size(uintptr_t addr);     \
 extern "C" void __asan_report_ ## type ## size(uintptr_t addr) {    \
   GET_BP_PC_SP;                                                     \
   __asan_report_error(pc, bp, sp, addr, is_write, size);            \
 }

 ASAN_REPORT_ERROR(load, false, 1)
 ASAN_REPORT_ERROR(load, false, 2)
 ASAN_REPORT_ERROR(load, false, 4)
 ASAN_REPORT_ERROR(load, false, 8)
 ASAN_REPORT_ERROR(load, false, 16)
 ASAN_REPORT_ERROR(store, true, 1)
 ASAN_REPORT_ERROR(store, true, 2)
 ASAN_REPORT_ERROR(store, true, 4)
 ASAN_REPORT_ERROR(store, true, 8)
 ASAN_REPORT_ERROR(store, true, 16)

 // Force the linker to keep the symbols for various ASan interface functions.
 // We want to keep those in the executable in order to let the instrumented
 // dynamic libraries access the symbol even if it is not used by the executable
 // itself. This should help if the build system is removing dead code at link
 // time.
 static void force_interface_symbols() {
   volatile int fake_condition = 0;  // prevent dead condition elimination.
   if (fake_condition) {
     __asan_report_load1(NULL);
     __asan_report_load2(NULL);
     __asan_report_load4(NULL);
     __asan_report_load8(NULL);
     __asan_report_load16(NULL);
     __asan_report_store1(NULL);
     __asan_report_store2(NULL);
     __asan_report_store4(NULL);
     __asan_report_store8(NULL);
     __asan_report_store16(NULL);
     __asan_register_global(0, 0, NULL);
     __asan_register_globals(NULL, 0);
     __asan_unregister_globals(NULL, 0);
   }
 }

 // -------------------------- Init ------------------- {{{1
 #if defined(_WIN32)
 // atoll is not defined on Windows.
 int64_t atoll(const char *str) {
   UNIMPLEMENTED();
   return -1;
 }
 #endif

 static int64_t IntFlagValue(const char *flags, const char *flag,
                             int64_t default_val) {
   if (!flags) return default_val;
   const char *str = internal_strstr(flags, flag);
   if (!str) return default_val;
   return atoll(str + internal_strlen(flag));
 }

 static void asan_atexit() {
   Printf("AddressSanitizer exit stats:\n");
   __asan_print_accumulated_stats();
 }

 void CheckFailed(const char *cond, const char *file, int line) {
   Report("CHECK failed: %s at %s:%d\n", cond, file, line);
   PRINT_CURRENT_STACK();
   ShowStatsAndAbort();
 }

 }  // namespace __asan

 // ---------------------- Interface ---------------- {{{1
 using namespace __asan;  // NOLINT

 int __asan_set_error_exit_code(int exit_code) {
   int old = FLAG_exitcode;
   FLAG_exitcode = exit_code;
   return old;
 }

 void __asan_report_error(uintptr_t pc, uintptr_t bp, uintptr_t sp,
                          uintptr_t addr, bool is_write, size_t access_size) {
   // Do not print more than one report, otherwise they will mix up.
   static int num_calls = 0;
   if (AtomicInc(&num_calls) > 1) return;

   Printf("=================================================================\n");
   const char *bug_descr = "unknown-crash";
   if (AddrIsInMem(addr)) {
     uint8_t *shadow_addr = (uint8_t*)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++;
     switch (*shadow_addr) {
       case kAsanHeapLeftRedzoneMagic:
       case kAsanHeapRightRedzoneMagic:
         bug_descr = "heap-buffer-overflow";
         break;
       case kAsanHeapFreeMagic:
         bug_descr = "heap-use-after-free";
         break;
       case kAsanStackLeftRedzoneMagic:
         bug_descr = "stack-buffer-underflow";
         break;
       case kAsanStackMidRedzoneMagic:
       case kAsanStackRightRedzoneMagic:
       case kAsanStackPartialRedzoneMagic:
         bug_descr = "stack-buffer-overflow";
         break;
       case kAsanStackAfterReturnMagic:
         bug_descr = "stack-use-after-return";
         break;
       case kAsanUserPoisonedMemoryMagic:
         bug_descr = "use-after-poison";
         break;
       case kAsanGlobalRedzoneMagic:
         bug_descr = "global-buffer-overflow";
         break;
     }
   }

   AsanThread *curr_thread = asanThreadRegistry().GetCurrent();
   int curr_tid = asanThreadRegistry().GetCurrentTidOrMinusOne();

   if (curr_thread) {
     // We started reporting an error message. Stop using the fake stack
     // in case we will call an instrumented function from a symbolizer.
     curr_thread->fake_stack().StopUsingFakeStack();
   }

   Report("ERROR: AddressSanitizer %s on address "
          "%p at pc 0x%lx bp 0x%lx sp 0x%lx\n",
          bug_descr, addr, pc, bp, sp);

   Printf("%s of size %d at %p thread T%d\n",
          access_size ? (is_write ? "WRITE" : "READ") : "ACCESS",
          access_size, addr, curr_tid);

   if (FLAG_debug) {
     PrintBytes("PC: ", (uintptr_t*)pc);
   }

   GET_STACK_TRACE_WITH_PC_AND_BP(kStackTraceMax, pc, bp);
   stack.PrintStack();

   CHECK(AddrIsInMem(addr));

   DescribeAddress(addr, access_size);

   uintptr_t shadow_addr = MemToShadow(addr);
   Report("ABORTING\n");
   __asan_print_accumulated_stats();
   Printf("Shadow byte and word:\n");
   Printf("  %p: %x\n", shadow_addr, *(unsigned char*)shadow_addr);
   uintptr_t aligned_shadow = shadow_addr & ~(kWordSize - 1);
   PrintBytes("  ", (uintptr_t*)(aligned_shadow));
   Printf("More shadow bytes:\n");
   PrintBytes("  ", (uintptr_t*)(aligned_shadow-4*kWordSize));
   PrintBytes("  ", (uintptr_t*)(aligned_shadow-3*kWordSize));
   PrintBytes("  ", (uintptr_t*)(aligned_shadow-2*kWordSize));
   PrintBytes("  ", (uintptr_t*)(aligned_shadow-1*kWordSize));
   PrintBytes("=>", (uintptr_t*)(aligned_shadow+0*kWordSize));
   PrintBytes("  ", (uintptr_t*)(aligned_shadow+1*kWordSize));
   PrintBytes("  ", (uintptr_t*)(aligned_shadow+2*kWordSize));
   PrintBytes("  ", (uintptr_t*)(aligned_shadow+3*kWordSize));
   PrintBytes("  ", (uintptr_t*)(aligned_shadow+4*kWordSize));
   AsanDie();
 }

 void __asan_init() {
   if (asan_inited) return;
   asan_init_is_running = true;

   // Make sure we are not statically linked.
   AsanDoesNotSupportStaticLinkage();

   // flags
   const char *options = AsanGetEnv("ASAN_OPTIONS");
   FLAG_malloc_context_size =
       IntFlagValue(options, "malloc_context_size=", kMallocContextSize);
   CHECK(FLAG_malloc_context_size <= kMallocContextSize);

   FLAG_max_malloc_fill_size =
       IntFlagValue(options, "max_malloc_fill_size=", 0);

   FLAG_v = IntFlagValue(options, "verbosity=", 0);

   FLAG_redzone = IntFlagValue(options, "redzone=", 128);
   CHECK(FLAG_redzone >= 32);
   CHECK((FLAG_redzone & (FLAG_redzone - 1)) == 0);

   FLAG_atexit = IntFlagValue(options, "atexit=", 0);
   FLAG_poison_shadow = IntFlagValue(options, "poison_shadow=", 1);
   FLAG_report_globals = IntFlagValue(options, "report_globals=", 1);
   FLAG_handle_segv = IntFlagValue(options, "handle_segv=", ASAN_NEEDS_SEGV);
   FLAG_symbolize = IntFlagValue(options, "symbolize=", 1);
   FLAG_demangle = IntFlagValue(options, "demangle=", 1);
   FLAG_debug = IntFlagValue(options, "debug=", 0);
   FLAG_replace_cfallocator = IntFlagValue(options, "replace_cfallocator=", 1);
   FLAG_replace_str = IntFlagValue(options, "replace_str=", 1);
   FLAG_replace_intrin = IntFlagValue(options, "replace_intrin=", 1);
   FLAG_use_fake_stack = IntFlagValue(options, "use_fake_stack=", 1);
   FLAG_exitcode = IntFlagValue(options, "exitcode=", EXIT_FAILURE);
   FLAG_allow_user_poisoning = IntFlagValue(options,
                                            "allow_user_poisoning=", 1);
   FLAG_sleep_before_dying = IntFlagValue(options, "sleep_before_dying=", 0);

   if (FLAG_atexit) {
     atexit(asan_atexit);
   }

   FLAG_quarantine_size =
       IntFlagValue(options, "quarantine_size=", 1UL << 28);

   // interceptors
   InitializeAsanInterceptors();

   ReplaceSystemMalloc();
   InstallSignalHandlers();

   if (FLAG_v) {
     Printf("|| `[%p, %p]` || HighMem    ||\n", kHighMemBeg, kHighMemEnd);
     Printf("|| `[%p, %p]` || HighShadow ||\n",
            kHighShadowBeg, kHighShadowEnd);
     Printf("|| `[%p, %p]` || ShadowGap  ||\n",
            kShadowGapBeg, kShadowGapEnd);
     Printf("|| `[%p, %p]` || LowShadow  ||\n",
            kLowShadowBeg, kLowShadowEnd);
     Printf("|| `[%p, %p]` || LowMem     ||\n", kLowMemBeg, kLowMemEnd);
     Printf("MemToShadow(shadow): %p %p %p %p\n",
            MEM_TO_SHADOW(kLowShadowBeg),
            MEM_TO_SHADOW(kLowShadowEnd),
            MEM_TO_SHADOW(kHighShadowBeg),
            MEM_TO_SHADOW(kHighShadowEnd));
     Printf("red_zone=%ld\n", FLAG_redzone);
     Printf("malloc_context_size=%ld\n", (int)FLAG_malloc_context_size);

     Printf("SHADOW_SCALE: %lx\n", SHADOW_SCALE);
     Printf("SHADOW_GRANULARITY: %lx\n", SHADOW_GRANULARITY);
     Printf("SHADOW_OFFSET: %lx\n", SHADOW_OFFSET);
     CHECK(SHADOW_SCALE >= 3 && SHADOW_SCALE <= 7);
   }

   if (__WORDSIZE == 64) {
     // Disable core dumper -- it makes little sense to dump 16T+ core.
     AsanDisableCoreDumper();
   }

   {
     if (kLowShadowBeg != kLowShadowEnd) {
       // mmap the low shadow plus one page.
       ReserveShadowMemoryRange(kLowShadowBeg - kPageSize, kLowShadowEnd);
     }
     // mmap the high shadow.
     ReserveShadowMemoryRange(kHighShadowBeg, kHighShadowEnd);
     // protect the gap
     void *prot = AsanMprotect(kShadowGapBeg, kShadowGapEnd - kShadowGapBeg + 1);
     CHECK(prot == (void*)kShadowGapBeg);
   }

   // On Linux AsanThread::ThreadStart() calls malloc() that's why asan_inited
   // should be set to 1 prior to initializing the threads.
   asan_inited = 1;
   asan_init_is_running = false;

   asanThreadRegistry().Init();
   asanThreadRegistry().GetMain()->ThreadStart();
   force_interface_symbols();  // no-op.

   if (FLAG_v) {
     Report("AddressSanitizer Init done\n");
   }
 }

 #if defined(ASAN_USE_PREINIT_ARRAY)
 // On Linux, we force __asan_init to be called before anyone else
 // by placing it into .preinit_array section.
 // FIXME: do we have anything like this on Mac?
 __attribute__((section(".preinit_array")))
   typeof(__asan_init) *__asan_preinit =__asan_init;
 #endif
	//===-- asan_rtl.cc ---------------------------------------------- C++ --===//
	//
	// 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.
	//
	// Main file of the ASan run-time library.
	//===----------------------------------------------------------------------===//
	#include "asan_allocator.h"
	#include "asan_interceptors.h"
	#include "asan_interface.h"
	#include "asan_internal.h"
	#include "asan_lock.h"
	#include "asan_mapping.h"
	#include "asan_procmaps.h"
	#include "asan_stack.h"
	#include "asan_stats.h"
	#include "asan_thread.h"
	#include "asan_thread_registry.h"

	namespace __asan {

	// -------------------------- Flags ------------------------- {{{1
	static const size_t kMallocContextSize = 30;
	static int FLAG_atexit;

	size_t FLAG_redzone; // power of two, >= 32
	size_t FLAG_quarantine_size;
	int FLAG_demangle;
	bool FLAG_symbolize;
	int FLAG_v;
	int FLAG_debug;
	bool FLAG_poison_shadow;
	int FLAG_report_globals;
	size_t FLAG_malloc_context_size = kMallocContextSize;
	uintptr_t FLAG_large_malloc;
	bool FLAG_handle_segv;
	bool FLAG_replace_str;
	bool FLAG_replace_intrin;
	bool FLAG_replace_cfallocator; // Used on Mac only.
	size_t FLAG_max_malloc_fill_size = 0;
	bool FLAG_use_fake_stack;
	int FLAG_exitcode = EXIT_FAILURE;
	bool FLAG_allow_user_poisoning;
	int FLAG_sleep_before_dying;

	// -------------------------- Globals --------------------- {{{1
	int asan_inited;
	bool asan_init_is_running;

	// -------------------------- Misc ---------------- {{{1
	void ShowStatsAndAbort() {
	__asan_print_accumulated_stats();
	AsanDie();
	}

	static void PrintBytes(const char before, uintptr_t a) {
	uint8_t bytes = (uint8_t)a;
	size_t byte_num = (__WORDSIZE) / 8;
	Printf("%s%p:", before, (uintptr_t)a);
	for (size_t i = 0; i < byte_num; i++) {
	Printf(" %lx%lx", bytes[i] >> 4, bytes[i] & 15);
	}
	Printf("\n");
	}

	size_t ReadFileToBuffer(const char file_name, char *buff,
	size_t *buff_size, size_t max_len) {
	const size_t kMinFileLen = kPageSize;
	size_t read_len = 0;
	*buff = 0;
	*buff_size = 0;
	// The files we usually open are not seekable, so try different buffer sizes.
	for (size_t size = kMinFileLen; size <= max_len; size *= 2) {
	int fd = AsanOpenReadonly(file_name);
	if (fd < 0) return -1;
	AsanUnmapOrDie(buff, buff_size);
	buff = (char)AsanMmapSomewhereOrDie(size, __FUNCTION__);
	*buff_size = size;
	// Read up to one page at a time.
	read_len = 0;
	bool reached_eof = false;
	while (read_len + kPageSize <= size) {
	size_t just_read = AsanRead(fd, *buff + read_len, kPageSize);
	if (just_read == 0) {
	reached_eof = true;
	break;
	}
	read_len += just_read;
	}
	AsanClose(fd);
	if (reached_eof) // We've read the whole file.
	break;
	}
	return read_len;
	}

	// ---------------------- mmap -------------------- {{{1
	void OutOfMemoryMessageAndDie(const char *mem_type, size_t size) {
	Report("ERROR: AddressSanitizer failed to allocate "
	"0x%lx (%ld) bytes of %s\n",
	size, size, mem_type);
	PRINT_CURRENT_STACK();
	ShowStatsAndAbort();
	}

	// Reserve memory range [beg, end].
	static void ReserveShadowMemoryRange(uintptr_t beg, uintptr_t end) {
	CHECK((beg % kPageSize) == 0);
	CHECK(((end + 1) % kPageSize) == 0);
	size_t size = end - beg + 1;
	void *res = AsanMmapFixedNoReserve(beg, size);
	CHECK(res == (void*)beg && "ReserveShadowMemoryRange failed");
	}

	// ---------------------- LowLevelAllocator ------------- {{{1
	void *LowLevelAllocator::Allocate(size_t size) {
	CHECK((size & (size - 1)) == 0 && "size must be a power of two");
	if (allocated_end_ - allocated_current_ < size) {
	size_t size_to_allocate = Max(size, kPageSize);
	allocated_current_ =
	(char*)AsanMmapSomewhereOrDie(size_to_allocate, __FUNCTION__);
	allocated_end_ = allocated_current_ + size_to_allocate;
	PoisonShadow((uintptr_t)allocated_current_, size_to_allocate,
	kAsanInternalHeapMagic);
	}
	CHECK(allocated_end_ - allocated_current_ >= size);
	void *res = allocated_current_;
	allocated_current_ += size;
	return res;
	}

	// ---------------------- DescribeAddress -------------------- {{{1
	static bool DescribeStackAddress(uintptr_t addr, uintptr_t access_size) {
	AsanThread *t = asanThreadRegistry().FindThreadByStackAddress(addr);
	if (!t) return false;
	const intptr_t kBufSize = 4095;
	char buf[kBufSize];
	uintptr_t offset = 0;
	const char *frame_descr = t->GetFrameNameByAddr(addr, &offset);
	// This string is created by the compiler and has the following form:
	// "FunctioName n alloc_1 alloc_2 ... alloc_n"
	// where alloc_i looks like "offset size len ObjectName ".
	CHECK(frame_descr);
	// Report the function name and the offset.
	const char *name_end = real_strchr(frame_descr, ' ');
	CHECK(name_end);
	buf[0] = 0;
	internal_strncat(buf, frame_descr,
	Min(kBufSize,
	static_cast<intptr_t>(name_end - frame_descr)));
	Printf("Address %p is located at offset %ld "
	"in frame <%s> of T%d's stack:\n",
	addr, offset, buf, t->tid());
	// Report the number of stack objects.
	char *p;
	size_t n_objects = strtol(name_end, &p, 10);
	CHECK(n_objects > 0);
	Printf(" This frame has %ld object(s):\n", n_objects);
	// Report all objects in this frame.
	for (size_t i = 0; i < n_objects; i++) {
	size_t beg, size;
	intptr_t len;
	beg = strtol(p, &p, 10);
	size = strtol(p, &p, 10);
	len = strtol(p, &p, 10);
	if (beg <= 0 \|\| size <= 0 \|\| len < 0 \|\| *p != ' ') {
	Printf("AddressSanitizer can't parse the stack frame descriptor: \|%s\|\n",
	frame_descr);
	break;
	}
	p++;
	buf[0] = 0;
	internal_strncat(buf, p, Min(kBufSize, len));
	p += len;
	Printf(" [%ld, %ld) '%s'\n", beg, beg + size, buf);
	}
	Printf("HINT: this may be a false positive if your program uses "
	"some custom stack unwind mechanism\n"
	" (longjmp and C++ exceptions are supported)\n");
	t->summary()->Announce();
	return true;
	}

	static NOINLINE void DescribeAddress(uintptr_t addr, uintptr_t access_size) {
	// Check if this is a global.
	if (DescribeAddrIfGlobal(addr))
	return;

	if (DescribeStackAddress(addr, access_size))
	return;

	// finally, check if this is a heap.
	DescribeHeapAddress(addr, access_size);
	}

	// -------------------------- Run-time entry ------------------- {{{1
	// exported functions
	#define ASAN_REPORT_ERROR(type, is_write, size) \
	NOINLINE ASAN_INTERFACE_ATTRIBUTE \
	extern "C" void __asan_report_ ## type ## size(uintptr_t addr); \
	extern "C" void __asan_report_ ## type ## size(uintptr_t addr) { \
	GET_BP_PC_SP; \
	__asan_report_error(pc, bp, sp, addr, is_write, size); \
	}

	ASAN_REPORT_ERROR(load, false, 1)
	ASAN_REPORT_ERROR(load, false, 2)
	ASAN_REPORT_ERROR(load, false, 4)
	ASAN_REPORT_ERROR(load, false, 8)
	ASAN_REPORT_ERROR(load, false, 16)
	ASAN_REPORT_ERROR(store, true, 1)
	ASAN_REPORT_ERROR(store, true, 2)
	ASAN_REPORT_ERROR(store, true, 4)
	ASAN_REPORT_ERROR(store, true, 8)
	ASAN_REPORT_ERROR(store, true, 16)

	// Force the linker to keep the symbols for various ASan interface functions.
	// We want to keep those in the executable in order to let the instrumented
	// dynamic libraries access the symbol even if it is not used by the executable
	// itself. This should help if the build system is removing dead code at link
	// time.
	static void force_interface_symbols() {
	volatile int fake_condition = 0; // prevent dead condition elimination.
	if (fake_condition) {
	__asan_report_load1(NULL);
	__asan_report_load2(NULL);
	__asan_report_load4(NULL);
	__asan_report_load8(NULL);
	__asan_report_load16(NULL);
	__asan_report_store1(NULL);
	__asan_report_store2(NULL);
	__asan_report_store4(NULL);
	__asan_report_store8(NULL);
	__asan_report_store16(NULL);
	__asan_register_global(0, 0, NULL);
	__asan_register_globals(NULL, 0);
	__asan_unregister_globals(NULL, 0);
	}
	}

	// -------------------------- Init ------------------- {{{1
	#if defined(_WIN32)
	// atoll is not defined on Windows.
	int64_t atoll(const char *str) {
	UNIMPLEMENTED();
	return -1;
	}
	#endif

	static int64_t IntFlagValue(const char flags, const char flag,
	int64_t default_val) {
	if (!flags) return default_val;
	const char *str = internal_strstr(flags, flag);
	if (!str) return default_val;
	return atoll(str + internal_strlen(flag));
	}

	static void asan_atexit() {
	Printf("AddressSanitizer exit stats:\n");
	__asan_print_accumulated_stats();
	}

	void CheckFailed(const char cond, const char file, int line) {
	Report("CHECK failed: %s at %s:%d\n", cond, file, line);
	PRINT_CURRENT_STACK();
	ShowStatsAndAbort();
	}

	} // namespace __asan

	// ---------------------- Interface ---------------- {{{1
	using namespace __asan; // NOLINT

	int __asan_set_error_exit_code(int exit_code) {
	int old = FLAG_exitcode;
	FLAG_exitcode = exit_code;
	return old;
	}

	void __asan_report_error(uintptr_t pc, uintptr_t bp, uintptr_t sp,
	uintptr_t addr, bool is_write, size_t access_size) {
	// Do not print more than one report, otherwise they will mix up.
	static int num_calls = 0;
	if (AtomicInc(&num_calls) > 1) return;

	Printf("=================================================================\n");
	const char *bug_descr = "unknown-crash";
	if (AddrIsInMem(addr)) {
	uint8_t shadow_addr = (uint8_t)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++;
	switch (*shadow_addr) {
	case kAsanHeapLeftRedzoneMagic:
	case kAsanHeapRightRedzoneMagic:
	bug_descr = "heap-buffer-overflow";
	break;
	case kAsanHeapFreeMagic:
	bug_descr = "heap-use-after-free";
	break;
	case kAsanStackLeftRedzoneMagic:
	bug_descr = "stack-buffer-underflow";
	break;
	case kAsanStackMidRedzoneMagic:
	case kAsanStackRightRedzoneMagic:
	case kAsanStackPartialRedzoneMagic:
	bug_descr = "stack-buffer-overflow";
	break;
	case kAsanStackAfterReturnMagic:
	bug_descr = "stack-use-after-return";
	break;
	case kAsanUserPoisonedMemoryMagic:
	bug_descr = "use-after-poison";
	break;
	case kAsanGlobalRedzoneMagic:
	bug_descr = "global-buffer-overflow";
	break;
	}
	}

	AsanThread *curr_thread = asanThreadRegistry().GetCurrent();
	int curr_tid = asanThreadRegistry().GetCurrentTidOrMinusOne();

	if (curr_thread) {
	// We started reporting an error message. Stop using the fake stack
	// in case we will call an instrumented function from a symbolizer.
	curr_thread->fake_stack().StopUsingFakeStack();
	}

	Report("ERROR: AddressSanitizer %s on address "
	"%p at pc 0x%lx bp 0x%lx sp 0x%lx\n",
	bug_descr, addr, pc, bp, sp);

	Printf("%s of size %d at %p thread T%d\n",
	access_size ? (is_write ? "WRITE" : "READ") : "ACCESS",
	access_size, addr, curr_tid);

	if (FLAG_debug) {
	PrintBytes("PC: ", (uintptr_t*)pc);
	}

	GET_STACK_TRACE_WITH_PC_AND_BP(kStackTraceMax, pc, bp);
	stack.PrintStack();

	CHECK(AddrIsInMem(addr));

	DescribeAddress(addr, access_size);

	uintptr_t shadow_addr = MemToShadow(addr);
	Report("ABORTING\n");
	__asan_print_accumulated_stats();
	Printf("Shadow byte and word:\n");
	Printf(" %p: %x\n", shadow_addr, (unsigned char)shadow_addr);
	uintptr_t aligned_shadow = shadow_addr & ~(kWordSize - 1);
	PrintBytes(" ", (uintptr_t*)(aligned_shadow));
	Printf("More shadow bytes:\n");
	PrintBytes(" ", (uintptr_t)(aligned_shadow-4kWordSize));
	PrintBytes(" ", (uintptr_t)(aligned_shadow-3kWordSize));
	PrintBytes(" ", (uintptr_t)(aligned_shadow-2kWordSize));
	PrintBytes(" ", (uintptr_t)(aligned_shadow-1kWordSize));
	PrintBytes("=>", (uintptr_t)(aligned_shadow+0kWordSize));
	PrintBytes(" ", (uintptr_t)(aligned_shadow+1kWordSize));
	PrintBytes(" ", (uintptr_t)(aligned_shadow+2kWordSize));
	PrintBytes(" ", (uintptr_t)(aligned_shadow+3kWordSize));
	PrintBytes(" ", (uintptr_t)(aligned_shadow+4kWordSize));
	AsanDie();
	}

	void __asan_init() {
	if (asan_inited) return;
	asan_init_is_running = true;

	// Make sure we are not statically linked.
	AsanDoesNotSupportStaticLinkage();

	// flags
	const char *options = AsanGetEnv("ASAN_OPTIONS");
	FLAG_malloc_context_size =
	IntFlagValue(options, "malloc_context_size=", kMallocContextSize);
	CHECK(FLAG_malloc_context_size <= kMallocContextSize);

	FLAG_max_malloc_fill_size =
	IntFlagValue(options, "max_malloc_fill_size=", 0);

	FLAG_v = IntFlagValue(options, "verbosity=", 0);

	FLAG_redzone = IntFlagValue(options, "redzone=", 128);
	CHECK(FLAG_redzone >= 32);
	CHECK((FLAG_redzone & (FLAG_redzone - 1)) == 0);

	FLAG_atexit = IntFlagValue(options, "atexit=", 0);
	FLAG_poison_shadow = IntFlagValue(options, "poison_shadow=", 1);
	FLAG_report_globals = IntFlagValue(options, "report_globals=", 1);
	FLAG_handle_segv = IntFlagValue(options, "handle_segv=", ASAN_NEEDS_SEGV);
	FLAG_symbolize = IntFlagValue(options, "symbolize=", 1);
	FLAG_demangle = IntFlagValue(options, "demangle=", 1);
	FLAG_debug = IntFlagValue(options, "debug=", 0);
	FLAG_replace_cfallocator = IntFlagValue(options, "replace_cfallocator=", 1);
	FLAG_replace_str = IntFlagValue(options, "replace_str=", 1);
	FLAG_replace_intrin = IntFlagValue(options, "replace_intrin=", 1);
	FLAG_use_fake_stack = IntFlagValue(options, "use_fake_stack=", 1);
	FLAG_exitcode = IntFlagValue(options, "exitcode=", EXIT_FAILURE);
	FLAG_allow_user_poisoning = IntFlagValue(options,
	"allow_user_poisoning=", 1);
	FLAG_sleep_before_dying = IntFlagValue(options, "sleep_before_dying=", 0);

	if (FLAG_atexit) {
	atexit(asan_atexit);
	}

	FLAG_quarantine_size =
	IntFlagValue(options, "quarantine_size=", 1UL << 28);

	// interceptors
	InitializeAsanInterceptors();

	ReplaceSystemMalloc();
	InstallSignalHandlers();

	if (FLAG_v) {
	Printf("\|\| `[%p, %p]` \|\| HighMem \|\|\n", kHighMemBeg, kHighMemEnd);
	Printf("\|\| `[%p, %p]` \|\| HighShadow \|\|\n",
	kHighShadowBeg, kHighShadowEnd);
	Printf("\|\| `[%p, %p]` \|\| ShadowGap \|\|\n",
	kShadowGapBeg, kShadowGapEnd);
	Printf("\|\| `[%p, %p]` \|\| LowShadow \|\|\n",
	kLowShadowBeg, kLowShadowEnd);
	Printf("\|\| `[%p, %p]` \|\| LowMem \|\|\n", kLowMemBeg, kLowMemEnd);
	Printf("MemToShadow(shadow): %p %p %p %p\n",
	MEM_TO_SHADOW(kLowShadowBeg),
	MEM_TO_SHADOW(kLowShadowEnd),
	MEM_TO_SHADOW(kHighShadowBeg),
	MEM_TO_SHADOW(kHighShadowEnd));
	Printf("red_zone=%ld\n", FLAG_redzone);
	Printf("malloc_context_size=%ld\n", (int)FLAG_malloc_context_size);

	Printf("SHADOW_SCALE: %lx\n", SHADOW_SCALE);
	Printf("SHADOW_GRANULARITY: %lx\n", SHADOW_GRANULARITY);
	Printf("SHADOW_OFFSET: %lx\n", SHADOW_OFFSET);
	CHECK(SHADOW_SCALE >= 3 && SHADOW_SCALE <= 7);
	}

	if (__WORDSIZE == 64) {
	// Disable core dumper -- it makes little sense to dump 16T+ core.
	AsanDisableCoreDumper();
	}

	{
	if (kLowShadowBeg != kLowShadowEnd) {
	// mmap the low shadow plus one page.
	ReserveShadowMemoryRange(kLowShadowBeg - kPageSize, kLowShadowEnd);
	}
	// mmap the high shadow.
	ReserveShadowMemoryRange(kHighShadowBeg, kHighShadowEnd);
	// protect the gap
	void *prot = AsanMprotect(kShadowGapBeg, kShadowGapEnd - kShadowGapBeg + 1);
	CHECK(prot == (void*)kShadowGapBeg);
	}

	// On Linux AsanThread::ThreadStart() calls malloc() that's why asan_inited
	// should be set to 1 prior to initializing the threads.
	asan_inited = 1;
	asan_init_is_running = false;

	asanThreadRegistry().Init();
	asanThreadRegistry().GetMain()->ThreadStart();
	force_interface_symbols(); // no-op.

	if (FLAG_v) {
	Report("AddressSanitizer Init done\n");
	}
	}

	#if defined(ASAN_USE_PREINIT_ARRAY)
	// On Linux, we force __asan_init to be called before anyone else
	// by placing it into .preinit_array section.
	// FIXME: do we have anything like this on Mac?
	__attribute__((section(".preinit_array")))
	typeof(__asan_init) *__asan_preinit =__asan_init;
	#endif