lib/hwasan/hwasan_report.cpp - compiler-rt - Git at Google

 //===-- hwasan_report.cpp -------------------------------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // This file is a part of HWAddressSanitizer.
 //
 // Error reporting.
 //===----------------------------------------------------------------------===//

 #include "hwasan.h"
 #include "hwasan_allocator.h"
 #include "hwasan_mapping.h"
 #include "hwasan_report.h"
 #include "hwasan_thread.h"
 #include "hwasan_thread_list.h"
 #include "sanitizer_common/sanitizer_allocator_internal.h"
 #include "sanitizer_common/sanitizer_common.h"
 #include "sanitizer_common/sanitizer_flags.h"
 #include "sanitizer_common/sanitizer_mutex.h"
 #include "sanitizer_common/sanitizer_report_decorator.h"
 #include "sanitizer_common/sanitizer_stackdepot.h"
 #include "sanitizer_common/sanitizer_stacktrace_printer.h"
 #include "sanitizer_common/sanitizer_symbolizer.h"

 using namespace __sanitizer;

 namespace __hwasan {

 class ScopedReport {
  public:
   ScopedReport(bool fatal = false) : error_message_(1), fatal(fatal) {
     BlockingMutexLock lock(&error_message_lock_);
     error_message_ptr_ = fatal ? &error_message_ : nullptr;
     ++hwasan_report_count;
   }

   ~ScopedReport() {
     {
       BlockingMutexLock lock(&error_message_lock_);
       if (fatal)
         SetAbortMessage(error_message_.data());
       error_message_ptr_ = nullptr;
     }
     if (common_flags()->print_module_map >= 2 ||
         (fatal && common_flags()->print_module_map))
       DumpProcessMap();
     if (fatal)
       Die();
   }

   static void MaybeAppendToErrorMessage(const char *msg) {
     BlockingMutexLock lock(&error_message_lock_);
     if (!error_message_ptr_)
       return;
     uptr len = internal_strlen(msg);
     uptr old_size = error_message_ptr_->size();
     error_message_ptr_->resize(old_size + len);
     // overwrite old trailing '\0', keep new trailing '\0' untouched.
     internal_memcpy(&(*error_message_ptr_)[old_size - 1], msg, len);
   }
  private:
   ScopedErrorReportLock error_report_lock_;
   InternalMmapVector<char> error_message_;
   bool fatal;

   static InternalMmapVector<char> *error_message_ptr_;
   static BlockingMutex error_message_lock_;
 };

 InternalMmapVector<char> *ScopedReport::error_message_ptr_;
 BlockingMutex ScopedReport::error_message_lock_;

 // If there is an active ScopedReport, append to its error message.
 void AppendToErrorMessageBuffer(const char *buffer) {
   ScopedReport::MaybeAppendToErrorMessage(buffer);
 }

 static StackTrace GetStackTraceFromId(u32 id) {
   CHECK(id);
   StackTrace res = StackDepotGet(id);
   CHECK(res.trace);
   return res;
 }

 // A RAII object that holds a copy of the current thread stack ring buffer.
 // The actual stack buffer may change while we are iterating over it (for
 // example, Printf may call syslog() which can itself be built with hwasan).
 class SavedStackAllocations {
  public:
   SavedStackAllocations(StackAllocationsRingBuffer *rb) {
     uptr size = rb->size() * sizeof(uptr);
     void *storage =
         MmapAlignedOrDieOnFatalError(size, size * 2, "saved stack allocations");
     new (&rb_) StackAllocationsRingBuffer(*rb, storage);
   }

   ~SavedStackAllocations() {
     StackAllocationsRingBuffer *rb = get();
     UnmapOrDie(rb->StartOfStorage(), rb->size() * sizeof(uptr));
   }

   StackAllocationsRingBuffer *get() {
     return (StackAllocationsRingBuffer *)&rb_;
   }

  private:
   uptr rb_;
 };

 class Decorator: public __sanitizer::SanitizerCommonDecorator {
  public:
   Decorator() : SanitizerCommonDecorator() { }
   const char *Access() { return Blue(); }
   const char *Allocation() const { return Magenta(); }
   const char *Origin() const { return Magenta(); }
   const char *Name() const { return Green(); }
   const char *Location() { return Green(); }
   const char *Thread() { return Green(); }
 };

 // Returns the index of the rb element that matches tagged_addr (plus one),
 // or zero if found nothing.
 uptr FindHeapAllocation(HeapAllocationsRingBuffer *rb,
                         uptr tagged_addr,
                         HeapAllocationRecord *har) {
   if (!rb) return 0;
   for (uptr i = 0, size = rb->size(); i < size; i++) {
     auto h = (*rb)[i];
     if (h.tagged_addr <= tagged_addr &&
         h.tagged_addr + h.requested_size > tagged_addr) {
       *har = h;
       return i + 1;
     }
   }
   return 0;
 }

 static void PrintStackAllocations(StackAllocationsRingBuffer *sa,
                                   tag_t addr_tag, uptr untagged_addr) {
   uptr frames = Min((uptr)flags()->stack_history_size, sa->size());
   bool found_local = false;
   for (uptr i = 0; i < frames; i++) {
     const uptr *record_addr = &(*sa)[i];
     uptr record = *record_addr;
     if (!record)
       break;
     tag_t base_tag =
         reinterpret_cast<uptr>(record_addr) >> kRecordAddrBaseTagShift;
     uptr fp = (record >> kRecordFPShift) << kRecordFPLShift;
     uptr pc_mask = (1ULL << kRecordFPShift) - 1;
     uptr pc = record & pc_mask;
     FrameInfo frame;
     if (Symbolizer::GetOrInit()->SymbolizeFrame(pc, &frame)) {
       for (LocalInfo &local : frame.locals) {
         if (!local.has_frame_offset || !local.has_size || !local.has_tag_offset)
           continue;
         tag_t obj_tag = base_tag ^ local.tag_offset;
         if (obj_tag != addr_tag)
           continue;
         // Calculate the offset from the object address to the faulting
         // address. Because we only store bits 4-19 of FP (bits 0-3 are
         // guaranteed to be zero), the calculation is performed mod 2^20 and may
         // harmlessly underflow if the address mod 2^20 is below the object
         // address.
         uptr obj_offset =
             (untagged_addr - fp - local.frame_offset) & (kRecordFPModulus - 1);
         if (obj_offset >= local.size)
           continue;
         if (!found_local) {
           Printf("Potentially referenced stack objects:\n");
           found_local = true;
         }
         Printf("  %s in %s %s:%d\n", local.name, local.function_name,
                local.decl_file, local.decl_line);
       }
       frame.Clear();
     }
   }

   if (found_local)
     return;

   // We didn't find any locals. Most likely we don't have symbols, so dump
   // the information that we have for offline analysis.
   InternalScopedString frame_desc(GetPageSizeCached() * 2);
   Printf("Previously allocated frames:\n");
   for (uptr i = 0; i < frames; i++) {
     const uptr *record_addr = &(*sa)[i];
     uptr record = *record_addr;
     if (!record)
       break;
     uptr pc_mask = (1ULL << 48) - 1;
     uptr pc = record & pc_mask;
     frame_desc.append("  record_addr:0x%zx record:0x%zx",
                       reinterpret_cast<uptr>(record_addr), record);
     if (SymbolizedStack *frame = Symbolizer::GetOrInit()->SymbolizePC(pc)) {
       RenderFrame(&frame_desc, " %F %L\n", 0, frame->info,
                   common_flags()->symbolize_vs_style,
                   common_flags()->strip_path_prefix);
       frame->ClearAll();
     }
     Printf("%s", frame_desc.data());
     frame_desc.clear();
   }
 }

 // Returns true if tag == *tag_ptr, reading tags from short granules if
 // necessary. This may return a false positive if tags 1-15 are used as a
 // regular tag rather than a short granule marker.
 static bool TagsEqual(tag_t tag, tag_t *tag_ptr) {
   if (tag == *tag_ptr)
     return true;
   if (*tag_ptr == 0 || *tag_ptr > kShadowAlignment - 1)
     return false;
   uptr mem = ShadowToMem(reinterpret_cast<uptr>(tag_ptr));
   tag_t inline_tag = *reinterpret_cast<tag_t *>(mem + kShadowAlignment - 1);
   return tag == inline_tag;
 }

 void PrintAddressDescription(
     uptr tagged_addr, uptr access_size,
     StackAllocationsRingBuffer *current_stack_allocations) {
   Decorator d;
   int num_descriptions_printed = 0;
   uptr untagged_addr = UntagAddr(tagged_addr);

   // Print some very basic information about the address, if it's a heap.
   HwasanChunkView chunk = FindHeapChunkByAddress(untagged_addr);
   if (uptr beg = chunk.Beg()) {
     uptr size = chunk.ActualSize();
     Printf("%s[%p,%p) is a %s %s heap chunk; "
            "size: %zd offset: %zd\n%s",
            d.Location(),
            beg, beg + size,
            chunk.FromSmallHeap() ? "small" : "large",
            chunk.IsAllocated() ? "allocated" : "unallocated",
            size, untagged_addr - beg,
            d.Default());
   }

   // Check if this looks like a heap buffer overflow by scanning
   // the shadow left and right and looking for the first adjacent
   // object with a different memory tag. If that tag matches addr_tag,
   // check the allocator if it has a live chunk there.
   tag_t addr_tag = GetTagFromPointer(tagged_addr);
   tag_t *tag_ptr = reinterpret_cast<tag_t*>(MemToShadow(untagged_addr));
   tag_t *candidate = nullptr, *left = tag_ptr, *right = tag_ptr;
   for (int i = 0; i < 1000; i++) {
     if (TagsEqual(addr_tag, left)) {
       candidate = left;
       break;
     }
     --left;
     if (TagsEqual(addr_tag, right)) {
       candidate = right;
       break;
     }
     ++right;
   }

   if (candidate) {
     uptr mem = ShadowToMem(reinterpret_cast<uptr>(candidate));
     HwasanChunkView chunk = FindHeapChunkByAddress(mem);
     if (chunk.IsAllocated()) {
       Printf("%s", d.Location());
       Printf("%p is located %zd bytes to the %s of %zd-byte region [%p,%p)\n",
              untagged_addr,
              candidate == left ? untagged_addr - chunk.End()
                                : chunk.Beg() - untagged_addr,
              candidate == left ? "right" : "left", chunk.UsedSize(),
              chunk.Beg(), chunk.End());
       Printf("%s", d.Allocation());
       Printf("allocated here:\n");
       Printf("%s", d.Default());
       GetStackTraceFromId(chunk.GetAllocStackId()).Print();
       num_descriptions_printed++;
     } else {
       // Check whether the address points into a loaded library. If so, this is
       // most likely a global variable.
       const char *module_name;
       uptr module_address;
       Symbolizer *sym = Symbolizer::GetOrInit();
       if (sym->GetModuleNameAndOffsetForPC(mem, &module_name,
                                            &module_address)) {
         DataInfo info;
         if (sym->SymbolizeData(mem, &info) && info.start) {
           Printf(
               "%p is located %zd bytes to the %s of %zd-byte global variable "
               "%s [%p,%p) in %s\n",
               untagged_addr,
               candidate == left ? untagged_addr - (info.start + info.size)
                                 : info.start - untagged_addr,
               candidate == left ? "right" : "left", info.size, info.name,
               info.start, info.start + info.size, module_name);
         } else {
           Printf("%p is located to the %s of a global variable in (%s+0x%x)\n",
                  untagged_addr, candidate == left ? "right" : "left",
                  module_name, module_address);
         }
         num_descriptions_printed++;
       }
     }
   }

   hwasanThreadList().VisitAllLiveThreads([&](Thread *t) {
     // Scan all threads' ring buffers to find if it's a heap-use-after-free.
     HeapAllocationRecord har;
     if (uptr D = FindHeapAllocation(t->heap_allocations(), tagged_addr, &har)) {
       Printf("%s", d.Location());
       Printf("%p is located %zd bytes inside of %zd-byte region [%p,%p)\n",
              untagged_addr, untagged_addr - UntagAddr(har.tagged_addr),
              har.requested_size, UntagAddr(har.tagged_addr),
              UntagAddr(har.tagged_addr) + har.requested_size);
       Printf("%s", d.Allocation());
       Printf("freed by thread T%zd here:\n", t->unique_id());
       Printf("%s", d.Default());
       GetStackTraceFromId(har.free_context_id).Print();

       Printf("%s", d.Allocation());
       Printf("previously allocated here:\n", t);
       Printf("%s", d.Default());
       GetStackTraceFromId(har.alloc_context_id).Print();

       // Print a developer note: the index of this heap object
       // in the thread's deallocation ring buffer.
       Printf("hwasan_dev_note_heap_rb_distance: %zd %zd\n", D,
              flags()->heap_history_size);

       t->Announce();
       num_descriptions_printed++;
     }

     // Very basic check for stack memory.
     if (t->AddrIsInStack(untagged_addr)) {
       Printf("%s", d.Location());
       Printf("Address %p is located in stack of thread T%zd\n", untagged_addr,
              t->unique_id());
       Printf("%s", d.Default());
       t->Announce();

       auto *sa = (t == GetCurrentThread() && current_stack_allocations)
                      ? current_stack_allocations
                      : t->stack_allocations();
       PrintStackAllocations(sa, addr_tag, untagged_addr);
       num_descriptions_printed++;
     }
   });

   // Print the remaining threads, as an extra information, 1 line per thread.
   hwasanThreadList().VisitAllLiveThreads([&](Thread *t) { t->Announce(); });

   if (!num_descriptions_printed)
     // We exhausted our possibilities. Bail out.
     Printf("HWAddressSanitizer can not describe address in more detail.\n");
 }

 void ReportStats() {}

 static void PrintTagInfoAroundAddr(tag_t *tag_ptr, uptr num_rows,
                                    void (*print_tag)(InternalScopedString &s,
                                                      tag_t *tag)) {
   const uptr row_len = 16;  // better be power of two.
   tag_t *center_row_beg = reinterpret_cast<tag_t *>(
       RoundDownTo(reinterpret_cast<uptr>(tag_ptr), row_len));
   tag_t *beg_row = center_row_beg - row_len * (num_rows / 2);
   tag_t *end_row = center_row_beg + row_len * ((num_rows + 1) / 2);
   InternalScopedString s(GetPageSizeCached() * 8);
   for (tag_t *row = beg_row; row < end_row; row += row_len) {
     s.append("%s", row == center_row_beg ? "=>" : "  ");
     for (uptr i = 0; i < row_len; i++) {
       s.append("%s", row + i == tag_ptr ? "[" : " ");
       print_tag(s, &row[i]);
       s.append("%s", row + i == tag_ptr ? "]" : " ");
     }
     s.append("%s\n", row == center_row_beg ? "<=" : "  ");
   }
   Printf("%s", s.data());
 }

 static void PrintTagsAroundAddr(tag_t *tag_ptr) {
   Printf(
       "Memory tags around the buggy address (one tag corresponds to %zd "
       "bytes):\n", kShadowAlignment);
   PrintTagInfoAroundAddr(tag_ptr, 17, [](InternalScopedString &s, tag_t *tag) {
     s.append("%02x", *tag);
   });

   Printf(
       "Tags for short granules around the buggy address (one tag corresponds "
       "to %zd bytes):\n",
       kShadowAlignment);
   PrintTagInfoAroundAddr(tag_ptr, 3, [](InternalScopedString &s, tag_t *tag) {
     if (*tag >= 1 && *tag <= kShadowAlignment) {
       uptr granule_addr = ShadowToMem(reinterpret_cast<uptr>(tag));
       s.append("%02x",
                *reinterpret_cast<u8 *>(granule_addr + kShadowAlignment - 1));
     } else {
       s.append("..");
     }
   });
   Printf(
       "See "
       "https://clang.llvm.org/docs/"
       "HardwareAssistedAddressSanitizerDesign.html#short-granules for a "
       "description of short granule tags\n");
 }

 void ReportInvalidFree(StackTrace *stack, uptr tagged_addr) {
   ScopedReport R(flags()->halt_on_error);

   uptr untagged_addr = UntagAddr(tagged_addr);
   tag_t ptr_tag = GetTagFromPointer(tagged_addr);
   tag_t *tag_ptr = reinterpret_cast<tag_t*>(MemToShadow(untagged_addr));
   tag_t mem_tag = *tag_ptr;
   Decorator d;
   Printf("%s", d.Error());
   uptr pc = stack->size ? stack->trace[0] : 0;
   const char *bug_type = "invalid-free";
   Report("ERROR: %s: %s on address %p at pc %p\n", SanitizerToolName, bug_type,
          untagged_addr, pc);
   Printf("%s", d.Access());
   Printf("tags: %02x/%02x (ptr/mem)\n", ptr_tag, mem_tag);
   Printf("%s", d.Default());

   stack->Print();

   PrintAddressDescription(tagged_addr, 0, nullptr);

   PrintTagsAroundAddr(tag_ptr);

   ReportErrorSummary(bug_type, stack);
 }

 void ReportTailOverwritten(StackTrace *stack, uptr tagged_addr, uptr orig_size,
                            const u8 *expected) {
   uptr tail_size = kShadowAlignment - (orig_size % kShadowAlignment);
   ScopedReport R(flags()->halt_on_error);
   Decorator d;
   uptr untagged_addr = UntagAddr(tagged_addr);
   Printf("%s", d.Error());
   const char *bug_type = "alocation-tail-overwritten";
   Report("ERROR: %s: %s; heap object [%p,%p) of size %zd\n", SanitizerToolName,
          bug_type, untagged_addr, untagged_addr + orig_size, orig_size);
   Printf("\n%s", d.Default());
   stack->Print();
   HwasanChunkView chunk = FindHeapChunkByAddress(untagged_addr);
   if (chunk.Beg()) {
     Printf("%s", d.Allocation());
     Printf("allocated here:\n");
     Printf("%s", d.Default());
     GetStackTraceFromId(chunk.GetAllocStackId()).Print();
   }

   InternalScopedString s(GetPageSizeCached() * 8);
   CHECK_GT(tail_size, 0U);
   CHECK_LT(tail_size, kShadowAlignment);
   u8 *tail = reinterpret_cast<u8*>(untagged_addr + orig_size);
   s.append("Tail contains: ");
   for (uptr i = 0; i < kShadowAlignment - tail_size; i++)
     s.append(".. ");
   for (uptr i = 0; i < tail_size; i++)
     s.append("%02x ", tail[i]);
   s.append("\n");
   s.append("Expected:      ");
   for (uptr i = 0; i < kShadowAlignment - tail_size; i++)
     s.append(".. ");
   for (uptr i = 0; i < tail_size; i++)
     s.append("%02x ", expected[i]);
   s.append("\n");
   s.append("               ");
   for (uptr i = 0; i < kShadowAlignment - tail_size; i++)
     s.append("   ");
   for (uptr i = 0; i < tail_size; i++)
     s.append("%s ", expected[i] != tail[i] ? "^^" : "  ");

   s.append("\nThis error occurs when a buffer overflow overwrites memory\n"
     "to the right of a heap object, but within the %zd-byte granule, e.g.\n"
     "   char *x = new char[20];\n"
     "   x[25] = 42;\n"
     "%s does not detect such bugs in uninstrumented code at the time of write,"
     "\nbut can detect them at the time of free/delete.\n"
     "To disable this feature set HWASAN_OPTIONS=free_checks_tail_magic=0\n",
     kShadowAlignment, SanitizerToolName);
   Printf("%s", s.data());
   GetCurrentThread()->Announce();

   tag_t *tag_ptr = reinterpret_cast<tag_t*>(MemToShadow(untagged_addr));
   PrintTagsAroundAddr(tag_ptr);

   ReportErrorSummary(bug_type, stack);
 }

 void ReportTagMismatch(StackTrace *stack, uptr tagged_addr, uptr access_size,
                        bool is_store, bool fatal, uptr *registers_frame) {
   ScopedReport R(fatal);
   SavedStackAllocations current_stack_allocations(
       GetCurrentThread()->stack_allocations());

   Decorator d;
   Printf("%s", d.Error());
   uptr untagged_addr = UntagAddr(tagged_addr);
   // TODO: when possible, try to print heap-use-after-free, etc.
   const char *bug_type = "tag-mismatch";
   uptr pc = stack->size ? stack->trace[0] : 0;
   Report("ERROR: %s: %s on address %p at pc %p\n", SanitizerToolName, bug_type,
          untagged_addr, pc);

   Thread *t = GetCurrentThread();

   sptr offset =
       __hwasan_test_shadow(reinterpret_cast<void *>(tagged_addr), access_size);
   CHECK(offset >= 0 && offset < static_cast<sptr>(access_size));
   tag_t ptr_tag = GetTagFromPointer(tagged_addr);
   tag_t *tag_ptr =
       reinterpret_cast<tag_t *>(MemToShadow(untagged_addr + offset));
   tag_t mem_tag = *tag_ptr;

   Printf("%s", d.Access());
   Printf("%s of size %zu at %p tags: %02x/%02x (ptr/mem) in thread T%zd\n",
          is_store ? "WRITE" : "READ", access_size, untagged_addr, ptr_tag,
          mem_tag, t->unique_id());
   if (offset != 0)
     Printf("Invalid access starting at offset [%zu, %zu)\n", offset,
            Min(access_size, static_cast<uptr>(offset) + (1 << kShadowScale)));
   Printf("%s", d.Default());

   stack->Print();

   PrintAddressDescription(tagged_addr, access_size,
                           current_stack_allocations.get());
   t->Announce();

   PrintTagsAroundAddr(tag_ptr);

   if (registers_frame)
     ReportRegisters(registers_frame, pc);

   ReportErrorSummary(bug_type, stack);
 }

 // See the frame breakdown defined in __hwasan_tag_mismatch (from
 // hwasan_tag_mismatch_aarch64.S).
 void ReportRegisters(uptr *frame, uptr pc) {
   Printf("Registers where the failure occurred (pc %p):\n", pc);

   // We explicitly print a single line (4 registers/line) each iteration to
   // reduce the amount of logcat error messages printed. Each Printf() will
   // result in a new logcat line, irrespective of whether a newline is present,
   // and so we wish to reduce the number of Printf() calls we have to make.
   Printf("    x0  %016llx  x1  %016llx  x2  %016llx  x3  %016llx\n",
        frame[0], frame[1], frame[2], frame[3]);
   Printf("    x4  %016llx  x5  %016llx  x6  %016llx  x7  %016llx\n",
        frame[4], frame[5], frame[6], frame[7]);
   Printf("    x8  %016llx  x9  %016llx  x10 %016llx  x11 %016llx\n",
        frame[8], frame[9], frame[10], frame[11]);
   Printf("    x12 %016llx  x13 %016llx  x14 %016llx  x15 %016llx\n",
        frame[12], frame[13], frame[14], frame[15]);
   Printf("    x16 %016llx  x17 %016llx  x18 %016llx  x19 %016llx\n",
        frame[16], frame[17], frame[18], frame[19]);
   Printf("    x20 %016llx  x21 %016llx  x22 %016llx  x23 %016llx\n",
        frame[20], frame[21], frame[22], frame[23]);
   Printf("    x24 %016llx  x25 %016llx  x26 %016llx  x27 %016llx\n",
        frame[24], frame[25], frame[26], frame[27]);
   Printf("    x28 %016llx  x29 %016llx  x30 %016llx\n",
        frame[28], frame[29], frame[30]);
 }

 }  // namespace __hwasan
	//===-- hwasan_report.cpp -------------------------------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// This file is a part of HWAddressSanitizer.
	//
	// Error reporting.
	//===----------------------------------------------------------------------===//

	#include "hwasan.h"
	#include "hwasan_allocator.h"
	#include "hwasan_mapping.h"
	#include "hwasan_report.h"
	#include "hwasan_thread.h"
	#include "hwasan_thread_list.h"
	#include "sanitizer_common/sanitizer_allocator_internal.h"
	#include "sanitizer_common/sanitizer_common.h"
	#include "sanitizer_common/sanitizer_flags.h"
	#include "sanitizer_common/sanitizer_mutex.h"
	#include "sanitizer_common/sanitizer_report_decorator.h"
	#include "sanitizer_common/sanitizer_stackdepot.h"
	#include "sanitizer_common/sanitizer_stacktrace_printer.h"
	#include "sanitizer_common/sanitizer_symbolizer.h"

	using namespace __sanitizer;

	namespace __hwasan {

	class ScopedReport {
	public:
	ScopedReport(bool fatal = false) : error_message_(1), fatal(fatal) {
	BlockingMutexLock lock(&error_message_lock_);
	error_message_ptr_ = fatal ? &error_message_ : nullptr;
	++hwasan_report_count;
	}

	~ScopedReport() {
	{
	BlockingMutexLock lock(&error_message_lock_);
	if (fatal)
	SetAbortMessage(error_message_.data());
	error_message_ptr_ = nullptr;
	}
	if (common_flags()->print_module_map >= 2 \|\|
	(fatal && common_flags()->print_module_map))
	DumpProcessMap();
	if (fatal)
	Die();
	}

	static void MaybeAppendToErrorMessage(const char *msg) {
	BlockingMutexLock lock(&error_message_lock_);
	if (!error_message_ptr_)
	return;
	uptr len = internal_strlen(msg);
	uptr old_size = error_message_ptr_->size();
	error_message_ptr_->resize(old_size + len);
	// overwrite old trailing '\0', keep new trailing '\0' untouched.
	internal_memcpy(&(*error_message_ptr_)[old_size - 1], msg, len);
	}
	private:
	ScopedErrorReportLock error_report_lock_;
	InternalMmapVector<char> error_message_;
	bool fatal;

	static InternalMmapVector<char> *error_message_ptr_;
	static BlockingMutex error_message_lock_;
	};

	InternalMmapVector<char> *ScopedReport::error_message_ptr_;
	BlockingMutex ScopedReport::error_message_lock_;

	// If there is an active ScopedReport, append to its error message.
	void AppendToErrorMessageBuffer(const char *buffer) {
	ScopedReport::MaybeAppendToErrorMessage(buffer);
	}

	static StackTrace GetStackTraceFromId(u32 id) {
	CHECK(id);
	StackTrace res = StackDepotGet(id);
	CHECK(res.trace);
	return res;
	}

	// A RAII object that holds a copy of the current thread stack ring buffer.
	// The actual stack buffer may change while we are iterating over it (for
	// example, Printf may call syslog() which can itself be built with hwasan).
	class SavedStackAllocations {
	public:
	SavedStackAllocations(StackAllocationsRingBuffer *rb) {
	uptr size = rb->size() * sizeof(uptr);
	void *storage =
	MmapAlignedOrDieOnFatalError(size, size * 2, "saved stack allocations");
	new (&rb_) StackAllocationsRingBuffer(*rb, storage);
	}

	~SavedStackAllocations() {
	StackAllocationsRingBuffer *rb = get();
	UnmapOrDie(rb->StartOfStorage(), rb->size() * sizeof(uptr));
	}

	StackAllocationsRingBuffer *get() {
	return (StackAllocationsRingBuffer *)&rb_;
	}

	private:
	uptr rb_;
	};

	class Decorator: public __sanitizer::SanitizerCommonDecorator {
	public:
	Decorator() : SanitizerCommonDecorator() { }
	const char *Access() { return Blue(); }
	const char *Allocation() const { return Magenta(); }
	const char *Origin() const { return Magenta(); }
	const char *Name() const { return Green(); }
	const char *Location() { return Green(); }
	const char *Thread() { return Green(); }
	};

	// Returns the index of the rb element that matches tagged_addr (plus one),
	// or zero if found nothing.
	uptr FindHeapAllocation(HeapAllocationsRingBuffer *rb,
	uptr tagged_addr,
	HeapAllocationRecord *har) {
	if (!rb) return 0;
	for (uptr i = 0, size = rb->size(); i < size; i++) {
	auto h = (*rb)[i];
	if (h.tagged_addr <= tagged_addr &&
	h.tagged_addr + h.requested_size > tagged_addr) {
	*har = h;
	return i + 1;
	}
	}
	return 0;
	}

	static void PrintStackAllocations(StackAllocationsRingBuffer *sa,
	tag_t addr_tag, uptr untagged_addr) {
	uptr frames = Min((uptr)flags()->stack_history_size, sa->size());
	bool found_local = false;
	for (uptr i = 0; i < frames; i++) {
	const uptr record_addr = &(sa)[i];
	uptr record = *record_addr;
	if (!record)
	break;
	tag_t base_tag =
	reinterpret_cast<uptr>(record_addr) >> kRecordAddrBaseTagShift;
	uptr fp = (record >> kRecordFPShift) << kRecordFPLShift;
	uptr pc_mask = (1ULL << kRecordFPShift) - 1;
	uptr pc = record & pc_mask;
	FrameInfo frame;
	if (Symbolizer::GetOrInit()->SymbolizeFrame(pc, &frame)) {
	for (LocalInfo &local : frame.locals) {
	if (!local.has_frame_offset \|\| !local.has_size \|\| !local.has_tag_offset)
	continue;
	tag_t obj_tag = base_tag ^ local.tag_offset;
	if (obj_tag != addr_tag)
	continue;
	// Calculate the offset from the object address to the faulting
	// address. Because we only store bits 4-19 of FP (bits 0-3 are
	// guaranteed to be zero), the calculation is performed mod 2^20 and may
	// harmlessly underflow if the address mod 2^20 is below the object
	// address.
	uptr obj_offset =
	(untagged_addr - fp - local.frame_offset) & (kRecordFPModulus - 1);
	if (obj_offset >= local.size)
	continue;
	if (!found_local) {
	Printf("Potentially referenced stack objects:\n");
	found_local = true;
	}
	Printf(" %s in %s %s:%d\n", local.name, local.function_name,
	local.decl_file, local.decl_line);
	}
	frame.Clear();
	}
	}

	if (found_local)
	return;

	// We didn't find any locals. Most likely we don't have symbols, so dump
	// the information that we have for offline analysis.
	InternalScopedString frame_desc(GetPageSizeCached() * 2);
	Printf("Previously allocated frames:\n");
	for (uptr i = 0; i < frames; i++) {
	const uptr record_addr = &(sa)[i];
	uptr record = *record_addr;
	if (!record)
	break;
	uptr pc_mask = (1ULL << 48) - 1;
	uptr pc = record & pc_mask;
	frame_desc.append(" record_addr:0x%zx record:0x%zx",
	reinterpret_cast<uptr>(record_addr), record);
	if (SymbolizedStack *frame = Symbolizer::GetOrInit()->SymbolizePC(pc)) {
	RenderFrame(&frame_desc, " %F %L\n", 0, frame->info,
	common_flags()->symbolize_vs_style,
	common_flags()->strip_path_prefix);
	frame->ClearAll();
	}
	Printf("%s", frame_desc.data());
	frame_desc.clear();
	}
	}

	// Returns true if tag == *tag_ptr, reading tags from short granules if
	// necessary. This may return a false positive if tags 1-15 are used as a
	// regular tag rather than a short granule marker.
	static bool TagsEqual(tag_t tag, tag_t *tag_ptr) {
	if (tag == *tag_ptr)
	return true;
	if (tag_ptr == 0 \|\| tag_ptr > kShadowAlignment - 1)
	return false;
	uptr mem = ShadowToMem(reinterpret_cast<uptr>(tag_ptr));
	tag_t inline_tag = reinterpret_cast<tag_t >(mem + kShadowAlignment - 1);
	return tag == inline_tag;
	}

	void PrintAddressDescription(
	uptr tagged_addr, uptr access_size,
	StackAllocationsRingBuffer *current_stack_allocations) {
	Decorator d;
	int num_descriptions_printed = 0;
	uptr untagged_addr = UntagAddr(tagged_addr);

	// Print some very basic information about the address, if it's a heap.
	HwasanChunkView chunk = FindHeapChunkByAddress(untagged_addr);
	if (uptr beg = chunk.Beg()) {
	uptr size = chunk.ActualSize();
	Printf("%s[%p,%p) is a %s %s heap chunk; "
	"size: %zd offset: %zd\n%s",
	d.Location(),
	beg, beg + size,
	chunk.FromSmallHeap() ? "small" : "large",
	chunk.IsAllocated() ? "allocated" : "unallocated",
	size, untagged_addr - beg,
	d.Default());
	}

	// Check if this looks like a heap buffer overflow by scanning
	// the shadow left and right and looking for the first adjacent
	// object with a different memory tag. If that tag matches addr_tag,
	// check the allocator if it has a live chunk there.
	tag_t addr_tag = GetTagFromPointer(tagged_addr);
	tag_t tag_ptr = reinterpret_cast<tag_t>(MemToShadow(untagged_addr));
	tag_t candidate = nullptr, left = tag_ptr, *right = tag_ptr;
	for (int i = 0; i < 1000; i++) {
	if (TagsEqual(addr_tag, left)) {
	candidate = left;
	break;
	}
	--left;
	if (TagsEqual(addr_tag, right)) {
	candidate = right;
	break;
	}
	++right;
	}

	if (candidate) {
	uptr mem = ShadowToMem(reinterpret_cast<uptr>(candidate));
	HwasanChunkView chunk = FindHeapChunkByAddress(mem);
	if (chunk.IsAllocated()) {
	Printf("%s", d.Location());
	Printf("%p is located %zd bytes to the %s of %zd-byte region [%p,%p)\n",
	untagged_addr,
	candidate == left ? untagged_addr - chunk.End()
	: chunk.Beg() - untagged_addr,
	candidate == left ? "right" : "left", chunk.UsedSize(),
	chunk.Beg(), chunk.End());
	Printf("%s", d.Allocation());
	Printf("allocated here:\n");
	Printf("%s", d.Default());
	GetStackTraceFromId(chunk.GetAllocStackId()).Print();
	num_descriptions_printed++;
	} else {
	// Check whether the address points into a loaded library. If so, this is
	// most likely a global variable.
	const char *module_name;
	uptr module_address;
	Symbolizer *sym = Symbolizer::GetOrInit();
	if (sym->GetModuleNameAndOffsetForPC(mem, &module_name,
	&module_address)) {
	DataInfo info;
	if (sym->SymbolizeData(mem, &info) && info.start) {
	Printf(
	"%p is located %zd bytes to the %s of %zd-byte global variable "
	"%s [%p,%p) in %s\n",
	untagged_addr,
	candidate == left ? untagged_addr - (info.start + info.size)
	: info.start - untagged_addr,
	candidate == left ? "right" : "left", info.size, info.name,
	info.start, info.start + info.size, module_name);
	} else {
	Printf("%p is located to the %s of a global variable in (%s+0x%x)\n",
	untagged_addr, candidate == left ? "right" : "left",
	module_name, module_address);
	}
	num_descriptions_printed++;
	}
	}
	}

	hwasanThreadList().VisitAllLiveThreads([&](Thread *t) {
	// Scan all threads' ring buffers to find if it's a heap-use-after-free.
	HeapAllocationRecord har;
	if (uptr D = FindHeapAllocation(t->heap_allocations(), tagged_addr, &har)) {
	Printf("%s", d.Location());
	Printf("%p is located %zd bytes inside of %zd-byte region [%p,%p)\n",
	untagged_addr, untagged_addr - UntagAddr(har.tagged_addr),
	har.requested_size, UntagAddr(har.tagged_addr),
	UntagAddr(har.tagged_addr) + har.requested_size);
	Printf("%s", d.Allocation());
	Printf("freed by thread T%zd here:\n", t->unique_id());
	Printf("%s", d.Default());
	GetStackTraceFromId(har.free_context_id).Print();

	Printf("%s", d.Allocation());
	Printf("previously allocated here:\n", t);
	Printf("%s", d.Default());
	GetStackTraceFromId(har.alloc_context_id).Print();

	// Print a developer note: the index of this heap object
	// in the thread's deallocation ring buffer.
	Printf("hwasan_dev_note_heap_rb_distance: %zd %zd\n", D,
	flags()->heap_history_size);

	t->Announce();
	num_descriptions_printed++;
	}

	// Very basic check for stack memory.
	if (t->AddrIsInStack(untagged_addr)) {
	Printf("%s", d.Location());
	Printf("Address %p is located in stack of thread T%zd\n", untagged_addr,
	t->unique_id());
	Printf("%s", d.Default());
	t->Announce();

	auto *sa = (t == GetCurrentThread() && current_stack_allocations)
	? current_stack_allocations
	: t->stack_allocations();
	PrintStackAllocations(sa, addr_tag, untagged_addr);
	num_descriptions_printed++;
	}
	});

	// Print the remaining threads, as an extra information, 1 line per thread.
	hwasanThreadList().VisitAllLiveThreads([&](Thread *t) { t->Announce(); });

	if (!num_descriptions_printed)
	// We exhausted our possibilities. Bail out.
	Printf("HWAddressSanitizer can not describe address in more detail.\n");
	}

	void ReportStats() {}

	static void PrintTagInfoAroundAddr(tag_t *tag_ptr, uptr num_rows,
	void (*print_tag)(InternalScopedString &s,
	tag_t *tag)) {
	const uptr row_len = 16; // better be power of two.
	tag_t center_row_beg = reinterpret_cast<tag_t >(
	RoundDownTo(reinterpret_cast<uptr>(tag_ptr), row_len));
	tag_t beg_row = center_row_beg - row_len (num_rows / 2);
	tag_t end_row = center_row_beg + row_len ((num_rows + 1) / 2);
	InternalScopedString s(GetPageSizeCached() * 8);
	for (tag_t *row = beg_row; row < end_row; row += row_len) {
	s.append("%s", row == center_row_beg ? "=>" : " ");
	for (uptr i = 0; i < row_len; i++) {
	s.append("%s", row + i == tag_ptr ? "[" : " ");
	print_tag(s, &row[i]);
	s.append("%s", row + i == tag_ptr ? "]" : " ");
	}
	s.append("%s\n", row == center_row_beg ? "<=" : " ");
	}
	Printf("%s", s.data());
	}

	static void PrintTagsAroundAddr(tag_t *tag_ptr) {
	Printf(
	"Memory tags around the buggy address (one tag corresponds to %zd "
	"bytes):\n", kShadowAlignment);
	PrintTagInfoAroundAddr(tag_ptr, 17, [](InternalScopedString &s, tag_t *tag) {
	s.append("%02x", *tag);
	});

	Printf(
	"Tags for short granules around the buggy address (one tag corresponds "
	"to %zd bytes):\n",
	kShadowAlignment);
	PrintTagInfoAroundAddr(tag_ptr, 3, [](InternalScopedString &s, tag_t *tag) {
	if (tag >= 1 && tag <= kShadowAlignment) {
	uptr granule_addr = ShadowToMem(reinterpret_cast<uptr>(tag));
	s.append("%02x",
	reinterpret_cast<u8 >(granule_addr + kShadowAlignment - 1));
	} else {
	s.append("..");
	}
	});
	Printf(
	"See "
	"https://clang.llvm.org/docs/"
	"HardwareAssistedAddressSanitizerDesign.html#short-granules for a "
	"description of short granule tags\n");
	}

	void ReportInvalidFree(StackTrace *stack, uptr tagged_addr) {
	ScopedReport R(flags()->halt_on_error);

	uptr untagged_addr = UntagAddr(tagged_addr);
	tag_t ptr_tag = GetTagFromPointer(tagged_addr);
	tag_t tag_ptr = reinterpret_cast<tag_t>(MemToShadow(untagged_addr));
	tag_t mem_tag = *tag_ptr;
	Decorator d;
	Printf("%s", d.Error());
	uptr pc = stack->size ? stack->trace[0] : 0;
	const char *bug_type = "invalid-free";
	Report("ERROR: %s: %s on address %p at pc %p\n", SanitizerToolName, bug_type,
	untagged_addr, pc);
	Printf("%s", d.Access());
	Printf("tags: %02x/%02x (ptr/mem)\n", ptr_tag, mem_tag);
	Printf("%s", d.Default());

	stack->Print();

	PrintAddressDescription(tagged_addr, 0, nullptr);

	PrintTagsAroundAddr(tag_ptr);

	ReportErrorSummary(bug_type, stack);
	}

	void ReportTailOverwritten(StackTrace *stack, uptr tagged_addr, uptr orig_size,
	const u8 *expected) {
	uptr tail_size = kShadowAlignment - (orig_size % kShadowAlignment);
	ScopedReport R(flags()->halt_on_error);
	Decorator d;
	uptr untagged_addr = UntagAddr(tagged_addr);
	Printf("%s", d.Error());
	const char *bug_type = "alocation-tail-overwritten";
	Report("ERROR: %s: %s; heap object [%p,%p) of size %zd\n", SanitizerToolName,
	bug_type, untagged_addr, untagged_addr + orig_size, orig_size);
	Printf("\n%s", d.Default());
	stack->Print();
	HwasanChunkView chunk = FindHeapChunkByAddress(untagged_addr);
	if (chunk.Beg()) {
	Printf("%s", d.Allocation());
	Printf("allocated here:\n");
	Printf("%s", d.Default());
	GetStackTraceFromId(chunk.GetAllocStackId()).Print();
	}

	InternalScopedString s(GetPageSizeCached() * 8);
	CHECK_GT(tail_size, 0U);
	CHECK_LT(tail_size, kShadowAlignment);
	u8 tail = reinterpret_cast<u8>(untagged_addr + orig_size);
	s.append("Tail contains: ");
	for (uptr i = 0; i < kShadowAlignment - tail_size; i++)
	s.append(".. ");
	for (uptr i = 0; i < tail_size; i++)
	s.append("%02x ", tail[i]);
	s.append("\n");
	s.append("Expected: ");
	for (uptr i = 0; i < kShadowAlignment - tail_size; i++)
	s.append(".. ");
	for (uptr i = 0; i < tail_size; i++)
	s.append("%02x ", expected[i]);
	s.append("\n");
	s.append(" ");
	for (uptr i = 0; i < kShadowAlignment - tail_size; i++)
	s.append(" ");
	for (uptr i = 0; i < tail_size; i++)
	s.append("%s ", expected[i] != tail[i] ? "^^" : " ");

	s.append("\nThis error occurs when a buffer overflow overwrites memory\n"
	"to the right of a heap object, but within the %zd-byte granule, e.g.\n"
	" char *x = new char[20];\n"
	" x[25] = 42;\n"
	"%s does not detect such bugs in uninstrumented code at the time of write,"
	"\nbut can detect them at the time of free/delete.\n"
	"To disable this feature set HWASAN_OPTIONS=free_checks_tail_magic=0\n",
	kShadowAlignment, SanitizerToolName);
	Printf("%s", s.data());
	GetCurrentThread()->Announce();

	tag_t tag_ptr = reinterpret_cast<tag_t>(MemToShadow(untagged_addr));
	PrintTagsAroundAddr(tag_ptr);

	ReportErrorSummary(bug_type, stack);
	}

	void ReportTagMismatch(StackTrace *stack, uptr tagged_addr, uptr access_size,
	bool is_store, bool fatal, uptr *registers_frame) {
	ScopedReport R(fatal);
	SavedStackAllocations current_stack_allocations(
	GetCurrentThread()->stack_allocations());

	Decorator d;
	Printf("%s", d.Error());
	uptr untagged_addr = UntagAddr(tagged_addr);
	// TODO: when possible, try to print heap-use-after-free, etc.
	const char *bug_type = "tag-mismatch";
	uptr pc = stack->size ? stack->trace[0] : 0;
	Report("ERROR: %s: %s on address %p at pc %p\n", SanitizerToolName, bug_type,
	untagged_addr, pc);

	Thread *t = GetCurrentThread();

	sptr offset =
	__hwasan_test_shadow(reinterpret_cast<void *>(tagged_addr), access_size);
	CHECK(offset >= 0 && offset < static_cast<sptr>(access_size));
	tag_t ptr_tag = GetTagFromPointer(tagged_addr);
	tag_t *tag_ptr =
	reinterpret_cast<tag_t *>(MemToShadow(untagged_addr + offset));
	tag_t mem_tag = *tag_ptr;

	Printf("%s", d.Access());
	Printf("%s of size %zu at %p tags: %02x/%02x (ptr/mem) in thread T%zd\n",
	is_store ? "WRITE" : "READ", access_size, untagged_addr, ptr_tag,
	mem_tag, t->unique_id());
	if (offset != 0)
	Printf("Invalid access starting at offset [%zu, %zu)\n", offset,
	Min(access_size, static_cast<uptr>(offset) + (1 << kShadowScale)));
	Printf("%s", d.Default());

	stack->Print();

	PrintAddressDescription(tagged_addr, access_size,
	current_stack_allocations.get());
	t->Announce();

	PrintTagsAroundAddr(tag_ptr);

	if (registers_frame)
	ReportRegisters(registers_frame, pc);

	ReportErrorSummary(bug_type, stack);
	}

	// See the frame breakdown defined in __hwasan_tag_mismatch (from
	// hwasan_tag_mismatch_aarch64.S).
	void ReportRegisters(uptr *frame, uptr pc) {
	Printf("Registers where the failure occurred (pc %p):\n", pc);

	// We explicitly print a single line (4 registers/line) each iteration to
	// reduce the amount of logcat error messages printed. Each Printf() will
	// result in a new logcat line, irrespective of whether a newline is present,
	// and so we wish to reduce the number of Printf() calls we have to make.
	Printf(" x0 %016llx x1 %016llx x2 %016llx x3 %016llx\n",
	frame[0], frame[1], frame[2], frame[3]);
	Printf(" x4 %016llx x5 %016llx x6 %016llx x7 %016llx\n",
	frame[4], frame[5], frame[6], frame[7]);
	Printf(" x8 %016llx x9 %016llx x10 %016llx x11 %016llx\n",
	frame[8], frame[9], frame[10], frame[11]);
	Printf(" x12 %016llx x13 %016llx x14 %016llx x15 %016llx\n",
	frame[12], frame[13], frame[14], frame[15]);
	Printf(" x16 %016llx x17 %016llx x18 %016llx x19 %016llx\n",
	frame[16], frame[17], frame[18], frame[19]);
	Printf(" x20 %016llx x21 %016llx x22 %016llx x23 %016llx\n",
	frame[20], frame[21], frame[22], frame[23]);
	Printf(" x24 %016llx x25 %016llx x26 %016llx x27 %016llx\n",
	frame[24], frame[25], frame[26], frame[27]);
	Printf(" x28 %016llx x29 %016llx x30 %016llx\n",
	frame[28], frame[29], frame[30]);
	}

	} // namespace __hwasan