debuggerd/libdebuggerd/tombstone_proto_to_text.cpp - third_party/android/platform/system/core - Git at Google

 /*
  * Copyright (C) 2020 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include <libdebuggerd/tombstone.h>

 #include <inttypes.h>

 #include <functional>
 #include <set>
 #include <string>
 #include <unordered_set>
 #include <utility>
 #include <vector>

 #include <android-base/stringprintf.h>
 #include <android-base/strings.h>
 #include <android-base/unique_fd.h>
 #include <async_safe/log.h>
 #include <bionic/macros.h>

 #include "tombstone.pb.h"

 using android::base::StringAppendF;
 using android::base::StringPrintf;

 #define CB(log, ...) callback(StringPrintf(__VA_ARGS__), log)
 #define CBL(...) CB(true, __VA_ARGS__)
 #define CBS(...) CB(false, __VA_ARGS__)
 using CallbackType = std::function<void(const std::string& line, bool should_log)>;

 static const char* abi_string(const Tombstone& tombstone) {
   switch (tombstone.arch()) {
     case Architecture::ARM32:
       return "arm";
     case Architecture::ARM64:
       return "arm64";
     case Architecture::RISCV64:
       return "riscv64";
     case Architecture::X86:
       return "x86";
     case Architecture::X86_64:
       return "x86_64";
     default:
       return "<unknown>";
   }
 }

 static int pointer_width(const Tombstone& tombstone) {
   switch (tombstone.arch()) {
     case Architecture::ARM32:
       return 4;
     case Architecture::ARM64:
       return 8;
     case Architecture::RISCV64:
       return 8;
     case Architecture::X86:
       return 4;
     case Architecture::X86_64:
       return 8;
     default:
       return 8;
   }
 }

 static void print_thread_header(CallbackType callback, const Tombstone& tombstone,
                                 const Thread& thread, bool should_log) {
   const char* process_name = "<unknown>";
   if (!tombstone.command_line().empty()) {
     process_name = tombstone.command_line()[0].c_str();
     CB(should_log, "Cmdline: %s", android::base::Join(tombstone.command_line(), " ").c_str());
   }
   CB(should_log, "pid: %d, tid: %d, name: %s  >>> %s <<<", tombstone.pid(), thread.id(),
      thread.name().c_str(), process_name);
   CB(should_log, "uid: %d", tombstone.uid());
   if (thread.tagged_addr_ctrl() != -1) {
     CB(should_log, "tagged_addr_ctrl: %016" PRIx64 "%s", thread.tagged_addr_ctrl(),
        describe_tagged_addr_ctrl(thread.tagged_addr_ctrl()).c_str());
   }
   if (thread.pac_enabled_keys() != -1) {
     CB(should_log, "pac_enabled_keys: %016" PRIx64 "%s", thread.pac_enabled_keys(),
        describe_pac_enabled_keys(thread.pac_enabled_keys()).c_str());
   }
 }

 static void print_register_row(CallbackType callback, int word_size,
                                std::vector<std::pair<std::string, uint64_t>> row, bool should_log) {
   std::string output = "  ";
   for (const auto& [name, value] : row) {
     output += android::base::StringPrintf("  %-3s %0*" PRIx64, name.c_str(), 2 * word_size,
                                           static_cast<uint64_t>(value));
   }
   callback(output, should_log);
 }

 static void print_thread_registers(CallbackType callback, const Tombstone& tombstone,
                                    const Thread& thread, bool should_log) {
   static constexpr size_t column_count = 4;
   std::vector<std::pair<std::string, uint64_t>> current_row;
   std::vector<std::pair<std::string, uint64_t>> special_row;
   std::unordered_set<std::string> special_registers;

   int word_size = pointer_width(tombstone);

   switch (tombstone.arch()) {
     case Architecture::ARM32:
       special_registers = {"ip", "lr", "sp", "pc", "pst"};
       break;

     case Architecture::ARM64:
       special_registers = {"ip", "lr", "sp", "pc", "pst"};
       break;

     case Architecture::RISCV64:
       special_registers = {"ra", "sp", "pc"};
       break;

     case Architecture::X86:
       special_registers = {"ebp", "esp", "eip"};
       break;

     case Architecture::X86_64:
       special_registers = {"rbp", "rsp", "rip"};
       break;

     default:
       async_safe_fatal("unknown architecture");
   }

   for (const auto& reg : thread.registers()) {
     auto row = &current_row;
     if (special_registers.count(reg.name()) == 1) {
       row = &special_row;
     }

     row->emplace_back(reg.name(), reg.u64());
     if (current_row.size() == column_count) {
       print_register_row(callback, word_size, current_row, should_log);
       current_row.clear();
     }
   }

   if (!current_row.empty()) {
     print_register_row(callback, word_size, current_row, should_log);
   }

   print_register_row(callback, word_size, special_row, should_log);
 }

 static void print_backtrace(CallbackType callback, const Tombstone& tombstone,
                             const google::protobuf::RepeatedPtrField<BacktraceFrame>& backtrace,
                             bool should_log) {
   int index = 0;
   for (const auto& frame : backtrace) {
     std::string function;

     if (!frame.function_name().empty()) {
       function =
           StringPrintf(" (%s+%" PRId64 ")", frame.function_name().c_str(), frame.function_offset());
     }

     std::string build_id;
     if (!frame.build_id().empty()) {
       build_id = StringPrintf(" (BuildId: %s)", frame.build_id().c_str());
     }

     std::string line =
         StringPrintf("      #%02d pc %0*" PRIx64 "  %s", index++, pointer_width(tombstone) * 2,
                      frame.rel_pc(), frame.file_name().c_str());
     if (frame.file_map_offset() != 0) {
       line += StringPrintf(" (offset 0x%" PRIx64 ")", frame.file_map_offset());
     }
     line += function + build_id;
     CB(should_log, "%s", line.c_str());
   }
 }

 static void print_thread_backtrace(CallbackType callback, const Tombstone& tombstone,
                                    const Thread& thread, bool should_log) {
   CBS("");
   CB(should_log, "%d total frames", thread.current_backtrace().size());
   CB(should_log, "backtrace:");
   if (!thread.backtrace_note().empty()) {
     CB(should_log, "  NOTE: %s",
        android::base::Join(thread.backtrace_note(), "\n  NOTE: ").c_str());
   }
   print_backtrace(callback, tombstone, thread.current_backtrace(), should_log);
 }

 static void print_thread_memory_dump(CallbackType callback, const Tombstone& tombstone,
                                      const Thread& thread) {
   static constexpr size_t bytes_per_line = 16;
   static_assert(bytes_per_line == kTagGranuleSize);
   int word_size = pointer_width(tombstone);
   for (const auto& mem : thread.memory_dump()) {
     CBS("");
     if (mem.mapping_name().empty()) {
       CBS("memory near %s:", mem.register_name().c_str());
     } else {
       CBS("memory near %s (%s):", mem.register_name().c_str(), mem.mapping_name().c_str());
     }
     uint64_t addr = mem.begin_address();
     for (size_t offset = 0; offset < mem.memory().size(); offset += bytes_per_line) {
       uint64_t tagged_addr = addr;
       if (mem.has_arm_mte_metadata() &&
           mem.arm_mte_metadata().memory_tags().size() > offset / kTagGranuleSize) {
         tagged_addr |=
             static_cast<uint64_t>(mem.arm_mte_metadata().memory_tags()[offset / kTagGranuleSize])
             << 56;
       }
       std::string line = StringPrintf("    %0*" PRIx64, word_size * 2, tagged_addr + offset);

       size_t bytes = std::min(bytes_per_line, mem.memory().size() - offset);
       for (size_t i = 0; i < bytes; i += word_size) {
         uint64_t word = 0;

         // Assumes little-endian, but what doesn't?
         memcpy(&word, mem.memory().data() + offset + i, word_size);

         StringAppendF(&line, " %0*" PRIx64, word_size * 2, word);
       }

       char ascii[bytes_per_line + 1];

       memset(ascii, '.', sizeof(ascii));
       ascii[bytes_per_line] = '\0';

       for (size_t i = 0; i < bytes; ++i) {
         uint8_t byte = mem.memory()[offset + i];
         if (byte >= 0x20 && byte < 0x7f) {
           ascii[i] = byte;
         }
       }

       CBS("%s  %s", line.c_str(), ascii);
     }
   }
 }

 static void print_thread(CallbackType callback, const Tombstone& tombstone, const Thread& thread) {
   print_thread_header(callback, tombstone, thread, false);
   print_thread_registers(callback, tombstone, thread, false);
   print_thread_backtrace(callback, tombstone, thread, false);
   print_thread_memory_dump(callback, tombstone, thread);
 }

 static void print_tag_dump(CallbackType callback, const Tombstone& tombstone) {
   if (!tombstone.has_signal_info()) return;

   const Signal& signal = tombstone.signal_info();

   if (!signal.has_fault_address() || !signal.has_fault_adjacent_metadata()) {
     return;
   }

   const MemoryDump& memory_dump = signal.fault_adjacent_metadata();

   if (!memory_dump.has_arm_mte_metadata() || memory_dump.arm_mte_metadata().memory_tags().empty()) {
     return;
   }

   const std::string& tags = memory_dump.arm_mte_metadata().memory_tags();

   CBS("");
   CBS("Memory tags around the fault address (0x%" PRIx64 "), one tag per %zu bytes:",
       signal.fault_address(), kTagGranuleSize);
   constexpr uintptr_t kRowStartMask = ~(kNumTagColumns * kTagGranuleSize - 1);

   size_t tag_index = 0;
   size_t num_tags = tags.length();
   uintptr_t fault_granule = untag_address(signal.fault_address()) & ~(kTagGranuleSize - 1);
   for (size_t row = 0; tag_index < num_tags; ++row) {
     uintptr_t row_addr =
         (memory_dump.begin_address() + row * kNumTagColumns * kTagGranuleSize) & kRowStartMask;
     std::string row_contents;
     bool row_has_fault = false;

     for (size_t column = 0; column < kNumTagColumns; ++column) {
       uintptr_t granule_addr = row_addr + column * kTagGranuleSize;
       if (granule_addr < memory_dump.begin_address() ||
           granule_addr >= memory_dump.begin_address() + num_tags * kTagGranuleSize) {
         row_contents += " . ";
       } else if (granule_addr == fault_granule) {
         row_contents += StringPrintf("[%1hhx]", tags[tag_index++]);
         row_has_fault = true;
       } else {
         row_contents += StringPrintf(" %1hhx ", tags[tag_index++]);
       }
     }

     if (row_contents.back() == ' ') row_contents.pop_back();

     if (row_has_fault) {
       CBS("    =>0x%" PRIxPTR ":%s", row_addr, row_contents.c_str());
     } else {
       CBS("      0x%" PRIxPTR ":%s", row_addr, row_contents.c_str());
     }
   }
 }

 static void print_memory_maps(CallbackType callback, const Tombstone& tombstone) {
   int word_size = pointer_width(tombstone);
   const auto format_pointer = [word_size](uint64_t ptr) -> std::string {
     if (word_size == 8) {
       uint64_t top = ptr >> 32;
       uint64_t bottom = ptr & 0xFFFFFFFF;
       return StringPrintf("%08" PRIx64 "'%08" PRIx64, top, bottom);
     }

     return StringPrintf("%0*" PRIx64, word_size * 2, ptr);
   };

   std::string memory_map_header =
       StringPrintf("memory map (%d %s):", tombstone.memory_mappings().size(),
                    tombstone.memory_mappings().size() == 1 ? "entry" : "entries");

   const Signal& signal_info = tombstone.signal_info();
   bool has_fault_address = signal_info.has_fault_address();
   uint64_t fault_address = untag_address(signal_info.fault_address());
   bool preamble_printed = false;
   bool printed_fault_address_marker = false;
   for (const auto& map : tombstone.memory_mappings()) {
     if (!preamble_printed) {
       preamble_printed = true;
       if (has_fault_address) {
         if (fault_address < map.begin_address()) {
           memory_map_header +=
               StringPrintf("\n--->Fault address falls at %s before any mapped regions",
                            format_pointer(fault_address).c_str());
           printed_fault_address_marker = true;
         } else {
           memory_map_header += " (fault address prefixed with --->)";
         }
       }
       CBS("%s", memory_map_header.c_str());
     }

     std::string line = "    ";
     if (has_fault_address && !printed_fault_address_marker) {
       if (fault_address < map.begin_address()) {
         printed_fault_address_marker = true;
         CBS("--->Fault address falls at %s between mapped regions",
             format_pointer(fault_address).c_str());
       } else if (fault_address >= map.begin_address() && fault_address < map.end_address()) {
         printed_fault_address_marker = true;
         line = "--->";
       }
     }
     StringAppendF(&line, "%s-%s", format_pointer(map.begin_address()).c_str(),
                   format_pointer(map.end_address() - 1).c_str());
     StringAppendF(&line, " %s%s%s", map.read() ? "r" : "-", map.write() ? "w" : "-",
                   map.execute() ? "x" : "-");
     StringAppendF(&line, "  %8" PRIx64 "  %8" PRIx64, map.offset(),
                   map.end_address() - map.begin_address());

     if (!map.mapping_name().empty()) {
       StringAppendF(&line, "  %s", map.mapping_name().c_str());

       if (!map.build_id().empty()) {
         StringAppendF(&line, " (BuildId: %s)", map.build_id().c_str());
       }

       if (map.load_bias() != 0) {
         StringAppendF(&line, " (load bias 0x%" PRIx64 ")", map.load_bias());
       }
     }

     CBS("%s", line.c_str());
   }

   if (has_fault_address && !printed_fault_address_marker) {
     CBS("--->Fault address falls at %s after any mapped regions",
         format_pointer(fault_address).c_str());
   }
 }

 static void print_main_thread(CallbackType callback, const Tombstone& tombstone,
                               const Thread& thread) {
   print_thread_header(callback, tombstone, thread, true);

   const Signal& signal_info = tombstone.signal_info();
   std::string sender_desc;

   if (signal_info.has_sender()) {
     sender_desc =
         StringPrintf(" from pid %d, uid %d", signal_info.sender_pid(), signal_info.sender_uid());
   }

   bool is_async_mte_crash = false;
   bool is_mte_crash = false;
   if (!tombstone.has_signal_info()) {
     CBL("signal information missing");
   } else {
     std::string fault_addr_desc;
     if (signal_info.has_fault_address()) {
       fault_addr_desc =
           StringPrintf("0x%0*" PRIx64, 2 * pointer_width(tombstone), signal_info.fault_address());
     } else {
       fault_addr_desc = "--------";
     }

     CBL("signal %d (%s), code %d (%s%s), fault addr %s", signal_info.number(),
         signal_info.name().c_str(), signal_info.code(), signal_info.code_name().c_str(),
         sender_desc.c_str(), fault_addr_desc.c_str());
 #ifdef SEGV_MTEAERR
     is_async_mte_crash = signal_info.number() == SIGSEGV && signal_info.code() == SEGV_MTEAERR;
     is_mte_crash = is_async_mte_crash ||
                    (signal_info.number() == SIGSEGV && signal_info.code() == SEGV_MTESERR);
 #endif
   }

   if (tombstone.causes_size() == 1) {
     CBL("Cause: %s", tombstone.causes(0).human_readable().c_str());
   }

   if (!tombstone.abort_message().empty()) {
     CBL("Abort message: '%s'", tombstone.abort_message().c_str());
   }

   print_thread_registers(callback, tombstone, thread, true);
   if (is_async_mte_crash) {
     CBL("Note: This crash is a delayed async MTE crash. Memory corruption has occurred");
     CBL("      in this process. The stack trace below is the first system call or context");
     CBL("      switch that was executed after the memory corruption happened.");
   }
   print_thread_backtrace(callback, tombstone, thread, true);

   if (tombstone.causes_size() > 1) {
     CBS("");
     CBL("Note: multiple potential causes for this crash were detected, listing them in decreasing "
         "order of likelihood.");
   }

   for (const Cause& cause : tombstone.causes()) {
     if (tombstone.causes_size() > 1) {
       CBS("");
       CBL("Cause: %s", cause.human_readable().c_str());
     }

     if (cause.has_memory_error() && cause.memory_error().has_heap()) {
       const HeapObject& heap_object = cause.memory_error().heap();

       if (heap_object.deallocation_backtrace_size() != 0) {
         CBS("");
         CBL("deallocated by thread %" PRIu64 ":", heap_object.deallocation_tid());
         print_backtrace(callback, tombstone, heap_object.deallocation_backtrace(), true);
       }

       if (heap_object.allocation_backtrace_size() != 0) {
         CBS("");
         CBL("allocated by thread %" PRIu64 ":", heap_object.allocation_tid());
         print_backtrace(callback, tombstone, heap_object.allocation_backtrace(), true);
       }
     }
   }

   print_tag_dump(callback, tombstone);

   if (is_mte_crash) {
     CBS("");
     CBL("Learn more about MTE reports: "
         "https://source.android.com/docs/security/test/memory-safety/mte-reports");
   }

   print_thread_memory_dump(callback, tombstone, thread);

   CBS("");

   // No memory maps to print.
   if (!tombstone.memory_mappings().empty()) {
     print_memory_maps(callback, tombstone);
   } else {
     CBS("No memory maps found");
   }
 }

 void print_logs(CallbackType callback, const Tombstone& tombstone, int tail) {
   for (const auto& buffer : tombstone.log_buffers()) {
     if (tail) {
       CBS("--------- tail end of log %s", buffer.name().c_str());
     } else {
       CBS("--------- log %s", buffer.name().c_str());
     }

     int begin = 0;
     if (tail != 0) {
       begin = std::max(0, buffer.logs().size() - tail);
     }

     for (int i = begin; i < buffer.logs().size(); ++i) {
       const LogMessage& msg = buffer.logs(i);

       static const char* kPrioChars = "!.VDIWEFS";
       char priority = (msg.priority() < strlen(kPrioChars) ? kPrioChars[msg.priority()] : '?');
       CBS("%s %5u %5u %c %-8s: %s", msg.timestamp().c_str(), msg.pid(), msg.tid(), priority,
           msg.tag().c_str(), msg.message().c_str());
     }
   }
 }

 bool tombstone_proto_to_text(const Tombstone& tombstone, CallbackType callback) {
   CBL("*** *** *** *** *** *** *** *** *** *** *** *** *** *** *** ***");
   CBL("Build fingerprint: '%s'", tombstone.build_fingerprint().c_str());
   CBL("Revision: '%s'", tombstone.revision().c_str());
   CBL("ABI: '%s'", abi_string(tombstone));
   CBL("Timestamp: %s", tombstone.timestamp().c_str());
   CBL("Process uptime: %ds", tombstone.process_uptime());

   // Process header
   const auto& threads = tombstone.threads();
   auto main_thread_it = threads.find(tombstone.tid());
   if (main_thread_it == threads.end()) {
     CBL("failed to find entry for main thread in tombstone");
     return false;
   }

   const auto& main_thread = main_thread_it->second;

   print_main_thread(callback, tombstone, main_thread);

   print_logs(callback, tombstone, 50);

   // protobuf's map is unordered, so sort the keys first.
   std::set<int> thread_ids;
   for (const auto& [tid, _] : threads) {
     if (tid != tombstone.tid()) {
       thread_ids.insert(tid);
     }
   }

   for (const auto& tid : thread_ids) {
     CBS("--- --- --- --- --- --- --- --- --- --- --- --- --- --- --- ---");
     print_thread(callback, tombstone, threads.find(tid)->second);
   }

   if (tombstone.open_fds().size() > 0) {
     CBS("");
     CBS("open files:");
     for (const auto& fd : tombstone.open_fds()) {
       std::optional<std::string> owner;
       if (!fd.owner().empty()) {
         owner = StringPrintf("owned by %s 0x%" PRIx64, fd.owner().c_str(), fd.tag());
       }

       CBS("    fd %d: %s (%s)", fd.fd(), fd.path().c_str(), owner ? owner->c_str() : "unowned");
     }
   }

   print_logs(callback, tombstone, 0);

   return true;
 }
	/*
	* Copyright (C) 2020 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include <libdebuggerd/tombstone.h>

	#include <inttypes.h>

	#include <functional>
	#include <set>
	#include <string>
	#include <unordered_set>
	#include <utility>
	#include <vector>

	#include <android-base/stringprintf.h>
	#include <android-base/strings.h>
	#include <android-base/unique_fd.h>
	#include <async_safe/log.h>
	#include <bionic/macros.h>

	#include "tombstone.pb.h"

	using android::base::StringAppendF;
	using android::base::StringPrintf;

	#define CB(log, ...) callback(StringPrintf(__VA_ARGS__), log)
	#define CBL(...) CB(true, __VA_ARGS__)
	#define CBS(...) CB(false, __VA_ARGS__)
	using CallbackType = std::function<void(const std::string& line, bool should_log)>;

	static const char* abi_string(const Tombstone& tombstone) {
	switch (tombstone.arch()) {
	case Architecture::ARM32:
	return "arm";
	case Architecture::ARM64:
	return "arm64";
	case Architecture::RISCV64:
	return "riscv64";
	case Architecture::X86:
	return "x86";
	case Architecture::X86_64:
	return "x86_64";
	default:
	return "<unknown>";
	}
	}

	static int pointer_width(const Tombstone& tombstone) {
	switch (tombstone.arch()) {
	case Architecture::ARM32:
	return 4;
	case Architecture::ARM64:
	return 8;
	case Architecture::RISCV64:
	return 8;
	case Architecture::X86:
	return 4;
	case Architecture::X86_64:
	return 8;
	default:
	return 8;
	}
	}

	static void print_thread_header(CallbackType callback, const Tombstone& tombstone,
	const Thread& thread, bool should_log) {
	const char* process_name = "<unknown>";
	if (!tombstone.command_line().empty()) {
	process_name = tombstone.command_line()[0].c_str();
	CB(should_log, "Cmdline: %s", android::base::Join(tombstone.command_line(), " ").c_str());
	}
	CB(should_log, "pid: %d, tid: %d, name: %s >>> %s <<<", tombstone.pid(), thread.id(),
	thread.name().c_str(), process_name);
	CB(should_log, "uid: %d", tombstone.uid());
	if (thread.tagged_addr_ctrl() != -1) {
	CB(should_log, "tagged_addr_ctrl: %016" PRIx64 "%s", thread.tagged_addr_ctrl(),
	describe_tagged_addr_ctrl(thread.tagged_addr_ctrl()).c_str());
	}
	if (thread.pac_enabled_keys() != -1) {
	CB(should_log, "pac_enabled_keys: %016" PRIx64 "%s", thread.pac_enabled_keys(),
	describe_pac_enabled_keys(thread.pac_enabled_keys()).c_str());
	}
	}

	static void print_register_row(CallbackType callback, int word_size,
	std::vector<std::pair<std::string, uint64_t>> row, bool should_log) {
	std::string output = " ";
	for (const auto& [name, value] : row) {
	output += android::base::StringPrintf(" %-3s %0" PRIx64, name.c_str(), 2 word_size,
	static_cast<uint64_t>(value));
	}
	callback(output, should_log);
	}

	static void print_thread_registers(CallbackType callback, const Tombstone& tombstone,
	const Thread& thread, bool should_log) {
	static constexpr size_t column_count = 4;
	std::vector<std::pair<std::string, uint64_t>> current_row;
	std::vector<std::pair<std::string, uint64_t>> special_row;
	std::unordered_set<std::string> special_registers;

	int word_size = pointer_width(tombstone);

	switch (tombstone.arch()) {
	case Architecture::ARM32:
	special_registers = {"ip", "lr", "sp", "pc", "pst"};
	break;

	case Architecture::ARM64:
	special_registers = {"ip", "lr", "sp", "pc", "pst"};
	break;

	case Architecture::RISCV64:
	special_registers = {"ra", "sp", "pc"};
	break;

	case Architecture::X86:
	special_registers = {"ebp", "esp", "eip"};
	break;

	case Architecture::X86_64:
	special_registers = {"rbp", "rsp", "rip"};
	break;

	default:
	async_safe_fatal("unknown architecture");
	}

	for (const auto& reg : thread.registers()) {
	auto row = &current_row;
	if (special_registers.count(reg.name()) == 1) {
	row = &special_row;
	}

	row->emplace_back(reg.name(), reg.u64());
	if (current_row.size() == column_count) {
	print_register_row(callback, word_size, current_row, should_log);
	current_row.clear();
	}
	}

	if (!current_row.empty()) {
	print_register_row(callback, word_size, current_row, should_log);
	}

	print_register_row(callback, word_size, special_row, should_log);
	}

	static void print_backtrace(CallbackType callback, const Tombstone& tombstone,
	const google::protobuf::RepeatedPtrField<BacktraceFrame>& backtrace,
	bool should_log) {
	int index = 0;
	for (const auto& frame : backtrace) {
	std::string function;

	if (!frame.function_name().empty()) {
	function =
	StringPrintf(" (%s+%" PRId64 ")", frame.function_name().c_str(), frame.function_offset());
	}

	std::string build_id;
	if (!frame.build_id().empty()) {
	build_id = StringPrintf(" (BuildId: %s)", frame.build_id().c_str());
	}

	std::string line =
	StringPrintf(" #%02d pc %0" PRIx64 " %s", index++, pointer_width(tombstone) 2,
	frame.rel_pc(), frame.file_name().c_str());
	if (frame.file_map_offset() != 0) {
	line += StringPrintf(" (offset 0x%" PRIx64 ")", frame.file_map_offset());
	}
	line += function + build_id;
	CB(should_log, "%s", line.c_str());
	}
	}

	static void print_thread_backtrace(CallbackType callback, const Tombstone& tombstone,
	const Thread& thread, bool should_log) {
	CBS("");
	CB(should_log, "%d total frames", thread.current_backtrace().size());
	CB(should_log, "backtrace:");
	if (!thread.backtrace_note().empty()) {
	CB(should_log, " NOTE: %s",
	android::base::Join(thread.backtrace_note(), "\n NOTE: ").c_str());
	}
	print_backtrace(callback, tombstone, thread.current_backtrace(), should_log);
	}

	static void print_thread_memory_dump(CallbackType callback, const Tombstone& tombstone,
	const Thread& thread) {
	static constexpr size_t bytes_per_line = 16;
	static_assert(bytes_per_line == kTagGranuleSize);
	int word_size = pointer_width(tombstone);
	for (const auto& mem : thread.memory_dump()) {
	CBS("");
	if (mem.mapping_name().empty()) {
	CBS("memory near %s:", mem.register_name().c_str());
	} else {
	CBS("memory near %s (%s):", mem.register_name().c_str(), mem.mapping_name().c_str());
	}
	uint64_t addr = mem.begin_address();
	for (size_t offset = 0; offset < mem.memory().size(); offset += bytes_per_line) {
	uint64_t tagged_addr = addr;
	if (mem.has_arm_mte_metadata() &&
	mem.arm_mte_metadata().memory_tags().size() > offset / kTagGranuleSize) {
	tagged_addr \|=
	static_cast<uint64_t>(mem.arm_mte_metadata().memory_tags()[offset / kTagGranuleSize])
	<< 56;
	}
	std::string line = StringPrintf(" %0" PRIx64, word_size 2, tagged_addr + offset);

	size_t bytes = std::min(bytes_per_line, mem.memory().size() - offset);
	for (size_t i = 0; i < bytes; i += word_size) {
	uint64_t word = 0;

	// Assumes little-endian, but what doesn't?
	memcpy(&word, mem.memory().data() + offset + i, word_size);

	StringAppendF(&line, " %0" PRIx64, word_size 2, word);
	}

	char ascii[bytes_per_line + 1];

	memset(ascii, '.', sizeof(ascii));
	ascii[bytes_per_line] = '\0';

	for (size_t i = 0; i < bytes; ++i) {
	uint8_t byte = mem.memory()[offset + i];
	if (byte >= 0x20 && byte < 0x7f) {
	ascii[i] = byte;
	}
	}

	CBS("%s %s", line.c_str(), ascii);
	}
	}
	}

	static void print_thread(CallbackType callback, const Tombstone& tombstone, const Thread& thread) {
	print_thread_header(callback, tombstone, thread, false);
	print_thread_registers(callback, tombstone, thread, false);
	print_thread_backtrace(callback, tombstone, thread, false);
	print_thread_memory_dump(callback, tombstone, thread);
	}

	static void print_tag_dump(CallbackType callback, const Tombstone& tombstone) {
	if (!tombstone.has_signal_info()) return;

	const Signal& signal = tombstone.signal_info();

	if (!signal.has_fault_address() \|\| !signal.has_fault_adjacent_metadata()) {
	return;
	}

	const MemoryDump& memory_dump = signal.fault_adjacent_metadata();

	if (!memory_dump.has_arm_mte_metadata() \|\| memory_dump.arm_mte_metadata().memory_tags().empty()) {
	return;
	}

	const std::string& tags = memory_dump.arm_mte_metadata().memory_tags();

	CBS("");
	CBS("Memory tags around the fault address (0x%" PRIx64 "), one tag per %zu bytes:",
	signal.fault_address(), kTagGranuleSize);
	constexpr uintptr_t kRowStartMask = ~(kNumTagColumns * kTagGranuleSize - 1);

	size_t tag_index = 0;
	size_t num_tags = tags.length();
	uintptr_t fault_granule = untag_address(signal.fault_address()) & ~(kTagGranuleSize - 1);
	for (size_t row = 0; tag_index < num_tags; ++row) {
	uintptr_t row_addr =
	(memory_dump.begin_address() + row * kNumTagColumns * kTagGranuleSize) & kRowStartMask;
	std::string row_contents;
	bool row_has_fault = false;

	for (size_t column = 0; column < kNumTagColumns; ++column) {
	uintptr_t granule_addr = row_addr + column * kTagGranuleSize;
	if (granule_addr < memory_dump.begin_address() \|\|
	granule_addr >= memory_dump.begin_address() + num_tags * kTagGranuleSize) {
	row_contents += " . ";
	} else if (granule_addr == fault_granule) {
	row_contents += StringPrintf("[%1hhx]", tags[tag_index++]);
	row_has_fault = true;
	} else {
	row_contents += StringPrintf(" %1hhx ", tags[tag_index++]);
	}
	}

	if (row_contents.back() == ' ') row_contents.pop_back();

	if (row_has_fault) {
	CBS(" =>0x%" PRIxPTR ":%s", row_addr, row_contents.c_str());
	} else {
	CBS(" 0x%" PRIxPTR ":%s", row_addr, row_contents.c_str());
	}
	}
	}

	static void print_memory_maps(CallbackType callback, const Tombstone& tombstone) {
	int word_size = pointer_width(tombstone);
	const auto format_pointer = [word_size](uint64_t ptr) -> std::string {
	if (word_size == 8) {
	uint64_t top = ptr >> 32;
	uint64_t bottom = ptr & 0xFFFFFFFF;
	return StringPrintf("%08" PRIx64 "'%08" PRIx64, top, bottom);
	}

	return StringPrintf("%0" PRIx64, word_size 2, ptr);
	};

	std::string memory_map_header =
	StringPrintf("memory map (%d %s):", tombstone.memory_mappings().size(),
	tombstone.memory_mappings().size() == 1 ? "entry" : "entries");

	const Signal& signal_info = tombstone.signal_info();
	bool has_fault_address = signal_info.has_fault_address();
	uint64_t fault_address = untag_address(signal_info.fault_address());
	bool preamble_printed = false;
	bool printed_fault_address_marker = false;
	for (const auto& map : tombstone.memory_mappings()) {
	if (!preamble_printed) {
	preamble_printed = true;
	if (has_fault_address) {
	if (fault_address < map.begin_address()) {
	memory_map_header +=
	StringPrintf("\n--->Fault address falls at %s before any mapped regions",
	format_pointer(fault_address).c_str());
	printed_fault_address_marker = true;
	} else {
	memory_map_header += " (fault address prefixed with --->)";
	}
	}
	CBS("%s", memory_map_header.c_str());
	}

	std::string line = " ";
	if (has_fault_address && !printed_fault_address_marker) {
	if (fault_address < map.begin_address()) {
	printed_fault_address_marker = true;
	CBS("--->Fault address falls at %s between mapped regions",
	format_pointer(fault_address).c_str());
	} else if (fault_address >= map.begin_address() && fault_address < map.end_address()) {
	printed_fault_address_marker = true;
	line = "--->";
	}
	}
	StringAppendF(&line, "%s-%s", format_pointer(map.begin_address()).c_str(),
	format_pointer(map.end_address() - 1).c_str());
	StringAppendF(&line, " %s%s%s", map.read() ? "r" : "-", map.write() ? "w" : "-",
	map.execute() ? "x" : "-");
	StringAppendF(&line, " %8" PRIx64 " %8" PRIx64, map.offset(),
	map.end_address() - map.begin_address());

	if (!map.mapping_name().empty()) {
	StringAppendF(&line, " %s", map.mapping_name().c_str());

	if (!map.build_id().empty()) {
	StringAppendF(&line, " (BuildId: %s)", map.build_id().c_str());
	}

	if (map.load_bias() != 0) {
	StringAppendF(&line, " (load bias 0x%" PRIx64 ")", map.load_bias());
	}
	}

	CBS("%s", line.c_str());
	}

	if (has_fault_address && !printed_fault_address_marker) {
	CBS("--->Fault address falls at %s after any mapped regions",
	format_pointer(fault_address).c_str());
	}
	}

	static void print_main_thread(CallbackType callback, const Tombstone& tombstone,
	const Thread& thread) {
	print_thread_header(callback, tombstone, thread, true);

	const Signal& signal_info = tombstone.signal_info();
	std::string sender_desc;

	if (signal_info.has_sender()) {
	sender_desc =
	StringPrintf(" from pid %d, uid %d", signal_info.sender_pid(), signal_info.sender_uid());
	}

	bool is_async_mte_crash = false;
	bool is_mte_crash = false;
	if (!tombstone.has_signal_info()) {
	CBL("signal information missing");
	} else {
	std::string fault_addr_desc;
	if (signal_info.has_fault_address()) {
	fault_addr_desc =
	StringPrintf("0x%0" PRIx64, 2 pointer_width(tombstone), signal_info.fault_address());
	} else {
	fault_addr_desc = "--------";
	}

	CBL("signal %d (%s), code %d (%s%s), fault addr %s", signal_info.number(),
	signal_info.name().c_str(), signal_info.code(), signal_info.code_name().c_str(),
	sender_desc.c_str(), fault_addr_desc.c_str());
	#ifdef SEGV_MTEAERR
	is_async_mte_crash = signal_info.number() == SIGSEGV && signal_info.code() == SEGV_MTEAERR;
	is_mte_crash = is_async_mte_crash \|\|
	(signal_info.number() == SIGSEGV && signal_info.code() == SEGV_MTESERR);
	#endif
	}

	if (tombstone.causes_size() == 1) {
	CBL("Cause: %s", tombstone.causes(0).human_readable().c_str());
	}

	if (!tombstone.abort_message().empty()) {
	CBL("Abort message: '%s'", tombstone.abort_message().c_str());
	}

	print_thread_registers(callback, tombstone, thread, true);
	if (is_async_mte_crash) {
	CBL("Note: This crash is a delayed async MTE crash. Memory corruption has occurred");
	CBL(" in this process. The stack trace below is the first system call or context");
	CBL(" switch that was executed after the memory corruption happened.");
	}
	print_thread_backtrace(callback, tombstone, thread, true);

	if (tombstone.causes_size() > 1) {
	CBS("");
	CBL("Note: multiple potential causes for this crash were detected, listing them in decreasing "
	"order of likelihood.");
	}

	for (const Cause& cause : tombstone.causes()) {
	if (tombstone.causes_size() > 1) {
	CBS("");
	CBL("Cause: %s", cause.human_readable().c_str());
	}

	if (cause.has_memory_error() && cause.memory_error().has_heap()) {
	const HeapObject& heap_object = cause.memory_error().heap();

	if (heap_object.deallocation_backtrace_size() != 0) {
	CBS("");
	CBL("deallocated by thread %" PRIu64 ":", heap_object.deallocation_tid());
	print_backtrace(callback, tombstone, heap_object.deallocation_backtrace(), true);
	}

	if (heap_object.allocation_backtrace_size() != 0) {
	CBS("");
	CBL("allocated by thread %" PRIu64 ":", heap_object.allocation_tid());
	print_backtrace(callback, tombstone, heap_object.allocation_backtrace(), true);
	}
	}
	}

	print_tag_dump(callback, tombstone);

	if (is_mte_crash) {
	CBS("");
	CBL("Learn more about MTE reports: "
	"https://source.android.com/docs/security/test/memory-safety/mte-reports");
	}

	print_thread_memory_dump(callback, tombstone, thread);

	CBS("");

	// No memory maps to print.
	if (!tombstone.memory_mappings().empty()) {
	print_memory_maps(callback, tombstone);
	} else {
	CBS("No memory maps found");
	}
	}

	void print_logs(CallbackType callback, const Tombstone& tombstone, int tail) {
	for (const auto& buffer : tombstone.log_buffers()) {
	if (tail) {
	CBS("--------- tail end of log %s", buffer.name().c_str());
	} else {
	CBS("--------- log %s", buffer.name().c_str());
	}

	int begin = 0;
	if (tail != 0) {
	begin = std::max(0, buffer.logs().size() - tail);
	}

	for (int i = begin; i < buffer.logs().size(); ++i) {
	const LogMessage& msg = buffer.logs(i);

	static const char* kPrioChars = "!.VDIWEFS";
	char priority = (msg.priority() < strlen(kPrioChars) ? kPrioChars[msg.priority()] : '?');
	CBS("%s %5u %5u %c %-8s: %s", msg.timestamp().c_str(), msg.pid(), msg.tid(), priority,
	msg.tag().c_str(), msg.message().c_str());
	}
	}
	}

	bool tombstone_proto_to_text(const Tombstone& tombstone, CallbackType callback) {
	CBL("* * * * * * * * * * * * * * * *");
	CBL("Build fingerprint: '%s'", tombstone.build_fingerprint().c_str());
	CBL("Revision: '%s'", tombstone.revision().c_str());
	CBL("ABI: '%s'", abi_string(tombstone));
	CBL("Timestamp: %s", tombstone.timestamp().c_str());
	CBL("Process uptime: %ds", tombstone.process_uptime());

	// Process header
	const auto& threads = tombstone.threads();
	auto main_thread_it = threads.find(tombstone.tid());
	if (main_thread_it == threads.end()) {
	CBL("failed to find entry for main thread in tombstone");
	return false;
	}

	const auto& main_thread = main_thread_it->second;

	print_main_thread(callback, tombstone, main_thread);

	print_logs(callback, tombstone, 50);

	// protobuf's map is unordered, so sort the keys first.
	std::set<int> thread_ids;
	for (const auto& [tid, _] : threads) {
	if (tid != tombstone.tid()) {
	thread_ids.insert(tid);
	}
	}

	for (const auto& tid : thread_ids) {
	CBS("--- --- --- --- --- --- --- --- --- --- --- --- --- --- --- ---");
	print_thread(callback, tombstone, threads.find(tid)->second);
	}

	if (tombstone.open_fds().size() > 0) {
	CBS("");
	CBS("open files:");
	for (const auto& fd : tombstone.open_fds()) {
	std::optional<std::string> owner;
	if (!fd.owner().empty()) {
	owner = StringPrintf("owned by %s 0x%" PRIx64, fd.owner().c_str(), fd.tag());
	}

	CBS(" fd %d: %s (%s)", fd.fd(), fd.path().c_str(), owner ? owner->c_str() : "unowned");
	}
	}

	print_logs(callback, tombstone, 0);

	return true;
	}