third_party/llvm-project/compiler-rt/lib/fuzzer/FuzzerUtilFuchsia.cpp - cobalt - Git at Google

 //===- FuzzerUtilFuchsia.cpp - Misc utils for Fuchsia. --------------------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//
 // Misc utils implementation using Fuchsia/Zircon APIs.
 //===----------------------------------------------------------------------===//
 #include "FuzzerPlatform.h"

 #if LIBFUZZER_FUCHSIA

 #include "FuzzerInternal.h"
 #include "FuzzerUtil.h"
 #include <cassert>
 #include <cerrno>
 #include <cinttypes>
 #include <cstdint>
 #include <fcntl.h>
 #include <lib/fdio/fdio.h>
 #include <lib/fdio/spawn.h>
 #include <string>
 #include <sys/select.h>
 #include <thread>
 #include <unistd.h>
 #include <zircon/errors.h>
 #include <zircon/process.h>
 #include <zircon/sanitizer.h>
 #include <zircon/status.h>
 #include <zircon/syscalls.h>
 #include <zircon/syscalls/debug.h>
 #include <zircon/syscalls/exception.h>
 #include <zircon/syscalls/object.h>
 #include <zircon/types.h>

 #include <vector>

 namespace fuzzer {

 // Given that Fuchsia doesn't have the POSIX signals that libFuzzer was written
 // around, the general approach is to spin up dedicated threads to watch for
 // each requested condition (alarm, interrupt, crash).  Of these, the crash
 // handler is the most involved, as it requires resuming the crashed thread in
 // order to invoke the sanitizers to get the needed state.

 // Forward declaration of assembly trampoline needed to resume crashed threads.
 // This appears to have external linkage to  C++, which is why it's not in the
 // anonymous namespace.  The assembly definition inside MakeTrampoline()
 // actually defines the symbol with internal linkage only.
 void CrashTrampolineAsm() __asm__("CrashTrampolineAsm");

 namespace {

 // The signal handler thread uses Zircon exceptions to resume crashed threads
 // into libFuzzer's POSIX signal handlers. The associated event is used to
 // signal when the thread is running, and when it should stop.
 std::thread SignalHandler;
 zx_handle_t SignalHandlerEvent = ZX_HANDLE_INVALID;

 // Helper function to handle Zircon syscall failures.
 void ExitOnErr(zx_status_t Status, const char *Syscall) {
   if (Status != ZX_OK) {
     Printf("libFuzzer: %s failed: %s\n", Syscall,
            _zx_status_get_string(Status));
     exit(1);
   }
 }

 void AlarmHandler(int Seconds) {
   while (true) {
     SleepSeconds(Seconds);
     Fuzzer::StaticAlarmCallback();
   }
 }

 // For the crash handler, we need to call Fuzzer::StaticCrashSignalCallback
 // without POSIX signal handlers.  To achieve this, we use an assembly function
 // to add the necessary CFI unwinding information and a C function to bridge
 // from that back into C++.

 // FIXME: This works as a short-term solution, but this code really shouldn't be
 // architecture dependent. A better long term solution is to implement remote
 // unwinding and expose the necessary APIs through sanitizer_common and/or ASAN
 // to allow the exception handling thread to gather the crash state directly.
 //
 // Alternatively, Fuchsia may in future actually implement basic signal
 // handling for the machine trap signals.
 #if defined(__x86_64__)
 #define FOREACH_REGISTER(OP_REG, OP_NUM) \
   OP_REG(rax)                            \
   OP_REG(rbx)                            \
   OP_REG(rcx)                            \
   OP_REG(rdx)                            \
   OP_REG(rsi)                            \
   OP_REG(rdi)                            \
   OP_REG(rbp)                            \
   OP_REG(rsp)                            \
   OP_REG(r8)                             \
   OP_REG(r9)                             \
   OP_REG(r10)                            \
   OP_REG(r11)                            \
   OP_REG(r12)                            \
   OP_REG(r13)                            \
   OP_REG(r14)                            \
   OP_REG(r15)                            \
   OP_REG(rip)

 #elif defined(__aarch64__)
 #define FOREACH_REGISTER(OP_REG, OP_NUM) \
   OP_NUM(0)                              \
   OP_NUM(1)                              \
   OP_NUM(2)                              \
   OP_NUM(3)                              \
   OP_NUM(4)                              \
   OP_NUM(5)                              \
   OP_NUM(6)                              \
   OP_NUM(7)                              \
   OP_NUM(8)                              \
   OP_NUM(9)                              \
   OP_NUM(10)                             \
   OP_NUM(11)                             \
   OP_NUM(12)                             \
   OP_NUM(13)                             \
   OP_NUM(14)                             \
   OP_NUM(15)                             \
   OP_NUM(16)                             \
   OP_NUM(17)                             \
   OP_NUM(18)                             \
   OP_NUM(19)                             \
   OP_NUM(20)                             \
   OP_NUM(21)                             \
   OP_NUM(22)                             \
   OP_NUM(23)                             \
   OP_NUM(24)                             \
   OP_NUM(25)                             \
   OP_NUM(26)                             \
   OP_NUM(27)                             \
   OP_NUM(28)                             \
   OP_NUM(29)                             \
   OP_REG(sp)

 #else
 #error "Unsupported architecture for fuzzing on Fuchsia"
 #endif

 // Produces a CFI directive for the named or numbered register.
 // The value used refers to an assembler immediate operand with the same name
 // as the register (see ASM_OPERAND_REG).
 #define CFI_OFFSET_REG(reg) ".cfi_offset " #reg ", %c[" #reg "]\n"
 #define CFI_OFFSET_NUM(num) CFI_OFFSET_REG(x##num)

 // Produces an assembler immediate operand for the named or numbered register.
 // This operand contains the offset of the register relative to the CFA.
 #define ASM_OPERAND_REG(reg)                                                   \
   [reg] "i"(offsetof(zx_thread_state_general_regs_t, reg)),
 #define ASM_OPERAND_NUM(num)                                                   \
   [x##num] "i"(offsetof(zx_thread_state_general_regs_t, r[num])),

 // Trampoline to bridge from the assembly below to the static C++ crash
 // callback.
 __attribute__((noreturn))
 static void StaticCrashHandler() {
   Fuzzer::StaticCrashSignalCallback();
   for (;;) {
     _Exit(1);
   }
 }

 // This trampoline function has the necessary CFI information to unwind
 // and get a backtrace:
 //  * The stack contains a copy of all the registers at the point of crash,
 //    the code has CFI directives specifying how to restore them.
 //  * A call to StaticCrashHandler, which will print the stacktrace and exit
 //    the fuzzer, generating a crash artifact.
 //
 // The __attribute__((used)) is necessary because the function
 // is never called; it's just a container around the assembly to allow it to
 // use operands for compile-time computed constants.
 __attribute__((used))
 void MakeTrampoline() {
   __asm__(
       ".cfi_endproc\n"
       ".pushsection .text.CrashTrampolineAsm\n"
       ".type CrashTrampolineAsm,STT_FUNC\n"
       "CrashTrampolineAsm:\n"
       ".cfi_startproc simple\n"
       ".cfi_signal_frame\n"
 #if defined(__x86_64__)
       ".cfi_return_column rip\n"
       ".cfi_def_cfa rsp, 0\n"
       FOREACH_REGISTER(CFI_OFFSET_REG, CFI_OFFSET_NUM)
       "call %c[StaticCrashHandler]\n"
       "ud2\n"
 #elif defined(__aarch64__)
       ".cfi_return_column 33\n"
       ".cfi_def_cfa sp, 0\n"
       FOREACH_REGISTER(CFI_OFFSET_REG, CFI_OFFSET_NUM)
       ".cfi_offset 33, %c[pc]\n"
       ".cfi_offset 30, %c[lr]\n"
       "bl %c[StaticCrashHandler]\n"
       "brk 1\n"
 #else
 #error "Unsupported architecture for fuzzing on Fuchsia"
 #endif
      ".cfi_endproc\n"
      ".size CrashTrampolineAsm, . - CrashTrampolineAsm\n"
      ".popsection\n"
      ".cfi_startproc\n"
       : // No outputs
       : FOREACH_REGISTER(ASM_OPERAND_REG, ASM_OPERAND_NUM)
 #if defined(__aarch64__)
         ASM_OPERAND_REG(pc) ASM_OPERAND_REG(lr)
 #endif
         [StaticCrashHandler] "i"(StaticCrashHandler));
 }

 void CrashHandler() {
   assert(SignalHandlerEvent != ZX_HANDLE_INVALID);

   // This structure is used to ensure we close handles to objects we create in
   // this handler.
   struct ScopedHandle {
     ~ScopedHandle() { _zx_handle_close(Handle); }
     zx_handle_t Handle = ZX_HANDLE_INVALID;
   };

   // Create the exception channel.  We need to claim to be a "debugger" so the
   // kernel will allow us to modify and resume dying threads (see below). Once
   // the channel is set, we can signal the main thread to continue and wait
   // for the exception to arrive.
   ScopedHandle Channel;
   zx_handle_t Self = _zx_process_self();
   ExitOnErr(_zx_task_create_exception_channel(
                 Self, ZX_EXCEPTION_CHANNEL_DEBUGGER, &Channel.Handle),
             "_zx_task_create_exception_channel");

   ExitOnErr(_zx_object_signal(SignalHandlerEvent, 0, ZX_USER_SIGNAL_0),
             "_zx_object_signal");

   // This thread lives as long as the process in order to keep handling
   // crashes.  In practice, the first crashed thread to reach the end of the
   // StaticCrashHandler will end the process.
   while (true) {
     zx_wait_item_t WaitItems[] = {
         {
             .handle = SignalHandlerEvent,
             .waitfor = ZX_SIGNAL_HANDLE_CLOSED,
             .pending = 0,
         },
         {
             .handle = Channel.Handle,
             .waitfor = ZX_CHANNEL_READABLE | ZX_CHANNEL_PEER_CLOSED,
             .pending = 0,
         },
     };
     auto Status = _zx_object_wait_many(
         WaitItems, sizeof(WaitItems) / sizeof(WaitItems[0]), ZX_TIME_INFINITE);
     if (Status != ZX_OK || (WaitItems[1].pending & ZX_CHANNEL_READABLE) == 0) {
       break;
     }

     zx_exception_info_t ExceptionInfo;
     ScopedHandle Exception;
     ExitOnErr(_zx_channel_read(Channel.Handle, 0, &ExceptionInfo,
                                &Exception.Handle, sizeof(ExceptionInfo), 1,
                                nullptr, nullptr),
               "_zx_channel_read");

     // Ignore informational synthetic exceptions.
     if (ZX_EXCP_THREAD_STARTING == ExceptionInfo.type ||
         ZX_EXCP_THREAD_EXITING == ExceptionInfo.type ||
         ZX_EXCP_PROCESS_STARTING == ExceptionInfo.type) {
       continue;
     }

     // At this point, we want to get the state of the crashing thread, but
     // libFuzzer and the sanitizers assume this will happen from that same
     // thread via a POSIX signal handler. "Resurrecting" the thread in the
     // middle of the appropriate callback is as simple as forcibly setting the
     // instruction pointer/program counter, provided we NEVER EVER return from
     // that function (since otherwise our stack will not be valid).
     ScopedHandle Thread;
     ExitOnErr(_zx_exception_get_thread(Exception.Handle, &Thread.Handle),
               "_zx_exception_get_thread");

     zx_thread_state_general_regs_t GeneralRegisters;
     ExitOnErr(_zx_thread_read_state(Thread.Handle, ZX_THREAD_STATE_GENERAL_REGS,
                                     &GeneralRegisters,
                                     sizeof(GeneralRegisters)),
               "_zx_thread_read_state");

     // To unwind properly, we need to push the crashing thread's register state
     // onto the stack and jump into a trampoline with CFI instructions on how
     // to restore it.
 #if defined(__x86_64__)
     uintptr_t StackPtr =
         (GeneralRegisters.rsp - (128 + sizeof(GeneralRegisters))) &
         -(uintptr_t)16;
     __unsanitized_memcpy(reinterpret_cast<void *>(StackPtr), &GeneralRegisters,
                          sizeof(GeneralRegisters));
     GeneralRegisters.rsp = StackPtr;
     GeneralRegisters.rip = reinterpret_cast<zx_vaddr_t>(CrashTrampolineAsm);

 #elif defined(__aarch64__)
     uintptr_t StackPtr =
         (GeneralRegisters.sp - sizeof(GeneralRegisters)) & -(uintptr_t)16;
     __unsanitized_memcpy(reinterpret_cast<void *>(StackPtr), &GeneralRegisters,
                          sizeof(GeneralRegisters));
     GeneralRegisters.sp = StackPtr;
     GeneralRegisters.pc = reinterpret_cast<zx_vaddr_t>(CrashTrampolineAsm);

 #else
 #error "Unsupported architecture for fuzzing on Fuchsia"
 #endif

     // Now force the crashing thread's state.
     ExitOnErr(
         _zx_thread_write_state(Thread.Handle, ZX_THREAD_STATE_GENERAL_REGS,
                                &GeneralRegisters, sizeof(GeneralRegisters)),
         "_zx_thread_write_state");

     // Set the exception to HANDLED so it resumes the thread on close.
     uint32_t ExceptionState = ZX_EXCEPTION_STATE_HANDLED;
     ExitOnErr(_zx_object_set_property(Exception.Handle, ZX_PROP_EXCEPTION_STATE,
                                       &ExceptionState, sizeof(ExceptionState)),
               "zx_object_set_property");
   }
 }

 void StopSignalHandler() {
   _zx_handle_close(SignalHandlerEvent);
   if (SignalHandler.joinable()) {
     SignalHandler.join();
   }
 }

 } // namespace

 // Platform specific functions.
 void SetSignalHandler(const FuzzingOptions &Options) {
   // Make sure information from libFuzzer and the sanitizers are easy to
   // reassemble. `__sanitizer_log_write` has the added benefit of ensuring the
   // DSO map is always available for the symbolizer.
   // A uint64_t fits in 20 chars, so 64 is plenty.
   char Buf[64];
   memset(Buf, 0, sizeof(Buf));
   snprintf(Buf, sizeof(Buf), "==%lu== INFO: libFuzzer starting.\n", GetPid());
   if (EF->__sanitizer_log_write)
     __sanitizer_log_write(Buf, sizeof(Buf));
   Printf("%s", Buf);

   // Set up alarm handler if needed.
   if (Options.HandleAlrm && Options.UnitTimeoutSec > 0) {
     std::thread T(AlarmHandler, Options.UnitTimeoutSec / 2 + 1);
     T.detach();
   }

   // Options.HandleInt and Options.HandleTerm are not supported on Fuchsia

   // Early exit if no crash handler needed.
   if (!Options.HandleSegv && !Options.HandleBus && !Options.HandleIll &&
       !Options.HandleFpe && !Options.HandleAbrt)
     return;

   // Set up the crash handler and wait until it is ready before proceeding.
   ExitOnErr(_zx_event_create(0, &SignalHandlerEvent), "_zx_event_create");

   SignalHandler = std::thread(CrashHandler);
   zx_status_t Status = _zx_object_wait_one(SignalHandlerEvent, ZX_USER_SIGNAL_0,
                                            ZX_TIME_INFINITE, nullptr);
   ExitOnErr(Status, "_zx_object_wait_one");

   std::atexit(StopSignalHandler);
 }

 void SleepSeconds(int Seconds) {
   _zx_nanosleep(_zx_deadline_after(ZX_SEC(Seconds)));
 }

 unsigned long GetPid() {
   zx_status_t rc;
   zx_info_handle_basic_t Info;
   if ((rc = _zx_object_get_info(_zx_process_self(), ZX_INFO_HANDLE_BASIC, &Info,
                                 sizeof(Info), NULL, NULL)) != ZX_OK) {
     Printf("libFuzzer: unable to get info about self: %s\n",
            _zx_status_get_string(rc));
     exit(1);
   }
   return Info.koid;
 }

 size_t GetPeakRSSMb() {
   zx_status_t rc;
   zx_info_task_stats_t Info;
   if ((rc = _zx_object_get_info(_zx_process_self(), ZX_INFO_TASK_STATS, &Info,
                                 sizeof(Info), NULL, NULL)) != ZX_OK) {
     Printf("libFuzzer: unable to get info about self: %s\n",
            _zx_status_get_string(rc));
     exit(1);
   }
   return (Info.mem_private_bytes + Info.mem_shared_bytes) >> 20;
 }

 template <typename Fn>
 class RunOnDestruction {
  public:
   explicit RunOnDestruction(Fn fn) : fn_(fn) {}
   ~RunOnDestruction() { fn_(); }

  private:
   Fn fn_;
 };

 template <typename Fn>
 RunOnDestruction<Fn> at_scope_exit(Fn fn) {
   return RunOnDestruction<Fn>(fn);
 }

 static fdio_spawn_action_t clone_fd_action(int localFd, int targetFd) {
   return {
       .action = FDIO_SPAWN_ACTION_CLONE_FD,
       .fd =
           {
               .local_fd = localFd,
               .target_fd = targetFd,
           },
   };
 }

 int ExecuteCommand(const Command &Cmd) {
   zx_status_t rc;

   // Convert arguments to C array
   auto Args = Cmd.getArguments();
   size_t Argc = Args.size();
   assert(Argc != 0);
   std::unique_ptr<const char *[]> Argv(new const char *[Argc + 1]);
   for (size_t i = 0; i < Argc; ++i)
     Argv[i] = Args[i].c_str();
   Argv[Argc] = nullptr;

   // Determine output.  On Fuchsia, the fuzzer is typically run as a component
   // that lacks a mutable working directory. Fortunately, when this is the case
   // a mutable output directory must be specified using "-artifact_prefix=...",
   // so write the log file(s) there.
   // However, we don't want to apply this logic for absolute paths.
   int FdOut = STDOUT_FILENO;
   bool discardStdout = false;
   bool discardStderr = false;

   if (Cmd.hasOutputFile()) {
     std::string Path = Cmd.getOutputFile();
     if (Path == getDevNull()) {
       // On Fuchsia, there's no "/dev/null" like-file, so we
       // just don't copy the FDs into the spawned process.
       discardStdout = true;
     } else {
       bool IsAbsolutePath = Path.length() > 1 && Path[0] == '/';
       if (!IsAbsolutePath && Cmd.hasFlag("artifact_prefix"))
         Path = Cmd.getFlagValue("artifact_prefix") + "/" + Path;

       FdOut = open(Path.c_str(), O_WRONLY | O_CREAT | O_TRUNC, 0);
       if (FdOut == -1) {
         Printf("libFuzzer: failed to open %s: %s\n", Path.c_str(),
                strerror(errno));
         return ZX_ERR_IO;
       }
     }
   }
   auto CloseFdOut = at_scope_exit([FdOut]() {
     if (FdOut != STDOUT_FILENO)
       close(FdOut);
   });

   // Determine stderr
   int FdErr = STDERR_FILENO;
   if (Cmd.isOutAndErrCombined()) {
     FdErr = FdOut;
     if (discardStdout)
       discardStderr = true;
   }

   // Clone the file descriptors into the new process
   std::vector<fdio_spawn_action_t> SpawnActions;
   SpawnActions.push_back(clone_fd_action(STDIN_FILENO, STDIN_FILENO));

   if (!discardStdout)
     SpawnActions.push_back(clone_fd_action(FdOut, STDOUT_FILENO));
   if (!discardStderr)
     SpawnActions.push_back(clone_fd_action(FdErr, STDERR_FILENO));

   // Start the process.
   char ErrorMsg[FDIO_SPAWN_ERR_MSG_MAX_LENGTH];
   zx_handle_t ProcessHandle = ZX_HANDLE_INVALID;
   rc = fdio_spawn_etc(ZX_HANDLE_INVALID,
                       FDIO_SPAWN_CLONE_ALL & (~FDIO_SPAWN_CLONE_STDIO), Argv[0],
                       Argv.get(), nullptr, SpawnActions.size(),
                       SpawnActions.data(), &ProcessHandle, ErrorMsg);

   if (rc != ZX_OK) {
     Printf("libFuzzer: failed to launch '%s': %s, %s\n", Argv[0], ErrorMsg,
            _zx_status_get_string(rc));
     return rc;
   }
   auto CloseHandle = at_scope_exit([&]() { _zx_handle_close(ProcessHandle); });

   // Now join the process and return the exit status.
   if ((rc = _zx_object_wait_one(ProcessHandle, ZX_PROCESS_TERMINATED,
                                 ZX_TIME_INFINITE, nullptr)) != ZX_OK) {
     Printf("libFuzzer: failed to join '%s': %s\n", Argv[0],
            _zx_status_get_string(rc));
     return rc;
   }

   zx_info_process_t Info;
   if ((rc = _zx_object_get_info(ProcessHandle, ZX_INFO_PROCESS, &Info,
                                 sizeof(Info), nullptr, nullptr)) != ZX_OK) {
     Printf("libFuzzer: unable to get return code from '%s': %s\n", Argv[0],
            _zx_status_get_string(rc));
     return rc;
   }

   return static_cast<int>(Info.return_code);
 }

 bool ExecuteCommand(const Command &BaseCmd, std::string *CmdOutput) {
   auto LogFilePath = TempPath("SimPopenOut", ".txt");
   Command Cmd(BaseCmd);
   Cmd.setOutputFile(LogFilePath);
   int Ret = ExecuteCommand(Cmd);
   *CmdOutput = FileToString(LogFilePath);
   RemoveFile(LogFilePath);
   return Ret == 0;
 }

 const void *SearchMemory(const void *Data, size_t DataLen, const void *Patt,
                          size_t PattLen) {
   return memmem(Data, DataLen, Patt, PattLen);
 }

 // In fuchsia, accessing /dev/null is not supported. There's nothing
 // similar to a file that discards everything that is written to it.
 // The way of doing something similar in fuchsia is by using
 // fdio_null_create and binding that to a file descriptor.
 void DiscardOutput(int Fd) {
   fdio_t *fdio_null = fdio_null_create();
   if (fdio_null == nullptr) return;
   int nullfd = fdio_bind_to_fd(fdio_null, -1, 0);
   if (nullfd < 0) return;
   dup2(nullfd, Fd);
 }

 } // namespace fuzzer

 #endif // LIBFUZZER_FUCHSIA
	//===- FuzzerUtilFuchsia.cpp - Misc utils for Fuchsia. --------------------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//
	// Misc utils implementation using Fuchsia/Zircon APIs.
	//===----------------------------------------------------------------------===//
	#include "FuzzerPlatform.h"

	#if LIBFUZZER_FUCHSIA

	#include "FuzzerInternal.h"
	#include "FuzzerUtil.h"
	#include <cassert>
	#include <cerrno>
	#include <cinttypes>
	#include <cstdint>
	#include <fcntl.h>
	#include <lib/fdio/fdio.h>
	#include <lib/fdio/spawn.h>
	#include <string>
	#include <sys/select.h>
	#include <thread>
	#include <unistd.h>
	#include <zircon/errors.h>
	#include <zircon/process.h>
	#include <zircon/sanitizer.h>
	#include <zircon/status.h>
	#include <zircon/syscalls.h>
	#include <zircon/syscalls/debug.h>
	#include <zircon/syscalls/exception.h>
	#include <zircon/syscalls/object.h>
	#include <zircon/types.h>

	#include <vector>

	namespace fuzzer {

	// Given that Fuchsia doesn't have the POSIX signals that libFuzzer was written
	// around, the general approach is to spin up dedicated threads to watch for
	// each requested condition (alarm, interrupt, crash). Of these, the crash
	// handler is the most involved, as it requires resuming the crashed thread in
	// order to invoke the sanitizers to get the needed state.

	// Forward declaration of assembly trampoline needed to resume crashed threads.
	// This appears to have external linkage to C++, which is why it's not in the
	// anonymous namespace. The assembly definition inside MakeTrampoline()
	// actually defines the symbol with internal linkage only.
	void CrashTrampolineAsm() __asm__("CrashTrampolineAsm");

	namespace {

	// The signal handler thread uses Zircon exceptions to resume crashed threads
	// into libFuzzer's POSIX signal handlers. The associated event is used to
	// signal when the thread is running, and when it should stop.
	std::thread SignalHandler;
	zx_handle_t SignalHandlerEvent = ZX_HANDLE_INVALID;

	// Helper function to handle Zircon syscall failures.
	void ExitOnErr(zx_status_t Status, const char *Syscall) {
	if (Status != ZX_OK) {
	Printf("libFuzzer: %s failed: %s\n", Syscall,
	_zx_status_get_string(Status));
	exit(1);
	}
	}

	void AlarmHandler(int Seconds) {
	while (true) {
	SleepSeconds(Seconds);
	Fuzzer::StaticAlarmCallback();
	}
	}

	// For the crash handler, we need to call Fuzzer::StaticCrashSignalCallback
	// without POSIX signal handlers. To achieve this, we use an assembly function
	// to add the necessary CFI unwinding information and a C function to bridge
	// from that back into C++.

	// FIXME: This works as a short-term solution, but this code really shouldn't be
	// architecture dependent. A better long term solution is to implement remote
	// unwinding and expose the necessary APIs through sanitizer_common and/or ASAN
	// to allow the exception handling thread to gather the crash state directly.
	//
	// Alternatively, Fuchsia may in future actually implement basic signal
	// handling for the machine trap signals.
	#if defined(__x86_64__)
	#define FOREACH_REGISTER(OP_REG, OP_NUM) \
	OP_REG(rax) \
	OP_REG(rbx) \
	OP_REG(rcx) \
	OP_REG(rdx) \
	OP_REG(rsi) \
	OP_REG(rdi) \
	OP_REG(rbp) \
	OP_REG(rsp) \
	OP_REG(r8) \
	OP_REG(r9) \
	OP_REG(r10) \
	OP_REG(r11) \
	OP_REG(r12) \
	OP_REG(r13) \
	OP_REG(r14) \
	OP_REG(r15) \
	OP_REG(rip)

	#elif defined(__aarch64__)
	#define FOREACH_REGISTER(OP_REG, OP_NUM) \
	OP_NUM(0) \
	OP_NUM(1) \
	OP_NUM(2) \
	OP_NUM(3) \
	OP_NUM(4) \
	OP_NUM(5) \
	OP_NUM(6) \
	OP_NUM(7) \
	OP_NUM(8) \
	OP_NUM(9) \
	OP_NUM(10) \
	OP_NUM(11) \
	OP_NUM(12) \
	OP_NUM(13) \
	OP_NUM(14) \
	OP_NUM(15) \
	OP_NUM(16) \
	OP_NUM(17) \
	OP_NUM(18) \
	OP_NUM(19) \
	OP_NUM(20) \
	OP_NUM(21) \
	OP_NUM(22) \
	OP_NUM(23) \
	OP_NUM(24) \
	OP_NUM(25) \
	OP_NUM(26) \
	OP_NUM(27) \
	OP_NUM(28) \
	OP_NUM(29) \
	OP_REG(sp)

	#else
	#error "Unsupported architecture for fuzzing on Fuchsia"
	#endif

	// Produces a CFI directive for the named or numbered register.
	// The value used refers to an assembler immediate operand with the same name
	// as the register (see ASM_OPERAND_REG).
	#define CFI_OFFSET_REG(reg) ".cfi_offset " #reg ", %c[" #reg "]\n"
	#define CFI_OFFSET_NUM(num) CFI_OFFSET_REG(x##num)

	// Produces an assembler immediate operand for the named or numbered register.
	// This operand contains the offset of the register relative to the CFA.
	#define ASM_OPERAND_REG(reg) \
	[reg] "i"(offsetof(zx_thread_state_general_regs_t, reg)),
	#define ASM_OPERAND_NUM(num) \
	[x##num] "i"(offsetof(zx_thread_state_general_regs_t, r[num])),

	// Trampoline to bridge from the assembly below to the static C++ crash
	// callback.
	__attribute__((noreturn))
	static void StaticCrashHandler() {
	Fuzzer::StaticCrashSignalCallback();
	for (;;) {
	_Exit(1);
	}
	}

	// This trampoline function has the necessary CFI information to unwind
	// and get a backtrace:
	// * The stack contains a copy of all the registers at the point of crash,
	// the code has CFI directives specifying how to restore them.
	// * A call to StaticCrashHandler, which will print the stacktrace and exit
	// the fuzzer, generating a crash artifact.
	//
	// The __attribute__((used)) is necessary because the function
	// is never called; it's just a container around the assembly to allow it to
	// use operands for compile-time computed constants.
	__attribute__((used))
	void MakeTrampoline() {
	__asm__(
	".cfi_endproc\n"
	".pushsection .text.CrashTrampolineAsm\n"
	".type CrashTrampolineAsm,STT_FUNC\n"
	"CrashTrampolineAsm:\n"
	".cfi_startproc simple\n"
	".cfi_signal_frame\n"
	#if defined(__x86_64__)
	".cfi_return_column rip\n"
	".cfi_def_cfa rsp, 0\n"
	FOREACH_REGISTER(CFI_OFFSET_REG, CFI_OFFSET_NUM)
	"call %c[StaticCrashHandler]\n"
	"ud2\n"
	#elif defined(__aarch64__)
	".cfi_return_column 33\n"
	".cfi_def_cfa sp, 0\n"
	FOREACH_REGISTER(CFI_OFFSET_REG, CFI_OFFSET_NUM)
	".cfi_offset 33, %c[pc]\n"
	".cfi_offset 30, %c[lr]\n"
	"bl %c[StaticCrashHandler]\n"
	"brk 1\n"
	#else
	#error "Unsupported architecture for fuzzing on Fuchsia"
	#endif
	".cfi_endproc\n"
	".size CrashTrampolineAsm, . - CrashTrampolineAsm\n"
	".popsection\n"
	".cfi_startproc\n"
	: // No outputs
	: FOREACH_REGISTER(ASM_OPERAND_REG, ASM_OPERAND_NUM)
	#if defined(__aarch64__)
	ASM_OPERAND_REG(pc) ASM_OPERAND_REG(lr)
	#endif
	[StaticCrashHandler] "i"(StaticCrashHandler));
	}

	void CrashHandler() {
	assert(SignalHandlerEvent != ZX_HANDLE_INVALID);

	// This structure is used to ensure we close handles to objects we create in
	// this handler.
	struct ScopedHandle {
	~ScopedHandle() { _zx_handle_close(Handle); }
	zx_handle_t Handle = ZX_HANDLE_INVALID;
	};

	// Create the exception channel. We need to claim to be a "debugger" so the
	// kernel will allow us to modify and resume dying threads (see below). Once
	// the channel is set, we can signal the main thread to continue and wait
	// for the exception to arrive.
	ScopedHandle Channel;
	zx_handle_t Self = _zx_process_self();
	ExitOnErr(_zx_task_create_exception_channel(
	Self, ZX_EXCEPTION_CHANNEL_DEBUGGER, &Channel.Handle),
	"_zx_task_create_exception_channel");

	ExitOnErr(_zx_object_signal(SignalHandlerEvent, 0, ZX_USER_SIGNAL_0),
	"_zx_object_signal");

	// This thread lives as long as the process in order to keep handling
	// crashes. In practice, the first crashed thread to reach the end of the
	// StaticCrashHandler will end the process.
	while (true) {
	zx_wait_item_t WaitItems[] = {
	{
	.handle = SignalHandlerEvent,
	.waitfor = ZX_SIGNAL_HANDLE_CLOSED,
	.pending = 0,
	},
	{
	.handle = Channel.Handle,
	.waitfor = ZX_CHANNEL_READABLE \| ZX_CHANNEL_PEER_CLOSED,
	.pending = 0,
	},
	};
	auto Status = _zx_object_wait_many(
	WaitItems, sizeof(WaitItems) / sizeof(WaitItems[0]), ZX_TIME_INFINITE);
	if (Status != ZX_OK \|\| (WaitItems[1].pending & ZX_CHANNEL_READABLE) == 0) {
	break;
	}

	zx_exception_info_t ExceptionInfo;
	ScopedHandle Exception;
	ExitOnErr(_zx_channel_read(Channel.Handle, 0, &ExceptionInfo,
	&Exception.Handle, sizeof(ExceptionInfo), 1,
	nullptr, nullptr),
	"_zx_channel_read");

	// Ignore informational synthetic exceptions.
	if (ZX_EXCP_THREAD_STARTING == ExceptionInfo.type \|\|
	ZX_EXCP_THREAD_EXITING == ExceptionInfo.type \|\|
	ZX_EXCP_PROCESS_STARTING == ExceptionInfo.type) {
	continue;
	}

	// At this point, we want to get the state of the crashing thread, but
	// libFuzzer and the sanitizers assume this will happen from that same
	// thread via a POSIX signal handler. "Resurrecting" the thread in the
	// middle of the appropriate callback is as simple as forcibly setting the
	// instruction pointer/program counter, provided we NEVER EVER return from
	// that function (since otherwise our stack will not be valid).
	ScopedHandle Thread;
	ExitOnErr(_zx_exception_get_thread(Exception.Handle, &Thread.Handle),
	"_zx_exception_get_thread");

	zx_thread_state_general_regs_t GeneralRegisters;
	ExitOnErr(_zx_thread_read_state(Thread.Handle, ZX_THREAD_STATE_GENERAL_REGS,
	&GeneralRegisters,
	sizeof(GeneralRegisters)),
	"_zx_thread_read_state");

	// To unwind properly, we need to push the crashing thread's register state
	// onto the stack and jump into a trampoline with CFI instructions on how
	// to restore it.
	#if defined(__x86_64__)
	uintptr_t StackPtr =
	(GeneralRegisters.rsp - (128 + sizeof(GeneralRegisters))) &
	-(uintptr_t)16;
	__unsanitized_memcpy(reinterpret_cast<void *>(StackPtr), &GeneralRegisters,
	sizeof(GeneralRegisters));
	GeneralRegisters.rsp = StackPtr;
	GeneralRegisters.rip = reinterpret_cast<zx_vaddr_t>(CrashTrampolineAsm);

	#elif defined(__aarch64__)
	uintptr_t StackPtr =
	(GeneralRegisters.sp - sizeof(GeneralRegisters)) & -(uintptr_t)16;
	__unsanitized_memcpy(reinterpret_cast<void *>(StackPtr), &GeneralRegisters,
	sizeof(GeneralRegisters));
	GeneralRegisters.sp = StackPtr;
	GeneralRegisters.pc = reinterpret_cast<zx_vaddr_t>(CrashTrampolineAsm);

	#else
	#error "Unsupported architecture for fuzzing on Fuchsia"
	#endif

	// Now force the crashing thread's state.
	ExitOnErr(
	_zx_thread_write_state(Thread.Handle, ZX_THREAD_STATE_GENERAL_REGS,
	&GeneralRegisters, sizeof(GeneralRegisters)),
	"_zx_thread_write_state");

	// Set the exception to HANDLED so it resumes the thread on close.
	uint32_t ExceptionState = ZX_EXCEPTION_STATE_HANDLED;
	ExitOnErr(_zx_object_set_property(Exception.Handle, ZX_PROP_EXCEPTION_STATE,
	&ExceptionState, sizeof(ExceptionState)),
	"zx_object_set_property");
	}
	}

	void StopSignalHandler() {
	_zx_handle_close(SignalHandlerEvent);
	if (SignalHandler.joinable()) {
	SignalHandler.join();
	}
	}

	} // namespace

	// Platform specific functions.
	void SetSignalHandler(const FuzzingOptions &Options) {
	// Make sure information from libFuzzer and the sanitizers are easy to
	// reassemble. `__sanitizer_log_write` has the added benefit of ensuring the
	// DSO map is always available for the symbolizer.
	// A uint64_t fits in 20 chars, so 64 is plenty.
	char Buf[64];
	memset(Buf, 0, sizeof(Buf));
	snprintf(Buf, sizeof(Buf), "==%lu== INFO: libFuzzer starting.\n", GetPid());
	if (EF->__sanitizer_log_write)
	__sanitizer_log_write(Buf, sizeof(Buf));
	Printf("%s", Buf);

	// Set up alarm handler if needed.
	if (Options.HandleAlrm && Options.UnitTimeoutSec > 0) {
	std::thread T(AlarmHandler, Options.UnitTimeoutSec / 2 + 1);
	T.detach();
	}

	// Options.HandleInt and Options.HandleTerm are not supported on Fuchsia

	// Early exit if no crash handler needed.
	if (!Options.HandleSegv && !Options.HandleBus && !Options.HandleIll &&
	!Options.HandleFpe && !Options.HandleAbrt)
	return;

	// Set up the crash handler and wait until it is ready before proceeding.
	ExitOnErr(_zx_event_create(0, &SignalHandlerEvent), "_zx_event_create");

	SignalHandler = std::thread(CrashHandler);
	zx_status_t Status = _zx_object_wait_one(SignalHandlerEvent, ZX_USER_SIGNAL_0,
	ZX_TIME_INFINITE, nullptr);
	ExitOnErr(Status, "_zx_object_wait_one");

	std::atexit(StopSignalHandler);
	}

	void SleepSeconds(int Seconds) {
	_zx_nanosleep(_zx_deadline_after(ZX_SEC(Seconds)));
	}

	unsigned long GetPid() {
	zx_status_t rc;
	zx_info_handle_basic_t Info;
	if ((rc = _zx_object_get_info(_zx_process_self(), ZX_INFO_HANDLE_BASIC, &Info,
	sizeof(Info), NULL, NULL)) != ZX_OK) {
	Printf("libFuzzer: unable to get info about self: %s\n",
	_zx_status_get_string(rc));
	exit(1);
	}
	return Info.koid;
	}

	size_t GetPeakRSSMb() {
	zx_status_t rc;
	zx_info_task_stats_t Info;
	if ((rc = _zx_object_get_info(_zx_process_self(), ZX_INFO_TASK_STATS, &Info,
	sizeof(Info), NULL, NULL)) != ZX_OK) {
	Printf("libFuzzer: unable to get info about self: %s\n",
	_zx_status_get_string(rc));
	exit(1);
	}
	return (Info.mem_private_bytes + Info.mem_shared_bytes) >> 20;
	}

	template <typename Fn>
	class RunOnDestruction {
	public:
	explicit RunOnDestruction(Fn fn) : fn_(fn) {}
	~RunOnDestruction() { fn_(); }

	private:
	Fn fn_;
	};

	template <typename Fn>
	RunOnDestruction<Fn> at_scope_exit(Fn fn) {
	return RunOnDestruction<Fn>(fn);
	}

	static fdio_spawn_action_t clone_fd_action(int localFd, int targetFd) {
	return {
	.action = FDIO_SPAWN_ACTION_CLONE_FD,
	.fd =
	{
	.local_fd = localFd,
	.target_fd = targetFd,
	},
	};
	}

	int ExecuteCommand(const Command &Cmd) {
	zx_status_t rc;

	// Convert arguments to C array
	auto Args = Cmd.getArguments();
	size_t Argc = Args.size();
	assert(Argc != 0);
	std::unique_ptr<const char []> Argv(new const char [Argc + 1]);
	for (size_t i = 0; i < Argc; ++i)
	Argv[i] = Args[i].c_str();
	Argv[Argc] = nullptr;

	// Determine output. On Fuchsia, the fuzzer is typically run as a component
	// that lacks a mutable working directory. Fortunately, when this is the case
	// a mutable output directory must be specified using "-artifact_prefix=...",
	// so write the log file(s) there.
	// However, we don't want to apply this logic for absolute paths.
	int FdOut = STDOUT_FILENO;
	bool discardStdout = false;
	bool discardStderr = false;

	if (Cmd.hasOutputFile()) {
	std::string Path = Cmd.getOutputFile();
	if (Path == getDevNull()) {
	// On Fuchsia, there's no "/dev/null" like-file, so we
	// just don't copy the FDs into the spawned process.
	discardStdout = true;
	} else {
	bool IsAbsolutePath = Path.length() > 1 && Path[0] == '/';
	if (!IsAbsolutePath && Cmd.hasFlag("artifact_prefix"))
	Path = Cmd.getFlagValue("artifact_prefix") + "/" + Path;

	FdOut = open(Path.c_str(), O_WRONLY \| O_CREAT \| O_TRUNC, 0);
	if (FdOut == -1) {
	Printf("libFuzzer: failed to open %s: %s\n", Path.c_str(),
	strerror(errno));
	return ZX_ERR_IO;
	}
	}
	}
	auto CloseFdOut = at_scope_exit([FdOut]() {
	if (FdOut != STDOUT_FILENO)
	close(FdOut);
	});

	// Determine stderr
	int FdErr = STDERR_FILENO;
	if (Cmd.isOutAndErrCombined()) {
	FdErr = FdOut;
	if (discardStdout)
	discardStderr = true;
	}

	// Clone the file descriptors into the new process
	std::vector<fdio_spawn_action_t> SpawnActions;
	SpawnActions.push_back(clone_fd_action(STDIN_FILENO, STDIN_FILENO));

	if (!discardStdout)
	SpawnActions.push_back(clone_fd_action(FdOut, STDOUT_FILENO));
	if (!discardStderr)
	SpawnActions.push_back(clone_fd_action(FdErr, STDERR_FILENO));

	// Start the process.
	char ErrorMsg[FDIO_SPAWN_ERR_MSG_MAX_LENGTH];
	zx_handle_t ProcessHandle = ZX_HANDLE_INVALID;
	rc = fdio_spawn_etc(ZX_HANDLE_INVALID,
	FDIO_SPAWN_CLONE_ALL & (~FDIO_SPAWN_CLONE_STDIO), Argv[0],
	Argv.get(), nullptr, SpawnActions.size(),
	SpawnActions.data(), &ProcessHandle, ErrorMsg);

	if (rc != ZX_OK) {
	Printf("libFuzzer: failed to launch '%s': %s, %s\n", Argv[0], ErrorMsg,
	_zx_status_get_string(rc));
	return rc;
	}
	auto CloseHandle = at_scope_exit([&]() { _zx_handle_close(ProcessHandle); });

	// Now join the process and return the exit status.
	if ((rc = _zx_object_wait_one(ProcessHandle, ZX_PROCESS_TERMINATED,
	ZX_TIME_INFINITE, nullptr)) != ZX_OK) {
	Printf("libFuzzer: failed to join '%s': %s\n", Argv[0],
	_zx_status_get_string(rc));
	return rc;
	}

	zx_info_process_t Info;
	if ((rc = _zx_object_get_info(ProcessHandle, ZX_INFO_PROCESS, &Info,
	sizeof(Info), nullptr, nullptr)) != ZX_OK) {
	Printf("libFuzzer: unable to get return code from '%s': %s\n", Argv[0],
	_zx_status_get_string(rc));
	return rc;
	}

	return static_cast<int>(Info.return_code);
	}

	bool ExecuteCommand(const Command &BaseCmd, std::string *CmdOutput) {
	auto LogFilePath = TempPath("SimPopenOut", ".txt");
	Command Cmd(BaseCmd);
	Cmd.setOutputFile(LogFilePath);
	int Ret = ExecuteCommand(Cmd);
	*CmdOutput = FileToString(LogFilePath);
	RemoveFile(LogFilePath);
	return Ret == 0;
	}

	const void SearchMemory(const void Data, size_t DataLen, const void *Patt,
	size_t PattLen) {
	return memmem(Data, DataLen, Patt, PattLen);
	}

	// In fuchsia, accessing /dev/null is not supported. There's nothing
	// similar to a file that discards everything that is written to it.
	// The way of doing something similar in fuchsia is by using
	// fdio_null_create and binding that to a file descriptor.
	void DiscardOutput(int Fd) {
	fdio_t *fdio_null = fdio_null_create();
	if (fdio_null == nullptr) return;
	int nullfd = fdio_bind_to_fd(fdio_null, -1, 0);
	if (nullfd < 0) return;
	dup2(nullfd, Fd);
	}

	} // namespace fuzzer

	#endif // LIBFUZZER_FUCHSIA