compiler-rt/lib/xray/xray_x86_64.cpp - llvm-project - Git at Google

 #include "cpuid.h"
 #include "sanitizer_common/sanitizer_common.h"
 #if !SANITIZER_FUCHSIA
 #include "sanitizer_common/sanitizer_posix.h"
 #endif
 #include "xray_defs.h"
 #include "xray_interface_internal.h"

 #if SANITIZER_FREEBSD || SANITIZER_NETBSD || SANITIZER_MAC
 #include <sys/types.h>
 #include <sys/sysctl.h>
 #elif SANITIZER_FUCHSIA
 #include <zircon/syscalls.h>
 #endif

 #include <atomic>
 #include <cstdint>
 #include <errno.h>
 #include <fcntl.h>
 #include <iterator>
 #include <limits>
 #include <tuple>
 #include <unistd.h>

 namespace __xray {

 #if SANITIZER_LINUX
 static std::pair<ssize_t, bool>
 retryingReadSome(int Fd, char *Begin, char *End) XRAY_NEVER_INSTRUMENT {
   auto BytesToRead = std::distance(Begin, End);
   ssize_t BytesRead;
   ssize_t TotalBytesRead = 0;
   while (BytesToRead && (BytesRead = read(Fd, Begin, BytesToRead))) {
     if (BytesRead == -1) {
       if (errno == EINTR)
         continue;
       Report("Read error; errno = %d\n", errno);
       return std::make_pair(TotalBytesRead, false);
     }

     TotalBytesRead += BytesRead;
     BytesToRead -= BytesRead;
     Begin += BytesRead;
   }
   return std::make_pair(TotalBytesRead, true);
 }

 static bool readValueFromFile(const char *Filename,
                               long long *Value) XRAY_NEVER_INSTRUMENT {
   int Fd = open(Filename, O_RDONLY | O_CLOEXEC);
   if (Fd == -1)
     return false;
   static constexpr size_t BufSize = 256;
   char Line[BufSize] = {};
   ssize_t BytesRead;
   bool Success;
   std::tie(BytesRead, Success) = retryingReadSome(Fd, Line, Line + BufSize);
   close(Fd);
   if (!Success)
     return false;
   const char *End = nullptr;
   long long Tmp = internal_simple_strtoll(Line, &End, 10);
   bool Result = false;
   if (Line[0] != '\0' && (*End == '\n' || *End == '\0')) {
     *Value = Tmp;
     Result = true;
   }
   return Result;
 }

 uint64_t getTSCFrequency() XRAY_NEVER_INSTRUMENT {
   long long TSCFrequency = -1;
   if (readValueFromFile("/sys/devices/system/cpu/cpu0/tsc_freq_khz",
                         &TSCFrequency)) {
     TSCFrequency *= 1000;
   } else if (readValueFromFile(
                  "/sys/devices/system/cpu/cpu0/cpufreq/cpuinfo_max_freq",
                  &TSCFrequency)) {
     TSCFrequency *= 1000;
   } else {
     Report("Unable to determine CPU frequency for TSC accounting.\n");
   }
   return TSCFrequency == -1 ? 0 : static_cast<uint64_t>(TSCFrequency);
 }
 #elif SANITIZER_FREEBSD || SANITIZER_NETBSD || SANITIZER_MAC
 uint64_t getTSCFrequency() XRAY_NEVER_INSTRUMENT {
     long long TSCFrequency = -1;
     size_t tscfreqsz = sizeof(TSCFrequency);
 #if SANITIZER_MAC
     if (internal_sysctlbyname("machdep.tsc.frequency", &TSCFrequency,
                               &tscfreqsz, NULL, 0) != -1) {

 #else
     if (internal_sysctlbyname("machdep.tsc_freq", &TSCFrequency, &tscfreqsz,
                               NULL, 0) != -1) {
 #endif
         return static_cast<uint64_t>(TSCFrequency);
     } else {
       Report("Unable to determine CPU frequency for TSC accounting.\n");
     }

     return 0;
 }
 #elif !SANITIZER_FUCHSIA
 uint64_t getTSCFrequency() XRAY_NEVER_INSTRUMENT {
     /* Not supported */
     return 0;
 }
 #endif

 static constexpr uint8_t CallOpCode = 0xe8;
 static constexpr uint16_t MovR10Seq = 0xba41;
 static constexpr uint16_t Jmp9Seq = 0x09eb;
 static constexpr uint16_t Jmp20Seq = 0x14eb;
 static constexpr uint16_t Jmp15Seq = 0x0feb;
 static constexpr uint8_t JmpOpCode = 0xe9;
 static constexpr uint8_t RetOpCode = 0xc3;
 static constexpr uint16_t NopwSeq = 0x9066;

 static constexpr int64_t MinOffset{std::numeric_limits<int32_t>::min()};
 static constexpr int64_t MaxOffset{std::numeric_limits<int32_t>::max()};

 bool patchFunctionEntry(const bool Enable, const uint32_t FuncId,
                         const XRaySledEntry &Sled,
                         void (*Trampoline)()) XRAY_NEVER_INSTRUMENT {
   // Here we do the dance of replacing the following sled:
   //
   // xray_sled_n:
   //   jmp +9
   //   <9 byte nop>
   //
   // With the following:
   //
   //   mov r10d, <function id>
   //   call <relative 32bit offset to entry trampoline>
   //
   // We need to do this in the following order:
   //
   // 1. Put the function id first, 2 bytes from the start of the sled (just
   // after the 2-byte jmp instruction).
   // 2. Put the call opcode 6 bytes from the start of the sled.
   // 3. Put the relative offset 7 bytes from the start of the sled.
   // 4. Do an atomic write over the jmp instruction for the "mov r10d"
   // opcode and first operand.
   //
   // Prerequisite is to compute the relative offset to the trampoline's address.
   const uint64_t Address = Sled.address();
   int64_t TrampolineOffset = reinterpret_cast<int64_t>(Trampoline) -
                              (static_cast<int64_t>(Address) + 11);
   if (TrampolineOffset < MinOffset || TrampolineOffset > MaxOffset) {
     Report("XRay Entry trampoline (%p) too far from sled (%p)\n",
            reinterpret_cast<void *>(Trampoline),
            reinterpret_cast<void *>(Address));
     return false;
   }
   if (Enable) {
     *reinterpret_cast<uint32_t *>(Address + 2) = FuncId;
     *reinterpret_cast<uint8_t *>(Address + 6) = CallOpCode;
     *reinterpret_cast<uint32_t *>(Address + 7) = TrampolineOffset;
     std::atomic_store_explicit(
         reinterpret_cast<std::atomic<uint16_t> *>(Address), MovR10Seq,
         std::memory_order_release);
   } else {
     std::atomic_store_explicit(
         reinterpret_cast<std::atomic<uint16_t> *>(Address), Jmp9Seq,
         std::memory_order_release);
     // FIXME: Write out the nops still?
   }
   return true;
 }

 bool patchFunctionExit(const bool Enable, const uint32_t FuncId,
                        const XRaySledEntry &Sled) XRAY_NEVER_INSTRUMENT {
   // Here we do the dance of replacing the following sled:
   //
   // xray_sled_n:
   //   ret
   //   <10 byte nop>
   //
   // With the following:
   //
   //   mov r10d, <function id>
   //   jmp <relative 32bit offset to exit trampoline>
   //
   // 1. Put the function id first, 2 bytes from the start of the sled (just
   // after the 1-byte ret instruction).
   // 2. Put the jmp opcode 6 bytes from the start of the sled.
   // 3. Put the relative offset 7 bytes from the start of the sled.
   // 4. Do an atomic write over the jmp instruction for the "mov r10d"
   // opcode and first operand.
   //
   // Prerequisite is to compute the relative offset fo the
   // __xray_FunctionExit function's address.
   const uint64_t Address = Sled.address();
   int64_t TrampolineOffset = reinterpret_cast<int64_t>(__xray_FunctionExit) -
                              (static_cast<int64_t>(Address) + 11);
   if (TrampolineOffset < MinOffset || TrampolineOffset > MaxOffset) {
     Report("XRay Exit trampoline (%p) too far from sled (%p)\n",
            reinterpret_cast<void *>(__xray_FunctionExit),
            reinterpret_cast<void *>(Address));
     return false;
   }
   if (Enable) {
     *reinterpret_cast<uint32_t *>(Address + 2) = FuncId;
     *reinterpret_cast<uint8_t *>(Address + 6) = JmpOpCode;
     *reinterpret_cast<uint32_t *>(Address + 7) = TrampolineOffset;
     std::atomic_store_explicit(
         reinterpret_cast<std::atomic<uint16_t> *>(Address), MovR10Seq,
         std::memory_order_release);
   } else {
     std::atomic_store_explicit(
         reinterpret_cast<std::atomic<uint8_t> *>(Address), RetOpCode,
         std::memory_order_release);
     // FIXME: Write out the nops still?
   }
   return true;
 }

 bool patchFunctionTailExit(const bool Enable, const uint32_t FuncId,
                            const XRaySledEntry &Sled) XRAY_NEVER_INSTRUMENT {
   // Here we do the dance of replacing the tail call sled with a similar
   // sequence as the entry sled, but calls the tail exit sled instead.
   const uint64_t Address = Sled.address();
   int64_t TrampolineOffset =
       reinterpret_cast<int64_t>(__xray_FunctionTailExit) -
       (static_cast<int64_t>(Address) + 11);
   if (TrampolineOffset < MinOffset || TrampolineOffset > MaxOffset) {
     Report("XRay Tail Exit trampoline (%p) too far from sled (%p)\n",
            reinterpret_cast<void *>(__xray_FunctionTailExit),
            reinterpret_cast<void *>(Address));
     return false;
   }
   if (Enable) {
     *reinterpret_cast<uint32_t *>(Address + 2) = FuncId;
     *reinterpret_cast<uint8_t *>(Address + 6) = CallOpCode;
     *reinterpret_cast<uint32_t *>(Address + 7) = TrampolineOffset;
     std::atomic_store_explicit(
         reinterpret_cast<std::atomic<uint16_t> *>(Address), MovR10Seq,
         std::memory_order_release);
   } else {
     std::atomic_store_explicit(
         reinterpret_cast<std::atomic<uint16_t> *>(Address), Jmp9Seq,
         std::memory_order_release);
     // FIXME: Write out the nops still?
   }
   return true;
 }

 bool patchCustomEvent(const bool Enable, const uint32_t FuncId,
                       const XRaySledEntry &Sled) XRAY_NEVER_INSTRUMENT {
   // Here we do the dance of replacing the following sled:
   //
   // In Version 0:
   //
   // xray_sled_n:
   //   jmp +20          // 2 bytes
   //   ...
   //
   // With the following:
   //
   //   nopw             // 2 bytes*
   //   ...
   //
   //
   // The "unpatch" should just turn the 'nopw' back to a 'jmp +20'.
   //
   // ---
   //
   // In Version 1 or 2:
   //
   //   The jump offset is now 15 bytes (0x0f), so when restoring the nopw back
   //   to a jmp, use 15 bytes instead.
   //
   const uint64_t Address = Sled.address();
   if (Enable) {
     std::atomic_store_explicit(
         reinterpret_cast<std::atomic<uint16_t> *>(Address), NopwSeq,
         std::memory_order_release);
   } else {
     switch (Sled.Version) {
     case 1:
     case 2:
       std::atomic_store_explicit(
           reinterpret_cast<std::atomic<uint16_t> *>(Address), Jmp15Seq,
           std::memory_order_release);
       break;
     case 0:
     default:
       std::atomic_store_explicit(
           reinterpret_cast<std::atomic<uint16_t> *>(Address), Jmp20Seq,
           std::memory_order_release);
       break;
     }
     }
   return false;
 }

 bool patchTypedEvent(const bool Enable, const uint32_t FuncId,
                       const XRaySledEntry &Sled) XRAY_NEVER_INSTRUMENT {
   // Here we do the dance of replacing the following sled:
   //
   // xray_sled_n:
   //   jmp +20          // 2 byte instruction
   //   ...
   //
   // With the following:
   //
   //   nopw             // 2 bytes
   //   ...
   //
   //
   // The "unpatch" should just turn the 'nopw' back to a 'jmp +20'.
   // The 20 byte sled stashes three argument registers, calls the trampoline,
   // unstashes the registers and returns. If the arguments are already in
   // the correct registers, the stashing and unstashing become equivalently
   // sized nops.
   const uint64_t Address = Sled.address();
   if (Enable) {
     std::atomic_store_explicit(
         reinterpret_cast<std::atomic<uint16_t> *>(Address), NopwSeq,
         std::memory_order_release);
   } else {
     std::atomic_store_explicit(
         reinterpret_cast<std::atomic<uint16_t> *>(Address), Jmp20Seq,
         std::memory_order_release);
   }
   return false;
 }

 #if !SANITIZER_FUCHSIA
 // We determine whether the CPU we're running on has the correct features we
 // need. In x86_64 this will be rdtscp support.
 bool probeRequiredCPUFeatures() XRAY_NEVER_INSTRUMENT {
   unsigned int EAX, EBX, ECX, EDX;

   // We check whether rdtscp support is enabled. According to the x86_64 manual,
   // level should be set at 0x80000001, and we should have a look at bit 27 in
   // EDX. That's 0x8000000 (or 1u << 27).
   __asm__ __volatile__("cpuid" : "=a"(EAX), "=b"(EBX), "=c"(ECX), "=d"(EDX)
     : "0"(0x80000001));
   if (!(EDX & (1u << 27))) {
     Report("Missing rdtscp support.\n");
     return false;
   }
   // Also check whether we can determine the CPU frequency, since if we cannot,
   // we should use the emulated TSC instead.
   if (!getTSCFrequency()) {
     Report("Unable to determine CPU frequency.\n");
     return false;
   }
   return true;
 }
 #endif

 } // namespace __xray
	#include "cpuid.h"
	#include "sanitizer_common/sanitizer_common.h"
	#if !SANITIZER_FUCHSIA
	#include "sanitizer_common/sanitizer_posix.h"
	#endif
	#include "xray_defs.h"
	#include "xray_interface_internal.h"

	#if SANITIZER_FREEBSD \|\| SANITIZER_NETBSD \|\| SANITIZER_MAC
	#include <sys/types.h>
	#include <sys/sysctl.h>
	#elif SANITIZER_FUCHSIA
	#include <zircon/syscalls.h>
	#endif

	#include <atomic>
	#include <cstdint>
	#include <errno.h>
	#include <fcntl.h>
	#include <iterator>
	#include <limits>
	#include <tuple>
	#include <unistd.h>

	namespace __xray {

	#if SANITIZER_LINUX
	static std::pair<ssize_t, bool>
	retryingReadSome(int Fd, char Begin, char End) XRAY_NEVER_INSTRUMENT {
	auto BytesToRead = std::distance(Begin, End);
	ssize_t BytesRead;
	ssize_t TotalBytesRead = 0;
	while (BytesToRead && (BytesRead = read(Fd, Begin, BytesToRead))) {
	if (BytesRead == -1) {
	if (errno == EINTR)
	continue;
	Report("Read error; errno = %d\n", errno);
	return std::make_pair(TotalBytesRead, false);
	}

	TotalBytesRead += BytesRead;
	BytesToRead -= BytesRead;
	Begin += BytesRead;
	}
	return std::make_pair(TotalBytesRead, true);
	}

	static bool readValueFromFile(const char *Filename,
	long long *Value) XRAY_NEVER_INSTRUMENT {
	int Fd = open(Filename, O_RDONLY \| O_CLOEXEC);
	if (Fd == -1)
	return false;
	static constexpr size_t BufSize = 256;
	char Line[BufSize] = {};
	ssize_t BytesRead;
	bool Success;
	std::tie(BytesRead, Success) = retryingReadSome(Fd, Line, Line + BufSize);
	close(Fd);
	if (!Success)
	return false;
	const char *End = nullptr;
	long long Tmp = internal_simple_strtoll(Line, &End, 10);
	bool Result = false;
	if (Line[0] != '\0' && (End == '\n' \|\| End == '\0')) {
	*Value = Tmp;
	Result = true;
	}
	return Result;
	}

	uint64_t getTSCFrequency() XRAY_NEVER_INSTRUMENT {
	long long TSCFrequency = -1;
	if (readValueFromFile("/sys/devices/system/cpu/cpu0/tsc_freq_khz",
	&TSCFrequency)) {
	TSCFrequency *= 1000;
	} else if (readValueFromFile(
	"/sys/devices/system/cpu/cpu0/cpufreq/cpuinfo_max_freq",
	&TSCFrequency)) {
	TSCFrequency *= 1000;
	} else {
	Report("Unable to determine CPU frequency for TSC accounting.\n");
	}
	return TSCFrequency == -1 ? 0 : static_cast<uint64_t>(TSCFrequency);
	}
	#elif SANITIZER_FREEBSD \|\| SANITIZER_NETBSD \|\| SANITIZER_MAC
	uint64_t getTSCFrequency() XRAY_NEVER_INSTRUMENT {
	long long TSCFrequency = -1;
	size_t tscfreqsz = sizeof(TSCFrequency);
	#if SANITIZER_MAC
	if (internal_sysctlbyname("machdep.tsc.frequency", &TSCFrequency,
	&tscfreqsz, NULL, 0) != -1) {

	#else
	if (internal_sysctlbyname("machdep.tsc_freq", &TSCFrequency, &tscfreqsz,
	NULL, 0) != -1) {
	#endif
	return static_cast<uint64_t>(TSCFrequency);
	} else {
	Report("Unable to determine CPU frequency for TSC accounting.\n");
	}

	return 0;
	}
	#elif !SANITIZER_FUCHSIA
	uint64_t getTSCFrequency() XRAY_NEVER_INSTRUMENT {
	/* Not supported */
	return 0;
	}
	#endif

	static constexpr uint8_t CallOpCode = 0xe8;
	static constexpr uint16_t MovR10Seq = 0xba41;
	static constexpr uint16_t Jmp9Seq = 0x09eb;
	static constexpr uint16_t Jmp20Seq = 0x14eb;
	static constexpr uint16_t Jmp15Seq = 0x0feb;
	static constexpr uint8_t JmpOpCode = 0xe9;
	static constexpr uint8_t RetOpCode = 0xc3;
	static constexpr uint16_t NopwSeq = 0x9066;

	static constexpr int64_t MinOffset{std::numeric_limits<int32_t>::min()};
	static constexpr int64_t MaxOffset{std::numeric_limits<int32_t>::max()};

	bool patchFunctionEntry(const bool Enable, const uint32_t FuncId,
	const XRaySledEntry &Sled,
	void (*Trampoline)()) XRAY_NEVER_INSTRUMENT {
	// Here we do the dance of replacing the following sled:
	//
	// xray_sled_n:
	// jmp +9
	// <9 byte nop>
	//
	// With the following:
	//
	// mov r10d, <function id>
	// call <relative 32bit offset to entry trampoline>
	//
	// We need to do this in the following order:
	//
	// 1. Put the function id first, 2 bytes from the start of the sled (just
	// after the 2-byte jmp instruction).
	// 2. Put the call opcode 6 bytes from the start of the sled.
	// 3. Put the relative offset 7 bytes from the start of the sled.
	// 4. Do an atomic write over the jmp instruction for the "mov r10d"
	// opcode and first operand.
	//
	// Prerequisite is to compute the relative offset to the trampoline's address.
	const uint64_t Address = Sled.address();
	int64_t TrampolineOffset = reinterpret_cast<int64_t>(Trampoline) -
	(static_cast<int64_t>(Address) + 11);
	if (TrampolineOffset < MinOffset \|\| TrampolineOffset > MaxOffset) {
	Report("XRay Entry trampoline (%p) too far from sled (%p)\n",
	reinterpret_cast<void *>(Trampoline),
	reinterpret_cast<void *>(Address));
	return false;
	}
	if (Enable) {
	reinterpret_cast<uint32_t >(Address + 2) = FuncId;
	reinterpret_cast<uint8_t >(Address + 6) = CallOpCode;
	reinterpret_cast<uint32_t >(Address + 7) = TrampolineOffset;
	std::atomic_store_explicit(
	reinterpret_cast<std::atomic<uint16_t> *>(Address), MovR10Seq,
	std::memory_order_release);
	} else {
	std::atomic_store_explicit(
	reinterpret_cast<std::atomic<uint16_t> *>(Address), Jmp9Seq,
	std::memory_order_release);
	// FIXME: Write out the nops still?
	}
	return true;
	}

	bool patchFunctionExit(const bool Enable, const uint32_t FuncId,
	const XRaySledEntry &Sled) XRAY_NEVER_INSTRUMENT {
	// Here we do the dance of replacing the following sled:
	//
	// xray_sled_n:
	// ret
	// <10 byte nop>
	//
	// With the following:
	//
	// mov r10d, <function id>
	// jmp <relative 32bit offset to exit trampoline>
	//
	// 1. Put the function id first, 2 bytes from the start of the sled (just
	// after the 1-byte ret instruction).
	// 2. Put the jmp opcode 6 bytes from the start of the sled.
	// 3. Put the relative offset 7 bytes from the start of the sled.
	// 4. Do an atomic write over the jmp instruction for the "mov r10d"
	// opcode and first operand.
	//
	// Prerequisite is to compute the relative offset fo the
	// __xray_FunctionExit function's address.
	const uint64_t Address = Sled.address();
	int64_t TrampolineOffset = reinterpret_cast<int64_t>(__xray_FunctionExit) -
	(static_cast<int64_t>(Address) + 11);
	if (TrampolineOffset < MinOffset \|\| TrampolineOffset > MaxOffset) {
	Report("XRay Exit trampoline (%p) too far from sled (%p)\n",
	reinterpret_cast<void *>(__xray_FunctionExit),
	reinterpret_cast<void *>(Address));
	return false;
	}
	if (Enable) {
	reinterpret_cast<uint32_t >(Address + 2) = FuncId;
	reinterpret_cast<uint8_t >(Address + 6) = JmpOpCode;
	reinterpret_cast<uint32_t >(Address + 7) = TrampolineOffset;
	std::atomic_store_explicit(
	reinterpret_cast<std::atomic<uint16_t> *>(Address), MovR10Seq,
	std::memory_order_release);
	} else {
	std::atomic_store_explicit(
	reinterpret_cast<std::atomic<uint8_t> *>(Address), RetOpCode,
	std::memory_order_release);
	// FIXME: Write out the nops still?
	}
	return true;
	}

	bool patchFunctionTailExit(const bool Enable, const uint32_t FuncId,
	const XRaySledEntry &Sled) XRAY_NEVER_INSTRUMENT {
	// Here we do the dance of replacing the tail call sled with a similar
	// sequence as the entry sled, but calls the tail exit sled instead.
	const uint64_t Address = Sled.address();
	int64_t TrampolineOffset =
	reinterpret_cast<int64_t>(__xray_FunctionTailExit) -
	(static_cast<int64_t>(Address) + 11);
	if (TrampolineOffset < MinOffset \|\| TrampolineOffset > MaxOffset) {
	Report("XRay Tail Exit trampoline (%p) too far from sled (%p)\n",
	reinterpret_cast<void *>(__xray_FunctionTailExit),
	reinterpret_cast<void *>(Address));
	return false;
	}
	if (Enable) {
	reinterpret_cast<uint32_t >(Address + 2) = FuncId;
	reinterpret_cast<uint8_t >(Address + 6) = CallOpCode;
	reinterpret_cast<uint32_t >(Address + 7) = TrampolineOffset;
	std::atomic_store_explicit(
	reinterpret_cast<std::atomic<uint16_t> *>(Address), MovR10Seq,
	std::memory_order_release);
	} else {
	std::atomic_store_explicit(
	reinterpret_cast<std::atomic<uint16_t> *>(Address), Jmp9Seq,
	std::memory_order_release);
	// FIXME: Write out the nops still?
	}
	return true;
	}

	bool patchCustomEvent(const bool Enable, const uint32_t FuncId,
	const XRaySledEntry &Sled) XRAY_NEVER_INSTRUMENT {
	// Here we do the dance of replacing the following sled:
	//
	// In Version 0:
	//
	// xray_sled_n:
	// jmp +20 // 2 bytes
	// ...
	//
	// With the following:
	//
	// nopw // 2 bytes*
	// ...
	//
	//
	// The "unpatch" should just turn the 'nopw' back to a 'jmp +20'.
	//
	// ---
	//
	// In Version 1 or 2:
	//
	// The jump offset is now 15 bytes (0x0f), so when restoring the nopw back
	// to a jmp, use 15 bytes instead.
	//
	const uint64_t Address = Sled.address();
	if (Enable) {
	std::atomic_store_explicit(
	reinterpret_cast<std::atomic<uint16_t> *>(Address), NopwSeq,
	std::memory_order_release);
	} else {
	switch (Sled.Version) {
	case 1:
	case 2:
	std::atomic_store_explicit(
	reinterpret_cast<std::atomic<uint16_t> *>(Address), Jmp15Seq,
	std::memory_order_release);
	break;
	case 0:
	default:
	std::atomic_store_explicit(
	reinterpret_cast<std::atomic<uint16_t> *>(Address), Jmp20Seq,
	std::memory_order_release);
	break;
	}
	}
	return false;
	}

	bool patchTypedEvent(const bool Enable, const uint32_t FuncId,
	const XRaySledEntry &Sled) XRAY_NEVER_INSTRUMENT {
	// Here we do the dance of replacing the following sled:
	//
	// xray_sled_n:
	// jmp +20 // 2 byte instruction
	// ...
	//
	// With the following:
	//
	// nopw // 2 bytes
	// ...
	//
	//
	// The "unpatch" should just turn the 'nopw' back to a 'jmp +20'.
	// The 20 byte sled stashes three argument registers, calls the trampoline,
	// unstashes the registers and returns. If the arguments are already in
	// the correct registers, the stashing and unstashing become equivalently
	// sized nops.
	const uint64_t Address = Sled.address();
	if (Enable) {
	std::atomic_store_explicit(
	reinterpret_cast<std::atomic<uint16_t> *>(Address), NopwSeq,
	std::memory_order_release);
	} else {
	std::atomic_store_explicit(
	reinterpret_cast<std::atomic<uint16_t> *>(Address), Jmp20Seq,
	std::memory_order_release);
	}
	return false;
	}

	#if !SANITIZER_FUCHSIA
	// We determine whether the CPU we're running on has the correct features we
	// need. In x86_64 this will be rdtscp support.
	bool probeRequiredCPUFeatures() XRAY_NEVER_INSTRUMENT {
	unsigned int EAX, EBX, ECX, EDX;

	// We check whether rdtscp support is enabled. According to the x86_64 manual,
	// level should be set at 0x80000001, and we should have a look at bit 27 in
	// EDX. That's 0x8000000 (or 1u << 27).
	__asm__ __volatile__("cpuid" : "=a"(EAX), "=b"(EBX), "=c"(ECX), "=d"(EDX)
	: "0"(0x80000001));
	if (!(EDX & (1u << 27))) {
	Report("Missing rdtscp support.\n");
	return false;
	}
	// Also check whether we can determine the CPU frequency, since if we cannot,
	// we should use the emulated TSC instead.
	if (!getTSCFrequency()) {
	Report("Unable to determine CPU frequency.\n");
	return false;
	}
	return true;
	}
	#endif

	} // namespace __xray