X86MCTargetDesc.cpp

Go to the documentation of this file.

//===-- X86MCTargetDesc.cpp - X86 Target Descriptions ---------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This file provides X86 specific target descriptions.
//
//===----------------------------------------------------------------------===//
 
#include "X86MCTargetDesc.h"
#include "TargetInfo/X86TargetInfo.h"
#include "X86ATTInstPrinter.h"
#include "X86BaseInfo.h"
#include "X86IntelInstPrinter.h"
#include "X86MCAsmInfo.h"
#include "X86TargetStreamer.h"
#include "llvm-c/Visibility.h"
#include "llvm/ADT/APInt.h"
#include "llvm/DebugInfo/CodeView/CodeView.h"
#include "llvm/MC/MCDwarf.h"
#include "llvm/MC/MCInstrAnalysis.h"
#include "llvm/MC/MCInstrInfo.h"
#include "llvm/MC/MCRegisterInfo.h"
#include "llvm/MC/MCStreamer.h"
#include "llvm/MC/MCSubtargetInfo.h"
#include "llvm/MC/TargetRegistry.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/TargetParser/Host.h"
#include "llvm/TargetParser/Triple.h"
 
using namespace llvm;
 
#define GET_REGINFO_MC_DESC
#include "X86GenRegisterInfo.inc"
 
#define GET_INSTRINFO_MC_DESC
#define GET_INSTRINFO_MC_HELPERS
#define ENABLE_INSTR_PREDICATE_VERIFIER
#include "X86GenInstrInfo.inc"
 
#define GET_SUBTARGETINFO_MC_DESC
#include "X86GenSubtargetInfo.inc"
 
std::string X86_MC::ParseX86Triple(const Triple &TT) {
  std::string FS;
  // SSE2 should default to enabled in 64-bit mode, but can be turned off
  // explicitly.
  if (TT.isX86_64())
    FS = "+64bit-mode,-32bit-mode,-16bit-mode,+sse2";
  else if (TT.getEnvironment() != Triple::CODE16)
    FS = "-64bit-mode,+32bit-mode,-16bit-mode";
  else
    FS = "-64bit-mode,-32bit-mode,+16bit-mode";
 
  if (TT.isX32())
    FS += ",+x32";
 
  return FS;
}
 
unsigned X86_MC::getDwarfRegFlavour(const Triple &TT, bool isEH) {
  if (TT.isX86_64())
    return DWARFFlavour::X86_64;
 
  if (TT.isOSDarwin())
    return isEH ? DWARFFlavour::X86_32_DarwinEH : DWARFFlavour::X86_32_Generic;
  if (TT.isOSCygMing())
    // Unsupported by now, just quick fallback
    return DWARFFlavour::X86_32_Generic;
  return DWARFFlavour::X86_32_Generic;
}
 
bool X86_MC::hasLockPrefix(const MCInst &MI) {
  return MI.getFlags() & X86::IP_HAS_LOCK;
}
 
static bool isMemOperand(const MCInst &MI, unsigned Op, unsigned RegClassID) {
  const MCOperand &Base = MI.getOperand(Op + X86::AddrBaseReg);
  const MCOperand &Index = MI.getOperand(Op + X86::AddrIndexReg);
  const MCRegisterClass &RC = X86MCRegisterClasses[RegClassID];
 
  return (Base.isReg() && Base.getReg() && RC.contains(Base.getReg())) ||
         (Index.isReg() && Index.getReg() && RC.contains(Index.getReg()));
}
 
bool X86_MC::is16BitMemOperand(const MCInst &MI, unsigned Op,
                               const MCSubtargetInfo &STI) {
  const MCOperand &Base = MI.getOperand(Op + X86::AddrBaseReg);
  const MCOperand &Index = MI.getOperand(Op + X86::AddrIndexReg);
 
  if (STI.hasFeature(X86::Is16Bit) && Base.isReg() && !Base.getReg() &&
      Index.isReg() && !Index.getReg())
    return true;
  return isMemOperand(MI, Op, X86::GR16RegClassID);
}
 
bool X86_MC::is32BitMemOperand(const MCInst &MI, unsigned Op) {
  const MCOperand &Base = MI.getOperand(Op + X86::AddrBaseReg);
  const MCOperand &Index = MI.getOperand(Op + X86::AddrIndexReg);
  if (Base.isReg() && Base.getReg() == X86::EIP) {
    assert(Index.isReg() && !Index.getReg() && "Invalid eip-based address");
    return true;
  }
  if (Index.isReg() && Index.getReg() == X86::EIZ)
    return true;
  return isMemOperand(MI, Op, X86::GR32RegClassID);
}
 
#ifndef NDEBUG
bool X86_MC::is64BitMemOperand(const MCInst &MI, unsigned Op) {
  return isMemOperand(MI, Op, X86::GR64RegClassID);
}
#endif
 
bool X86_MC::needsAddressSizeOverride(const MCInst &MI,
                                      const MCSubtargetInfo &STI,
                                      int MemoryOperand, uint64_t TSFlags) {
  uint64_t AdSize = TSFlags & X86II::AdSizeMask;
  bool Is16BitMode = STI.hasFeature(X86::Is16Bit);
  bool Is32BitMode = STI.hasFeature(X86::Is32Bit);
  bool Is64BitMode = STI.hasFeature(X86::Is64Bit);
  if ((Is16BitMode && AdSize == X86II::AdSize32) ||
      (Is32BitMode && AdSize == X86II::AdSize16) ||
      (Is64BitMode && AdSize == X86II::AdSize32))
    return true;
  uint64_t Form = TSFlags & X86II::FormMask;
  switch (Form) {
  default:
    break;
  case X86II::RawFrmDstSrc: {
    MCRegister siReg = MI.getOperand(1).getReg();
    assert(((siReg == X86::SI && MI.getOperand(0).getReg() == X86::DI) ||
            (siReg == X86::ESI && MI.getOperand(0).getReg() == X86::EDI) ||
            (siReg == X86::RSI && MI.getOperand(0).getReg() == X86::RDI)) &&
           "SI and DI register sizes do not match");
    return (!Is32BitMode && siReg == X86::ESI) ||
           (Is32BitMode && siReg == X86::SI);
  }
  case X86II::RawFrmSrc: {
    MCRegister siReg = MI.getOperand(0).getReg();
    return (!Is32BitMode && siReg == X86::ESI) ||
           (Is32BitMode && siReg == X86::SI);
  }
  case X86II::RawFrmDst: {
    MCRegister siReg = MI.getOperand(0).getReg();
    return (!Is32BitMode && siReg == X86::EDI) ||
           (Is32BitMode && siReg == X86::DI);
  }
  }
 
  // Determine where the memory operand starts, if present.
  if (MemoryOperand < 0)
    return false;
 
  if (STI.hasFeature(X86::Is64Bit)) {
    assert(!is16BitMemOperand(MI, MemoryOperand, STI));
    return is32BitMemOperand(MI, MemoryOperand);
  }
  if (STI.hasFeature(X86::Is32Bit)) {
    assert(!is64BitMemOperand(MI, MemoryOperand));
    return is16BitMemOperand(MI, MemoryOperand, STI);
  }
  assert(STI.hasFeature(X86::Is16Bit));
  assert(!is64BitMemOperand(MI, MemoryOperand));
  return !is16BitMemOperand(MI, MemoryOperand, STI);
}
 
void X86_MC::initLLVMToSEHAndCVRegMapping(MCRegisterInfo *MRI) {
  // FIXME: TableGen these.
  for (unsigned Reg = X86::NoRegister + 1; Reg < X86::NUM_TARGET_REGS; ++Reg) {
    unsigned SEH = MRI->getEncodingValue(Reg);
    MRI->mapLLVMRegToSEHReg(Reg, SEH);
  }
 
  // Mapping from CodeView to MC register id.
  static const struct {
    codeview::RegisterId CVReg;
    MCPhysReg Reg;
  } RegMap[] = {
      {codeview::RegisterId::AL, X86::AL},
      {codeview::RegisterId::CL, X86::CL},
      {codeview::RegisterId::DL, X86::DL},
      {codeview::RegisterId::BL, X86::BL},
      {codeview::RegisterId::AH, X86::AH},
      {codeview::RegisterId::CH, X86::CH},
      {codeview::RegisterId::DH, X86::DH},
      {codeview::RegisterId::BH, X86::BH},
      {codeview::RegisterId::AX, X86::AX},
      {codeview::RegisterId::CX, X86::CX},
      {codeview::RegisterId::DX, X86::DX},
      {codeview::RegisterId::BX, X86::BX},
      {codeview::RegisterId::SP, X86::SP},
      {codeview::RegisterId::BP, X86::BP},
      {codeview::RegisterId::SI, X86::SI},
      {codeview::RegisterId::DI, X86::DI},
      {codeview::RegisterId::EAX, X86::EAX},
      {codeview::RegisterId::ECX, X86::ECX},
      {codeview::RegisterId::EDX, X86::EDX},
      {codeview::RegisterId::EBX, X86::EBX},
      {codeview::RegisterId::ESP, X86::ESP},
      {codeview::RegisterId::EBP, X86::EBP},
      {codeview::RegisterId::ESI, X86::ESI},
      {codeview::RegisterId::EDI, X86::EDI},
 
      {codeview::RegisterId::EFLAGS, X86::EFLAGS},
 
      {codeview::RegisterId::ST0, X86::ST0},
      {codeview::RegisterId::ST1, X86::ST1},
      {codeview::RegisterId::ST2, X86::ST2},
      {codeview::RegisterId::ST3, X86::ST3},
      {codeview::RegisterId::ST4, X86::ST4},
      {codeview::RegisterId::ST5, X86::ST5},
      {codeview::RegisterId::ST6, X86::ST6},
      {codeview::RegisterId::ST7, X86::ST7},
 
      {codeview::RegisterId::ST0, X86::FP0},
      {codeview::RegisterId::ST1, X86::FP1},
      {codeview::RegisterId::ST2, X86::FP2},
      {codeview::RegisterId::ST3, X86::FP3},
      {codeview::RegisterId::ST4, X86::FP4},
      {codeview::RegisterId::ST5, X86::FP5},
      {codeview::RegisterId::ST6, X86::FP6},
      {codeview::RegisterId::ST7, X86::FP7},
 
      {codeview::RegisterId::MM0, X86::MM0},
      {codeview::RegisterId::MM1, X86::MM1},
      {codeview::RegisterId::MM2, X86::MM2},
      {codeview::RegisterId::MM3, X86::MM3},
      {codeview::RegisterId::MM4, X86::MM4},
      {codeview::RegisterId::MM5, X86::MM5},
      {codeview::RegisterId::MM6, X86::MM6},
      {codeview::RegisterId::MM7, X86::MM7},
 
      {codeview::RegisterId::XMM0, X86::XMM0},
      {codeview::RegisterId::XMM1, X86::XMM1},
      {codeview::RegisterId::XMM2, X86::XMM2},
      {codeview::RegisterId::XMM3, X86::XMM3},
      {codeview::RegisterId::XMM4, X86::XMM4},
      {codeview::RegisterId::XMM5, X86::XMM5},
      {codeview::RegisterId::XMM6, X86::XMM6},
      {codeview::RegisterId::XMM7, X86::XMM7},
 
      {codeview::RegisterId::XMM8, X86::XMM8},
      {codeview::RegisterId::XMM9, X86::XMM9},
      {codeview::RegisterId::XMM10, X86::XMM10},
      {codeview::RegisterId::XMM11, X86::XMM11},
      {codeview::RegisterId::XMM12, X86::XMM12},
      {codeview::RegisterId::XMM13, X86::XMM13},
      {codeview::RegisterId::XMM14, X86::XMM14},
      {codeview::RegisterId::XMM15, X86::XMM15},
 
      {codeview::RegisterId::SIL, X86::SIL},
      {codeview::RegisterId::DIL, X86::DIL},
      {codeview::RegisterId::BPL, X86::BPL},
      {codeview::RegisterId::SPL, X86::SPL},
      {codeview::RegisterId::RAX, X86::RAX},
      {codeview::RegisterId::RBX, X86::RBX},
      {codeview::RegisterId::RCX, X86::RCX},
      {codeview::RegisterId::RDX, X86::RDX},
      {codeview::RegisterId::RSI, X86::RSI},
      {codeview::RegisterId::RDI, X86::RDI},
      {codeview::RegisterId::RBP, X86::RBP},
      {codeview::RegisterId::RSP, X86::RSP},
      {codeview::RegisterId::R8, X86::R8},
      {codeview::RegisterId::R9, X86::R9},
      {codeview::RegisterId::R10, X86::R10},
      {codeview::RegisterId::R11, X86::R11},
      {codeview::RegisterId::R12, X86::R12},
      {codeview::RegisterId::R13, X86::R13},
      {codeview::RegisterId::R14, X86::R14},
      {codeview::RegisterId::R15, X86::R15},
      {codeview::RegisterId::R8B, X86::R8B},
      {codeview::RegisterId::R9B, X86::R9B},
      {codeview::RegisterId::R10B, X86::R10B},
      {codeview::RegisterId::R11B, X86::R11B},
      {codeview::RegisterId::R12B, X86::R12B},
      {codeview::RegisterId::R13B, X86::R13B},
      {codeview::RegisterId::R14B, X86::R14B},
      {codeview::RegisterId::R15B, X86::R15B},
      {codeview::RegisterId::R8W, X86::R8W},
      {codeview::RegisterId::R9W, X86::R9W},
      {codeview::RegisterId::R10W, X86::R10W},
      {codeview::RegisterId::R11W, X86::R11W},
      {codeview::RegisterId::R12W, X86::R12W},
      {codeview::RegisterId::R13W, X86::R13W},
      {codeview::RegisterId::R14W, X86::R14W},
      {codeview::RegisterId::R15W, X86::R15W},
      {codeview::RegisterId::R8D, X86::R8D},
      {codeview::RegisterId::R9D, X86::R9D},
      {codeview::RegisterId::R10D, X86::R10D},
      {codeview::RegisterId::R11D, X86::R11D},
      {codeview::RegisterId::R12D, X86::R12D},
      {codeview::RegisterId::R13D, X86::R13D},
      {codeview::RegisterId::R14D, X86::R14D},
      {codeview::RegisterId::R15D, X86::R15D},
      {codeview::RegisterId::AMD64_YMM0, X86::YMM0},
      {codeview::RegisterId::AMD64_YMM1, X86::YMM1},
      {codeview::RegisterId::AMD64_YMM2, X86::YMM2},
      {codeview::RegisterId::AMD64_YMM3, X86::YMM3},
      {codeview::RegisterId::AMD64_YMM4, X86::YMM4},
      {codeview::RegisterId::AMD64_YMM5, X86::YMM5},
      {codeview::RegisterId::AMD64_YMM6, X86::YMM6},
      {codeview::RegisterId::AMD64_YMM7, X86::YMM7},
      {codeview::RegisterId::AMD64_YMM8, X86::YMM8},
      {codeview::RegisterId::AMD64_YMM9, X86::YMM9},
      {codeview::RegisterId::AMD64_YMM10, X86::YMM10},
      {codeview::RegisterId::AMD64_YMM11, X86::YMM11},
      {codeview::RegisterId::AMD64_YMM12, X86::YMM12},
      {codeview::RegisterId::AMD64_YMM13, X86::YMM13},
      {codeview::RegisterId::AMD64_YMM14, X86::YMM14},
      {codeview::RegisterId::AMD64_YMM15, X86::YMM15},
      {codeview::RegisterId::AMD64_YMM16, X86::YMM16},
      {codeview::RegisterId::AMD64_YMM17, X86::YMM17},
      {codeview::RegisterId::AMD64_YMM18, X86::YMM18},
      {codeview::RegisterId::AMD64_YMM19, X86::YMM19},
      {codeview::RegisterId::AMD64_YMM20, X86::YMM20},
      {codeview::RegisterId::AMD64_YMM21, X86::YMM21},
      {codeview::RegisterId::AMD64_YMM22, X86::YMM22},
      {codeview::RegisterId::AMD64_YMM23, X86::YMM23},
      {codeview::RegisterId::AMD64_YMM24, X86::YMM24},
      {codeview::RegisterId::AMD64_YMM25, X86::YMM25},
      {codeview::RegisterId::AMD64_YMM26, X86::YMM26},
      {codeview::RegisterId::AMD64_YMM27, X86::YMM27},
      {codeview::RegisterId::AMD64_YMM28, X86::YMM28},
      {codeview::RegisterId::AMD64_YMM29, X86::YMM29},
      {codeview::RegisterId::AMD64_YMM30, X86::YMM30},
      {codeview::RegisterId::AMD64_YMM31, X86::YMM31},
      {codeview::RegisterId::AMD64_ZMM0, X86::ZMM0},
      {codeview::RegisterId::AMD64_ZMM1, X86::ZMM1},
      {codeview::RegisterId::AMD64_ZMM2, X86::ZMM2},
      {codeview::RegisterId::AMD64_ZMM3, X86::ZMM3},
      {codeview::RegisterId::AMD64_ZMM4, X86::ZMM4},
      {codeview::RegisterId::AMD64_ZMM5, X86::ZMM5},
      {codeview::RegisterId::AMD64_ZMM6, X86::ZMM6},
      {codeview::RegisterId::AMD64_ZMM7, X86::ZMM7},
      {codeview::RegisterId::AMD64_ZMM8, X86::ZMM8},
      {codeview::RegisterId::AMD64_ZMM9, X86::ZMM9},
      {codeview::RegisterId::AMD64_ZMM10, X86::ZMM10},
      {codeview::RegisterId::AMD64_ZMM11, X86::ZMM11},
      {codeview::RegisterId::AMD64_ZMM12, X86::ZMM12},
      {codeview::RegisterId::AMD64_ZMM13, X86::ZMM13},
      {codeview::RegisterId::AMD64_ZMM14, X86::ZMM14},
      {codeview::RegisterId::AMD64_ZMM15, X86::ZMM15},
      {codeview::RegisterId::AMD64_ZMM16, X86::ZMM16},
      {codeview::RegisterId::AMD64_ZMM17, X86::ZMM17},
      {codeview::RegisterId::AMD64_ZMM18, X86::ZMM18},
      {codeview::RegisterId::AMD64_ZMM19, X86::ZMM19},
      {codeview::RegisterId::AMD64_ZMM20, X86::ZMM20},
      {codeview::RegisterId::AMD64_ZMM21, X86::ZMM21},
      {codeview::RegisterId::AMD64_ZMM22, X86::ZMM22},
      {codeview::RegisterId::AMD64_ZMM23, X86::ZMM23},
      {codeview::RegisterId::AMD64_ZMM24, X86::ZMM24},
      {codeview::RegisterId::AMD64_ZMM25, X86::ZMM25},
      {codeview::RegisterId::AMD64_ZMM26, X86::ZMM26},
      {codeview::RegisterId::AMD64_ZMM27, X86::ZMM27},
      {codeview::RegisterId::AMD64_ZMM28, X86::ZMM28},
      {codeview::RegisterId::AMD64_ZMM29, X86::ZMM29},
      {codeview::RegisterId::AMD64_ZMM30, X86::ZMM30},
      {codeview::RegisterId::AMD64_ZMM31, X86::ZMM31},
      {codeview::RegisterId::AMD64_K0, X86::K0},
      {codeview::RegisterId::AMD64_K1, X86::K1},
      {codeview::RegisterId::AMD64_K2, X86::K2},
      {codeview::RegisterId::AMD64_K3, X86::K3},
      {codeview::RegisterId::AMD64_K4, X86::K4},
      {codeview::RegisterId::AMD64_K5, X86::K5},
      {codeview::RegisterId::AMD64_K6, X86::K6},
      {codeview::RegisterId::AMD64_K7, X86::K7},
      {codeview::RegisterId::AMD64_XMM16, X86::XMM16},
      {codeview::RegisterId::AMD64_XMM17, X86::XMM17},
      {codeview::RegisterId::AMD64_XMM18, X86::XMM18},
      {codeview::RegisterId::AMD64_XMM19, X86::XMM19},
      {codeview::RegisterId::AMD64_XMM20, X86::XMM20},
      {codeview::RegisterId::AMD64_XMM21, X86::XMM21},
      {codeview::RegisterId::AMD64_XMM22, X86::XMM22},
      {codeview::RegisterId::AMD64_XMM23, X86::XMM23},
      {codeview::RegisterId::AMD64_XMM24, X86::XMM24},
      {codeview::RegisterId::AMD64_XMM25, X86::XMM25},
      {codeview::RegisterId::AMD64_XMM26, X86::XMM26},
      {codeview::RegisterId::AMD64_XMM27, X86::XMM27},
      {codeview::RegisterId::AMD64_XMM28, X86::XMM28},
      {codeview::RegisterId::AMD64_XMM29, X86::XMM29},
      {codeview::RegisterId::AMD64_XMM30, X86::XMM30},
      {codeview::RegisterId::AMD64_XMM31, X86::XMM31},
 
  };
  for (const auto &I : RegMap)
    MRI->mapLLVMRegToCVReg(I.Reg, static_cast<int>(I.CVReg));
}
 
MCSubtargetInfo *X86_MC::createX86MCSubtargetInfo(const Triple &TT,
                                                  StringRef CPU, StringRef FS) {
  std::string ArchFS = X86_MC::ParseX86Triple(TT);
  assert(!ArchFS.empty() && "Failed to parse X86 triple");
  if (!FS.empty())
    ArchFS = (Twine(ArchFS) + "," + FS).str();
 
  if (CPU.empty())
    CPU = "generic";
 
  return createX86MCSubtargetInfoImpl(TT, CPU, /*TuneCPU*/ CPU, ArchFS);
}
 
static MCInstrInfo *createX86MCInstrInfo() {
  MCInstrInfo *X = new MCInstrInfo();
  InitX86MCInstrInfo(X);
  return X;
}
 
static MCRegisterInfo *createX86MCRegisterInfo(const Triple &TT) {
  unsigned RA = TT.isX86_64() ? X86::RIP  // Should have dwarf #16.
                              : X86::EIP; // Should have dwarf #8.
 
  MCRegisterInfo *X = new MCRegisterInfo();
  InitX86MCRegisterInfo(X, RA, X86_MC::getDwarfRegFlavour(TT, false),
                        X86_MC::getDwarfRegFlavour(TT, true), RA);
  X86_MC::initLLVMToSEHAndCVRegMapping(X);
  return X;
}
 
static void populateReservedIdentifiers(MCAsmInfo &MAI,
                                        const MCRegisterInfo &MRI) {
  auto &Set = MAI.getReservedIdentifiers();
  // Register names: `call rsi` is misassembled as an indirect call. Use the
  // Intel printer's table directly — it's the lowercase asm name in stable
  // storage. MRI::getName() returns the uppercase enum name and would need
  // an extra .lower() heap allocation per entry.
  for (unsigned i = 1, e = MRI.getNumRegs(); i < e; ++i)
    if (const char *Name = X86IntelInstPrinter::getRegisterName(i))
      if (Name[0])
        Set.insert(CachedHashStringRef(Name));
  // Keywords that GAS Intel syntax misparses as constants, modifiers, or
  // pseudo-registers instead of symbol references (e.g., `call byte` calls
  // address 1, not symbol "byte"; `call flat` errors out).
  for (StringRef KW : {"byte", "word", "dword", "fword", "qword", "mmword",
                       "tbyte", "oword", "xmmword", "ymmword", "zmmword",
                       "offset", "flat", "near", "far", "short"})
    Set.insert(CachedHashStringRef(KW));
  // Operator keywords parsed by GAS/X86AsmParser in Intel mode.
  for (StringRef KW : {"and", "eq", "ge", "gt", "le", "lt", "mod", "ne", "not",
                       "or", "shl", "shr", "xor"})
    Set.insert(CachedHashStringRef(KW));
}
 
static MCAsmInfo *createX86MCAsmInfo(const MCRegisterInfo &MRI,
                                     const Triple &TheTriple,
                                     const MCTargetOptions &Options) {
  bool is64Bit = TheTriple.isX86_64();
 
  MCAsmInfo *MAI;
  if (TheTriple.isOSBinFormatMachO()) {
    if (is64Bit)
      MAI = new X86_64MCAsmInfoDarwin(TheTriple, Options);
    else
      MAI = new X86MCAsmInfoDarwin(TheTriple, Options);
  } else if (TheTriple.isOSBinFormatELF()) {
    // Force the use of an ELF container.
    MAI = new X86ELFMCAsmInfo(TheTriple, Options);
  } else if (TheTriple.isWindowsMSVCEnvironment() ||
             TheTriple.isWindowsCoreCLREnvironment() || TheTriple.isUEFI()) {
    if (Options.getAssemblyLanguage().equals_insensitive("masm"))
      MAI = new X86MCAsmInfoMicrosoftMASM(TheTriple, Options);
    else
      MAI = new X86MCAsmInfoMicrosoft(TheTriple, Options);
  } else if (TheTriple.isOSCygMing() ||
             TheTriple.isWindowsItaniumEnvironment()) {
    MAI = new X86MCAsmInfoGNUCOFF(TheTriple, Options);
  } else {
    // The default is ELF.
    MAI = new X86ELFMCAsmInfo(TheTriple, Options);
  }
  populateReservedIdentifiers(*MAI, MRI);
 
  // Initialize initial frame state.
  // Calculate amount of bytes used for return address storing
  int stackGrowth = is64Bit ? -8 : -4;
 
  // Initial state of the frame pointer is esp+stackGrowth.
  unsigned StackPtr = is64Bit ? X86::RSP : X86::ESP;
  MCCFIInstruction Inst = MCCFIInstruction::cfiDefCfa(
      nullptr, MRI.getDwarfRegNum(StackPtr, true), -stackGrowth);
  MAI->addInitialFrameState(Inst);
 
  // Add return address to move list
  unsigned InstPtr = is64Bit ? X86::RIP : X86::EIP;
  MCCFIInstruction Inst2 = MCCFIInstruction::createOffset(
      nullptr, MRI.getDwarfRegNum(InstPtr, true), stackGrowth);
  MAI->addInitialFrameState(Inst2);
 
  return MAI;
}
 
static MCInstPrinter *createX86MCInstPrinter(const Triple &T,
                                             unsigned SyntaxVariant,
                                             const MCAsmInfo &MAI,
                                             const MCInstrInfo &MII,
                                             const MCRegisterInfo &MRI) {
  if (SyntaxVariant == 0)
    return new X86ATTInstPrinter(MAI, MII, MRI);
  if (SyntaxVariant == 1)
    return new X86IntelInstPrinter(MAI, MII, MRI);
  return nullptr;
}
 
static MCRelocationInfo *createX86MCRelocationInfo(const Triple &TheTriple,
                                                   MCContext &Ctx) {
  // Default to the stock relocation info.
  return llvm::createMCRelocationInfo(TheTriple, Ctx);
}
 
namespace llvm {
namespace X86_MC {
 
class X86MCInstrAnalysis : public MCInstrAnalysis {
  X86MCInstrAnalysis(const X86MCInstrAnalysis &) = delete;
  X86MCInstrAnalysis &operator=(const X86MCInstrAnalysis &) = delete;
  ~X86MCInstrAnalysis() override = default;
 
public:
  X86MCInstrAnalysis(const MCInstrInfo *MCII) : MCInstrAnalysis(MCII) {}
 
#define GET_STIPREDICATE_DECLS_FOR_MC_ANALYSIS
#include "X86GenSubtargetInfo.inc"
 
  bool clearsSuperRegisters(const MCRegisterInfo &MRI, const MCInst &Inst,
                            APInt &Mask) const override;
  std::vector<std::pair<uint64_t, uint64_t>>
  findPltEntries(uint64_t PltSectionVA, ArrayRef<uint8_t> PltContents,
                 const MCSubtargetInfo &STI) const override;
 
  bool evaluateBranch(const MCInst &Inst, uint64_t Addr, uint64_t Size,
                      uint64_t &Target) const override;
  std::optional<uint64_t>
  evaluateMemoryOperandAddress(const MCInst &Inst, const MCSubtargetInfo *STI,
                               uint64_t Addr, uint64_t Size) const override;
  std::optional<uint64_t>
  getMemoryOperandRelocationOffset(const MCInst &Inst,
                                   uint64_t Size) const override;
};
 
#define GET_STIPREDICATE_DEFS_FOR_MC_ANALYSIS
#include "X86GenSubtargetInfo.inc"
 
bool X86MCInstrAnalysis::clearsSuperRegisters(const MCRegisterInfo &MRI,
                                              const MCInst &Inst,
                                              APInt &Mask) const {
  const MCInstrDesc &Desc = Info->get(Inst.getOpcode());
  unsigned NumDefs = Desc.getNumDefs();
  unsigned NumImplicitDefs = Desc.implicit_defs().size();
  assert(Mask.getBitWidth() == NumDefs + NumImplicitDefs &&
         "Unexpected number of bits in the mask!");
 
  bool HasVEX = (Desc.TSFlags & X86II::EncodingMask) == X86II::VEX;
  bool HasEVEX = (Desc.TSFlags & X86II::EncodingMask) == X86II::EVEX;
  bool HasXOP = (Desc.TSFlags & X86II::EncodingMask) == X86II::XOP;
 
  const MCRegisterClass &GR32RC = MRI.getRegClass(X86::GR32RegClassID);
  const MCRegisterClass &VR128XRC = MRI.getRegClass(X86::VR128XRegClassID);
  const MCRegisterClass &VR256XRC = MRI.getRegClass(X86::VR256XRegClassID);
 
  auto ClearsSuperReg = [=](MCRegister RegID) {
    // On X86-64, a general purpose integer register is viewed as a 64-bit
    // register internal to the processor.
    // An update to the lower 32 bits of a 64 bit integer register is
    // architecturally defined to zero extend the upper 32 bits.
    if (GR32RC.contains(RegID))
      return true;
 
    // Early exit if this instruction has no vex/evex/xop prefix.
    if (!HasEVEX && !HasVEX && !HasXOP)
      return false;
 
    // All VEX and EVEX encoded instructions are defined to zero the high bits
    // of the destination register up to VLMAX (i.e. the maximum vector register
    // width pertaining to the instruction).
    // We assume the same behavior for XOP instructions too.
    return VR128XRC.contains(RegID) || VR256XRC.contains(RegID);
  };
 
  Mask.clearAllBits();
  for (unsigned I = 0, E = NumDefs; I < E; ++I) {
    const MCOperand &Op = Inst.getOperand(I);
    if (ClearsSuperReg(Op.getReg()))
      Mask.setBit(I);
  }
 
  for (unsigned I = 0, E = NumImplicitDefs; I < E; ++I) {
    const MCPhysReg Reg = Desc.implicit_defs()[I];
    if (ClearsSuperReg(Reg))
      Mask.setBit(NumDefs + I);
  }
 
  return Mask.getBoolValue();
}
 
static std::vector<std::pair<uint64_t, uint64_t>>
findX86PltEntries(uint64_t PltSectionVA, ArrayRef<uint8_t> PltContents) {
  // Do a lightweight parsing of PLT entries.
  std::vector<std::pair<uint64_t, uint64_t>> Result;
  for (uint64_t Byte = 0, End = PltContents.size(); Byte + 6 < End; ) {
    // Recognize a jmp.
    if (PltContents[Byte] == 0xff && PltContents[Byte + 1] == 0xa3) {
      // The jmp instruction at the beginning of each PLT entry jumps to the
      // address of the base of the .got.plt section plus the immediate.
      // Set the 1 << 32 bit to let ELFObjectFileBase::getPltEntries convert the
      // offset to an address. Imm may be a negative int32_t if the GOT entry is
      // in .got.
      uint32_t Imm = support::endian::read32le(PltContents.data() + Byte + 2);
      Result.emplace_back(PltSectionVA + Byte, Imm | (uint64_t(1) << 32));
      Byte += 6;
    } else if (PltContents[Byte] == 0xff && PltContents[Byte + 1] == 0x25) {
      // The jmp instruction at the beginning of each PLT entry jumps to the
      // immediate.
      uint32_t Imm = support::endian::read32le(PltContents.data() + Byte + 2);
      Result.push_back(std::make_pair(PltSectionVA + Byte, Imm));
      Byte += 6;
    } else
      Byte++;
  }
  return Result;
}
 
static std::vector<std::pair<uint64_t, uint64_t>>
findX86_64PltEntries(uint64_t PltSectionVA, ArrayRef<uint8_t> PltContents) {
  // Do a lightweight parsing of PLT entries.
  std::vector<std::pair<uint64_t, uint64_t>> Result;
  for (uint64_t Byte = 0, End = PltContents.size(); Byte + 6 < End; ) {
    // Recognize a jmp.
    if (PltContents[Byte] == 0xff && PltContents[Byte + 1] == 0x25) {
      // The jmp instruction at the beginning of each PLT entry jumps to the
      // address of the next instruction plus the immediate.
      uint32_t Imm = support::endian::read32le(PltContents.data() + Byte + 2);
      Result.push_back(
          std::make_pair(PltSectionVA + Byte, PltSectionVA + Byte + 6 + Imm));
      Byte += 6;
    } else
      Byte++;
  }
  return Result;
}
 
std::vector<std::pair<uint64_t, uint64_t>>
X86MCInstrAnalysis::findPltEntries(uint64_t PltSectionVA,
                                   ArrayRef<uint8_t> PltContents,
                                   const MCSubtargetInfo &STI) const {
  const Triple &TargetTriple = STI.getTargetTriple();
  switch (TargetTriple.getArch()) {
  case Triple::x86:
    return findX86PltEntries(PltSectionVA, PltContents);
  case Triple::x86_64:
    return findX86_64PltEntries(PltSectionVA, PltContents);
  default:
    return {};
  }
}
 
bool X86MCInstrAnalysis::evaluateBranch(const MCInst &Inst, uint64_t Addr,
                                        uint64_t Size, uint64_t &Target) const {
  if (Inst.getNumOperands() == 0 ||
      Info->get(Inst.getOpcode()).operands()[0].OperandType !=
          MCOI::OPERAND_PCREL)
    return false;
  Target = Addr + Size + Inst.getOperand(0).getImm();
  return true;
}
 
std::optional<uint64_t> X86MCInstrAnalysis::evaluateMemoryOperandAddress(
    const MCInst &Inst, const MCSubtargetInfo *STI, uint64_t Addr,
    uint64_t Size) const {
  const MCInstrDesc &MCID = Info->get(Inst.getOpcode());
  int MemOpStart = X86II::getMemoryOperandNo(MCID.TSFlags);
  if (MemOpStart == -1)
    return std::nullopt;
  MemOpStart += X86II::getOperandBias(MCID);
 
  const MCOperand &SegReg = Inst.getOperand(MemOpStart + X86::AddrSegmentReg);
  const MCOperand &BaseReg = Inst.getOperand(MemOpStart + X86::AddrBaseReg);
  const MCOperand &IndexReg = Inst.getOperand(MemOpStart + X86::AddrIndexReg);
  const MCOperand &ScaleAmt = Inst.getOperand(MemOpStart + X86::AddrScaleAmt);
  const MCOperand &Disp = Inst.getOperand(MemOpStart + X86::AddrDisp);
  if (SegReg.getReg() || IndexReg.getReg() || ScaleAmt.getImm() != 1 ||
      !Disp.isImm())
    return std::nullopt;
 
  // RIP-relative addressing.
  if (BaseReg.getReg() == X86::RIP)
    return Addr + Size + Disp.getImm();
 
  return std::nullopt;
}
 
std::optional<uint64_t>
X86MCInstrAnalysis::getMemoryOperandRelocationOffset(const MCInst &Inst,
                                                     uint64_t Size) const {
  if (Inst.getOpcode() != X86::LEA64r)
    return std::nullopt;
  const MCInstrDesc &MCID = Info->get(Inst.getOpcode());
  int MemOpStart = X86II::getMemoryOperandNo(MCID.TSFlags);
  if (MemOpStart == -1)
    return std::nullopt;
  MemOpStart += X86II::getOperandBias(MCID);
  const MCOperand &SegReg = Inst.getOperand(MemOpStart + X86::AddrSegmentReg);
  const MCOperand &BaseReg = Inst.getOperand(MemOpStart + X86::AddrBaseReg);
  const MCOperand &IndexReg = Inst.getOperand(MemOpStart + X86::AddrIndexReg);
  const MCOperand &ScaleAmt = Inst.getOperand(MemOpStart + X86::AddrScaleAmt);
  const MCOperand &Disp = Inst.getOperand(MemOpStart + X86::AddrDisp);
  // Must be a simple rip-relative address.
  if (BaseReg.getReg() != X86::RIP || SegReg.getReg() || IndexReg.getReg() ||
      ScaleAmt.getImm() != 1 || !Disp.isImm())
    return std::nullopt;
  // rip-relative ModR/M immediate is 32 bits.
  assert(Size > 4 && "invalid instruction size for rip-relative lea");
  return Size - 4;
}
 
} // end of namespace X86_MC
 
} // end of namespace llvm
 
static MCInstrAnalysis *createX86MCInstrAnalysis(const MCInstrInfo *Info) {
  return new X86_MC::X86MCInstrAnalysis(Info);
}
 
// Force static initialization.
extern "C" LLVM_C_ABI void LLVMInitializeX86TargetMC() {
  for (Target *T : {&getTheX86_32Target(), &getTheX86_64Target()}) {
    // Register the MC asm info.
    RegisterMCAsmInfoFn X(*T, createX86MCAsmInfo);
 
    // Register the MC instruction info.
    TargetRegistry::RegisterMCInstrInfo(*T, createX86MCInstrInfo);
 
    // Register the MC register info.
    TargetRegistry::RegisterMCRegInfo(*T, createX86MCRegisterInfo);
 
    // Register the MC subtarget info.
    TargetRegistry::RegisterMCSubtargetInfo(*T,
                                            X86_MC::createX86MCSubtargetInfo);
 
    // Register the MC instruction analyzer.
    TargetRegistry::RegisterMCInstrAnalysis(*T, createX86MCInstrAnalysis);
 
    // Register the code emitter.
    TargetRegistry::RegisterMCCodeEmitter(*T, createX86MCCodeEmitter);
 
    // Register the obj target streamer.
    TargetRegistry::RegisterObjectTargetStreamer(*T,
                                                 createX86ObjectTargetStreamer);
 
    // Register the asm target streamer.
    TargetRegistry::RegisterAsmTargetStreamer(*T, createX86AsmTargetStreamer);
 
    // Register the null streamer.
    TargetRegistry::RegisterNullTargetStreamer(*T, createX86NullTargetStreamer);
 
    TargetRegistry::RegisterCOFFStreamer(*T, createX86WinCOFFStreamer);
    TargetRegistry::RegisterELFStreamer(*T, createX86ELFStreamer);
 
    // Register the MCInstPrinter.
    TargetRegistry::RegisterMCInstPrinter(*T, createX86MCInstPrinter);
 
    // Register the MC relocation info.
    TargetRegistry::RegisterMCRelocationInfo(*T, createX86MCRelocationInfo);
  }
 
  // Register the asm backend.
  TargetRegistry::RegisterMCAsmBackend(getTheX86_32Target(),
                                       createX86_32AsmBackend);
  TargetRegistry::RegisterMCAsmBackend(getTheX86_64Target(),
                                       createX86_64AsmBackend);
}
 
MCRegister llvm::getX86SubSuperRegister(MCRegister Reg, unsigned Size,
                                        bool High) {
#define DEFAULT_NOREG                                                          \
  default:                                                                     \
    return X86::NoRegister;
#define SUB_SUPER(R1, R2, R3, R4, R)                                           \
  case X86::R1:                                                                \
  case X86::R2:                                                                \
  case X86::R3:                                                                \
  case X86::R4:                                                                \
    return X86::R;
#define A_SUB_SUPER(R)                                                         \
  case X86::AH:                                                                \
    SUB_SUPER(AL, AX, EAX, RAX, R)
#define D_SUB_SUPER(R)                                                         \
  case X86::DH:                                                                \
    SUB_SUPER(DL, DX, EDX, RDX, R)
#define C_SUB_SUPER(R)                                                         \
  case X86::CH:                                                                \
    SUB_SUPER(CL, CX, ECX, RCX, R)
#define B_SUB_SUPER(R)                                                         \
  case X86::BH:                                                                \
    SUB_SUPER(BL, BX, EBX, RBX, R)
#define SI_SUB_SUPER(R) SUB_SUPER(SIL, SI, ESI, RSI, R)
#define DI_SUB_SUPER(R) SUB_SUPER(DIL, DI, EDI, RDI, R)
#define BP_SUB_SUPER(R) SUB_SUPER(BPL, BP, EBP, RBP, R)
#define SP_SUB_SUPER(R) SUB_SUPER(SPL, SP, ESP, RSP, R)
#define NO_SUB_SUPER(NO, REG)                                                  \
  SUB_SUPER(R##NO##B, R##NO##W, R##NO##D, R##NO, REG)
#define NO_SUB_SUPER_B(NO) NO_SUB_SUPER(NO, R##NO##B)
#define NO_SUB_SUPER_W(NO) NO_SUB_SUPER(NO, R##NO##W)
#define NO_SUB_SUPER_D(NO) NO_SUB_SUPER(NO, R##NO##D)
#define NO_SUB_SUPER_Q(NO) NO_SUB_SUPER(NO, R##NO)
  switch (Size) {
  default:
    llvm_unreachable("illegal register size");
  case 8:
    if (High) {
      switch (Reg.id()) {
        DEFAULT_NOREG
        A_SUB_SUPER(AH)
        D_SUB_SUPER(DH)
        C_SUB_SUPER(CH)
        B_SUB_SUPER(BH)
      }
    } else {
      switch (Reg.id()) {
        DEFAULT_NOREG
        A_SUB_SUPER(AL)
        D_SUB_SUPER(DL)
        C_SUB_SUPER(CL)
        B_SUB_SUPER(BL)
        SI_SUB_SUPER(SIL)
        DI_SUB_SUPER(DIL)
        BP_SUB_SUPER(BPL)
        SP_SUB_SUPER(SPL)
        NO_SUB_SUPER_B(8)
        NO_SUB_SUPER_B(9)
        NO_SUB_SUPER_B(10)
        NO_SUB_SUPER_B(11)
        NO_SUB_SUPER_B(12)
        NO_SUB_SUPER_B(13)
        NO_SUB_SUPER_B(14)
        NO_SUB_SUPER_B(15)
        NO_SUB_SUPER_B(16)
        NO_SUB_SUPER_B(17)
        NO_SUB_SUPER_B(18)
        NO_SUB_SUPER_B(19)
        NO_SUB_SUPER_B(20)
        NO_SUB_SUPER_B(21)
        NO_SUB_SUPER_B(22)
        NO_SUB_SUPER_B(23)
        NO_SUB_SUPER_B(24)
        NO_SUB_SUPER_B(25)
        NO_SUB_SUPER_B(26)
        NO_SUB_SUPER_B(27)
        NO_SUB_SUPER_B(28)
        NO_SUB_SUPER_B(29)
        NO_SUB_SUPER_B(30)
        NO_SUB_SUPER_B(31)
      }
    }
  case 16:
    switch (Reg.id()) {
      DEFAULT_NOREG
      A_SUB_SUPER(AX)
      D_SUB_SUPER(DX)
      C_SUB_SUPER(CX)
      B_SUB_SUPER(BX)
      SI_SUB_SUPER(SI)
      DI_SUB_SUPER(DI)
      BP_SUB_SUPER(BP)
      SP_SUB_SUPER(SP)
      NO_SUB_SUPER_W(8)
      NO_SUB_SUPER_W(9)
      NO_SUB_SUPER_W(10)
      NO_SUB_SUPER_W(11)
      NO_SUB_SUPER_W(12)
      NO_SUB_SUPER_W(13)
      NO_SUB_SUPER_W(14)
      NO_SUB_SUPER_W(15)
      NO_SUB_SUPER_W(16)
      NO_SUB_SUPER_W(17)
      NO_SUB_SUPER_W(18)
      NO_SUB_SUPER_W(19)
      NO_SUB_SUPER_W(20)
      NO_SUB_SUPER_W(21)
      NO_SUB_SUPER_W(22)
      NO_SUB_SUPER_W(23)
      NO_SUB_SUPER_W(24)
      NO_SUB_SUPER_W(25)
      NO_SUB_SUPER_W(26)
      NO_SUB_SUPER_W(27)
      NO_SUB_SUPER_W(28)
      NO_SUB_SUPER_W(29)
      NO_SUB_SUPER_W(30)
      NO_SUB_SUPER_W(31)
    }
  case 32:
    switch (Reg.id()) {
      DEFAULT_NOREG
      A_SUB_SUPER(EAX)
      D_SUB_SUPER(EDX)
      C_SUB_SUPER(ECX)
      B_SUB_SUPER(EBX)
      SI_SUB_SUPER(ESI)
      DI_SUB_SUPER(EDI)
      BP_SUB_SUPER(EBP)
      SP_SUB_SUPER(ESP)
      NO_SUB_SUPER_D(8)
      NO_SUB_SUPER_D(9)
      NO_SUB_SUPER_D(10)
      NO_SUB_SUPER_D(11)
      NO_SUB_SUPER_D(12)
      NO_SUB_SUPER_D(13)
      NO_SUB_SUPER_D(14)
      NO_SUB_SUPER_D(15)
      NO_SUB_SUPER_D(16)
      NO_SUB_SUPER_D(17)
      NO_SUB_SUPER_D(18)
      NO_SUB_SUPER_D(19)
      NO_SUB_SUPER_D(20)
      NO_SUB_SUPER_D(21)
      NO_SUB_SUPER_D(22)
      NO_SUB_SUPER_D(23)
      NO_SUB_SUPER_D(24)
      NO_SUB_SUPER_D(25)
      NO_SUB_SUPER_D(26)
      NO_SUB_SUPER_D(27)
      NO_SUB_SUPER_D(28)
      NO_SUB_SUPER_D(29)
      NO_SUB_SUPER_D(30)
      NO_SUB_SUPER_D(31)
    }
  case 64:
    switch (Reg.id()) {
      DEFAULT_NOREG
      A_SUB_SUPER(RAX)
      D_SUB_SUPER(RDX)
      C_SUB_SUPER(RCX)
      B_SUB_SUPER(RBX)
      SI_SUB_SUPER(RSI)
      DI_SUB_SUPER(RDI)
      BP_SUB_SUPER(RBP)
      SP_SUB_SUPER(RSP)
      NO_SUB_SUPER_Q(8)
      NO_SUB_SUPER_Q(9)
      NO_SUB_SUPER_Q(10)
      NO_SUB_SUPER_Q(11)
      NO_SUB_SUPER_Q(12)
      NO_SUB_SUPER_Q(13)
      NO_SUB_SUPER_Q(14)
      NO_SUB_SUPER_Q(15)
      NO_SUB_SUPER_Q(16)
      NO_SUB_SUPER_Q(17)
      NO_SUB_SUPER_Q(18)
      NO_SUB_SUPER_Q(19)
      NO_SUB_SUPER_Q(20)
      NO_SUB_SUPER_Q(21)
      NO_SUB_SUPER_Q(22)
      NO_SUB_SUPER_Q(23)
      NO_SUB_SUPER_Q(24)
      NO_SUB_SUPER_Q(25)
      NO_SUB_SUPER_Q(26)
      NO_SUB_SUPER_Q(27)
      NO_SUB_SUPER_Q(28)
      NO_SUB_SUPER_Q(29)
      NO_SUB_SUPER_Q(30)
      NO_SUB_SUPER_Q(31)
    }
  }
}