//===-- X86Disassembler.cpp - Disassembler for x86 and x86_64 -------------===//

//

//                     The LLVM Compiler Infrastructure

//

// This file is distributed under the University of Illinois Open Source

// License. See LICENSE.TXT for details.

//

//===----------------------------------------------------------------------===//

//

// This file is part of the X86 Disassembler.

// It contains code to translate the data produced by the decoder into

//  MCInsts.

//

// The X86 disassembler is a table-driven disassembler for the 16-, 32-, and

// 64-bit X86 instruction sets.  The main decode sequence for an assembly

// instruction in this disassembler is:

//

// 1. Read the prefix bytes and determine the attributes of the instruction.

//    These attributes, recorded in enum attributeBits

//    (X86DisassemblerDecoderCommon.h), form a bitmask.  The table CONTEXTS_SYM

//    provides a mapping from bitmasks to contexts, which are represented by

//    enum InstructionContext (ibid.).

//

// 2. Read the opcode, and determine what kind of opcode it is.  The

//    disassembler distinguishes four kinds of opcodes, which are enumerated in

//    OpcodeType (X86DisassemblerDecoderCommon.h): one-byte (0xnn), two-byte

//    (0x0f 0xnn), three-byte-38 (0x0f 0x38 0xnn), or three-byte-3a

//    (0x0f 0x3a 0xnn).  Mandatory prefixes are treated as part of the context.

//

// 3. Depending on the opcode type, look in one of four ClassDecision structures

//    (X86DisassemblerDecoderCommon.h).  Use the opcode class to determine which

//    OpcodeDecision (ibid.) to look the opcode in.  Look up the opcode, to get

//    a ModRMDecision (ibid.).

//

// 4. Some instructions, such as escape opcodes or extended opcodes, or even

//    instructions that have ModRM*Reg / ModRM*Mem forms in LLVM, need the

//    ModR/M byte to complete decode.  The ModRMDecision's type is an entry from

//    ModRMDecisionType (X86DisassemblerDecoderCommon.h) that indicates if the

//    ModR/M byte is required and how to interpret it.

//

// 5. After resolving the ModRMDecision, the disassembler has a unique ID

//    of type InstrUID (X86DisassemblerDecoderCommon.h).  Looking this ID up in

//    INSTRUCTIONS_SYM yields the name of the instruction and the encodings and

//    meanings of its operands.

//

// 6. For each operand, its encoding is an entry from OperandEncoding

//    (X86DisassemblerDecoderCommon.h) and its type is an entry from

//    OperandType (ibid.).  The encoding indicates how to read it from the

//    instruction; the type indicates how to interpret the value once it has

//    been read.  For example, a register operand could be stored in the R/M

//    field of the ModR/M byte, the REG field of the ModR/M byte, or added to

//    the main opcode.  This is orthogonal from its meaning (an GPR or an XMM

//    register, for instance).  Given this information, the operands can be

//    extracted and interpreted.

//

// 7. As the last step, the disassembler translates the instruction information

//    and operands into a format understandable by the client - in this case, an

//    MCInst for use by the MC infrastructure.

//

// The disassembler is broken broadly into two parts: the table emitter that

// emits the instruction decode tables discussed above during compilation, and

// the disassembler itself.  The table emitter is documented in more detail in

// utils/TableGen/X86DisassemblerEmitter.h.

//

// X86Disassembler.cpp contains the code responsible for step 7, and for

//   invoking the decoder to execute steps 1-6.

// X86DisassemblerDecoderCommon.h contains the definitions needed by both the

//   table emitter and the disassembler.

// X86DisassemblerDecoder.h contains the public interface of the decoder,

//   factored out into C for possible use by other projects.

// X86DisassemblerDecoder.c contains the source code of the decoder, which is

//   responsible for steps 1-6.

//

//===----------------------------------------------------------------------===//

/* Capstone Disassembly Engine */

/* By Nguyen Anh Quynh <aquynh@gmail.com>, 2013-2019 */

#ifdef CAPSTONE_HAS_X86

#ifdef _MSC_VER

// disable MSVC's warning on strncpy()

#pragma warning(disable : 4996)

// disable MSVC's warning on strncpy()

#pragma warning(disable : 28719)

#endif

#include <capstone/platform.h>

#if defined(CAPSTONE_HAS_OSXKERNEL)

#include <Availability.h>

#endif

#include <string.h>

#include "../../cs_priv.h"

#include "X86BaseInfo.h"

#include "X86Disassembler.h"

#include "X86DisassemblerDecoderCommon.h"

#include "X86DisassemblerDecoder.h"

#include "../../MCInst.h"

#include "../../utils.h"

#include "X86Mapping.h"

#define GET_REGINFO_ENUM

#define GET_REGINFO_MC_DESC

#include "X86GenRegisterInfo.inc"

#define GET_INSTRINFO_ENUM

#ifdef CAPSTONE_X86_REDUCE

#include "X86GenInstrInfo_reduce.inc"

#else

#include "X86GenInstrInfo.inc"

#endif

// Fill-ins to make the compiler happy.  These constants are never actually

//   assigned; they are just filler to make an automatically-generated switch

//   statement work.

enum {

  X86_BX_SI = 500,

  X86_BX_DI = 501,

  X86_BP_SI = 502,

  X86_BP_DI = 503,

  X86_sib = 504,

  X86_sib64 = 505

};

//

// Private code that translates from struct InternalInstructions to MCInsts.

//

/// translateRegister - Translates an internal register to the appropriate LLVM

///   register, and appends it as an operand to an MCInst.

///

/// @param mcInst     - The MCInst to append to.

/// @param reg        - The Reg to append.

static void translateRegister(MCInst *mcInst, Reg reg)

{

#define ENTRY(x) X86_##x,

  static const uint16_t llvmRegnums[] = { ALL_REGS 0 };

#undef ENTRY

  uint16_t llvmRegnum = llvmRegnums[reg];

  MCOperand_CreateReg0(mcInst, llvmRegnum);

}

static const uint8_t segmentRegnums[SEG_OVERRIDE_max] = {

  0, // SEG_OVERRIDE_NONE

  X86_CS, X86_SS, X86_DS, X86_ES, X86_FS, X86_GS

};

/// translateSrcIndex   - Appends a source index operand to an MCInst.

///

/// @param mcInst       - The MCInst to append to.

/// @param insn         - The internal instruction.

static bool translateSrcIndex(MCInst *mcInst, InternalInstruction *insn)

{

  unsigned baseRegNo;

  if (insn->mode == MODE_64BIT)

    baseRegNo = insn->hasAdSize ? X86_ESI : X86_RSI;

  else if (insn->mode == MODE_32BIT)

    baseRegNo = insn->hasAdSize ? X86_SI : X86_ESI;

  else {

    // assert(insn->mode == MODE_16BIT);

    baseRegNo = insn->hasAdSize ? X86_ESI : X86_SI;

  }

  MCOperand_CreateReg0(mcInst, baseRegNo);

  MCOperand_CreateReg0(mcInst, segmentRegnums[insn->segmentOverride]);

  return false;

}

/// translateDstIndex   - Appends a destination index operand to an MCInst.

///

/// @param mcInst       - The MCInst to append to.

/// @param insn         - The internal instruction.

static bool translateDstIndex(MCInst *mcInst, InternalInstruction *insn)

{

  unsigned baseRegNo;

  if (insn->mode == MODE_64BIT)

    baseRegNo = insn->hasAdSize ? X86_EDI : X86_RDI;

  else if (insn->mode == MODE_32BIT)

    baseRegNo = insn->hasAdSize ? X86_DI : X86_EDI;

  else {

    // assert(insn->mode == MODE_16BIT);

    baseRegNo = insn->hasAdSize ? X86_EDI : X86_DI;

  }

  MCOperand_CreateReg0(mcInst, baseRegNo);

  return false;

}

/// translateImmediate  - Appends an immediate operand to an MCInst.

///

/// @param mcInst       - The MCInst to append to.

/// @param immediate    - The immediate value to append.

/// @param operand      - The operand, as stored in the descriptor table.

/// @param insn         - The internal instruction.

static void translateImmediate(MCInst *mcInst, uint64_t immediate,

             const OperandSpecifier *operand,

             InternalInstruction *insn)

{

  OperandType type;

  type = (OperandType)operand->type;

  if (type == TYPE_REL) {

    //isBranch = true;

    //pcrel = insn->startLocation + insn->immediateOffset + insn->immediateSize;

    switch (operand->encoding) {

    default:

      break;

    case ENCODING_Iv:

      switch (insn->displacementSize) {

      default:

        break;

      case 1:

        if (immediate & 0x80)

          immediate |= ~(0xffull);

        break;

      case 2:

        if (immediate & 0x8000)

          immediate |= ~(0xffffull);

        break;

      case 4:

        if (immediate & 0x80000000)

          immediate |= ~(0xffffffffull);

        break;

      case 8:

        break;

      }

      break;

    case ENCODING_IB:

      if (immediate & 0x80)

        immediate |= ~(0xffull);

      break;

    case ENCODING_IW:

      if (immediate & 0x8000)

        immediate |= ~(0xffffull);

      break;

    case ENCODING_ID:

      if (immediate & 0x80000000)

        immediate |= ~(0xffffffffull);

      break;

    }

  } // By default sign-extend all X86 immediates based on their encoding.

  else if (type == TYPE_IMM) {

    switch (operand->encoding) {

    default:

      break;

    case ENCODING_IB:

      if (immediate & 0x80)

        immediate |= ~(0xffull);

      break;

    case ENCODING_IW:

      if (immediate & 0x8000)

        immediate |= ~(0xffffull);

      break;

    case ENCODING_ID:

      if (immediate & 0x80000000)

        immediate |= ~(0xffffffffull);

      break;

    case ENCODING_IO:

      break;

    }

  } else if (type == TYPE_IMM3) {

#ifndef CAPSTONE_X86_REDUCE

    // Check for immediates that printSSECC can't handle.

    if (immediate >= 8) {

      unsigned NewOpc = 0;

      switch (MCInst_getOpcode(mcInst)) {

      default:

        break; // never reach

      case X86_CMPPDrmi:

        NewOpc = X86_CMPPDrmi_alt;

        break;

      case X86_CMPPDrri:

        NewOpc = X86_CMPPDrri_alt;

        break;

      case X86_CMPPSrmi:

        NewOpc = X86_CMPPSrmi_alt;

        break;

      case X86_CMPPSrri:

        NewOpc = X86_CMPPSrri_alt;

        break;

      case X86_CMPSDrm:

        NewOpc = X86_CMPSDrm_alt;

        break;

      case X86_CMPSDrr:

        NewOpc = X86_CMPSDrr_alt;

        break;

      case X86_CMPSSrm:

        NewOpc = X86_CMPSSrm_alt;

        break;

      case X86_CMPSSrr:

        NewOpc = X86_CMPSSrr_alt;

        break;

      case X86_VPCOMBri:

        NewOpc = X86_VPCOMBri_alt;

        break;

      case X86_VPCOMBmi:

        NewOpc = X86_VPCOMBmi_alt;

        break;

      case X86_VPCOMWri:

        NewOpc = X86_VPCOMWri_alt;

        break;

      case X86_VPCOMWmi:

        NewOpc = X86_VPCOMWmi_alt;

        break;

      case X86_VPCOMDri:

        NewOpc = X86_VPCOMDri_alt;

        break;

      case X86_VPCOMDmi:

        NewOpc = X86_VPCOMDmi_alt;

        break;

      case X86_VPCOMQri:

        NewOpc = X86_VPCOMQri_alt;

        break;

      case X86_VPCOMQmi:

        NewOpc = X86_VPCOMQmi_alt;

        break;

      case X86_VPCOMUBri:

        NewOpc = X86_VPCOMUBri_alt;

        break;

      case X86_VPCOMUBmi:

        NewOpc = X86_VPCOMUBmi_alt;

        break;

      case X86_VPCOMUWri:

        NewOpc = X86_VPCOMUWri_alt;

        break;

      case X86_VPCOMUWmi:

        NewOpc = X86_VPCOMUWmi_alt;

        break;

      case X86_VPCOMUDri:

        NewOpc = X86_VPCOMUDri_alt;

        break;

      case X86_VPCOMUDmi:

        NewOpc = X86_VPCOMUDmi_alt;

        break;

      case X86_VPCOMUQri:

        NewOpc = X86_VPCOMUQri_alt;

        break;

      case X86_VPCOMUQmi:

        NewOpc = X86_VPCOMUQmi_alt;

        break;

      }

      // Switch opcode to the one that doesn't get special printing.

      if (NewOpc != 0) {

        MCInst_setOpcode(mcInst, NewOpc);

      }

    }

#endif

  } else if (type == TYPE_IMM5) {

#ifndef CAPSTONE_X86_REDUCE

    // Check for immediates that printAVXCC can't handle.

    if (immediate >= 32) {

      unsigned NewOpc = 0;

      switch (MCInst_getOpcode(mcInst)) {

      default:

        break; // unexpected opcode

      case X86_VCMPPDrmi:

        NewOpc = X86_VCMPPDrmi_alt;

        break;

      case X86_VCMPPDrri:

        NewOpc = X86_VCMPPDrri_alt;

        break;

      case X86_VCMPPSrmi:

        NewOpc = X86_VCMPPSrmi_alt;

        break;

      case X86_VCMPPSrri:

        NewOpc = X86_VCMPPSrri_alt;

        break;

      case X86_VCMPSDrm:

        NewOpc = X86_VCMPSDrm_alt;

        break;

      case X86_VCMPSDrr:

        NewOpc = X86_VCMPSDrr_alt;

        break;

      case X86_VCMPSSrm:

        NewOpc = X86_VCMPSSrm_alt;

        break;

      case X86_VCMPSSrr:

        NewOpc = X86_VCMPSSrr_alt;

        break;

      case X86_VCMPPDYrmi:

        NewOpc = X86_VCMPPDYrmi_alt;

        break;

      case X86_VCMPPDYrri:

        NewOpc = X86_VCMPPDYrri_alt;

        break;

      case X86_VCMPPSYrmi:

        NewOpc = X86_VCMPPSYrmi_alt;

        break;

      case X86_VCMPPSYrri:

        NewOpc = X86_VCMPPSYrri_alt;

        break;

      case X86_VCMPPDZrmi:

        NewOpc = X86_VCMPPDZrmi_alt;

        break;

      case X86_VCMPPDZrri:

        NewOpc = X86_VCMPPDZrri_alt;

        break;

      case X86_VCMPPDZrrib:

        NewOpc = X86_VCMPPDZrrib_alt;

        break;

      case X86_VCMPPSZrmi:

        NewOpc = X86_VCMPPSZrmi_alt;

        break;

      case X86_VCMPPSZrri:

        NewOpc = X86_VCMPPSZrri_alt;

        break;

      case X86_VCMPPSZrrib:

        NewOpc = X86_VCMPPSZrrib_alt;

        break;

      case X86_VCMPPDZ128rmi:

        NewOpc = X86_VCMPPDZ128rmi_alt;

        break;

      case X86_VCMPPDZ128rri:

        NewOpc = X86_VCMPPDZ128rri_alt;

        break;

      case X86_VCMPPSZ128rmi:

        NewOpc = X86_VCMPPSZ128rmi_alt;

        break;

      case X86_VCMPPSZ128rri:

        NewOpc = X86_VCMPPSZ128rri_alt;

        break;

      case X86_VCMPPDZ256rmi:

        NewOpc = X86_VCMPPDZ256rmi_alt;

        break;

      case X86_VCMPPDZ256rri:

        NewOpc = X86_VCMPPDZ256rri_alt;

        break;

      case X86_VCMPPSZ256rmi:

        NewOpc = X86_VCMPPSZ256rmi_alt;

        break;

      case X86_VCMPPSZ256rri:

        NewOpc = X86_VCMPPSZ256rri_alt;

        break;

      case X86_VCMPSDZrm_Int:

        NewOpc = X86_VCMPSDZrmi_alt;

        break;

      case X86_VCMPSDZrr_Int:

        NewOpc = X86_VCMPSDZrri_alt;

        break;

      case X86_VCMPSDZrrb_Int:

        NewOpc = X86_VCMPSDZrrb_alt;

        break;

      case X86_VCMPSSZrm_Int:

        NewOpc = X86_VCMPSSZrmi_alt;

        break;

      case X86_VCMPSSZrr_Int:

        NewOpc = X86_VCMPSSZrri_alt;

        break;

      case X86_VCMPSSZrrb_Int:

        NewOpc = X86_VCMPSSZrrb_alt;

        break;

      }

      // Switch opcode to the one that doesn't get special printing.

      if (NewOpc != 0) {

        MCInst_setOpcode(mcInst, NewOpc);

      }

    }

#endif

  } else if (type == TYPE_AVX512ICC) {

#ifndef CAPSTONE_X86_REDUCE

    if (immediate >= 8 || ((immediate & 0x3) == 3)) {

      unsigned NewOpc = 0;

      switch (MCInst_getOpcode(mcInst)) {

      default: // llvm_unreachable("unexpected opcode");

      case X86_VPCMPBZ128rmi:

        NewOpc = X86_VPCMPBZ128rmi_alt;

        break;

      case X86_VPCMPBZ128rmik:

        NewOpc = X86_VPCMPBZ128rmik_alt;

        break;

      case X86_VPCMPBZ128rri:

        NewOpc = X86_VPCMPBZ128rri_alt;

        break;

      case X86_VPCMPBZ128rrik:

        NewOpc = X86_VPCMPBZ128rrik_alt;

        break;

      case X86_VPCMPBZ256rmi:

        NewOpc = X86_VPCMPBZ256rmi_alt;

        break;

      case X86_VPCMPBZ256rmik:

        NewOpc = X86_VPCMPBZ256rmik_alt;

        break;

      case X86_VPCMPBZ256rri:

        NewOpc = X86_VPCMPBZ256rri_alt;

        break;

      case X86_VPCMPBZ256rrik:

        NewOpc = X86_VPCMPBZ256rrik_alt;

        break;

      case X86_VPCMPBZrmi:

        NewOpc = X86_VPCMPBZrmi_alt;

        break;

      case X86_VPCMPBZrmik:

        NewOpc = X86_VPCMPBZrmik_alt;

        break;

      case X86_VPCMPBZrri:

        NewOpc = X86_VPCMPBZrri_alt;

        break;

      case X86_VPCMPBZrrik:

        NewOpc = X86_VPCMPBZrrik_alt;

        break;

      case X86_VPCMPDZ128rmi:

        NewOpc = X86_VPCMPDZ128rmi_alt;

        break;

      case X86_VPCMPDZ128rmib:

        NewOpc = X86_VPCMPDZ128rmib_alt;

        break;

      case X86_VPCMPDZ128rmibk:

        NewOpc = X86_VPCMPDZ128rmibk_alt;

        break;

      case X86_VPCMPDZ128rmik:

        NewOpc = X86_VPCMPDZ128rmik_alt;

        break;

      case X86_VPCMPDZ128rri:

        NewOpc = X86_VPCMPDZ128rri_alt;

        break;

      case X86_VPCMPDZ128rrik:

        NewOpc = X86_VPCMPDZ128rrik_alt;

        break;

      case X86_VPCMPDZ256rmi:

        NewOpc = X86_VPCMPDZ256rmi_alt;

        break;

      case X86_VPCMPDZ256rmib:

        NewOpc = X86_VPCMPDZ256rmib_alt;

        break;

      case X86_VPCMPDZ256rmibk:

        NewOpc = X86_VPCMPDZ256rmibk_alt;

        break;

      case X86_VPCMPDZ256rmik:

        NewOpc = X86_VPCMPDZ256rmik_alt;

        break;

      case X86_VPCMPDZ256rri:

        NewOpc = X86_VPCMPDZ256rri_alt;

        break;

      case X86_VPCMPDZ256rrik:

        NewOpc = X86_VPCMPDZ256rrik_alt;

        break;

      case X86_VPCMPDZrmi:

        NewOpc = X86_VPCMPDZrmi_alt;

        break;

      case X86_VPCMPDZrmib:

        NewOpc = X86_VPCMPDZrmib_alt;

        break;

      case X86_VPCMPDZrmibk:

        NewOpc = X86_VPCMPDZrmibk_alt;

        break;

      case X86_VPCMPDZrmik:

        NewOpc = X86_VPCMPDZrmik_alt;

        break;

      case X86_VPCMPDZrri:

        NewOpc = X86_VPCMPDZrri_alt;

        break;

      case X86_VPCMPDZrrik:

        NewOpc = X86_VPCMPDZrrik_alt;

        break;

      case X86_VPCMPQZ128rmi:

        NewOpc = X86_VPCMPQZ128rmi_alt;

        break;

      case X86_VPCMPQZ128rmib:

        NewOpc = X86_VPCMPQZ128rmib_alt;

        break;

      case X86_VPCMPQZ128rmibk:

        NewOpc = X86_VPCMPQZ128rmibk_alt;

        break;

      case X86_VPCMPQZ128rmik:

        NewOpc = X86_VPCMPQZ128rmik_alt;

        break;

      case X86_VPCMPQZ128rri:

        NewOpc = X86_VPCMPQZ128rri_alt;

        break;

      case X86_VPCMPQZ128rrik:

        NewOpc = X86_VPCMPQZ128rrik_alt;

        break;

      case X86_VPCMPQZ256rmi:

        NewOpc = X86_VPCMPQZ256rmi_alt;

        break;

      case X86_VPCMPQZ256rmib:

        NewOpc = X86_VPCMPQZ256rmib_alt;

        break;

      case X86_VPCMPQZ256rmibk:

        NewOpc = X86_VPCMPQZ256rmibk_alt;

        break;

      case X86_VPCMPQZ256rmik:

        NewOpc = X86_VPCMPQZ256rmik_alt;

        break;

      case X86_VPCMPQZ256rri:

        NewOpc = X86_VPCMPQZ256rri_alt;

        break;

      case X86_VPCMPQZ256rrik:

        NewOpc = X86_VPCMPQZ256rrik_alt;

        break;

      case X86_VPCMPQZrmi:

        NewOpc = X86_VPCMPQZrmi_alt;

        break;

      case X86_VPCMPQZrmib:

        NewOpc = X86_VPCMPQZrmib_alt;

        break;

      case X86_VPCMPQZrmibk:

        NewOpc = X86_VPCMPQZrmibk_alt;

        break;

      case X86_VPCMPQZrmik:

        NewOpc = X86_VPCMPQZrmik_alt;

        break;

      case X86_VPCMPQZrri:

        NewOpc = X86_VPCMPQZrri_alt;

        break;

      case X86_VPCMPQZrrik:

        NewOpc = X86_VPCMPQZrrik_alt;

        break;

      case X86_VPCMPUBZ128rmi:

        NewOpc = X86_VPCMPUBZ128rmi_alt;

        break;

      case X86_VPCMPUBZ128rmik:

        NewOpc = X86_VPCMPUBZ128rmik_alt;

        break;

      case X86_VPCMPUBZ128rri:

        NewOpc = X86_VPCMPUBZ128rri_alt;

        break;

      case X86_VPCMPUBZ128rrik:

        NewOpc = X86_VPCMPUBZ128rrik_alt;

        break;

      case X86_VPCMPUBZ256rmi:

        NewOpc = X86_VPCMPUBZ256rmi_alt;

        break;

      case X86_VPCMPUBZ256rmik:

        NewOpc = X86_VPCMPUBZ256rmik_alt;

        break;

      case X86_VPCMPUBZ256rri:

        NewOpc = X86_VPCMPUBZ256rri_alt;

        break;

      case X86_VPCMPUBZ256rrik:

        NewOpc = X86_VPCMPUBZ256rrik_alt;

        break;

      case X86_VPCMPUBZrmi:

        NewOpc = X86_VPCMPUBZrmi_alt;

        break;

      case X86_VPCMPUBZrmik:

        NewOpc = X86_VPCMPUBZrmik_alt;

        break;

      case X86_VPCMPUBZrri:

        NewOpc = X86_VPCMPUBZrri_alt;

        break;

      case X86_VPCMPUBZrrik:

        NewOpc = X86_VPCMPUBZrrik_alt;

        break;

      case X86_VPCMPUDZ128rmi:

        NewOpc = X86_VPCMPUDZ128rmi_alt;

        break;

      case X86_VPCMPUDZ128rmib:

        NewOpc = X86_VPCMPUDZ128rmib_alt;

        break;

      case X86_VPCMPUDZ128rmibk:

        NewOpc = X86_VPCMPUDZ128rmibk_alt;

        break;

      case X86_VPCMPUDZ128rmik:

        NewOpc = X86_VPCMPUDZ128rmik_alt;

        break;

      case X86_VPCMPUDZ128rri:

        NewOpc = X86_VPCMPUDZ128rri_alt;

        break;

      case X86_VPCMPUDZ128rrik:

        NewOpc = X86_VPCMPUDZ128rrik_alt;

        break;

      case X86_VPCMPUDZ256rmi:

        NewOpc = X86_VPCMPUDZ256rmi_alt;

        break;

      case X86_VPCMPUDZ256rmib:

        NewOpc = X86_VPCMPUDZ256rmib_alt;

        break;

      case X86_VPCMPUDZ256rmibk:

        NewOpc = X86_VPCMPUDZ256rmibk_alt;

        break;

      case X86_VPCMPUDZ256rmik:

        NewOpc = X86_VPCMPUDZ256rmik_alt;

        break;

      case X86_VPCMPUDZ256rri:

        NewOpc = X86_VPCMPUDZ256rri_alt;

        break;

      case X86_VPCMPUDZ256rrik:

        NewOpc = X86_VPCMPUDZ256rrik_alt;

        break;

      case X86_VPCMPUDZrmi:

        NewOpc = X86_VPCMPUDZrmi_alt;

        break;

      case X86_VPCMPUDZrmib:

        NewOpc = X86_VPCMPUDZrmib_alt;

        break;

      case X86_VPCMPUDZrmibk:

        NewOpc = X86_VPCMPUDZrmibk_alt;

        break;

      case X86_VPCMPUDZrmik:

        NewOpc = X86_VPCMPUDZrmik_alt;

        break;

      case X86_VPCMPUDZrri:

        NewOpc = X86_VPCMPUDZrri_alt;

        break;

      case X86_VPCMPUDZrrik:

        NewOpc = X86_VPCMPUDZrrik_alt;

        break;

      case X86_VPCMPUQZ128rmi:

        NewOpc = X86_VPCMPUQZ128rmi_alt;

        break;

      case X86_VPCMPUQZ128rmib:

        NewOpc = X86_VPCMPUQZ128rmib_alt;

        break;

      case X86_VPCMPUQZ128rmibk:

        NewOpc = X86_VPCMPUQZ128rmibk_alt;

        break;

      case X86_VPCMPUQZ128rmik:

        NewOpc = X86_VPCMPUQZ128rmik_alt;

        break;

      case X86_VPCMPUQZ128rri:

        NewOpc = X86_VPCMPUQZ128rri_alt;

        break;

      case X86_VPCMPUQZ128rrik:

        NewOpc = X86_VPCMPUQZ128rrik_alt;

        break;

      case X86_VPCMPUQZ256rmi:

        NewOpc = X86_VPCMPUQZ256rmi_alt;

        break;

      case X86_VPCMPUQZ256rmib:

        NewOpc = X86_VPCMPUQZ256rmib_alt;

        break;

      case X86_VPCMPUQZ256rmibk:

        NewOpc = X86_VPCMPUQZ256rmibk_alt;

        break;

      case X86_VPCMPUQZ256rmik:

        NewOpc = X86_VPCMPUQZ256rmik_alt;

        break;

      case X86_VPCMPUQZ256rri:

        NewOpc = X86_VPCMPUQZ256rri_alt;

        break;

      case X86_VPCMPUQZ256rrik:

        NewOpc = X86_VPCMPUQZ256rrik_alt;

        break;

      case X86_VPCMPUQZrmi:

        NewOpc = X86_VPCMPUQZrmi_alt;

        break;

      case X86_VPCMPUQZrmib:

        NewOpc = X86_VPCMPUQZrmib_alt;

        break;

      case X86_VPCMPUQZrmibk:

        NewOpc = X86_VPCMPUQZrmibk_alt;

        break;

      case X86_VPCMPUQZrmik:

        NewOpc = X86_VPCMPUQZrmik_alt;

        break;

      case X86_VPCMPUQZrri:

        NewOpc = X86_VPCMPUQZrri_alt;

        break;

      case X86_VPCMPUQZrrik:

        NewOpc = X86_VPCMPUQZrrik_alt;

        break;

      case X86_VPCMPUWZ128rmi:

        NewOpc = X86_VPCMPUWZ128rmi_alt;

        break;

      case X86_VPCMPUWZ128rmik:

        NewOpc = X86_VPCMPUWZ128rmik_alt;

        break;

      case X86_VPCMPUWZ128rri:

        NewOpc = X86_VPCMPUWZ128rri_alt;

        break;

      case X86_VPCMPUWZ128rrik:

        NewOpc = X86_VPCMPUWZ128rrik_alt;

        break;

      case X86_VPCMPUWZ256rmi:

        NewOpc = X86_VPCMPUWZ256rmi_alt;

        break;

      case X86_VPCMPUWZ256rmik:

        NewOpc = X86_VPCMPUWZ256rmik_alt;

        break;

      case X86_VPCMPUWZ256rri:

        NewOpc = X86_VPCMPUWZ256rri_alt;

        break;

      case X86_VPCMPUWZ256rrik:

        NewOpc = X86_VPCMPUWZ256rrik_alt;

        break;

      case X86_VPCMPUWZrmi:

        NewOpc = X86_VPCMPUWZrmi_alt;

        break;

      case X86_VPCMPUWZrmik:

        NewOpc = X86_VPCMPUWZrmik_alt;

        break;

      case X86_VPCMPUWZrri:

        NewOpc = X86_VPCMPUWZrri_alt;

        break;

      case X86_VPCMPUWZrrik:

        NewOpc = X86_VPCMPUWZrrik_alt;

        break;

      case X86_VPCMPWZ128rmi:

        NewOpc = X86_VPCMPWZ128rmi_alt;

        break;

      case X86_VPCMPWZ128rmik:

        NewOpc = X86_VPCMPWZ128rmik_alt;

        break;

      case X86_VPCMPWZ128rri:

        NewOpc = X86_VPCMPWZ128rri_alt;

        break;

      case X86_VPCMPWZ128rrik:

        NewOpc = X86_VPCMPWZ128rrik_alt;

        break;

      case X86_VPCMPWZ256rmi:

        NewOpc = X86_VPCMPWZ256rmi_alt;

        break;

      case X86_VPCMPWZ256rmik:

        NewOpc = X86_VPCMPWZ256rmik_alt;

        break;

      case X86_VPCMPWZ256rri:

        NewOpc = X86_VPCMPWZ256rri_alt;

        break;

      case X86_VPCMPWZ256rrik:

        NewOpc = X86_VPCMPWZ256rrik_alt;

        break;

      case X86_VPCMPWZrmi:

        NewOpc = X86_VPCMPWZrmi_alt;

        break;

      case X86_VPCMPWZrmik:

        NewOpc = X86_VPCMPWZrmik_alt;

        break;

      case X86_VPCMPWZrri:

        NewOpc = X86_VPCMPWZrri_alt;

        break;

      case X86_VPCMPWZrrik:

        NewOpc = X86_VPCMPWZrrik_alt;

        break;

      }

      // Switch opcode to the one that doesn't get special printing.

      if (NewOpc != 0) {

        MCInst_setOpcode(mcInst, NewOpc);

      }

    }

#endif

  }

  switch (type) {

  case TYPE_XMM:

    MCOperand_CreateReg0(mcInst,

             X86_XMM0 + ((uint32_t)immediate >> 4));

    return;

  case TYPE_YMM:

    MCOperand_CreateReg0(mcInst,

             X86_YMM0 + ((uint32_t)immediate >> 4));

    return;

  case TYPE_ZMM:

    MCOperand_CreateReg0(mcInst,

             X86_ZMM0 + ((uint32_t)immediate >> 4));

    return;

  default:

    // operand is 64 bits wide.  Do nothing.

    break;

  }

  MCOperand_CreateImm0(mcInst, immediate);

  if (type == TYPE_MOFFS) {

    MCOperand_CreateReg0(mcInst,

             segmentRegnums[insn->segmentOverride]);

  }

}

/// translateRMRegister - Translates a register stored in the R/M field of the

///   ModR/M byte to its LLVM equivalent and appends it to an MCInst.

/// @param mcInst       - The MCInst to append to.

/// @param insn         - The internal instruction to extract the R/M field

///                       from.

/// @return             - 0 on success; -1 otherwise

static bool translateRMRegister(MCInst *mcInst, InternalInstruction *insn)

{

  if (insn->eaBase == EA_BASE_sib || insn->eaBase == EA_BASE_sib64) {

    //debug("A R/M register operand may not have a SIB byte");

    return true;

  }

  switch (insn->eaBase) {

  case EA_BASE_NONE:

    //debug("EA_BASE_NONE for ModR/M base");

    return true;

#define ENTRY(x) case EA_BASE_##x:

    ALL_EA_BASES

#undef ENTRY

    //debug("A R/M register operand may not have a base; "

    //      "the operand must be a register.");

    return true;

#define ENTRY(x) \

  case EA_REG_##x: \

    MCOperand_CreateReg0(mcInst, X86_##x); \

    break;

    ALL_REGS

#undef ENTRY

  default:

    //debug("Unexpected EA base register");

    return true;

  }

  return false;

}

/// translateRMMemory - Translates a memory operand stored in the Mod and R/M

///   fields of an internal instruction (and possibly its SIB byte) to a memory

///   operand in LLVM's format, and appends it to an MCInst.

///

/// @param mcInst       - The MCInst to append to.

/// @param insn         - The instruction to extract Mod, R/M, and SIB fields

///                       from.

/// @return             - 0 on success; nonzero otherwise

static bool translateRMMemory(MCInst *mcInst, InternalInstruction *insn)

{

  // Addresses in an MCInst are represented as five operands:

  //   1. basereg       (register)  The R/M base, or (if there is a SIB) the

  //                                SIB base

  //   2. scaleamount   (immediate) 1, or (if there is a SIB) the specified

  //                                scale amount

  //   3. indexreg      (register)  x86_registerNONE, or (if there is a SIB)

  //                                the index (which is multiplied by the

  //                                scale amount)

  //   4. displacement  (immediate) 0, or the displacement if there is one

  //   5. segmentreg    (register)  x86_registerNONE for now, but could be set

  //                                if we have segment overrides

  int scaleAmount, indexReg;

  if (insn->eaBase == EA_BASE_sib || insn->eaBase == EA_BASE_sib64) {

    if (insn->sibBase != SIB_BASE_NONE) {

      switch (insn->sibBase) {

#define ENTRY(x) \

  case SIB_BASE_##x: \

    MCOperand_CreateReg0(mcInst, X86_##x); \

    break;

        ALL_SIB_BASES

#undef ENTRY

      default:

        //debug("Unexpected sibBase");

        return true;

      }

    } else {

      MCOperand_CreateReg0(mcInst, 0);

    }

    if (insn->sibIndex != SIB_INDEX_NONE) {

      switch (insn->sibIndex) {

      default:

        //debug("Unexpected sibIndex");

        return true;

#define ENTRY(x) \

  case SIB_INDEX_##x: \

    indexReg = X86_##x; \

    break;

        EA_BASES_32BIT

        EA_BASES_64BIT

        REGS_XMM

        REGS_YMM

        REGS_ZMM

#undef ENTRY

      }

    } else {

      // Use EIZ/RIZ for a few ambiguous cases where the SIB byte is present,

      // but no index is used and modrm alone should have been enough.

      // -No base register in 32-bit mode. In 64-bit mode this is used to

      //  avoid rip-relative addressing.

      // -Any base register used other than ESP/RSP/R12D/R12. Using these as a

      //  base always requires a SIB byte.

      // -A scale other than 1 is used.

      if (insn->sibScale != 1 ||

          (insn->sibBase == SIB_BASE_NONE &&

           insn->mode != MODE_64BIT) ||

          (insn->sibBase != SIB_BASE_NONE &&

           insn->sibBase != SIB_BASE_ESP &&

           insn->sibBase != SIB_BASE_RSP &&

           insn->sibBase != SIB_BASE_R12D &&

           insn->sibBase != SIB_BASE_R12)) {

        indexReg = insn->addressSize == 4 ? X86_EIZ :

                    X86_RIZ;

      } else

        indexReg = 0;

    }