third_party/LLVM/lib/Target/X86/Disassembler/X86DisassemblerDecoder.h - SwiftShader - Git at Google

 /*===- X86DisassemblerDecoderInternal.h - Disassembler decoder -----*- C -*-==*
  *
  *                     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 the public interface of the instruction decoder.
  * Documentation for the disassembler can be found in X86Disassembler.h.
  *
  *===----------------------------------------------------------------------===*/

 #ifndef X86DISASSEMBLERDECODER_H
 #define X86DISASSEMBLERDECODER_H

 #ifdef __cplusplus
 extern "C" {
 #endif

 #define INSTRUCTION_SPECIFIER_FIELDS  \
   const char*             name;

 #define INSTRUCTION_IDS     \
   const InstrUID *instructionIDs;

 #include "X86DisassemblerDecoderCommon.h"

 #undef INSTRUCTION_SPECIFIER_FIELDS
 #undef INSTRUCTION_IDS

 /*
  * Accessor functions for various fields of an Intel instruction
  */
 #define modFromModRM(modRM)  (((modRM) & 0xc0) >> 6)
 #define regFromModRM(modRM)  (((modRM) & 0x38) >> 3)
 #define rmFromModRM(modRM)   ((modRM) & 0x7)
 #define scaleFromSIB(sib)    (((sib) & 0xc0) >> 6)
 #define indexFromSIB(sib)    (((sib) & 0x38) >> 3)
 #define baseFromSIB(sib)     ((sib) & 0x7)
 #define wFromREX(rex)        (((rex) & 0x8) >> 3)
 #define rFromREX(rex)        (((rex) & 0x4) >> 2)
 #define xFromREX(rex)        (((rex) & 0x2) >> 1)
 #define bFromREX(rex)        ((rex) & 0x1)

 #define rFromVEX2of3(vex)       (((~(vex)) & 0x80) >> 7)
 #define xFromVEX2of3(vex)       (((~(vex)) & 0x40) >> 6)
 #define bFromVEX2of3(vex)       (((~(vex)) & 0x20) >> 5)
 #define mmmmmFromVEX2of3(vex)   ((vex) & 0x1f)
 #define wFromVEX3of3(vex)       (((vex) & 0x80) >> 7)
 #define vvvvFromVEX3of3(vex)    (((~(vex)) & 0x78) >> 3)
 #define lFromVEX3of3(vex)       (((vex) & 0x4) >> 2)
 #define ppFromVEX3of3(vex)      ((vex) & 0x3)

 #define rFromVEX2of2(vex)       (((~(vex)) & 0x80) >> 7)
 #define vvvvFromVEX2of2(vex)    (((~(vex)) & 0x78) >> 3)
 #define lFromVEX2of2(vex)       (((vex) & 0x4) >> 2)
 #define ppFromVEX2of2(vex)      ((vex) & 0x3)

 /*
  * These enums represent Intel registers for use by the decoder.
  */

 #define REGS_8BIT     \
   ENTRY(AL)           \
   ENTRY(CL)           \
   ENTRY(DL)           \
   ENTRY(BL)           \
   ENTRY(AH)           \
   ENTRY(CH)           \
   ENTRY(DH)           \
   ENTRY(BH)           \
   ENTRY(R8B)          \
   ENTRY(R9B)          \
   ENTRY(R10B)         \
   ENTRY(R11B)         \
   ENTRY(R12B)         \
   ENTRY(R13B)         \
   ENTRY(R14B)         \
   ENTRY(R15B)         \
   ENTRY(SPL)          \
   ENTRY(BPL)          \
   ENTRY(SIL)          \
   ENTRY(DIL)

 #define EA_BASES_16BIT  \
   ENTRY(BX_SI)          \
   ENTRY(BX_DI)          \
   ENTRY(BP_SI)          \
   ENTRY(BP_DI)          \
   ENTRY(SI)             \
   ENTRY(DI)             \
   ENTRY(BP)             \
   ENTRY(BX)             \
   ENTRY(R8W)            \
   ENTRY(R9W)            \
   ENTRY(R10W)           \
   ENTRY(R11W)           \
   ENTRY(R12W)           \
   ENTRY(R13W)           \
   ENTRY(R14W)           \
   ENTRY(R15W)

 #define REGS_16BIT    \
   ENTRY(AX)           \
   ENTRY(CX)           \
   ENTRY(DX)           \
   ENTRY(BX)           \
   ENTRY(SP)           \
   ENTRY(BP)           \
   ENTRY(SI)           \
   ENTRY(DI)           \
   ENTRY(R8W)          \
   ENTRY(R9W)          \
   ENTRY(R10W)         \
   ENTRY(R11W)         \
   ENTRY(R12W)         \
   ENTRY(R13W)         \
   ENTRY(R14W)         \
   ENTRY(R15W)

 #define EA_BASES_32BIT  \
   ENTRY(EAX)            \
   ENTRY(ECX)            \
   ENTRY(EDX)            \
   ENTRY(EBX)            \
   ENTRY(sib)            \
   ENTRY(EBP)            \
   ENTRY(ESI)            \
   ENTRY(EDI)            \
   ENTRY(R8D)            \
   ENTRY(R9D)            \
   ENTRY(R10D)           \
   ENTRY(R11D)           \
   ENTRY(R12D)           \
   ENTRY(R13D)           \
   ENTRY(R14D)           \
   ENTRY(R15D)

 #define REGS_32BIT  \
   ENTRY(EAX)        \
   ENTRY(ECX)        \
   ENTRY(EDX)        \
   ENTRY(EBX)        \
   ENTRY(ESP)        \
   ENTRY(EBP)        \
   ENTRY(ESI)        \
   ENTRY(EDI)        \
   ENTRY(R8D)        \
   ENTRY(R9D)        \
   ENTRY(R10D)       \
   ENTRY(R11D)       \
   ENTRY(R12D)       \
   ENTRY(R13D)       \
   ENTRY(R14D)       \
   ENTRY(R15D)

 #define EA_BASES_64BIT  \
   ENTRY(RAX)            \
   ENTRY(RCX)            \
   ENTRY(RDX)            \
   ENTRY(RBX)            \
   ENTRY(sib64)          \
   ENTRY(RBP)            \
   ENTRY(RSI)            \
   ENTRY(RDI)            \
   ENTRY(R8)             \
   ENTRY(R9)             \
   ENTRY(R10)            \
   ENTRY(R11)            \
   ENTRY(R12)            \
   ENTRY(R13)            \
   ENTRY(R14)            \
   ENTRY(R15)

 #define REGS_64BIT  \
   ENTRY(RAX)        \
   ENTRY(RCX)        \
   ENTRY(RDX)        \
   ENTRY(RBX)        \
   ENTRY(RSP)        \
   ENTRY(RBP)        \
   ENTRY(RSI)        \
   ENTRY(RDI)        \
   ENTRY(R8)         \
   ENTRY(R9)         \
   ENTRY(R10)        \
   ENTRY(R11)        \
   ENTRY(R12)        \
   ENTRY(R13)        \
   ENTRY(R14)        \
   ENTRY(R15)

 #define REGS_MMX  \
   ENTRY(MM0)      \
   ENTRY(MM1)      \
   ENTRY(MM2)      \
   ENTRY(MM3)      \
   ENTRY(MM4)      \
   ENTRY(MM5)      \
   ENTRY(MM6)      \
   ENTRY(MM7)

 #define REGS_XMM  \
   ENTRY(XMM0)     \
   ENTRY(XMM1)     \
   ENTRY(XMM2)     \
   ENTRY(XMM3)     \
   ENTRY(XMM4)     \
   ENTRY(XMM5)     \
   ENTRY(XMM6)     \
   ENTRY(XMM7)     \
   ENTRY(XMM8)     \
   ENTRY(XMM9)     \
   ENTRY(XMM10)    \
   ENTRY(XMM11)    \
   ENTRY(XMM12)    \
   ENTRY(XMM13)    \
   ENTRY(XMM14)    \
   ENTRY(XMM15)

 #define REGS_YMM  \
   ENTRY(YMM0)     \
   ENTRY(YMM1)     \
   ENTRY(YMM2)     \
   ENTRY(YMM3)     \
   ENTRY(YMM4)     \
   ENTRY(YMM5)     \
   ENTRY(YMM6)     \
   ENTRY(YMM7)     \
   ENTRY(YMM8)     \
   ENTRY(YMM9)     \
   ENTRY(YMM10)    \
   ENTRY(YMM11)    \
   ENTRY(YMM12)    \
   ENTRY(YMM13)    \
   ENTRY(YMM14)    \
   ENTRY(YMM15)

 #define REGS_SEGMENT \
   ENTRY(ES)          \
   ENTRY(CS)          \
   ENTRY(SS)          \
   ENTRY(DS)          \
   ENTRY(FS)          \
   ENTRY(GS)

 #define REGS_DEBUG  \
   ENTRY(DR0)        \
   ENTRY(DR1)        \
   ENTRY(DR2)        \
   ENTRY(DR3)        \
   ENTRY(DR4)        \
   ENTRY(DR5)        \
   ENTRY(DR6)        \
   ENTRY(DR7)

 #define REGS_CONTROL  \
   ENTRY(CR0)          \
   ENTRY(CR1)          \
   ENTRY(CR2)          \
   ENTRY(CR3)          \
   ENTRY(CR4)          \
   ENTRY(CR5)          \
   ENTRY(CR6)          \
   ENTRY(CR7)          \
   ENTRY(CR8)

 #define ALL_EA_BASES  \
   EA_BASES_16BIT      \
   EA_BASES_32BIT      \
   EA_BASES_64BIT

 #define ALL_SIB_BASES \
   REGS_32BIT          \
   REGS_64BIT

 #define ALL_REGS      \
   REGS_8BIT           \
   REGS_16BIT          \
   REGS_32BIT          \
   REGS_64BIT          \
   REGS_MMX            \
   REGS_XMM            \
   REGS_YMM            \
   REGS_SEGMENT        \
   REGS_DEBUG          \
   REGS_CONTROL        \
   ENTRY(RIP)

 /*
  * EABase - All possible values of the base field for effective-address
  *   computations, a.k.a. the Mod and R/M fields of the ModR/M byte.  We
  *   distinguish between bases (EA_BASE_*) and registers that just happen to be
  *   referred to when Mod == 0b11 (EA_REG_*).
  */
 typedef enum {
   EA_BASE_NONE,
 #define ENTRY(x) EA_BASE_##x,
   ALL_EA_BASES
 #undef ENTRY
 #define ENTRY(x) EA_REG_##x,
   ALL_REGS
 #undef ENTRY
   EA_max
 } EABase;

 /*
  * SIBIndex - All possible values of the SIB index field.
  *   Borrows entries from ALL_EA_BASES with the special case that
  *   sib is synonymous with NONE.
  */
 typedef enum {
   SIB_INDEX_NONE,
 #define ENTRY(x) SIB_INDEX_##x,
   ALL_EA_BASES
 #undef ENTRY
   SIB_INDEX_max
 } SIBIndex;

 /*
  * SIBBase - All possible values of the SIB base field.
  */
 typedef enum {
   SIB_BASE_NONE,
 #define ENTRY(x) SIB_BASE_##x,
   ALL_SIB_BASES
 #undef ENTRY
   SIB_BASE_max
 } SIBBase;

 /*
  * EADisplacement - Possible displacement types for effective-address
  *   computations.
  */
 typedef enum {
   EA_DISP_NONE,
   EA_DISP_8,
   EA_DISP_16,
   EA_DISP_32
 } EADisplacement;

 /*
  * Reg - All possible values of the reg field in the ModR/M byte.
  */
 typedef enum {
 #define ENTRY(x) MODRM_REG_##x,
   ALL_REGS
 #undef ENTRY
   MODRM_REG_max
 } Reg;

 /*
  * SegmentOverride - All possible segment overrides.
  */
 typedef enum {
   SEG_OVERRIDE_NONE,
   SEG_OVERRIDE_CS,
   SEG_OVERRIDE_SS,
   SEG_OVERRIDE_DS,
   SEG_OVERRIDE_ES,
   SEG_OVERRIDE_FS,
   SEG_OVERRIDE_GS,
   SEG_OVERRIDE_max
 } SegmentOverride;

 /*
  * VEXLeadingOpcodeByte - Possible values for the VEX.m-mmmm field
  */

 typedef enum {
   VEX_LOB_0F = 0x1,
   VEX_LOB_0F38 = 0x2,
   VEX_LOB_0F3A = 0x3
 } VEXLeadingOpcodeByte;

 /*
  * VEXPrefixCode - Possible values for the VEX.pp field
  */

 typedef enum {
   VEX_PREFIX_NONE = 0x0,
   VEX_PREFIX_66 = 0x1,
   VEX_PREFIX_F3 = 0x2,
   VEX_PREFIX_F2 = 0x3
 } VEXPrefixCode;

 typedef uint8_t BOOL;

 /*
  * byteReader_t - Type for the byte reader that the consumer must provide to
  *   the decoder.  Reads a single byte from the instruction's address space.
  * @param arg     - A baton that the consumer can associate with any internal
  *                  state that it needs.
  * @param byte    - A pointer to a single byte in memory that should be set to
  *                  contain the value at address.
  * @param address - The address in the instruction's address space that should
  *                  be read from.
  * @return        - -1 if the byte cannot be read for any reason; 0 otherwise.
  */
 typedef int (*byteReader_t)(void* arg, uint8_t* byte, uint64_t address);

 /*
  * dlog_t - Type for the logging function that the consumer can provide to
  *   get debugging output from the decoder.
  * @param arg     - A baton that the consumer can associate with any internal
  *                  state that it needs.
  * @param log     - A string that contains the message.  Will be reused after
  *                  the logger returns.
  */
 typedef void (*dlog_t)(void* arg, const char *log);

 /*
  * The x86 internal instruction, which is produced by the decoder.
  */
 struct InternalInstruction {
   /* Reader interface (C) */
   byteReader_t reader;
   /* Opaque value passed to the reader */
   void* readerArg;
   /* The address of the next byte to read via the reader */
   uint64_t readerCursor;

   /* Logger interface (C) */
   dlog_t dlog;
   /* Opaque value passed to the logger */
   void* dlogArg;

   /* General instruction information */

   /* The mode to disassemble for (64-bit, protected, real) */
   DisassemblerMode mode;
   /* The start of the instruction, usable with the reader */
   uint64_t startLocation;
   /* The length of the instruction, in bytes */
   size_t length;

   /* Prefix state */

   /* 1 if the prefix byte corresponding to the entry is present; 0 if not */
   uint8_t prefixPresent[0x100];
   /* contains the location (for use with the reader) of the prefix byte */
   uint64_t prefixLocations[0x100];
   /* The value of the VEX prefix, if present */
   uint8_t vexPrefix[3];
   /* The length of the VEX prefix (0 if not present) */
   uint8_t vexSize;
   /* The value of the REX prefix, if present */
   uint8_t rexPrefix;
   /* The location where a mandatory prefix would have to be (i.e., right before
      the opcode, or right before the REX prefix if one is present) */
   uint64_t necessaryPrefixLocation;
   /* The segment override type */
   SegmentOverride segmentOverride;

   /* Sizes of various critical pieces of data, in bytes */
   uint8_t registerSize;
   uint8_t addressSize;
   uint8_t displacementSize;
   uint8_t immediateSize;

   /* opcode state */

   /* The value of the two-byte escape prefix (usually 0x0f) */
   uint8_t twoByteEscape;
   /* The value of the three-byte escape prefix (usually 0x38 or 0x3a) */
   uint8_t threeByteEscape;
   /* The last byte of the opcode, not counting any ModR/M extension */
   uint8_t opcode;
   /* The ModR/M byte of the instruction, if it is an opcode extension */
   uint8_t modRMExtension;

   /* decode state */

   /* The type of opcode, used for indexing into the array of decode tables */
   OpcodeType opcodeType;
   /* The instruction ID, extracted from the decode table */
   uint16_t instructionID;
   /* The specifier for the instruction, from the instruction info table */
   const struct InstructionSpecifier *spec;

   /* state for additional bytes, consumed during operand decode.  Pattern:
      consumed___ indicates that the byte was already consumed and does not
      need to be consumed again */

   /* The VEX.vvvv field, which contains a third register operand for some AVX
      instructions */
   Reg                           vvvv;

   /* The ModR/M byte, which contains most register operands and some portion of
      all memory operands */
   BOOL                          consumedModRM;
   uint8_t                       modRM;

   /* The SIB byte, used for more complex 32- or 64-bit memory operands */
   BOOL                          consumedSIB;
   uint8_t                       sib;

   /* The displacement, used for memory operands */
   BOOL                          consumedDisplacement;
   int32_t                       displacement;

   /* Immediates.  There can be two in some cases */
   uint8_t                       numImmediatesConsumed;
   uint8_t                       numImmediatesTranslated;
   uint64_t                      immediates[2];

   /* A register or immediate operand encoded into the opcode */
   BOOL                          consumedOpcodeModifier;
   uint8_t                       opcodeModifier;
   Reg                           opcodeRegister;

   /* Portions of the ModR/M byte */

   /* These fields determine the allowable values for the ModR/M fields, which
      depend on operand and address widths */
   EABase                        eaBaseBase;
   EABase                        eaRegBase;
   Reg                           regBase;

   /* The Mod and R/M fields can encode a base for an effective address, or a
      register.  These are separated into two fields here */
   EABase                        eaBase;
   EADisplacement                eaDisplacement;
   /* The reg field always encodes a register */
   Reg                           reg;

   /* SIB state */
   SIBIndex                      sibIndex;
   uint8_t                       sibScale;
   SIBBase                       sibBase;
 };

 /* decodeInstruction - Decode one instruction and store the decoding results in
  *   a buffer provided by the consumer.
  * @param insn      - The buffer to store the instruction in.  Allocated by the
  *                    consumer.
  * @param reader    - The byteReader_t for the bytes to be read.
  * @param readerArg - An argument to pass to the reader for storing context
  *                    specific to the consumer.  May be NULL.
  * @param logger    - The dlog_t to be used in printing status messages from the
  *                    disassembler.  May be NULL.
  * @param loggerArg - An argument to pass to the logger for storing context
  *                    specific to the logger.  May be NULL.
  * @param startLoc  - The address (in the reader's address space) of the first
  *                    byte in the instruction.
  * @param mode      - The mode (16-bit, 32-bit, 64-bit) to decode in.
  * @return          - Nonzero if there was an error during decode, 0 otherwise.
  */
 int decodeInstruction(struct InternalInstruction* insn,
                       byteReader_t reader,
                       void* readerArg,
                       dlog_t logger,
                       void* loggerArg,
                       uint64_t startLoc,
                       DisassemblerMode mode);

 /* x86DisassemblerDebug - C-accessible function for printing a message to
  *   debugs()
  * @param file  - The name of the file printing the debug message.
  * @param line  - The line number that printed the debug message.
  * @param s     - The message to print.
  */

 void x86DisassemblerDebug(const char *file,
                           unsigned line,
                           const char *s);

 #ifdef __cplusplus
 }
 #endif

 #endif
	/===- X86DisassemblerDecoderInternal.h - Disassembler decoder ------ C --==
	*
	* 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 the public interface of the instruction decoder.
	* Documentation for the disassembler can be found in X86Disassembler.h.
	*
	===----------------------------------------------------------------------===/

	#ifndef X86DISASSEMBLERDECODER_H
	#define X86DISASSEMBLERDECODER_H

	#ifdef __cplusplus
	extern "C" {
	#endif

	#define INSTRUCTION_SPECIFIER_FIELDS \
	const char* name;

	#define INSTRUCTION_IDS \
	const InstrUID *instructionIDs;

	#include "X86DisassemblerDecoderCommon.h"

	#undef INSTRUCTION_SPECIFIER_FIELDS
	#undef INSTRUCTION_IDS

	/*
	* Accessor functions for various fields of an Intel instruction
	*/
	#define modFromModRM(modRM) (((modRM) & 0xc0) >> 6)
	#define regFromModRM(modRM) (((modRM) & 0x38) >> 3)
	#define rmFromModRM(modRM) ((modRM) & 0x7)
	#define scaleFromSIB(sib) (((sib) & 0xc0) >> 6)
	#define indexFromSIB(sib) (((sib) & 0x38) >> 3)
	#define baseFromSIB(sib) ((sib) & 0x7)
	#define wFromREX(rex) (((rex) & 0x8) >> 3)
	#define rFromREX(rex) (((rex) & 0x4) >> 2)
	#define xFromREX(rex) (((rex) & 0x2) >> 1)
	#define bFromREX(rex) ((rex) & 0x1)

	#define rFromVEX2of3(vex) (((~(vex)) & 0x80) >> 7)
	#define xFromVEX2of3(vex) (((~(vex)) & 0x40) >> 6)
	#define bFromVEX2of3(vex) (((~(vex)) & 0x20) >> 5)
	#define mmmmmFromVEX2of3(vex) ((vex) & 0x1f)
	#define wFromVEX3of3(vex) (((vex) & 0x80) >> 7)
	#define vvvvFromVEX3of3(vex) (((~(vex)) & 0x78) >> 3)
	#define lFromVEX3of3(vex) (((vex) & 0x4) >> 2)
	#define ppFromVEX3of3(vex) ((vex) & 0x3)

	#define rFromVEX2of2(vex) (((~(vex)) & 0x80) >> 7)
	#define vvvvFromVEX2of2(vex) (((~(vex)) & 0x78) >> 3)
	#define lFromVEX2of2(vex) (((vex) & 0x4) >> 2)
	#define ppFromVEX2of2(vex) ((vex) & 0x3)

	/*
	* These enums represent Intel registers for use by the decoder.
	*/

	#define REGS_8BIT \
	ENTRY(AL) \
	ENTRY(CL) \
	ENTRY(DL) \
	ENTRY(BL) \
	ENTRY(AH) \
	ENTRY(CH) \
	ENTRY(DH) \
	ENTRY(BH) \
	ENTRY(R8B) \
	ENTRY(R9B) \
	ENTRY(R10B) \
	ENTRY(R11B) \
	ENTRY(R12B) \
	ENTRY(R13B) \
	ENTRY(R14B) \
	ENTRY(R15B) \
	ENTRY(SPL) \
	ENTRY(BPL) \
	ENTRY(SIL) \
	ENTRY(DIL)

	#define EA_BASES_16BIT \
	ENTRY(BX_SI) \
	ENTRY(BX_DI) \
	ENTRY(BP_SI) \
	ENTRY(BP_DI) \
	ENTRY(SI) \
	ENTRY(DI) \
	ENTRY(BP) \
	ENTRY(BX) \
	ENTRY(R8W) \
	ENTRY(R9W) \
	ENTRY(R10W) \
	ENTRY(R11W) \
	ENTRY(R12W) \
	ENTRY(R13W) \
	ENTRY(R14W) \
	ENTRY(R15W)

	#define REGS_16BIT \
	ENTRY(AX) \
	ENTRY(CX) \
	ENTRY(DX) \
	ENTRY(BX) \
	ENTRY(SP) \
	ENTRY(BP) \
	ENTRY(SI) \
	ENTRY(DI) \
	ENTRY(R8W) \
	ENTRY(R9W) \
	ENTRY(R10W) \
	ENTRY(R11W) \
	ENTRY(R12W) \
	ENTRY(R13W) \
	ENTRY(R14W) \
	ENTRY(R15W)

	#define EA_BASES_32BIT \
	ENTRY(EAX) \
	ENTRY(ECX) \
	ENTRY(EDX) \
	ENTRY(EBX) \
	ENTRY(sib) \
	ENTRY(EBP) \
	ENTRY(ESI) \
	ENTRY(EDI) \
	ENTRY(R8D) \
	ENTRY(R9D) \
	ENTRY(R10D) \
	ENTRY(R11D) \
	ENTRY(R12D) \
	ENTRY(R13D) \
	ENTRY(R14D) \
	ENTRY(R15D)

	#define REGS_32BIT \
	ENTRY(EAX) \
	ENTRY(ECX) \
	ENTRY(EDX) \
	ENTRY(EBX) \
	ENTRY(ESP) \
	ENTRY(EBP) \
	ENTRY(ESI) \
	ENTRY(EDI) \
	ENTRY(R8D) \
	ENTRY(R9D) \
	ENTRY(R10D) \
	ENTRY(R11D) \
	ENTRY(R12D) \
	ENTRY(R13D) \
	ENTRY(R14D) \
	ENTRY(R15D)

	#define EA_BASES_64BIT \
	ENTRY(RAX) \
	ENTRY(RCX) \
	ENTRY(RDX) \
	ENTRY(RBX) \
	ENTRY(sib64) \
	ENTRY(RBP) \
	ENTRY(RSI) \
	ENTRY(RDI) \
	ENTRY(R8) \
	ENTRY(R9) \
	ENTRY(R10) \
	ENTRY(R11) \
	ENTRY(R12) \
	ENTRY(R13) \
	ENTRY(R14) \
	ENTRY(R15)

	#define REGS_64BIT \
	ENTRY(RAX) \
	ENTRY(RCX) \
	ENTRY(RDX) \
	ENTRY(RBX) \
	ENTRY(RSP) \
	ENTRY(RBP) \
	ENTRY(RSI) \
	ENTRY(RDI) \
	ENTRY(R8) \
	ENTRY(R9) \
	ENTRY(R10) \
	ENTRY(R11) \
	ENTRY(R12) \
	ENTRY(R13) \
	ENTRY(R14) \
	ENTRY(R15)

	#define REGS_MMX \
	ENTRY(MM0) \
	ENTRY(MM1) \
	ENTRY(MM2) \
	ENTRY(MM3) \
	ENTRY(MM4) \
	ENTRY(MM5) \
	ENTRY(MM6) \
	ENTRY(MM7)

	#define REGS_XMM \
	ENTRY(XMM0) \
	ENTRY(XMM1) \
	ENTRY(XMM2) \
	ENTRY(XMM3) \
	ENTRY(XMM4) \
	ENTRY(XMM5) \
	ENTRY(XMM6) \
	ENTRY(XMM7) \
	ENTRY(XMM8) \
	ENTRY(XMM9) \
	ENTRY(XMM10) \
	ENTRY(XMM11) \
	ENTRY(XMM12) \
	ENTRY(XMM13) \
	ENTRY(XMM14) \
	ENTRY(XMM15)

	#define REGS_YMM \
	ENTRY(YMM0) \
	ENTRY(YMM1) \
	ENTRY(YMM2) \
	ENTRY(YMM3) \
	ENTRY(YMM4) \
	ENTRY(YMM5) \
	ENTRY(YMM6) \
	ENTRY(YMM7) \
	ENTRY(YMM8) \
	ENTRY(YMM9) \
	ENTRY(YMM10) \
	ENTRY(YMM11) \
	ENTRY(YMM12) \
	ENTRY(YMM13) \
	ENTRY(YMM14) \
	ENTRY(YMM15)

	#define REGS_SEGMENT \
	ENTRY(ES) \
	ENTRY(CS) \
	ENTRY(SS) \
	ENTRY(DS) \
	ENTRY(FS) \
	ENTRY(GS)

	#define REGS_DEBUG \
	ENTRY(DR0) \
	ENTRY(DR1) \
	ENTRY(DR2) \
	ENTRY(DR3) \
	ENTRY(DR4) \
	ENTRY(DR5) \
	ENTRY(DR6) \
	ENTRY(DR7)

	#define REGS_CONTROL \
	ENTRY(CR0) \
	ENTRY(CR1) \
	ENTRY(CR2) \
	ENTRY(CR3) \
	ENTRY(CR4) \
	ENTRY(CR5) \
	ENTRY(CR6) \
	ENTRY(CR7) \
	ENTRY(CR8)

	#define ALL_EA_BASES \
	EA_BASES_16BIT \
	EA_BASES_32BIT \
	EA_BASES_64BIT

	#define ALL_SIB_BASES \
	REGS_32BIT \
	REGS_64BIT

	#define ALL_REGS \
	REGS_8BIT \
	REGS_16BIT \
	REGS_32BIT \
	REGS_64BIT \
	REGS_MMX \
	REGS_XMM \
	REGS_YMM \
	REGS_SEGMENT \
	REGS_DEBUG \
	REGS_CONTROL \
	ENTRY(RIP)

	/*
	* EABase - All possible values of the base field for effective-address
	* computations, a.k.a. the Mod and R/M fields of the ModR/M byte. We
	* distinguish between bases (EA_BASE_*) and registers that just happen to be
	* referred to when Mod == 0b11 (EA_REG_*).
	*/
	typedef enum {
	EA_BASE_NONE,
	#define ENTRY(x) EA_BASE_##x,
	ALL_EA_BASES
	#undef ENTRY
	#define ENTRY(x) EA_REG_##x,
	ALL_REGS
	#undef ENTRY
	EA_max
	} EABase;

	/*
	* SIBIndex - All possible values of the SIB index field.
	* Borrows entries from ALL_EA_BASES with the special case that
	* sib is synonymous with NONE.
	*/
	typedef enum {
	SIB_INDEX_NONE,
	#define ENTRY(x) SIB_INDEX_##x,
	ALL_EA_BASES
	#undef ENTRY
	SIB_INDEX_max
	} SIBIndex;

	/*
	* SIBBase - All possible values of the SIB base field.
	*/
	typedef enum {
	SIB_BASE_NONE,
	#define ENTRY(x) SIB_BASE_##x,
	ALL_SIB_BASES
	#undef ENTRY
	SIB_BASE_max
	} SIBBase;

	/*
	* EADisplacement - Possible displacement types for effective-address
	* computations.
	*/
	typedef enum {
	EA_DISP_NONE,
	EA_DISP_8,
	EA_DISP_16,
	EA_DISP_32
	} EADisplacement;

	/*
	* Reg - All possible values of the reg field in the ModR/M byte.
	*/
	typedef enum {
	#define ENTRY(x) MODRM_REG_##x,
	ALL_REGS
	#undef ENTRY
	MODRM_REG_max
	} Reg;

	/*
	* SegmentOverride - All possible segment overrides.
	*/
	typedef enum {
	SEG_OVERRIDE_NONE,
	SEG_OVERRIDE_CS,
	SEG_OVERRIDE_SS,
	SEG_OVERRIDE_DS,
	SEG_OVERRIDE_ES,
	SEG_OVERRIDE_FS,
	SEG_OVERRIDE_GS,
	SEG_OVERRIDE_max
	} SegmentOverride;

	/*
	* VEXLeadingOpcodeByte - Possible values for the VEX.m-mmmm field
	*/

	typedef enum {
	VEX_LOB_0F = 0x1,
	VEX_LOB_0F38 = 0x2,
	VEX_LOB_0F3A = 0x3
	} VEXLeadingOpcodeByte;

	/*
	* VEXPrefixCode - Possible values for the VEX.pp field
	*/

	typedef enum {
	VEX_PREFIX_NONE = 0x0,
	VEX_PREFIX_66 = 0x1,
	VEX_PREFIX_F3 = 0x2,
	VEX_PREFIX_F2 = 0x3
	} VEXPrefixCode;

	typedef uint8_t BOOL;

	/*
	* byteReader_t - Type for the byte reader that the consumer must provide to
	* the decoder. Reads a single byte from the instruction's address space.
	* @param arg - A baton that the consumer can associate with any internal
	* state that it needs.
	* @param byte - A pointer to a single byte in memory that should be set to
	* contain the value at address.
	* @param address - The address in the instruction's address space that should
	* be read from.
	* @return - -1 if the byte cannot be read for any reason; 0 otherwise.
	*/
	typedef int (byteReader_t)(void arg, uint8_t* byte, uint64_t address);

	/*
	* dlog_t - Type for the logging function that the consumer can provide to
	* get debugging output from the decoder.
	* @param arg - A baton that the consumer can associate with any internal
	* state that it needs.
	* @param log - A string that contains the message. Will be reused after
	* the logger returns.
	*/
	typedef void (dlog_t)(void arg, const char *log);

	/*
	* The x86 internal instruction, which is produced by the decoder.
	*/
	struct InternalInstruction {
	/* Reader interface (C) */
	byteReader_t reader;
	/* Opaque value passed to the reader */
	void* readerArg;
	/* The address of the next byte to read via the reader */
	uint64_t readerCursor;

	/* Logger interface (C) */
	dlog_t dlog;
	/* Opaque value passed to the logger */
	void* dlogArg;

	/* General instruction information */

	/* The mode to disassemble for (64-bit, protected, real) */
	DisassemblerMode mode;
	/* The start of the instruction, usable with the reader */
	uint64_t startLocation;
	/* The length of the instruction, in bytes */
	size_t length;

	/* Prefix state */

	/* 1 if the prefix byte corresponding to the entry is present; 0 if not */
	uint8_t prefixPresent[0x100];
	/* contains the location (for use with the reader) of the prefix byte */
	uint64_t prefixLocations[0x100];
	/* The value of the VEX prefix, if present */
	uint8_t vexPrefix[3];
	/* The length of the VEX prefix (0 if not present) */
	uint8_t vexSize;
	/* The value of the REX prefix, if present */
	uint8_t rexPrefix;
	/* The location where a mandatory prefix would have to be (i.e., right before
	the opcode, or right before the REX prefix if one is present) */
	uint64_t necessaryPrefixLocation;
	/* The segment override type */
	SegmentOverride segmentOverride;

	/* Sizes of various critical pieces of data, in bytes */
	uint8_t registerSize;
	uint8_t addressSize;
	uint8_t displacementSize;
	uint8_t immediateSize;

	/* opcode state */

	/* The value of the two-byte escape prefix (usually 0x0f) */
	uint8_t twoByteEscape;
	/* The value of the three-byte escape prefix (usually 0x38 or 0x3a) */
	uint8_t threeByteEscape;
	/* The last byte of the opcode, not counting any ModR/M extension */
	uint8_t opcode;
	/* The ModR/M byte of the instruction, if it is an opcode extension */
	uint8_t modRMExtension;

	/* decode state */

	/* The type of opcode, used for indexing into the array of decode tables */
	OpcodeType opcodeType;
	/* The instruction ID, extracted from the decode table */
	uint16_t instructionID;
	/* The specifier for the instruction, from the instruction info table */
	const struct InstructionSpecifier *spec;

	/* state for additional bytes, consumed during operand decode. Pattern:
	consumed___ indicates that the byte was already consumed and does not
	need to be consumed again */

	/* The VEX.vvvv field, which contains a third register operand for some AVX
	instructions */
	Reg vvvv;

	/* The ModR/M byte, which contains most register operands and some portion of
	all memory operands */
	BOOL consumedModRM;
	uint8_t modRM;

	/* The SIB byte, used for more complex 32- or 64-bit memory operands */
	BOOL consumedSIB;
	uint8_t sib;

	/* The displacement, used for memory operands */
	BOOL consumedDisplacement;
	int32_t displacement;

	/* Immediates. There can be two in some cases */
	uint8_t numImmediatesConsumed;
	uint8_t numImmediatesTranslated;
	uint64_t immediates[2];

	/* A register or immediate operand encoded into the opcode */
	BOOL consumedOpcodeModifier;
	uint8_t opcodeModifier;
	Reg opcodeRegister;

	/* Portions of the ModR/M byte */

	/* These fields determine the allowable values for the ModR/M fields, which
	depend on operand and address widths */
	EABase eaBaseBase;
	EABase eaRegBase;
	Reg regBase;

	/* The Mod and R/M fields can encode a base for an effective address, or a
	register. These are separated into two fields here */
	EABase eaBase;
	EADisplacement eaDisplacement;
	/* The reg field always encodes a register */
	Reg reg;

	/* SIB state */
	SIBIndex sibIndex;
	uint8_t sibScale;
	SIBBase sibBase;
	};

	/* decodeInstruction - Decode one instruction and store the decoding results in
	* a buffer provided by the consumer.
	* @param insn - The buffer to store the instruction in. Allocated by the
	* consumer.
	* @param reader - The byteReader_t for the bytes to be read.
	* @param readerArg - An argument to pass to the reader for storing context
	* specific to the consumer. May be NULL.
	* @param logger - The dlog_t to be used in printing status messages from the
	* disassembler. May be NULL.
	* @param loggerArg - An argument to pass to the logger for storing context
	* specific to the logger. May be NULL.
	* @param startLoc - The address (in the reader's address space) of the first
	* byte in the instruction.
	* @param mode - The mode (16-bit, 32-bit, 64-bit) to decode in.
	* @return - Nonzero if there was an error during decode, 0 otherwise.
	*/
	int decodeInstruction(struct InternalInstruction* insn,
	byteReader_t reader,
	void* readerArg,
	dlog_t logger,
	void* loggerArg,
	uint64_t startLoc,
	DisassemblerMode mode);

	/* x86DisassemblerDebug - C-accessible function for printing a message to
	* debugs()
	* @param file - The name of the file printing the debug message.
	* @param line - The line number that printed the debug message.
	* @param s - The message to print.
	*/

	void x86DisassemblerDebug(const char *file,
	unsigned line,
	const char *s);

	#ifdef __cplusplus
	}
	#endif

	#endif