arch/ARM/ARMBaseInfo.h - third_party/capstone - Git at Google

 //===-- ARMBaseInfo.h - Top level definitions for ARM -------- --*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file contains small standalone helper functions and enum definitions for
 // the ARM target useful for the compiler back-end and the MC libraries.
 // As such, it deliberately does not include references to LLVM core
 // code gen types, passes, etc..
 //
 //===----------------------------------------------------------------------===//

 /* Capstone Disassembly Engine */
 /* By Nguyen Anh Quynh <aquynh@gmail.com>, 2013-2015 */

 #ifndef CS_ARMBASEINFO_H
 #define CS_ARMBASEINFO_H

 #include "capstone/arm.h"

 // Defines symbolic names for ARM registers.  This defines a mapping from
 // register name to register number.
 //
 #define GET_REGINFO_ENUM
 #include "ARMGenRegisterInfo.inc"

 // Enums corresponding to ARM condition codes
 // The CondCodes constants map directly to the 4-bit encoding of the
 // condition field for predicated instructions.
 typedef enum ARMCC_CondCodes { // Meaning (integer)          Meaning (floating-point)
 	ARMCC_EQ,            // Equal                      Equal
 	ARMCC_NE,            // Not equal                  Not equal, or unordered
 	ARMCC_HS,            // Carry set                  >, ==, or unordered
 	ARMCC_LO,            // Carry clear                Less than
 	ARMCC_MI,            // Minus, negative            Less than
 	ARMCC_PL,            // Plus, positive or zero     >, ==, or unordered
 	ARMCC_VS,            // Overflow                   Unordered
 	ARMCC_VC,            // No overflow                Not unordered
 	ARMCC_HI,            // Unsigned higher            Greater than, or unordered
 	ARMCC_LS,            // Unsigned lower or same     Less than or equal
 	ARMCC_GE,            // Greater than or equal      Greater than or equal
 	ARMCC_LT,            // Less than                  Less than, or unordered
 	ARMCC_GT,            // Greater than               Greater than
 	ARMCC_LE,            // Less than or equal         <, ==, or unordered
 	ARMCC_AL             // Always (unconditional)     Always (unconditional)
 } ARMCC_CondCodes;

 inline static ARMCC_CondCodes ARMCC_getOppositeCondition(ARMCC_CondCodes CC)
 {
 	switch (CC) {
 		case ARMCC_EQ: return ARMCC_NE;
 		case ARMCC_NE: return ARMCC_EQ;
 		case ARMCC_HS: return ARMCC_LO;
 		case ARMCC_LO: return ARMCC_HS;
 		case ARMCC_MI: return ARMCC_PL;
 		case ARMCC_PL: return ARMCC_MI;
 		case ARMCC_VS: return ARMCC_VC;
 		case ARMCC_VC: return ARMCC_VS;
 		case ARMCC_HI: return ARMCC_LS;
 		case ARMCC_LS: return ARMCC_HI;
 		case ARMCC_GE: return ARMCC_LT;
 		case ARMCC_LT: return ARMCC_GE;
 		case ARMCC_GT: return ARMCC_LE;
 		case ARMCC_LE: return ARMCC_GT;
 		default: return ARMCC_AL;
 	}
 }

 inline static char *ARMCC_ARMCondCodeToString(ARMCC_CondCodes CC)
 {
 	switch (CC) {
 		case ARMCC_EQ:  return "eq";
 		case ARMCC_NE:  return "ne";
 		case ARMCC_HS:  return "hs";
 		case ARMCC_LO:  return "lo";
 		case ARMCC_MI:  return "mi";
 		case ARMCC_PL:  return "pl";
 		case ARMCC_VS:  return "vs";
 		case ARMCC_VC:  return "vc";
 		case ARMCC_HI:  return "hi";
 		case ARMCC_LS:  return "ls";
 		case ARMCC_GE:  return "ge";
 		case ARMCC_LT:  return "lt";
 		case ARMCC_GT:  return "gt";
 		case ARMCC_LE:  return "le";
 		case ARMCC_AL:  return "al";
 		default: return "";
 	}
 }

 inline static char *ARM_PROC_IFlagsToString(unsigned val)
 {
 	switch (val) {
 		case ARM_CPSFLAG_F: return "f";
 		case ARM_CPSFLAG_I: return "i";
 		case ARM_CPSFLAG_A: return "a";
 		default: return "";
 	}
 }

 inline static char *ARM_PROC_IModToString(unsigned val)
 {
 	switch (val) {
 		case ARM_CPSMODE_IE: return "ie";
 		case ARM_CPSMODE_ID: return "id";
 		default: return "";
 	}
 }

 inline static char *ARM_MB_MemBOptToString(unsigned val, bool HasV8)
 {
 	switch (val) {
 		default: return "BUGBUG";
 		case ARM_MB_SY:    return "sy";
 		case ARM_MB_ST:    return "st";
 		case ARM_MB_LD: return HasV8 ? "ld" : "#0xd";
 		case ARM_MB_RESERVED_12: return "#0xc";
 		case ARM_MB_ISH:   return "ish";
 		case ARM_MB_ISHST: return "ishst";
 		case ARM_MB_ISHLD: return HasV8 ?  "ishld" : "#0x9";
 		case ARM_MB_RESERVED_8: return "#0x8";
 		case ARM_MB_NSH:   return "nsh";
 		case ARM_MB_NSHST: return "nshst";
 		case ARM_MB_NSHLD: return HasV8 ? "nshld" : "#0x5";
 		case ARM_MB_RESERVED_4: return "#0x4";
 		case ARM_MB_OSH:   return "osh";
 		case ARM_MB_OSHST: return "oshst";
 		case ARM_MB_OSHLD: return HasV8 ? "oshld" : "#0x1";
 		case ARM_MB_RESERVED_0: return "#0x0";
 	}
 }

 enum ARM_ISB_InstSyncBOpt {
     ARM_ISB_RESERVED_0 = 0,
     ARM_ISB_RESERVED_1 = 1,
     ARM_ISB_RESERVED_2 = 2,
     ARM_ISB_RESERVED_3 = 3,
     ARM_ISB_RESERVED_4 = 4,
     ARM_ISB_RESERVED_5 = 5,
     ARM_ISB_RESERVED_6 = 6,
     ARM_ISB_RESERVED_7 = 7,
     ARM_ISB_RESERVED_8 = 8,
     ARM_ISB_RESERVED_9 = 9,
     ARM_ISB_RESERVED_10 = 10,
     ARM_ISB_RESERVED_11 = 11,
     ARM_ISB_RESERVED_12 = 12,
     ARM_ISB_RESERVED_13 = 13,
     ARM_ISB_RESERVED_14 = 14,
     ARM_ISB_SY = 15
 };

 inline static char *ARM_ISB_InstSyncBOptToString(unsigned val)
 {
 	switch (val) {
 		default: // never reach
 		case ARM_ISB_RESERVED_0:  return "#0x0";
 		case ARM_ISB_RESERVED_1:  return "#0x1";
 		case ARM_ISB_RESERVED_2:  return "#0x2";
 		case ARM_ISB_RESERVED_3:  return "#0x3";
 		case ARM_ISB_RESERVED_4:  return "#0x4";
 		case ARM_ISB_RESERVED_5:  return "#0x5";
 		case ARM_ISB_RESERVED_6:  return "#0x6";
 		case ARM_ISB_RESERVED_7:  return "#0x7";
 		case ARM_ISB_RESERVED_8:  return "#0x8";
 		case ARM_ISB_RESERVED_9:  return "#0x9";
 		case ARM_ISB_RESERVED_10: return "#0xa";
 		case ARM_ISB_RESERVED_11: return "#0xb";
 		case ARM_ISB_RESERVED_12: return "#0xc";
 		case ARM_ISB_RESERVED_13: return "#0xd";
 		case ARM_ISB_RESERVED_14: return "#0xe";
 		case ARM_ISB_SY:          return "sy";
 	}
 }

 /// isARMLowRegister - Returns true if the register is a low register (r0-r7).
 ///
 static inline bool isARMLowRegister(unsigned Reg)
 {
 	//using namespace ARM;
 	switch (Reg) {
 		case ARM_R0:  case ARM_R1:  case ARM_R2:  case ARM_R3:
 		case ARM_R4:  case ARM_R5:  case ARM_R6:  case ARM_R7:
 			return true;
 		default:
 			return false;
 	}
 }

 /// ARMII - This namespace holds all of the target specific flags that
 /// instruction info tracks.
 ///
 /// ARM Index Modes
 enum ARMII_IndexMode {
 	ARMII_IndexModeNone  = 0,
 	ARMII_IndexModePre   = 1,
 	ARMII_IndexModePost  = 2,
 	ARMII_IndexModeUpd   = 3
 };

 /// ARM Addressing Modes
 typedef enum ARMII_AddrMode {
 	ARMII_AddrModeNone    = 0,
 	ARMII_AddrMode1       = 1,
 	ARMII_AddrMode2       = 2,
 	ARMII_AddrMode3       = 3,
 	ARMII_AddrMode4       = 4,
 	ARMII_AddrMode5       = 5,
 	ARMII_AddrMode6       = 6,
 	ARMII_AddrModeT1_1    = 7,
 	ARMII_AddrModeT1_2    = 8,
 	ARMII_AddrModeT1_4    = 9,
 	ARMII_AddrModeT1_s    = 10, // i8 * 4 for pc and sp relative data
 	ARMII_AddrModeT2_i12  = 11,
 	ARMII_AddrModeT2_i8   = 12,
 	ARMII_AddrModeT2_so   = 13,
 	ARMII_AddrModeT2_pc   = 14, // +/- i12 for pc relative data
 	ARMII_AddrModeT2_i8s4 = 15, // i8 * 4
 	ARMII_AddrMode_i12    = 16
 } ARMII_AddrMode;

 inline static char *ARMII_AddrModeToString(ARMII_AddrMode addrmode)
 {
 	switch (addrmode) {
 		case ARMII_AddrModeNone:    return "AddrModeNone";
 		case ARMII_AddrMode1:       return "AddrMode1";
 		case ARMII_AddrMode2:       return "AddrMode2";
 		case ARMII_AddrMode3:       return "AddrMode3";
 		case ARMII_AddrMode4:       return "AddrMode4";
 		case ARMII_AddrMode5:       return "AddrMode5";
 		case ARMII_AddrMode6:       return "AddrMode6";
 		case ARMII_AddrModeT1_1:    return "AddrModeT1_1";
 		case ARMII_AddrModeT1_2:    return "AddrModeT1_2";
 		case ARMII_AddrModeT1_4:    return "AddrModeT1_4";
 		case ARMII_AddrModeT1_s:    return "AddrModeT1_s";
 		case ARMII_AddrModeT2_i12:  return "AddrModeT2_i12";
 		case ARMII_AddrModeT2_i8:   return "AddrModeT2_i8";
 		case ARMII_AddrModeT2_so:   return "AddrModeT2_so";
 		case ARMII_AddrModeT2_pc:   return "AddrModeT2_pc";
 		case ARMII_AddrModeT2_i8s4: return "AddrModeT2_i8s4";
 		case ARMII_AddrMode_i12:    return "AddrMode_i12";
 	}
 }

 /// Target Operand Flag enum.
 enum ARMII_TOF {
 	//===------------------------------------------------------------------===//
 	// ARM Specific MachineOperand flags.

 	ARMII_MO_NO_FLAG,

 	/// MO_LO16 - On a symbol operand, this represents a relocation containing
 	/// lower 16 bit of the address. Used only via movw instruction.
 	ARMII_MO_LO16,

 	/// MO_HI16 - On a symbol operand, this represents a relocation containing
 	/// higher 16 bit of the address. Used only via movt instruction.
 	ARMII_MO_HI16,

 	/// MO_LO16_NONLAZY - On a symbol operand "FOO", this represents a
 	/// relocation containing lower 16 bit of the non-lazy-ptr indirect symbol,
 	/// i.e. "FOO$non_lazy_ptr".
 	/// Used only via movw instruction.
 	ARMII_MO_LO16_NONLAZY,

 	/// MO_HI16_NONLAZY - On a symbol operand "FOO", this represents a
 	/// relocation containing lower 16 bit of the non-lazy-ptr indirect symbol,
 	/// i.e. "FOO$non_lazy_ptr". Used only via movt instruction.
 	ARMII_MO_HI16_NONLAZY,

 	/// MO_LO16_NONLAZY_PIC - On a symbol operand "FOO", this represents a
 	/// relocation containing lower 16 bit of the PC relative address of the
 	/// non-lazy-ptr indirect symbol, i.e. "FOO$non_lazy_ptr - LABEL".
 	/// Used only via movw instruction.
 	ARMII_MO_LO16_NONLAZY_PIC,

 	/// MO_HI16_NONLAZY_PIC - On a symbol operand "FOO", this represents a
 	/// relocation containing lower 16 bit of the PC relative address of the
 	/// non-lazy-ptr indirect symbol, i.e. "FOO$non_lazy_ptr - LABEL".
 	/// Used only via movt instruction.
 	ARMII_MO_HI16_NONLAZY_PIC,

 	/// MO_PLT - On a symbol operand, this represents an ELF PLT reference on a
 	/// call operand.
 	ARMII_MO_PLT
 };

 enum {
 	//===------------------------------------------------------------------===//
 	// Instruction Flags.

 	//===------------------------------------------------------------------===//
 	// This four-bit field describes the addressing mode used.
 	ARMII_AddrModeMask  = 0x1f, // The AddrMode enums are declared in ARMBaseInfo.h

 	// IndexMode - Unindex, pre-indexed, or post-indexed are valid for load
 	// and store ops only.  Generic "updating" flag is used for ld/st multiple.
 	// The index mode enums are declared in ARMBaseInfo.h
 	ARMII_IndexModeShift = 5,
 	ARMII_IndexModeMask  = 3 << ARMII_IndexModeShift,

 	//===------------------------------------------------------------------===//
 	// Instruction encoding formats.
 	//
 	ARMII_FormShift     = 7,
 	ARMII_FormMask      = 0x3f << ARMII_FormShift,

 	// Pseudo instructions
 	ARMII_Pseudo        = 0  << ARMII_FormShift,

 	// Multiply instructions
 	ARMII_MulFrm        = 1  << ARMII_FormShift,

 	// Branch instructions
 	ARMII_BrFrm         = 2  << ARMII_FormShift,
 	ARMII_BrMiscFrm     = 3  << ARMII_FormShift,

 	// Data Processing instructions
 	ARMII_DPFrm         = 4  << ARMII_FormShift,
 	ARMII_DPSoRegFrm    = 5  << ARMII_FormShift,

 	// Load and Store
 	ARMII_LdFrm         = 6  << ARMII_FormShift,
 	ARMII_StFrm         = 7  << ARMII_FormShift,
 	ARMII_LdMiscFrm     = 8  << ARMII_FormShift,
 	ARMII_StMiscFrm     = 9  << ARMII_FormShift,
 	ARMII_LdStMulFrm    = 10 << ARMII_FormShift,

 	ARMII_LdStExFrm     = 11 << ARMII_FormShift,

 	// Miscellaneous arithmetic instructions
 	ARMII_ArithMiscFrm  = 12 << ARMII_FormShift,
 	ARMII_SatFrm        = 13 << ARMII_FormShift,

 	// Extend instructions
 	ARMII_ExtFrm        = 14 << ARMII_FormShift,

 	// VFP formats
 	ARMII_VFPUnaryFrm   = 15 << ARMII_FormShift,
 	ARMII_VFPBinaryFrm  = 16 << ARMII_FormShift,
 	ARMII_VFPConv1Frm   = 17 << ARMII_FormShift,
 	ARMII_VFPConv2Frm   = 18 << ARMII_FormShift,
 	ARMII_VFPConv3Frm   = 19 << ARMII_FormShift,
 	ARMII_VFPConv4Frm   = 20 << ARMII_FormShift,
 	ARMII_VFPConv5Frm   = 21 << ARMII_FormShift,
 	ARMII_VFPLdStFrm    = 22 << ARMII_FormShift,
 	ARMII_VFPLdStMulFrm = 23 << ARMII_FormShift,
 	ARMII_VFPMiscFrm    = 24 << ARMII_FormShift,

 	// Thumb format
 	ARMII_ThumbFrm      = 25 << ARMII_FormShift,

 	// Miscelleaneous format
 	ARMII_MiscFrm       = 26 << ARMII_FormShift,

 	// NEON formats
 	ARMII_NGetLnFrm     = 27 << ARMII_FormShift,
 	ARMII_NSetLnFrm     = 28 << ARMII_FormShift,
 	ARMII_NDupFrm       = 29 << ARMII_FormShift,
 	ARMII_NLdStFrm      = 30 << ARMII_FormShift,
 	ARMII_N1RegModImmFrm= 31 << ARMII_FormShift,
 	ARMII_N2RegFrm      = 32 << ARMII_FormShift,
 	ARMII_NVCVTFrm      = 33 << ARMII_FormShift,
 	ARMII_NVDupLnFrm    = 34 << ARMII_FormShift,
 	ARMII_N2RegVShLFrm  = 35 << ARMII_FormShift,
 	ARMII_N2RegVShRFrm  = 36 << ARMII_FormShift,
 	ARMII_N3RegFrm      = 37 << ARMII_FormShift,
 	ARMII_N3RegVShFrm   = 38 << ARMII_FormShift,
 	ARMII_NVExtFrm      = 39 << ARMII_FormShift,
 	ARMII_NVMulSLFrm    = 40 << ARMII_FormShift,
 	ARMII_NVTBLFrm      = 41 << ARMII_FormShift,

 	//===------------------------------------------------------------------===//
 	// Misc flags.

 	// UnaryDP - Indicates this is a unary data processing instruction, i.e.
 	// it doesn't have a Rn operand.
 	ARMII_UnaryDP       = 1 << 13,

 	// Xform16Bit - Indicates this Thumb2 instruction may be transformed into
 	// a 16-bit Thumb instruction if certain conditions are met.
 	ARMII_Xform16Bit    = 1 << 14,

 	// ThumbArithFlagSetting - The instruction is a 16-bit flag setting Thumb
 	// instruction. Used by the parser to determine whether to require the 'S'
 	// suffix on the mnemonic (when not in an IT block) or preclude it (when
 	// in an IT block).
 	ARMII_ThumbArithFlagSetting = 1 << 18,

 	//===------------------------------------------------------------------===//
 	// Code domain.
 	ARMII_DomainShift   = 15,
 	ARMII_DomainMask    = 7 << ARMII_DomainShift,
 	ARMII_DomainGeneral = 0 << ARMII_DomainShift,
 	ARMII_DomainVFP     = 1 << ARMII_DomainShift,
 	ARMII_DomainNEON    = 2 << ARMII_DomainShift,
 	ARMII_DomainNEONA8  = 4 << ARMII_DomainShift,

 	//===------------------------------------------------------------------===//
 	// Field shifts - such shifts are used to set field while generating
 	// machine instructions.
 	//
 	// FIXME: This list will need adjusting/fixing as the MC code emitter
 	// takes shape and the ARMCodeEmitter.cpp bits go away.
 	ARMII_ShiftTypeShift = 4,

 	ARMII_M_BitShift     = 5,
 	ARMII_ShiftImmShift  = 5,
 	ARMII_ShiftShift     = 7,
 	ARMII_N_BitShift     = 7,
 	ARMII_ImmHiShift     = 8,
 	ARMII_SoRotImmShift  = 8,
 	ARMII_RegRsShift     = 8,
 	ARMII_ExtRotImmShift = 10,
 	ARMII_RegRdLoShift   = 12,
 	ARMII_RegRdShift     = 12,
 	ARMII_RegRdHiShift   = 16,
 	ARMII_RegRnShift     = 16,
 	ARMII_S_BitShift     = 20,
 	ARMII_W_BitShift     = 21,
 	ARMII_AM3_I_BitShift = 22,
 	ARMII_D_BitShift     = 22,
 	ARMII_U_BitShift     = 23,
 	ARMII_P_BitShift     = 24,
 	ARMII_I_BitShift     = 25,
 	ARMII_CondShift      = 28
 };

 #endif
	//===-- ARMBaseInfo.h - Top level definitions for ARM -------- --- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file contains small standalone helper functions and enum definitions for
	// the ARM target useful for the compiler back-end and the MC libraries.
	// As such, it deliberately does not include references to LLVM core
	// code gen types, passes, etc..
	//
	//===----------------------------------------------------------------------===//

	/* Capstone Disassembly Engine */
	/* By Nguyen Anh Quynh <aquynh@gmail.com>, 2013-2015 */

	#ifndef CS_ARMBASEINFO_H
	#define CS_ARMBASEINFO_H

	#include "capstone/arm.h"

	// Defines symbolic names for ARM registers. This defines a mapping from
	// register name to register number.
	//
	#define GET_REGINFO_ENUM
	#include "ARMGenRegisterInfo.inc"

	// Enums corresponding to ARM condition codes
	// The CondCodes constants map directly to the 4-bit encoding of the
	// condition field for predicated instructions.
	typedef enum ARMCC_CondCodes { // Meaning (integer) Meaning (floating-point)
	ARMCC_EQ, // Equal Equal
	ARMCC_NE, // Not equal Not equal, or unordered
	ARMCC_HS, // Carry set >, ==, or unordered
	ARMCC_LO, // Carry clear Less than
	ARMCC_MI, // Minus, negative Less than
	ARMCC_PL, // Plus, positive or zero >, ==, or unordered
	ARMCC_VS, // Overflow Unordered
	ARMCC_VC, // No overflow Not unordered
	ARMCC_HI, // Unsigned higher Greater than, or unordered
	ARMCC_LS, // Unsigned lower or same Less than or equal
	ARMCC_GE, // Greater than or equal Greater than or equal
	ARMCC_LT, // Less than Less than, or unordered
	ARMCC_GT, // Greater than Greater than
	ARMCC_LE, // Less than or equal <, ==, or unordered
	ARMCC_AL // Always (unconditional) Always (unconditional)
	} ARMCC_CondCodes;

	inline static ARMCC_CondCodes ARMCC_getOppositeCondition(ARMCC_CondCodes CC)
	{
	switch (CC) {
	case ARMCC_EQ: return ARMCC_NE;
	case ARMCC_NE: return ARMCC_EQ;
	case ARMCC_HS: return ARMCC_LO;
	case ARMCC_LO: return ARMCC_HS;
	case ARMCC_MI: return ARMCC_PL;
	case ARMCC_PL: return ARMCC_MI;
	case ARMCC_VS: return ARMCC_VC;
	case ARMCC_VC: return ARMCC_VS;
	case ARMCC_HI: return ARMCC_LS;
	case ARMCC_LS: return ARMCC_HI;
	case ARMCC_GE: return ARMCC_LT;
	case ARMCC_LT: return ARMCC_GE;
	case ARMCC_GT: return ARMCC_LE;
	case ARMCC_LE: return ARMCC_GT;
	default: return ARMCC_AL;
	}
	}

	inline static char *ARMCC_ARMCondCodeToString(ARMCC_CondCodes CC)
	{
	switch (CC) {
	case ARMCC_EQ: return "eq";
	case ARMCC_NE: return "ne";
	case ARMCC_HS: return "hs";
	case ARMCC_LO: return "lo";
	case ARMCC_MI: return "mi";
	case ARMCC_PL: return "pl";
	case ARMCC_VS: return "vs";
	case ARMCC_VC: return "vc";
	case ARMCC_HI: return "hi";
	case ARMCC_LS: return "ls";
	case ARMCC_GE: return "ge";
	case ARMCC_LT: return "lt";
	case ARMCC_GT: return "gt";
	case ARMCC_LE: return "le";
	case ARMCC_AL: return "al";
	default: return "";
	}
	}

	inline static char *ARM_PROC_IFlagsToString(unsigned val)
	{
	switch (val) {
	case ARM_CPSFLAG_F: return "f";
	case ARM_CPSFLAG_I: return "i";
	case ARM_CPSFLAG_A: return "a";
	default: return "";
	}
	}

	inline static char *ARM_PROC_IModToString(unsigned val)
	{
	switch (val) {
	case ARM_CPSMODE_IE: return "ie";
	case ARM_CPSMODE_ID: return "id";
	default: return "";
	}
	}

	inline static char *ARM_MB_MemBOptToString(unsigned val, bool HasV8)
	{
	switch (val) {
	default: return "BUGBUG";
	case ARM_MB_SY: return "sy";
	case ARM_MB_ST: return "st";
	case ARM_MB_LD: return HasV8 ? "ld" : "#0xd";
	case ARM_MB_RESERVED_12: return "#0xc";
	case ARM_MB_ISH: return "ish";
	case ARM_MB_ISHST: return "ishst";
	case ARM_MB_ISHLD: return HasV8 ? "ishld" : "#0x9";
	case ARM_MB_RESERVED_8: return "#0x8";
	case ARM_MB_NSH: return "nsh";
	case ARM_MB_NSHST: return "nshst";
	case ARM_MB_NSHLD: return HasV8 ? "nshld" : "#0x5";
	case ARM_MB_RESERVED_4: return "#0x4";
	case ARM_MB_OSH: return "osh";
	case ARM_MB_OSHST: return "oshst";
	case ARM_MB_OSHLD: return HasV8 ? "oshld" : "#0x1";
	case ARM_MB_RESERVED_0: return "#0x0";
	}
	}

	enum ARM_ISB_InstSyncBOpt {
	ARM_ISB_RESERVED_0 = 0,
	ARM_ISB_RESERVED_1 = 1,
	ARM_ISB_RESERVED_2 = 2,
	ARM_ISB_RESERVED_3 = 3,
	ARM_ISB_RESERVED_4 = 4,
	ARM_ISB_RESERVED_5 = 5,
	ARM_ISB_RESERVED_6 = 6,
	ARM_ISB_RESERVED_7 = 7,
	ARM_ISB_RESERVED_8 = 8,
	ARM_ISB_RESERVED_9 = 9,
	ARM_ISB_RESERVED_10 = 10,
	ARM_ISB_RESERVED_11 = 11,
	ARM_ISB_RESERVED_12 = 12,
	ARM_ISB_RESERVED_13 = 13,
	ARM_ISB_RESERVED_14 = 14,
	ARM_ISB_SY = 15
	};

	inline static char *ARM_ISB_InstSyncBOptToString(unsigned val)
	{
	switch (val) {
	default: // never reach
	case ARM_ISB_RESERVED_0: return "#0x0";
	case ARM_ISB_RESERVED_1: return "#0x1";
	case ARM_ISB_RESERVED_2: return "#0x2";
	case ARM_ISB_RESERVED_3: return "#0x3";
	case ARM_ISB_RESERVED_4: return "#0x4";
	case ARM_ISB_RESERVED_5: return "#0x5";
	case ARM_ISB_RESERVED_6: return "#0x6";
	case ARM_ISB_RESERVED_7: return "#0x7";
	case ARM_ISB_RESERVED_8: return "#0x8";
	case ARM_ISB_RESERVED_9: return "#0x9";
	case ARM_ISB_RESERVED_10: return "#0xa";
	case ARM_ISB_RESERVED_11: return "#0xb";
	case ARM_ISB_RESERVED_12: return "#0xc";
	case ARM_ISB_RESERVED_13: return "#0xd";
	case ARM_ISB_RESERVED_14: return "#0xe";
	case ARM_ISB_SY: return "sy";
	}
	}

	/// isARMLowRegister - Returns true if the register is a low register (r0-r7).
	///
	static inline bool isARMLowRegister(unsigned Reg)
	{
	//using namespace ARM;
	switch (Reg) {
	case ARM_R0: case ARM_R1: case ARM_R2: case ARM_R3:
	case ARM_R4: case ARM_R5: case ARM_R6: case ARM_R7:
	return true;
	default:
	return false;
	}
	}

	/// ARMII - This namespace holds all of the target specific flags that
	/// instruction info tracks.
	///
	/// ARM Index Modes
	enum ARMII_IndexMode {
	ARMII_IndexModeNone = 0,
	ARMII_IndexModePre = 1,
	ARMII_IndexModePost = 2,
	ARMII_IndexModeUpd = 3
	};

	/// ARM Addressing Modes
	typedef enum ARMII_AddrMode {
	ARMII_AddrModeNone = 0,
	ARMII_AddrMode1 = 1,
	ARMII_AddrMode2 = 2,
	ARMII_AddrMode3 = 3,
	ARMII_AddrMode4 = 4,
	ARMII_AddrMode5 = 5,
	ARMII_AddrMode6 = 6,
	ARMII_AddrModeT1_1 = 7,
	ARMII_AddrModeT1_2 = 8,
	ARMII_AddrModeT1_4 = 9,
	ARMII_AddrModeT1_s = 10, // i8 * 4 for pc and sp relative data
	ARMII_AddrModeT2_i12 = 11,
	ARMII_AddrModeT2_i8 = 12,
	ARMII_AddrModeT2_so = 13,
	ARMII_AddrModeT2_pc = 14, // +/- i12 for pc relative data
	ARMII_AddrModeT2_i8s4 = 15, // i8 * 4
	ARMII_AddrMode_i12 = 16
	} ARMII_AddrMode;

	inline static char *ARMII_AddrModeToString(ARMII_AddrMode addrmode)
	{
	switch (addrmode) {
	case ARMII_AddrModeNone: return "AddrModeNone";
	case ARMII_AddrMode1: return "AddrMode1";
	case ARMII_AddrMode2: return "AddrMode2";
	case ARMII_AddrMode3: return "AddrMode3";
	case ARMII_AddrMode4: return "AddrMode4";
	case ARMII_AddrMode5: return "AddrMode5";
	case ARMII_AddrMode6: return "AddrMode6";
	case ARMII_AddrModeT1_1: return "AddrModeT1_1";
	case ARMII_AddrModeT1_2: return "AddrModeT1_2";
	case ARMII_AddrModeT1_4: return "AddrModeT1_4";
	case ARMII_AddrModeT1_s: return "AddrModeT1_s";
	case ARMII_AddrModeT2_i12: return "AddrModeT2_i12";
	case ARMII_AddrModeT2_i8: return "AddrModeT2_i8";
	case ARMII_AddrModeT2_so: return "AddrModeT2_so";
	case ARMII_AddrModeT2_pc: return "AddrModeT2_pc";
	case ARMII_AddrModeT2_i8s4: return "AddrModeT2_i8s4";
	case ARMII_AddrMode_i12: return "AddrMode_i12";
	}
	}

	/// Target Operand Flag enum.
	enum ARMII_TOF {
	//===------------------------------------------------------------------===//
	// ARM Specific MachineOperand flags.

	ARMII_MO_NO_FLAG,

	/// MO_LO16 - On a symbol operand, this represents a relocation containing
	/// lower 16 bit of the address. Used only via movw instruction.
	ARMII_MO_LO16,

	/// MO_HI16 - On a symbol operand, this represents a relocation containing
	/// higher 16 bit of the address. Used only via movt instruction.
	ARMII_MO_HI16,

	/// MO_LO16_NONLAZY - On a symbol operand "FOO", this represents a
	/// relocation containing lower 16 bit of the non-lazy-ptr indirect symbol,
	/// i.e. "FOO$non_lazy_ptr".
	/// Used only via movw instruction.
	ARMII_MO_LO16_NONLAZY,

	/// MO_HI16_NONLAZY - On a symbol operand "FOO", this represents a
	/// relocation containing lower 16 bit of the non-lazy-ptr indirect symbol,
	/// i.e. "FOO$non_lazy_ptr". Used only via movt instruction.
	ARMII_MO_HI16_NONLAZY,

	/// MO_LO16_NONLAZY_PIC - On a symbol operand "FOO", this represents a
	/// relocation containing lower 16 bit of the PC relative address of the
	/// non-lazy-ptr indirect symbol, i.e. "FOO$non_lazy_ptr - LABEL".
	/// Used only via movw instruction.
	ARMII_MO_LO16_NONLAZY_PIC,

	/// MO_HI16_NONLAZY_PIC - On a symbol operand "FOO", this represents a
	/// relocation containing lower 16 bit of the PC relative address of the
	/// non-lazy-ptr indirect symbol, i.e. "FOO$non_lazy_ptr - LABEL".
	/// Used only via movt instruction.
	ARMII_MO_HI16_NONLAZY_PIC,

	/// MO_PLT - On a symbol operand, this represents an ELF PLT reference on a
	/// call operand.
	ARMII_MO_PLT
	};

	enum {
	//===------------------------------------------------------------------===//
	// Instruction Flags.

	//===------------------------------------------------------------------===//
	// This four-bit field describes the addressing mode used.
	ARMII_AddrModeMask = 0x1f, // The AddrMode enums are declared in ARMBaseInfo.h

	// IndexMode - Unindex, pre-indexed, or post-indexed are valid for load
	// and store ops only. Generic "updating" flag is used for ld/st multiple.
	// The index mode enums are declared in ARMBaseInfo.h
	ARMII_IndexModeShift = 5,
	ARMII_IndexModeMask = 3 << ARMII_IndexModeShift,

	//===------------------------------------------------------------------===//
	// Instruction encoding formats.
	//
	ARMII_FormShift = 7,
	ARMII_FormMask = 0x3f << ARMII_FormShift,

	// Pseudo instructions
	ARMII_Pseudo = 0 << ARMII_FormShift,

	// Multiply instructions
	ARMII_MulFrm = 1 << ARMII_FormShift,

	// Branch instructions
	ARMII_BrFrm = 2 << ARMII_FormShift,
	ARMII_BrMiscFrm = 3 << ARMII_FormShift,

	// Data Processing instructions
	ARMII_DPFrm = 4 << ARMII_FormShift,
	ARMII_DPSoRegFrm = 5 << ARMII_FormShift,

	// Load and Store
	ARMII_LdFrm = 6 << ARMII_FormShift,
	ARMII_StFrm = 7 << ARMII_FormShift,
	ARMII_LdMiscFrm = 8 << ARMII_FormShift,
	ARMII_StMiscFrm = 9 << ARMII_FormShift,
	ARMII_LdStMulFrm = 10 << ARMII_FormShift,

	ARMII_LdStExFrm = 11 << ARMII_FormShift,

	// Miscellaneous arithmetic instructions
	ARMII_ArithMiscFrm = 12 << ARMII_FormShift,
	ARMII_SatFrm = 13 << ARMII_FormShift,

	// Extend instructions
	ARMII_ExtFrm = 14 << ARMII_FormShift,

	// VFP formats
	ARMII_VFPUnaryFrm = 15 << ARMII_FormShift,
	ARMII_VFPBinaryFrm = 16 << ARMII_FormShift,
	ARMII_VFPConv1Frm = 17 << ARMII_FormShift,
	ARMII_VFPConv2Frm = 18 << ARMII_FormShift,
	ARMII_VFPConv3Frm = 19 << ARMII_FormShift,
	ARMII_VFPConv4Frm = 20 << ARMII_FormShift,
	ARMII_VFPConv5Frm = 21 << ARMII_FormShift,
	ARMII_VFPLdStFrm = 22 << ARMII_FormShift,
	ARMII_VFPLdStMulFrm = 23 << ARMII_FormShift,
	ARMII_VFPMiscFrm = 24 << ARMII_FormShift,

	// Thumb format
	ARMII_ThumbFrm = 25 << ARMII_FormShift,

	// Miscelleaneous format
	ARMII_MiscFrm = 26 << ARMII_FormShift,

	// NEON formats
	ARMII_NGetLnFrm = 27 << ARMII_FormShift,
	ARMII_NSetLnFrm = 28 << ARMII_FormShift,
	ARMII_NDupFrm = 29 << ARMII_FormShift,
	ARMII_NLdStFrm = 30 << ARMII_FormShift,
	ARMII_N1RegModImmFrm= 31 << ARMII_FormShift,
	ARMII_N2RegFrm = 32 << ARMII_FormShift,
	ARMII_NVCVTFrm = 33 << ARMII_FormShift,
	ARMII_NVDupLnFrm = 34 << ARMII_FormShift,
	ARMII_N2RegVShLFrm = 35 << ARMII_FormShift,
	ARMII_N2RegVShRFrm = 36 << ARMII_FormShift,
	ARMII_N3RegFrm = 37 << ARMII_FormShift,
	ARMII_N3RegVShFrm = 38 << ARMII_FormShift,
	ARMII_NVExtFrm = 39 << ARMII_FormShift,
	ARMII_NVMulSLFrm = 40 << ARMII_FormShift,
	ARMII_NVTBLFrm = 41 << ARMII_FormShift,

	//===------------------------------------------------------------------===//
	// Misc flags.

	// UnaryDP - Indicates this is a unary data processing instruction, i.e.
	// it doesn't have a Rn operand.
	ARMII_UnaryDP = 1 << 13,

	// Xform16Bit - Indicates this Thumb2 instruction may be transformed into
	// a 16-bit Thumb instruction if certain conditions are met.
	ARMII_Xform16Bit = 1 << 14,

	// ThumbArithFlagSetting - The instruction is a 16-bit flag setting Thumb
	// instruction. Used by the parser to determine whether to require the 'S'
	// suffix on the mnemonic (when not in an IT block) or preclude it (when
	// in an IT block).
	ARMII_ThumbArithFlagSetting = 1 << 18,

	//===------------------------------------------------------------------===//
	// Code domain.
	ARMII_DomainShift = 15,
	ARMII_DomainMask = 7 << ARMII_DomainShift,
	ARMII_DomainGeneral = 0 << ARMII_DomainShift,
	ARMII_DomainVFP = 1 << ARMII_DomainShift,
	ARMII_DomainNEON = 2 << ARMII_DomainShift,
	ARMII_DomainNEONA8 = 4 << ARMII_DomainShift,

	//===------------------------------------------------------------------===//
	// Field shifts - such shifts are used to set field while generating
	// machine instructions.
	//
	// FIXME: This list will need adjusting/fixing as the MC code emitter
	// takes shape and the ARMCodeEmitter.cpp bits go away.
	ARMII_ShiftTypeShift = 4,

	ARMII_M_BitShift = 5,
	ARMII_ShiftImmShift = 5,
	ARMII_ShiftShift = 7,
	ARMII_N_BitShift = 7,
	ARMII_ImmHiShift = 8,
	ARMII_SoRotImmShift = 8,
	ARMII_RegRsShift = 8,
	ARMII_ExtRotImmShift = 10,
	ARMII_RegRdLoShift = 12,
	ARMII_RegRdShift = 12,
	ARMII_RegRdHiShift = 16,
	ARMII_RegRnShift = 16,
	ARMII_S_BitShift = 20,
	ARMII_W_BitShift = 21,
	ARMII_AM3_I_BitShift = 22,
	ARMII_D_BitShift = 22,
	ARMII_U_BitShift = 23,
	ARMII_P_BitShift = 24,
	ARMII_I_BitShift = 25,
	ARMII_CondShift = 28
	};

	#endif