llvm-for-llvmta/lib/Target/RISCV/MCTargetDesc/RISCVBaseInfo.h

//===-- RISCVBaseInfo.h - Top level definitions for RISCV MC ----*- C++ -*-===//
//
// 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 contains small standalone enum definitions for the RISCV target
// useful for the compiler back-end and the MC libraries.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_LIB_TARGET_RISCV_MCTARGETDESC_RISCVBASEINFO_H
#define LLVM_LIB_TARGET_RISCV_MCTARGETDESC_RISCVBASEINFO_H

#include "MCTargetDesc/RISCVMCTargetDesc.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/ADT/StringSwitch.h"
#include "llvm/MC/MCInstrDesc.h"
#include "llvm/MC/SubtargetFeature.h"
#include "llvm/Support/MachineValueType.h"

namespace llvm {

// RISCVII - This namespace holds all of the target specific flags that
// instruction info tracks. All definitions must match RISCVInstrFormats.td.
namespace RISCVII {
enum {
  InstFormatPseudo = 0,
  InstFormatR = 1,
  InstFormatR4 = 2,
  InstFormatI = 3,
  InstFormatS = 4,
  InstFormatB = 5,
  InstFormatU = 6,
  InstFormatJ = 7,
  InstFormatCR = 8,
  InstFormatCI = 9,
  InstFormatCSS = 10,
  InstFormatCIW = 11,
  InstFormatCL = 12,
  InstFormatCS = 13,
  InstFormatCA = 14,
  InstFormatCB = 15,
  InstFormatCJ = 16,
  InstFormatOther = 17,

  InstFormatMask = 31,

  ConstraintShift = 5,
  ConstraintMask = 0b111 << ConstraintShift,

  VLMulShift = ConstraintShift + 3,
  VLMulMask = 0b111 << VLMulShift,

  // Do we need to add a dummy mask op when converting RVV Pseudo to MCInst.
  HasDummyMaskOpShift = VLMulShift + 3,
  HasDummyMaskOpMask = 1 << HasDummyMaskOpShift,

  // Does this instruction only update element 0 the destination register.
  WritesElement0Shift = HasDummyMaskOpShift + 1,
  WritesElement0Mask = 1 << WritesElement0Shift,

  // Does this instruction have a merge operand that must be removed when
  // converting to MCInst. It will be the first explicit use operand. Used by
  // RVV Pseudos.
  HasMergeOpShift = WritesElement0Shift + 1,
  HasMergeOpMask = 1 << HasMergeOpShift,

  // Does this instruction have a SEW operand. It will be the last explicit
  // operand. Used by RVV Pseudos.
  HasSEWOpShift = HasMergeOpShift + 1,
  HasSEWOpMask = 1 << HasSEWOpShift,

  // Does this instruction have a VL operand. It will be the second to last
  // explicit operand. Used by RVV Pseudos.
  HasVLOpShift = HasSEWOpShift + 1,
  HasVLOpMask = 1 << HasVLOpShift,
};

// Match with the definitions in RISCVInstrFormatsV.td
enum RVVConstraintType {
  NoConstraint = 0,
  VS2Constraint = 0b001,
  VS1Constraint = 0b010,
  VMConstraint = 0b100,
};

// RISC-V Specific Machine Operand Flags
enum {
  MO_None = 0,
  MO_CALL = 1,
  MO_PLT = 2,
  MO_LO = 3,
  MO_HI = 4,
  MO_PCREL_LO = 5,
  MO_PCREL_HI = 6,
  MO_GOT_HI = 7,
  MO_TPREL_LO = 8,
  MO_TPREL_HI = 9,
  MO_TPREL_ADD = 10,
  MO_TLS_GOT_HI = 11,
  MO_TLS_GD_HI = 12,

  // Used to differentiate between target-specific "direct" flags and "bitmask"
  // flags. A machine operand can only have one "direct" flag, but can have
  // multiple "bitmask" flags.
  MO_DIRECT_FLAG_MASK = 15
};
} // namespace RISCVII

namespace RISCVOp {
enum OperandType : unsigned {
  OPERAND_FIRST_RISCV_IMM = MCOI::OPERAND_FIRST_TARGET,
  OPERAND_UIMM4 = OPERAND_FIRST_RISCV_IMM,
  OPERAND_UIMM5,
  OPERAND_UIMM12,
  OPERAND_SIMM12,
  OPERAND_UIMM20,
  OPERAND_UIMMLOG2XLEN,
  OPERAND_LAST_RISCV_IMM = OPERAND_UIMMLOG2XLEN
};
} // namespace RISCVOp

// Describes the predecessor/successor bits used in the FENCE instruction.
namespace RISCVFenceField {
enum FenceField {
  I = 8,
  O = 4,
  R = 2,
  W = 1
};
}

// Describes the supported floating point rounding mode encodings.
namespace RISCVFPRndMode {
enum RoundingMode {
  RNE = 0,
  RTZ = 1,
  RDN = 2,
  RUP = 3,
  RMM = 4,
  DYN = 7,
  Invalid
};

inline static StringRef roundingModeToString(RoundingMode RndMode) {
  switch (RndMode) {
  default:
    llvm_unreachable("Unknown floating point rounding mode");
  case RISCVFPRndMode::RNE:
    return "rne";
  case RISCVFPRndMode::RTZ:
    return "rtz";
  case RISCVFPRndMode::RDN:
    return "rdn";
  case RISCVFPRndMode::RUP:
    return "rup";
  case RISCVFPRndMode::RMM:
    return "rmm";
  case RISCVFPRndMode::DYN:
    return "dyn";
  }
}

inline static RoundingMode stringToRoundingMode(StringRef Str) {
  return StringSwitch<RoundingMode>(Str)
      .Case("rne", RISCVFPRndMode::RNE)
      .Case("rtz", RISCVFPRndMode::RTZ)
      .Case("rdn", RISCVFPRndMode::RDN)
      .Case("rup", RISCVFPRndMode::RUP)
      .Case("rmm", RISCVFPRndMode::RMM)
      .Case("dyn", RISCVFPRndMode::DYN)
      .Default(RISCVFPRndMode::Invalid);
}

inline static bool isValidRoundingMode(unsigned Mode) {
  switch (Mode) {
  default:
    return false;
  case RISCVFPRndMode::RNE:
  case RISCVFPRndMode::RTZ:
  case RISCVFPRndMode::RDN:
  case RISCVFPRndMode::RUP:
  case RISCVFPRndMode::RMM:
  case RISCVFPRndMode::DYN:
    return true;
  }
}
} // namespace RISCVFPRndMode

namespace RISCVSysReg {
struct SysReg {
  const char *Name;
  unsigned Encoding;
  const char *AltName;
  // FIXME: add these additional fields when needed.
  // Privilege Access: Read, Write, Read-Only.
  // unsigned ReadWrite;
  // Privilege Mode: User, System or Machine.
  // unsigned Mode;
  // Check field name.
  // unsigned Extra;
  // Register number without the privilege bits.
  // unsigned Number;
  FeatureBitset FeaturesRequired;
  bool isRV32Only;

  bool haveRequiredFeatures(FeatureBitset ActiveFeatures) const {
    // Not in 32-bit mode.
    if (isRV32Only && ActiveFeatures[RISCV::Feature64Bit])
      return false;
    // No required feature associated with the system register.
    if (FeaturesRequired.none())
      return true;
    return (FeaturesRequired & ActiveFeatures) == FeaturesRequired;
  }
};

#define GET_SysRegsList_DECL
#include "RISCVGenSearchableTables.inc"
} // end namespace RISCVSysReg

namespace RISCVABI {

enum ABI {
  ABI_ILP32,
  ABI_ILP32F,
  ABI_ILP32D,
  ABI_ILP32E,
  ABI_LP64,
  ABI_LP64F,
  ABI_LP64D,
  ABI_Unknown
};

// Returns the target ABI, or else a StringError if the requested ABIName is
// not supported for the given TT and FeatureBits combination.
ABI computeTargetABI(const Triple &TT, FeatureBitset FeatureBits,
                     StringRef ABIName);

ABI getTargetABI(StringRef ABIName);

// Returns the register used to hold the stack pointer after realignment.
MCRegister getBPReg();

// Returns the register holding shadow call stack pointer.
MCRegister getSCSPReg();

} // namespace RISCVABI

namespace RISCVFeatures {

// Validates if the given combination of features are valid for the target
// triple. Exits with report_fatal_error if not.
void validate(const Triple &TT, const FeatureBitset &FeatureBits);

} // namespace RISCVFeatures

namespace RISCVVMVTs {

constexpr MVT vint8mf8_t = MVT::nxv1i8;
constexpr MVT vint8mf4_t = MVT::nxv2i8;
constexpr MVT vint8mf2_t = MVT::nxv4i8;
constexpr MVT vint8m1_t = MVT::nxv8i8;
constexpr MVT vint8m2_t = MVT::nxv16i8;
constexpr MVT vint8m4_t = MVT::nxv32i8;
constexpr MVT vint8m8_t = MVT::nxv64i8;

constexpr MVT vint16mf4_t = MVT::nxv1i16;
constexpr MVT vint16mf2_t = MVT::nxv2i16;
constexpr MVT vint16m1_t = MVT::nxv4i16;
constexpr MVT vint16m2_t = MVT::nxv8i16;
constexpr MVT vint16m4_t = MVT::nxv16i16;
constexpr MVT vint16m8_t = MVT::nxv32i16;

constexpr MVT vint32mf2_t = MVT::nxv1i32;
constexpr MVT vint32m1_t = MVT::nxv2i32;
constexpr MVT vint32m2_t = MVT::nxv4i32;
constexpr MVT vint32m4_t = MVT::nxv8i32;
constexpr MVT vint32m8_t = MVT::nxv16i32;

constexpr MVT vint64m1_t = MVT::nxv1i64;
constexpr MVT vint64m2_t = MVT::nxv2i64;
constexpr MVT vint64m4_t = MVT::nxv4i64;
constexpr MVT vint64m8_t = MVT::nxv8i64;

constexpr MVT vfloat16mf4_t = MVT::nxv1f16;
constexpr MVT vfloat16mf2_t = MVT::nxv2f16;
constexpr MVT vfloat16m1_t = MVT::nxv4f16;
constexpr MVT vfloat16m2_t = MVT::nxv8f16;
constexpr MVT vfloat16m4_t = MVT::nxv16f16;
constexpr MVT vfloat16m8_t = MVT::nxv32f16;

constexpr MVT vfloat32mf2_t = MVT::nxv1f32;
constexpr MVT vfloat32m1_t = MVT::nxv2f32;
constexpr MVT vfloat32m2_t = MVT::nxv4f32;
constexpr MVT vfloat32m4_t = MVT::nxv8f32;
constexpr MVT vfloat32m8_t = MVT::nxv16f32;

constexpr MVT vfloat64m1_t = MVT::nxv1f64;
constexpr MVT vfloat64m2_t = MVT::nxv2f64;
constexpr MVT vfloat64m4_t = MVT::nxv4f64;
constexpr MVT vfloat64m8_t = MVT::nxv8f64;

constexpr MVT vbool1_t = MVT::nxv64i1;
constexpr MVT vbool2_t = MVT::nxv32i1;
constexpr MVT vbool4_t = MVT::nxv16i1;
constexpr MVT vbool8_t = MVT::nxv8i1;
constexpr MVT vbool16_t = MVT::nxv4i1;
constexpr MVT vbool32_t = MVT::nxv2i1;
constexpr MVT vbool64_t = MVT::nxv1i1;

} // namespace RISCVVMVTs

enum class RISCVVSEW {
  SEW_8 = 0,
  SEW_16,
  SEW_32,
  SEW_64,
  SEW_128,
  SEW_256,
  SEW_512,
  SEW_1024,
};

enum class RISCVVLMUL {
  LMUL_1 = 0,
  LMUL_2,
  LMUL_4,
  LMUL_8,
  LMUL_RESERVED,
  LMUL_F8,
  LMUL_F4,
  LMUL_F2
};

namespace RISCVVType {
// Is this a SEW value that can be encoded into the VTYPE format.
inline static bool isValidSEW(unsigned SEW) {
  return isPowerOf2_32(SEW) && SEW >= 8 && SEW <= 1024;
}

// Is this a LMUL value that can be encoded into the VTYPE format.
inline static bool isValidLMUL(unsigned LMUL, bool Fractional) {
  return isPowerOf2_32(LMUL) && LMUL <= 8 && (!Fractional || LMUL != 1);
}

// Encode VTYPE into the binary format used by the the VSETVLI instruction which
// is used by our MC layer representation.
//
// Bits | Name       | Description
// -----+------------+------------------------------------------------
// 7    | vma        | Vector mask agnostic
// 6    | vta        | Vector tail agnostic
// 5:3  | vsew[2:0]  | Standard element width (SEW) setting
// 2:0  | vlmul[2:0] | Vector register group multiplier (LMUL) setting
inline static unsigned encodeVTYPE(RISCVVLMUL VLMUL, RISCVVSEW VSEW,
                                   bool TailAgnostic, bool MaskAgnostic) {
  unsigned VLMULBits = static_cast<unsigned>(VLMUL);
  unsigned VSEWBits = static_cast<unsigned>(VSEW);
  unsigned VTypeI = (VSEWBits << 3) | (VLMULBits & 0x7);
  if (TailAgnostic)
    VTypeI |= 0x40;
  if (MaskAgnostic)
    VTypeI |= 0x80;

  return VTypeI;
}

inline static RISCVVLMUL getVLMUL(unsigned VType) {
  unsigned VLMUL = VType & 0x7;
  return static_cast<RISCVVLMUL>(VLMUL);
}

inline static RISCVVSEW getVSEW(unsigned VType) {
  unsigned VSEW = (VType >> 3) & 0x7;
  return static_cast<RISCVVSEW>(VSEW);
}

inline static bool isTailAgnostic(unsigned VType) { return VType & 0x40; }

inline static bool isMaskAgnostic(unsigned VType) { return VType & 0x80; }

void printVType(unsigned VType, raw_ostream &OS);

} // namespace RISCVVType

namespace RISCVVPseudosTable {

struct PseudoInfo {
#include "MCTargetDesc/RISCVBaseInfo.h"
  uint16_t Pseudo;
  uint16_t BaseInstr;
};

using namespace RISCV;

#define GET_RISCVVPseudosTable_DECL
#include "RISCVGenSearchableTables.inc"

} // end namespace RISCVVPseudosTable

} // namespace llvm

#endif
first commit 2022-04-25 10:02:23 +02:00			`//===-- RISCVBaseInfo.h - Top level definitions for RISCV MC ----- C++ --===//`
			`//`
			`// 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 contains small standalone enum definitions for the RISCV target`
			`// useful for the compiler back-end and the MC libraries.`
			`//`
			`//===----------------------------------------------------------------------===//`
			`#ifndef LLVM_LIB_TARGET_RISCV_MCTARGETDESC_RISCVBASEINFO_H`
			`#define LLVM_LIB_TARGET_RISCV_MCTARGETDESC_RISCVBASEINFO_H`

			`#include "MCTargetDesc/RISCVMCTargetDesc.h"`
			`#include "llvm/ADT/StringRef.h"`
			`#include "llvm/ADT/StringSwitch.h"`
			`#include "llvm/MC/MCInstrDesc.h"`
			`#include "llvm/MC/SubtargetFeature.h"`
			`#include "llvm/Support/MachineValueType.h"`

			`namespace llvm {`

			`// RISCVII - This namespace holds all of the target specific flags that`
			`// instruction info tracks. All definitions must match RISCVInstrFormats.td.`
			`namespace RISCVII {`
			`enum {`
			`InstFormatPseudo = 0,`
			`InstFormatR = 1,`
			`InstFormatR4 = 2,`
			`InstFormatI = 3,`
			`InstFormatS = 4,`
			`InstFormatB = 5,`
			`InstFormatU = 6,`
			`InstFormatJ = 7,`
			`InstFormatCR = 8,`
			`InstFormatCI = 9,`
			`InstFormatCSS = 10,`
			`InstFormatCIW = 11,`
			`InstFormatCL = 12,`
			`InstFormatCS = 13,`
			`InstFormatCA = 14,`
			`InstFormatCB = 15,`
			`InstFormatCJ = 16,`
			`InstFormatOther = 17,`

			`InstFormatMask = 31,`

			`ConstraintShift = 5,`
			`ConstraintMask = 0b111 << ConstraintShift,`

			`VLMulShift = ConstraintShift + 3,`
			`VLMulMask = 0b111 << VLMulShift,`

			`// Do we need to add a dummy mask op when converting RVV Pseudo to MCInst.`
			`HasDummyMaskOpShift = VLMulShift + 3,`
			`HasDummyMaskOpMask = 1 << HasDummyMaskOpShift,`

			`// Does this instruction only update element 0 the destination register.`
			`WritesElement0Shift = HasDummyMaskOpShift + 1,`
			`WritesElement0Mask = 1 << WritesElement0Shift,`

			`// Does this instruction have a merge operand that must be removed when`
			`// converting to MCInst. It will be the first explicit use operand. Used by`
			`// RVV Pseudos.`
			`HasMergeOpShift = WritesElement0Shift + 1,`
			`HasMergeOpMask = 1 << HasMergeOpShift,`

			`// Does this instruction have a SEW operand. It will be the last explicit`
			`// operand. Used by RVV Pseudos.`
			`HasSEWOpShift = HasMergeOpShift + 1,`
			`HasSEWOpMask = 1 << HasSEWOpShift,`

			`// Does this instruction have a VL operand. It will be the second to last`
			`// explicit operand. Used by RVV Pseudos.`
			`HasVLOpShift = HasSEWOpShift + 1,`
			`HasVLOpMask = 1 << HasVLOpShift,`
			`};`

			`// Match with the definitions in RISCVInstrFormatsV.td`
			`enum RVVConstraintType {`
			`NoConstraint = 0,`
			`VS2Constraint = 0b001,`
			`VS1Constraint = 0b010,`
			`VMConstraint = 0b100,`
			`};`

			`// RISC-V Specific Machine Operand Flags`
			`enum {`
			`MO_None = 0,`
			`MO_CALL = 1,`
			`MO_PLT = 2,`
			`MO_LO = 3,`
			`MO_HI = 4,`
			`MO_PCREL_LO = 5,`
			`MO_PCREL_HI = 6,`
			`MO_GOT_HI = 7,`
			`MO_TPREL_LO = 8,`
			`MO_TPREL_HI = 9,`
			`MO_TPREL_ADD = 10,`
			`MO_TLS_GOT_HI = 11,`
			`MO_TLS_GD_HI = 12,`

			`// Used to differentiate between target-specific "direct" flags and "bitmask"`
			`// flags. A machine operand can only have one "direct" flag, but can have`
			`// multiple "bitmask" flags.`
			`MO_DIRECT_FLAG_MASK = 15`
			`};`
			`} // namespace RISCVII`

			`namespace RISCVOp {`
			`enum OperandType : unsigned {`
			`OPERAND_FIRST_RISCV_IMM = MCOI::OPERAND_FIRST_TARGET,`
			`OPERAND_UIMM4 = OPERAND_FIRST_RISCV_IMM,`
			`OPERAND_UIMM5,`
			`OPERAND_UIMM12,`
			`OPERAND_SIMM12,`
			`OPERAND_UIMM20,`
			`OPERAND_UIMMLOG2XLEN,`
			`OPERAND_LAST_RISCV_IMM = OPERAND_UIMMLOG2XLEN`
			`};`
			`} // namespace RISCVOp`

			`// Describes the predecessor/successor bits used in the FENCE instruction.`
			`namespace RISCVFenceField {`
			`enum FenceField {`
			`I = 8,`
			`O = 4,`
			`R = 2,`
			`W = 1`
			`};`
			`}`

			`// Describes the supported floating point rounding mode encodings.`
			`namespace RISCVFPRndMode {`
			`enum RoundingMode {`
			`RNE = 0,`
			`RTZ = 1,`
			`RDN = 2,`
			`RUP = 3,`
			`RMM = 4,`
			`DYN = 7,`
			`Invalid`
			`};`

			`inline static StringRef roundingModeToString(RoundingMode RndMode) {`
			`switch (RndMode) {`
			`default:`
			`llvm_unreachable("Unknown floating point rounding mode");`
			`case RISCVFPRndMode::RNE:`
			`return "rne";`
			`case RISCVFPRndMode::RTZ:`
			`return "rtz";`
			`case RISCVFPRndMode::RDN:`
			`return "rdn";`
			`case RISCVFPRndMode::RUP:`
			`return "rup";`
			`case RISCVFPRndMode::RMM:`
			`return "rmm";`
			`case RISCVFPRndMode::DYN:`
			`return "dyn";`
			`}`
			`}`

			`inline static RoundingMode stringToRoundingMode(StringRef Str) {`
			`return StringSwitch<RoundingMode>(Str)`
			`.Case("rne", RISCVFPRndMode::RNE)`
			`.Case("rtz", RISCVFPRndMode::RTZ)`
			`.Case("rdn", RISCVFPRndMode::RDN)`
			`.Case("rup", RISCVFPRndMode::RUP)`
			`.Case("rmm", RISCVFPRndMode::RMM)`
			`.Case("dyn", RISCVFPRndMode::DYN)`
			`.Default(RISCVFPRndMode::Invalid);`
			`}`

			`inline static bool isValidRoundingMode(unsigned Mode) {`
			`switch (Mode) {`
			`default:`
			`return false;`
			`case RISCVFPRndMode::RNE:`
			`case RISCVFPRndMode::RTZ:`
			`case RISCVFPRndMode::RDN:`
			`case RISCVFPRndMode::RUP:`
			`case RISCVFPRndMode::RMM:`
			`case RISCVFPRndMode::DYN:`
			`return true;`
			`}`
			`}`
			`} // namespace RISCVFPRndMode`

			`namespace RISCVSysReg {`
			`struct SysReg {`
			`const char *Name;`
			`unsigned Encoding;`
			`const char *AltName;`
			`// FIXME: add these additional fields when needed.`
			`// Privilege Access: Read, Write, Read-Only.`
			`// unsigned ReadWrite;`
			`// Privilege Mode: User, System or Machine.`
			`// unsigned Mode;`
			`// Check field name.`
			`// unsigned Extra;`
			`// Register number without the privilege bits.`
			`// unsigned Number;`
			`FeatureBitset FeaturesRequired;`
			`bool isRV32Only;`

			`bool haveRequiredFeatures(FeatureBitset ActiveFeatures) const {`
			`// Not in 32-bit mode.`
			`if (isRV32Only && ActiveFeatures[RISCV::Feature64Bit])`
			`return false;`
			`// No required feature associated with the system register.`
			`if (FeaturesRequired.none())`
			`return true;`
			`return (FeaturesRequired & ActiveFeatures) == FeaturesRequired;`
			`}`
			`};`

			`#define GET_SysRegsList_DECL`
			`#include "RISCVGenSearchableTables.inc"`
			`} // end namespace RISCVSysReg`

			`namespace RISCVABI {`

			`enum ABI {`
			`ABI_ILP32,`
			`ABI_ILP32F,`
			`ABI_ILP32D,`
			`ABI_ILP32E,`
			`ABI_LP64,`
			`ABI_LP64F,`
			`ABI_LP64D,`
			`ABI_Unknown`
			`};`

			`// Returns the target ABI, or else a StringError if the requested ABIName is`
			`// not supported for the given TT and FeatureBits combination.`
			`ABI computeTargetABI(const Triple &TT, FeatureBitset FeatureBits,`
			`StringRef ABIName);`

			`ABI getTargetABI(StringRef ABIName);`

			`// Returns the register used to hold the stack pointer after realignment.`
			`MCRegister getBPReg();`

			`// Returns the register holding shadow call stack pointer.`
			`MCRegister getSCSPReg();`

			`} // namespace RISCVABI`

			`namespace RISCVFeatures {`

			`// Validates if the given combination of features are valid for the target`
			`// triple. Exits with report_fatal_error if not.`
			`void validate(const Triple &TT, const FeatureBitset &FeatureBits);`

			`} // namespace RISCVFeatures`

			`namespace RISCVVMVTs {`

			`constexpr MVT vint8mf8_t = MVT::nxv1i8;`
			`constexpr MVT vint8mf4_t = MVT::nxv2i8;`
			`constexpr MVT vint8mf2_t = MVT::nxv4i8;`
			`constexpr MVT vint8m1_t = MVT::nxv8i8;`
			`constexpr MVT vint8m2_t = MVT::nxv16i8;`
			`constexpr MVT vint8m4_t = MVT::nxv32i8;`
			`constexpr MVT vint8m8_t = MVT::nxv64i8;`

			`constexpr MVT vint16mf4_t = MVT::nxv1i16;`
			`constexpr MVT vint16mf2_t = MVT::nxv2i16;`
			`constexpr MVT vint16m1_t = MVT::nxv4i16;`
			`constexpr MVT vint16m2_t = MVT::nxv8i16;`
			`constexpr MVT vint16m4_t = MVT::nxv16i16;`
			`constexpr MVT vint16m8_t = MVT::nxv32i16;`

			`constexpr MVT vint32mf2_t = MVT::nxv1i32;`
			`constexpr MVT vint32m1_t = MVT::nxv2i32;`
			`constexpr MVT vint32m2_t = MVT::nxv4i32;`
			`constexpr MVT vint32m4_t = MVT::nxv8i32;`
			`constexpr MVT vint32m8_t = MVT::nxv16i32;`

			`constexpr MVT vint64m1_t = MVT::nxv1i64;`
			`constexpr MVT vint64m2_t = MVT::nxv2i64;`
			`constexpr MVT vint64m4_t = MVT::nxv4i64;`
			`constexpr MVT vint64m8_t = MVT::nxv8i64;`

			`constexpr MVT vfloat16mf4_t = MVT::nxv1f16;`
			`constexpr MVT vfloat16mf2_t = MVT::nxv2f16;`
			`constexpr MVT vfloat16m1_t = MVT::nxv4f16;`
			`constexpr MVT vfloat16m2_t = MVT::nxv8f16;`
			`constexpr MVT vfloat16m4_t = MVT::nxv16f16;`
			`constexpr MVT vfloat16m8_t = MVT::nxv32f16;`

			`constexpr MVT vfloat32mf2_t = MVT::nxv1f32;`
			`constexpr MVT vfloat32m1_t = MVT::nxv2f32;`
			`constexpr MVT vfloat32m2_t = MVT::nxv4f32;`
			`constexpr MVT vfloat32m4_t = MVT::nxv8f32;`
			`constexpr MVT vfloat32m8_t = MVT::nxv16f32;`

			`constexpr MVT vfloat64m1_t = MVT::nxv1f64;`
			`constexpr MVT vfloat64m2_t = MVT::nxv2f64;`
			`constexpr MVT vfloat64m4_t = MVT::nxv4f64;`
			`constexpr MVT vfloat64m8_t = MVT::nxv8f64;`

			`constexpr MVT vbool1_t = MVT::nxv64i1;`
			`constexpr MVT vbool2_t = MVT::nxv32i1;`
			`constexpr MVT vbool4_t = MVT::nxv16i1;`
			`constexpr MVT vbool8_t = MVT::nxv8i1;`
			`constexpr MVT vbool16_t = MVT::nxv4i1;`
			`constexpr MVT vbool32_t = MVT::nxv2i1;`
			`constexpr MVT vbool64_t = MVT::nxv1i1;`

			`} // namespace RISCVVMVTs`

			`enum class RISCVVSEW {`
			`SEW_8 = 0,`
			`SEW_16,`
			`SEW_32,`
			`SEW_64,`
			`SEW_128,`
			`SEW_256,`
			`SEW_512,`
			`SEW_1024,`
			`};`

			`enum class RISCVVLMUL {`
			`LMUL_1 = 0,`
			`LMUL_2,`
			`LMUL_4,`
			`LMUL_8,`
			`LMUL_RESERVED,`
			`LMUL_F8,`
			`LMUL_F4,`
			`LMUL_F2`
			`};`

			`namespace RISCVVType {`
			`// Is this a SEW value that can be encoded into the VTYPE format.`
			`inline static bool isValidSEW(unsigned SEW) {`
			`return isPowerOf2_32(SEW) && SEW >= 8 && SEW <= 1024;`
			`}`

			`// Is this a LMUL value that can be encoded into the VTYPE format.`
			`inline static bool isValidLMUL(unsigned LMUL, bool Fractional) {`
			`return isPowerOf2_32(LMUL) && LMUL <= 8 && (!Fractional \|\| LMUL != 1);`
			`}`

			`// Encode VTYPE into the binary format used by the the VSETVLI instruction which`
			`// is used by our MC layer representation.`
			`//`
			`// Bits \| Name \| Description`
			`// -----+------------+------------------------------------------------`
			`// 7 \| vma \| Vector mask agnostic`
			`// 6 \| vta \| Vector tail agnostic`
			`// 5:3 \| vsew[2:0] \| Standard element width (SEW) setting`
			`// 2:0 \| vlmul[2:0] \| Vector register group multiplier (LMUL) setting`
			`inline static unsigned encodeVTYPE(RISCVVLMUL VLMUL, RISCVVSEW VSEW,`
			`bool TailAgnostic, bool MaskAgnostic) {`
			`unsigned VLMULBits = static_cast<unsigned>(VLMUL);`
			`unsigned VSEWBits = static_cast<unsigned>(VSEW);`
			`unsigned VTypeI = (VSEWBits << 3) \| (VLMULBits & 0x7);`
			`if (TailAgnostic)`
			`VTypeI \|= 0x40;`
			`if (MaskAgnostic)`
			`VTypeI \|= 0x80;`

			`return VTypeI;`
			`}`

			`inline static RISCVVLMUL getVLMUL(unsigned VType) {`
			`unsigned VLMUL = VType & 0x7;`
			`return static_cast<RISCVVLMUL>(VLMUL);`
			`}`

			`inline static RISCVVSEW getVSEW(unsigned VType) {`
			`unsigned VSEW = (VType >> 3) & 0x7;`
			`return static_cast<RISCVVSEW>(VSEW);`
			`}`

			`inline static bool isTailAgnostic(unsigned VType) { return VType & 0x40; }`

			`inline static bool isMaskAgnostic(unsigned VType) { return VType & 0x80; }`

			`void printVType(unsigned VType, raw_ostream &OS);`

			`} // namespace RISCVVType`

			`namespace RISCVVPseudosTable {`

			`struct PseudoInfo {`
			`#include "MCTargetDesc/RISCVBaseInfo.h"`
			`uint16_t Pseudo;`
			`uint16_t BaseInstr;`
			`};`

			`using namespace RISCV;`

			`#define GET_RISCVVPseudosTable_DECL`
			`#include "RISCVGenSearchableTables.inc"`

			`} // end namespace RISCVVPseudosTable`

			`} // namespace llvm`

			`#endif`