clang/include/clang/Support/RISCVVIntrinsicUtils.h - llvm-project - Git at Google

 //===--- RISCVVIntrinsicUtils.h - RISC-V Vector Intrinsic Utils -*- 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
 //
 //===----------------------------------------------------------------------===//

 #ifndef CLANG_SUPPORT_RISCVVINTRINSICUTILS_H
 #define CLANG_SUPPORT_RISCVVINTRINSICUTILS_H

 #include "llvm/ADT/ArrayRef.h"
 #include "llvm/ADT/BitmaskEnum.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/ADT/StringRef.h"
 #include <cstdint>
 #include <optional>
 #include <set>
 #include <string>
 #include <unordered_map>
 #include <vector>

 namespace llvm {
 class raw_ostream;
 } // end namespace llvm

 namespace clang {
 namespace RISCV {

 using VScaleVal = std::optional<unsigned>;

 // Modifier for vector type.
 enum class VectorTypeModifier : uint8_t {
   NoModifier,
   Widening2XVector,
   Widening4XVector,
   Widening8XVector,
   MaskVector,
   Log2EEW3,
   Log2EEW4,
   Log2EEW5,
   Log2EEW6,
   FixedSEW8,
   FixedSEW16,
   FixedSEW32,
   FixedSEW64,
   LFixedLog2LMULN3,
   LFixedLog2LMULN2,
   LFixedLog2LMULN1,
   LFixedLog2LMUL0,
   LFixedLog2LMUL1,
   LFixedLog2LMUL2,
   LFixedLog2LMUL3,
   SFixedLog2LMULN3,
   SFixedLog2LMULN2,
   SFixedLog2LMULN1,
   SFixedLog2LMUL0,
   SFixedLog2LMUL1,
   SFixedLog2LMUL2,
   SFixedLog2LMUL3,
   SEFixedLog2LMULN3,
   SEFixedLog2LMULN2,
   SEFixedLog2LMULN1,
   SEFixedLog2LMUL0,
   SEFixedLog2LMUL1,
   SEFixedLog2LMUL2,
   SEFixedLog2LMUL3,
   Tuple2,
   Tuple3,
   Tuple4,
   Tuple5,
   Tuple6,
   Tuple7,
   Tuple8,
 };

 // Similar to basic type but used to describe what's kind of type related to
 // basic vector type, used to compute type info of arguments.
 enum class BaseTypeModifier : uint8_t {
   Invalid,
   Scalar,
   Vector,
   Void,
   SizeT,
   Ptrdiff,
   UnsignedLong,
   SignedLong,
   Float32
 };

 // Modifier for type, used for both scalar and vector types.
 enum class TypeModifier : uint8_t {
   NoModifier = 0,
   Pointer = 1 << 0,
   Const = 1 << 1,
   Immediate = 1 << 2,
   UnsignedInteger = 1 << 3,
   SignedInteger = 1 << 4,
   Float = 1 << 5,
   BFloat = 1 << 6,
   // LMUL1 should be kind of VectorTypeModifier, but that might come with
   // Widening2XVector for widening reduction.
   // However that might require VectorTypeModifier become bitmask rather than
   // simple enum, so we decide keek LMUL1 in TypeModifier for code size
   // optimization of clang binary size.
   LMUL1 = 1 << 7,
   MaxOffset = 7,
   LLVM_MARK_AS_BITMASK_ENUM(LMUL1),
 };

 class Policy {
 public:
   enum PolicyType {
     Undisturbed,
     Agnostic,
   };

 private:
   // The default assumption for an RVV instruction is TAMA, as an undisturbed
   // policy generally will affect the performance of an out-of-order core.
   const PolicyType TailPolicy = Agnostic;
   const PolicyType MaskPolicy = Agnostic;

 public:
   Policy() = default;
   Policy(PolicyType TailPolicy) : TailPolicy(TailPolicy) {}
   Policy(PolicyType TailPolicy, PolicyType MaskPolicy)
       : TailPolicy(TailPolicy), MaskPolicy(MaskPolicy) {}

   bool isTAMAPolicy() const {
     return TailPolicy == Agnostic && MaskPolicy == Agnostic;
   }

   bool isTAMUPolicy() const {
     return TailPolicy == Agnostic && MaskPolicy == Undisturbed;
   }

   bool isTUMAPolicy() const {
     return TailPolicy == Undisturbed && MaskPolicy == Agnostic;
   }

   bool isTUMUPolicy() const {
     return TailPolicy == Undisturbed && MaskPolicy == Undisturbed;
   }

   bool isTAPolicy() const { return TailPolicy == Agnostic; }

   bool isTUPolicy() const { return TailPolicy == Undisturbed; }

   bool isMAPolicy() const { return MaskPolicy == Agnostic; }

   bool isMUPolicy() const { return MaskPolicy == Undisturbed; }

   bool operator==(const Policy &Other) const {
     return TailPolicy == Other.TailPolicy && MaskPolicy == Other.MaskPolicy;
   }

   bool operator!=(const Policy &Other) const { return !(*this == Other); }

   bool operator<(const Policy &Other) const {
     // Just for maintain the old order for quick test.
     if (MaskPolicy != Other.MaskPolicy)
       return Other.MaskPolicy < MaskPolicy;
     return TailPolicy < Other.TailPolicy;
   }
 };

 // PrototypeDescriptor is used to compute type info of arguments or return
 // value.
 struct PrototypeDescriptor {
   constexpr PrototypeDescriptor() = default;
   constexpr PrototypeDescriptor(
       BaseTypeModifier PT,
       VectorTypeModifier VTM = VectorTypeModifier::NoModifier,
       TypeModifier TM = TypeModifier::NoModifier)
       : PT(static_cast<uint8_t>(PT)), VTM(static_cast<uint8_t>(VTM)),
         TM(static_cast<uint8_t>(TM)) {}
   constexpr PrototypeDescriptor(uint8_t PT, uint8_t VTM, uint8_t TM)
       : PT(PT), VTM(VTM), TM(TM) {}

   uint8_t PT = static_cast<uint8_t>(BaseTypeModifier::Invalid);
   uint8_t VTM = static_cast<uint8_t>(VectorTypeModifier::NoModifier);
   uint8_t TM = static_cast<uint8_t>(TypeModifier::NoModifier);

   bool operator!=(const PrototypeDescriptor &PD) const {
     return !(*this == PD);
   }
   bool operator==(const PrototypeDescriptor &PD) const {
     return PD.PT == PT && PD.VTM == VTM && PD.TM == TM;
   }
   bool operator<(const PrototypeDescriptor &PD) const {
     return std::tie(PT, VTM, TM) < std::tie(PD.PT, PD.VTM, PD.TM);
   }
   static const PrototypeDescriptor Mask;
   static const PrototypeDescriptor Vector;
   static const PrototypeDescriptor VL;
   static std::optional<PrototypeDescriptor>
   parsePrototypeDescriptor(llvm::StringRef PrototypeStr);
 };

 llvm::SmallVector<PrototypeDescriptor>
 parsePrototypes(llvm::StringRef Prototypes);

 // Basic type of vector type.
 enum class BasicType : uint8_t {
   Unknown = 0,
   Int8 = 1 << 0,
   Int16 = 1 << 1,
   Int32 = 1 << 2,
   Int64 = 1 << 3,
   BFloat16 = 1 << 4,
   Float16 = 1 << 5,
   Float32 = 1 << 6,
   Float64 = 1 << 7,
   MaxOffset = 7,
   LLVM_MARK_AS_BITMASK_ENUM(Float64),
 };

 // Type of vector type.
 enum ScalarTypeKind : uint8_t {
   Void,
   Size_t,
   Ptrdiff_t,
   UnsignedLong,
   SignedLong,
   Boolean,
   SignedInteger,
   UnsignedInteger,
   Float,
   BFloat,
   Invalid,
   Undefined,
 };

 // Exponential LMUL
 struct LMULType {
   int Log2LMUL;
   LMULType(int Log2LMUL);
   // Return the C/C++ string representation of LMUL
   std::string str() const;
   std::optional<unsigned> getScale(unsigned ElementBitwidth) const;
   void MulLog2LMUL(int Log2LMUL);
 };

 class RVVType;
 using RVVTypePtr = RVVType *;
 using RVVTypes = std::vector<RVVTypePtr>;
 class RVVTypeCache;

 // This class is compact representation of a valid and invalid RVVType.
 class RVVType {
   friend class RVVTypeCache;

   BasicType BT;
   ScalarTypeKind ScalarType = Undefined;
   LMULType LMUL;
   bool IsPointer = false;
   // IsConstant indices are "int", but have the constant expression.
   bool IsImmediate = false;
   // Const qualifier for pointer to const object or object of const type.
   bool IsConstant = false;
   unsigned ElementBitwidth = 0;
   VScaleVal Scale = 0;
   bool Valid;
   bool IsTuple = false;
   unsigned NF = 0;

   std::string BuiltinStr;
   std::string ClangBuiltinStr;
   std::string Str;
   std::string ShortStr;

   enum class FixedLMULType { LargerThan, SmallerThan, SmallerOrEqual };

   RVVType(BasicType BT, int Log2LMUL, const PrototypeDescriptor &Profile);

 public:
   // Return the string representation of a type, which is an encoded string for
   // passing to the BUILTIN() macro in Builtins.def.
   const std::string &getBuiltinStr() const { return BuiltinStr; }

   // Return the clang builtin type for RVV vector type which are used in the
   // riscv_vector.h header file.
   const std::string &getClangBuiltinStr() const { return ClangBuiltinStr; }

   // Return the C/C++ string representation of a type for use in the
   // riscv_vector.h header file.
   const std::string &getTypeStr() const { return Str; }

   // Return the short name of a type for C/C++ name suffix.
   const std::string &getShortStr() {
     // Not all types are used in short name, so compute the short name by
     // demanded.
     if (ShortStr.empty())
       initShortStr();
     return ShortStr;
   }

   bool isValid() const { return Valid; }
   bool isScalar() const { return Scale && *Scale == 0; }
   bool isVector() const { return Scale && *Scale != 0; }
   bool isVector(unsigned Width) const {
     return isVector() && ElementBitwidth == Width;
   }
   bool isFloat() const { return ScalarType == ScalarTypeKind::Float; }
   bool isBFloat() const { return ScalarType == ScalarTypeKind::BFloat; }
   bool isSignedInteger() const {
     return ScalarType == ScalarTypeKind::SignedInteger;
   }
   bool isFloatVector(unsigned Width) const {
     return isVector() && isFloat() && ElementBitwidth == Width;
   }
   bool isFloat(unsigned Width) const {
     return isFloat() && ElementBitwidth == Width;
   }
   bool isConstant() const { return IsConstant; }
   bool isPointer() const { return IsPointer; }
   bool isTuple() const { return IsTuple; }
   unsigned getElementBitwidth() const { return ElementBitwidth; }

   ScalarTypeKind getScalarType() const { return ScalarType; }
   VScaleVal getScale() const { return Scale; }
   unsigned getNF() const {
     assert(NF > 1 && NF <= 8 && "Only legal NF should be fetched");
     return NF;
   }

 private:
   // Verify RVV vector type and set Valid.
   bool verifyType() const;

   // Creates a type based on basic types of TypeRange
   void applyBasicType();

   // Applies a prototype modifier to the current type. The result maybe an
   // invalid type.
   void applyModifier(const PrototypeDescriptor &prototype);

   void applyLog2EEW(unsigned Log2EEW);
   void applyFixedSEW(unsigned NewSEW);
   void applyFixedLog2LMUL(int Log2LMUL, enum FixedLMULType Type);

   // Compute and record a string for legal type.
   void initBuiltinStr();
   // Compute and record a builtin RVV vector type string.
   void initClangBuiltinStr();
   // Compute and record a type string for used in the header.
   void initTypeStr();
   // Compute and record a short name of a type for C/C++ name suffix.
   void initShortStr();
 };

 // This class is used to manage RVVType, RVVType should only created by this
 // class, also provided thread-safe cache capability.
 class RVVTypeCache {
 private:
   std::unordered_map<uint64_t, RVVType> LegalTypes;
   std::set<uint64_t> IllegalTypes;

 public:
   /// Compute output and input types by applying different config (basic type
   /// and LMUL with type transformers). It also record result of type in legal
   /// or illegal set to avoid compute the same config again. The result maybe
   /// have illegal RVVType.
   std::optional<RVVTypes>
   computeTypes(BasicType BT, int Log2LMUL, unsigned NF,
                llvm::ArrayRef<PrototypeDescriptor> Prototype);
   std::optional<RVVTypePtr> computeType(BasicType BT, int Log2LMUL,
                                         PrototypeDescriptor Proto);
 };

 enum PolicyScheme : uint8_t {
   SchemeNone,
   // Passthru operand is at first parameter in C builtin.
   HasPassthruOperand,
   HasPolicyOperand,
 };

 // TODO refactor RVVIntrinsic class design after support all intrinsic
 // combination. This represents an instantiation of an intrinsic with a
 // particular type and prototype
 class RVVIntrinsic {

 private:
   std::string BuiltinName; // Builtin name
   std::string Name;        // C intrinsic name.
   std::string OverloadedName;
   std::string IRName;
   bool IsMasked;
   bool HasMaskedOffOperand;
   bool HasVL;
   PolicyScheme Scheme;
   bool SupportOverloading;
   bool HasBuiltinAlias;
   std::string ManualCodegen;
   RVVTypePtr OutputType; // Builtin output type
   RVVTypes InputTypes;   // Builtin input types
   // The types we use to obtain the specific LLVM intrinsic. They are index of
   // InputTypes. -1 means the return type.
   std::vector<int64_t> IntrinsicTypes;
   unsigned NF = 1;
   Policy PolicyAttrs;

 public:
   RVVIntrinsic(llvm::StringRef Name, llvm::StringRef Suffix,
                llvm::StringRef OverloadedName, llvm::StringRef OverloadedSuffix,
                llvm::StringRef IRName, bool IsMasked, bool HasMaskedOffOperand,
                bool HasVL, PolicyScheme Scheme, bool SupportOverloading,
                bool HasBuiltinAlias, llvm::StringRef ManualCodegen,
                const RVVTypes &Types,
                const std::vector<int64_t> &IntrinsicTypes,
                unsigned NF, Policy PolicyAttrs, bool HasFRMRoundModeOp);
   ~RVVIntrinsic() = default;

   RVVTypePtr getOutputType() const { return OutputType; }
   const RVVTypes &getInputTypes() const { return InputTypes; }
   llvm::StringRef getBuiltinName() const { return BuiltinName; }
   bool hasMaskedOffOperand() const { return HasMaskedOffOperand; }
   bool hasVL() const { return HasVL; }
   bool hasPolicy() const { return Scheme != PolicyScheme::SchemeNone; }
   bool hasPassthruOperand() const {
     return Scheme == PolicyScheme::HasPassthruOperand;
   }
   bool hasPolicyOperand() const {
     return Scheme == PolicyScheme::HasPolicyOperand;
   }
   bool supportOverloading() const { return SupportOverloading; }
   bool hasBuiltinAlias() const { return HasBuiltinAlias; }
   bool hasManualCodegen() const { return !ManualCodegen.empty(); }
   bool isMasked() const { return IsMasked; }
   llvm::StringRef getIRName() const { return IRName; }
   llvm::StringRef getManualCodegen() const { return ManualCodegen; }
   PolicyScheme getPolicyScheme() const { return Scheme; }
   unsigned getNF() const { return NF; }
   const std::vector<int64_t> &getIntrinsicTypes() const {
     return IntrinsicTypes;
   }
   Policy getPolicyAttrs() const {
     return PolicyAttrs;
   }
   unsigned getPolicyAttrsBits() const {
     // CGBuiltin.cpp
     // The 0th bit simulates the `vta` of RVV
     // The 1st bit simulates the `vma` of RVV
     // int PolicyAttrs = 0;

     if (PolicyAttrs.isTUMAPolicy())
       return 2;
     if (PolicyAttrs.isTAMAPolicy())
       return 3;
     if (PolicyAttrs.isTUMUPolicy())
       return 0;
     if (PolicyAttrs.isTAMUPolicy())
       return 1;

     llvm_unreachable("unsupport policy");
     return 0;
   }

   // Return the type string for a BUILTIN() macro in Builtins.def.
   std::string getBuiltinTypeStr() const;

   static std::string
   getSuffixStr(RVVTypeCache &TypeCache, BasicType Type, int Log2LMUL,
                llvm::ArrayRef<PrototypeDescriptor> PrototypeDescriptors);

   static llvm::SmallVector<PrototypeDescriptor>
   computeBuiltinTypes(llvm::ArrayRef<PrototypeDescriptor> Prototype,
                       bool IsMasked, bool HasMaskedOffOperand, bool HasVL,
                       unsigned NF, PolicyScheme DefaultScheme,
                       Policy PolicyAttrs, bool IsTuple);

   static llvm::SmallVector<Policy> getSupportedUnMaskedPolicies();
   static llvm::SmallVector<Policy>
       getSupportedMaskedPolicies(bool HasTailPolicy, bool HasMaskPolicy);

   static void updateNamesAndPolicy(bool IsMasked, bool HasPolicy,
                                    std::string &Name, std::string &BuiltinName,
                                    std::string &OverloadedName,
                                    Policy &PolicyAttrs, bool HasFRMRoundModeOp);
 };

 // RVVRequire should be sync'ed with target features, but only
 // required features used in riscv_vector.td.
 enum RVVRequire : uint32_t {
   RVV_REQ_None = 0,
   RVV_REQ_RV64 = 1 << 0,
   RVV_REQ_Zvfhmin = 1 << 1,
   RVV_REQ_Xsfvcp = 1 << 2,
   RVV_REQ_Xsfvfnrclipxfqf = 1 << 3,
   RVV_REQ_Xsfvfwmaccqqq = 1 << 4,
   RVV_REQ_Xsfvqmaccdod = 1 << 5,
   RVV_REQ_Xsfvqmaccqoq = 1 << 6,
   RVV_REQ_Zvbb = 1 << 7,
   RVV_REQ_Zvbc = 1 << 8,
   RVV_REQ_Zvkb = 1 << 9,
   RVV_REQ_Zvkg = 1 << 10,
   RVV_REQ_Zvkned = 1 << 11,
   RVV_REQ_Zvknha = 1 << 12,
   RVV_REQ_Zvknhb = 1 << 13,
   RVV_REQ_Zvksed = 1 << 14,
   RVV_REQ_Zvksh = 1 << 15,
   RVV_REQ_Zvfbfwma = 1 << 16,
   RVV_REQ_Zvfbfmin = 1 << 17,
   RVV_REQ_Experimental = 1 << 18,

   LLVM_MARK_AS_BITMASK_ENUM(RVV_REQ_Experimental)
 };

 // Raw RVV intrinsic info, used to expand later.
 // This struct is highly compact for minimized code size.
 struct RVVIntrinsicRecord {
   // Intrinsic name, e.g. vadd_vv
   const char *Name;

   // Overloaded intrinsic name, could be empty if it can be computed from Name.
   // e.g. vadd
   const char *OverloadedName;

   // Prototype for this intrinsic, index of RVVSignatureTable.
   uint16_t PrototypeIndex;

   // Suffix of intrinsic name, index of RVVSignatureTable.
   uint16_t SuffixIndex;

   // Suffix of overloaded intrinsic name, index of RVVSignatureTable.
   uint16_t OverloadedSuffixIndex;

   // Length of the prototype.
   uint8_t PrototypeLength;

   // Length of intrinsic name suffix.
   uint8_t SuffixLength;

   // Length of overloaded intrinsic suffix.
   uint8_t OverloadedSuffixSize;

   // Required target features for this intrinsic.
   uint32_t RequiredExtensions;

   // Supported type, mask of BasicType.
   uint8_t TypeRangeMask;

   // Supported LMUL.
   uint8_t Log2LMULMask;

   // Number of fields, greater than 1 if it's segment load/store.
   uint8_t NF;

   bool HasMasked : 1;
   bool HasVL : 1;
   bool HasMaskedOffOperand : 1;
   bool HasTailPolicy : 1;
   bool HasMaskPolicy : 1;
   bool HasFRMRoundModeOp : 1;
   bool IsTuple : 1;
   LLVM_PREFERRED_TYPE(PolicyScheme)
   uint8_t UnMaskedPolicyScheme : 2;
   LLVM_PREFERRED_TYPE(PolicyScheme)
   uint8_t MaskedPolicyScheme : 2;
 };

 llvm::raw_ostream &operator<<(llvm::raw_ostream &OS,
                               const RVVIntrinsicRecord &RVVInstrRecord);

 LLVM_ENABLE_BITMASK_ENUMS_IN_NAMESPACE();
 } // end namespace RISCV

 } // end namespace clang

 #endif // CLANG_SUPPORT_RISCVVINTRINSICUTILS_H
	//===--- RISCVVIntrinsicUtils.h - RISC-V Vector Intrinsic Utils -- 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
	//
	//===----------------------------------------------------------------------===//

	#ifndef CLANG_SUPPORT_RISCVVINTRINSICUTILS_H
	#define CLANG_SUPPORT_RISCVVINTRINSICUTILS_H

	#include "llvm/ADT/ArrayRef.h"
	#include "llvm/ADT/BitmaskEnum.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/ADT/StringRef.h"
	#include <cstdint>
	#include <optional>
	#include <set>
	#include <string>
	#include <unordered_map>
	#include <vector>

	namespace llvm {
	class raw_ostream;
	} // end namespace llvm

	namespace clang {
	namespace RISCV {

	using VScaleVal = std::optional<unsigned>;

	// Modifier for vector type.
	enum class VectorTypeModifier : uint8_t {
	NoModifier,
	Widening2XVector,
	Widening4XVector,
	Widening8XVector,
	MaskVector,
	Log2EEW3,
	Log2EEW4,
	Log2EEW5,
	Log2EEW6,
	FixedSEW8,
	FixedSEW16,
	FixedSEW32,
	FixedSEW64,
	LFixedLog2LMULN3,
	LFixedLog2LMULN2,
	LFixedLog2LMULN1,
	LFixedLog2LMUL0,
	LFixedLog2LMUL1,
	LFixedLog2LMUL2,
	LFixedLog2LMUL3,
	SFixedLog2LMULN3,
	SFixedLog2LMULN2,
	SFixedLog2LMULN1,
	SFixedLog2LMUL0,
	SFixedLog2LMUL1,
	SFixedLog2LMUL2,
	SFixedLog2LMUL3,
	SEFixedLog2LMULN3,
	SEFixedLog2LMULN2,
	SEFixedLog2LMULN1,
	SEFixedLog2LMUL0,
	SEFixedLog2LMUL1,
	SEFixedLog2LMUL2,
	SEFixedLog2LMUL3,
	Tuple2,
	Tuple3,
	Tuple4,
	Tuple5,
	Tuple6,
	Tuple7,
	Tuple8,
	};

	// Similar to basic type but used to describe what's kind of type related to
	// basic vector type, used to compute type info of arguments.
	enum class BaseTypeModifier : uint8_t {
	Invalid,
	Scalar,
	Vector,
	Void,
	SizeT,
	Ptrdiff,
	UnsignedLong,
	SignedLong,
	Float32
	};

	// Modifier for type, used for both scalar and vector types.
	enum class TypeModifier : uint8_t {
	NoModifier = 0,
	Pointer = 1 << 0,
	Const = 1 << 1,
	Immediate = 1 << 2,
	UnsignedInteger = 1 << 3,
	SignedInteger = 1 << 4,
	Float = 1 << 5,
	BFloat = 1 << 6,
	// LMUL1 should be kind of VectorTypeModifier, but that might come with
	// Widening2XVector for widening reduction.
	// However that might require VectorTypeModifier become bitmask rather than
	// simple enum, so we decide keek LMUL1 in TypeModifier for code size
	// optimization of clang binary size.
	LMUL1 = 1 << 7,
	MaxOffset = 7,
	LLVM_MARK_AS_BITMASK_ENUM(LMUL1),
	};

	class Policy {
	public:
	enum PolicyType {
	Undisturbed,
	Agnostic,
	};

	private:
	// The default assumption for an RVV instruction is TAMA, as an undisturbed
	// policy generally will affect the performance of an out-of-order core.
	const PolicyType TailPolicy = Agnostic;
	const PolicyType MaskPolicy = Agnostic;

	public:
	Policy() = default;
	Policy(PolicyType TailPolicy) : TailPolicy(TailPolicy) {}
	Policy(PolicyType TailPolicy, PolicyType MaskPolicy)
	: TailPolicy(TailPolicy), MaskPolicy(MaskPolicy) {}

	bool isTAMAPolicy() const {
	return TailPolicy == Agnostic && MaskPolicy == Agnostic;
	}

	bool isTAMUPolicy() const {
	return TailPolicy == Agnostic && MaskPolicy == Undisturbed;
	}

	bool isTUMAPolicy() const {
	return TailPolicy == Undisturbed && MaskPolicy == Agnostic;
	}

	bool isTUMUPolicy() const {
	return TailPolicy == Undisturbed && MaskPolicy == Undisturbed;
	}

	bool isTAPolicy() const { return TailPolicy == Agnostic; }

	bool isTUPolicy() const { return TailPolicy == Undisturbed; }

	bool isMAPolicy() const { return MaskPolicy == Agnostic; }

	bool isMUPolicy() const { return MaskPolicy == Undisturbed; }

	bool operator==(const Policy &Other) const {
	return TailPolicy == Other.TailPolicy && MaskPolicy == Other.MaskPolicy;
	}

	bool operator!=(const Policy &Other) const { return !(*this == Other); }

	bool operator<(const Policy &Other) const {
	// Just for maintain the old order for quick test.
	if (MaskPolicy != Other.MaskPolicy)
	return Other.MaskPolicy < MaskPolicy;
	return TailPolicy < Other.TailPolicy;
	}
	};

	// PrototypeDescriptor is used to compute type info of arguments or return
	// value.
	struct PrototypeDescriptor {
	constexpr PrototypeDescriptor() = default;
	constexpr PrototypeDescriptor(
	BaseTypeModifier PT,
	VectorTypeModifier VTM = VectorTypeModifier::NoModifier,
	TypeModifier TM = TypeModifier::NoModifier)
	: PT(static_cast<uint8_t>(PT)), VTM(static_cast<uint8_t>(VTM)),
	TM(static_cast<uint8_t>(TM)) {}
	constexpr PrototypeDescriptor(uint8_t PT, uint8_t VTM, uint8_t TM)
	: PT(PT), VTM(VTM), TM(TM) {}

	uint8_t PT = static_cast<uint8_t>(BaseTypeModifier::Invalid);
	uint8_t VTM = static_cast<uint8_t>(VectorTypeModifier::NoModifier);
	uint8_t TM = static_cast<uint8_t>(TypeModifier::NoModifier);

	bool operator!=(const PrototypeDescriptor &PD) const {
	return !(*this == PD);
	}
	bool operator==(const PrototypeDescriptor &PD) const {
	return PD.PT == PT && PD.VTM == VTM && PD.TM == TM;
	}
	bool operator<(const PrototypeDescriptor &PD) const {
	return std::tie(PT, VTM, TM) < std::tie(PD.PT, PD.VTM, PD.TM);
	}
	static const PrototypeDescriptor Mask;
	static const PrototypeDescriptor Vector;
	static const PrototypeDescriptor VL;
	static std::optional<PrototypeDescriptor>
	parsePrototypeDescriptor(llvm::StringRef PrototypeStr);
	};

	llvm::SmallVector<PrototypeDescriptor>
	parsePrototypes(llvm::StringRef Prototypes);

	// Basic type of vector type.
	enum class BasicType : uint8_t {
	Unknown = 0,
	Int8 = 1 << 0,
	Int16 = 1 << 1,
	Int32 = 1 << 2,
	Int64 = 1 << 3,
	BFloat16 = 1 << 4,
	Float16 = 1 << 5,
	Float32 = 1 << 6,
	Float64 = 1 << 7,
	MaxOffset = 7,
	LLVM_MARK_AS_BITMASK_ENUM(Float64),
	};

	// Type of vector type.
	enum ScalarTypeKind : uint8_t {
	Void,
	Size_t,
	Ptrdiff_t,
	UnsignedLong,
	SignedLong,
	Boolean,
	SignedInteger,
	UnsignedInteger,
	Float,
	BFloat,
	Invalid,
	Undefined,
	};

	// Exponential LMUL
	struct LMULType {
	int Log2LMUL;
	LMULType(int Log2LMUL);
	// Return the C/C++ string representation of LMUL
	std::string str() const;
	std::optional<unsigned> getScale(unsigned ElementBitwidth) const;
	void MulLog2LMUL(int Log2LMUL);
	};

	class RVVType;
	using RVVTypePtr = RVVType *;
	using RVVTypes = std::vector<RVVTypePtr>;
	class RVVTypeCache;

	// This class is compact representation of a valid and invalid RVVType.
	class RVVType {
	friend class RVVTypeCache;

	BasicType BT;
	ScalarTypeKind ScalarType = Undefined;
	LMULType LMUL;
	bool IsPointer = false;
	// IsConstant indices are "int", but have the constant expression.
	bool IsImmediate = false;
	// Const qualifier for pointer to const object or object of const type.
	bool IsConstant = false;
	unsigned ElementBitwidth = 0;
	VScaleVal Scale = 0;
	bool Valid;
	bool IsTuple = false;
	unsigned NF = 0;

	std::string BuiltinStr;
	std::string ClangBuiltinStr;
	std::string Str;
	std::string ShortStr;

	enum class FixedLMULType { LargerThan, SmallerThan, SmallerOrEqual };

	RVVType(BasicType BT, int Log2LMUL, const PrototypeDescriptor &Profile);

	public:
	// Return the string representation of a type, which is an encoded string for
	// passing to the BUILTIN() macro in Builtins.def.
	const std::string &getBuiltinStr() const { return BuiltinStr; }

	// Return the clang builtin type for RVV vector type which are used in the
	// riscv_vector.h header file.
	const std::string &getClangBuiltinStr() const { return ClangBuiltinStr; }

	// Return the C/C++ string representation of a type for use in the
	// riscv_vector.h header file.
	const std::string &getTypeStr() const { return Str; }

	// Return the short name of a type for C/C++ name suffix.
	const std::string &getShortStr() {
	// Not all types are used in short name, so compute the short name by
	// demanded.
	if (ShortStr.empty())
	initShortStr();
	return ShortStr;
	}

	bool isValid() const { return Valid; }
	bool isScalar() const { return Scale && *Scale == 0; }
	bool isVector() const { return Scale && *Scale != 0; }
	bool isVector(unsigned Width) const {
	return isVector() && ElementBitwidth == Width;
	}
	bool isFloat() const { return ScalarType == ScalarTypeKind::Float; }
	bool isBFloat() const { return ScalarType == ScalarTypeKind::BFloat; }
	bool isSignedInteger() const {
	return ScalarType == ScalarTypeKind::SignedInteger;
	}
	bool isFloatVector(unsigned Width) const {
	return isVector() && isFloat() && ElementBitwidth == Width;
	}
	bool isFloat(unsigned Width) const {
	return isFloat() && ElementBitwidth == Width;
	}
	bool isConstant() const { return IsConstant; }
	bool isPointer() const { return IsPointer; }
	bool isTuple() const { return IsTuple; }
	unsigned getElementBitwidth() const { return ElementBitwidth; }

	ScalarTypeKind getScalarType() const { return ScalarType; }
	VScaleVal getScale() const { return Scale; }
	unsigned getNF() const {
	assert(NF > 1 && NF <= 8 && "Only legal NF should be fetched");
	return NF;
	}

	private:
	// Verify RVV vector type and set Valid.
	bool verifyType() const;

	// Creates a type based on basic types of TypeRange
	void applyBasicType();

	// Applies a prototype modifier to the current type. The result maybe an
	// invalid type.
	void applyModifier(const PrototypeDescriptor &prototype);

	void applyLog2EEW(unsigned Log2EEW);
	void applyFixedSEW(unsigned NewSEW);
	void applyFixedLog2LMUL(int Log2LMUL, enum FixedLMULType Type);

	// Compute and record a string for legal type.
	void initBuiltinStr();
	// Compute and record a builtin RVV vector type string.
	void initClangBuiltinStr();
	// Compute and record a type string for used in the header.
	void initTypeStr();
	// Compute and record a short name of a type for C/C++ name suffix.
	void initShortStr();
	};

	// This class is used to manage RVVType, RVVType should only created by this
	// class, also provided thread-safe cache capability.
	class RVVTypeCache {
	private:
	std::unordered_map<uint64_t, RVVType> LegalTypes;
	std::set<uint64_t> IllegalTypes;

	public:
	/// Compute output and input types by applying different config (basic type
	/// and LMUL with type transformers). It also record result of type in legal
	/// or illegal set to avoid compute the same config again. The result maybe
	/// have illegal RVVType.
	std::optional<RVVTypes>
	computeTypes(BasicType BT, int Log2LMUL, unsigned NF,
	llvm::ArrayRef<PrototypeDescriptor> Prototype);
	std::optional<RVVTypePtr> computeType(BasicType BT, int Log2LMUL,
	PrototypeDescriptor Proto);
	};

	enum PolicyScheme : uint8_t {
	SchemeNone,
	// Passthru operand is at first parameter in C builtin.
	HasPassthruOperand,
	HasPolicyOperand,
	};

	// TODO refactor RVVIntrinsic class design after support all intrinsic
	// combination. This represents an instantiation of an intrinsic with a
	// particular type and prototype
	class RVVIntrinsic {

	private:
	std::string BuiltinName; // Builtin name
	std::string Name; // C intrinsic name.
	std::string OverloadedName;
	std::string IRName;
	bool IsMasked;
	bool HasMaskedOffOperand;
	bool HasVL;
	PolicyScheme Scheme;
	bool SupportOverloading;
	bool HasBuiltinAlias;
	std::string ManualCodegen;
	RVVTypePtr OutputType; // Builtin output type
	RVVTypes InputTypes; // Builtin input types
	// The types we use to obtain the specific LLVM intrinsic. They are index of
	// InputTypes. -1 means the return type.
	std::vector<int64_t> IntrinsicTypes;
	unsigned NF = 1;
	Policy PolicyAttrs;

	public:
	RVVIntrinsic(llvm::StringRef Name, llvm::StringRef Suffix,
	llvm::StringRef OverloadedName, llvm::StringRef OverloadedSuffix,
	llvm::StringRef IRName, bool IsMasked, bool HasMaskedOffOperand,
	bool HasVL, PolicyScheme Scheme, bool SupportOverloading,
	bool HasBuiltinAlias, llvm::StringRef ManualCodegen,
	const RVVTypes &Types,
	const std::vector<int64_t> &IntrinsicTypes,
	unsigned NF, Policy PolicyAttrs, bool HasFRMRoundModeOp);
	~RVVIntrinsic() = default;

	RVVTypePtr getOutputType() const { return OutputType; }
	const RVVTypes &getInputTypes() const { return InputTypes; }
	llvm::StringRef getBuiltinName() const { return BuiltinName; }
	bool hasMaskedOffOperand() const { return HasMaskedOffOperand; }
	bool hasVL() const { return HasVL; }
	bool hasPolicy() const { return Scheme != PolicyScheme::SchemeNone; }
	bool hasPassthruOperand() const {
	return Scheme == PolicyScheme::HasPassthruOperand;
	}
	bool hasPolicyOperand() const {
	return Scheme == PolicyScheme::HasPolicyOperand;
	}
	bool supportOverloading() const { return SupportOverloading; }
	bool hasBuiltinAlias() const { return HasBuiltinAlias; }
	bool hasManualCodegen() const { return !ManualCodegen.empty(); }
	bool isMasked() const { return IsMasked; }
	llvm::StringRef getIRName() const { return IRName; }
	llvm::StringRef getManualCodegen() const { return ManualCodegen; }
	PolicyScheme getPolicyScheme() const { return Scheme; }
	unsigned getNF() const { return NF; }
	const std::vector<int64_t> &getIntrinsicTypes() const {
	return IntrinsicTypes;
	}
	Policy getPolicyAttrs() const {
	return PolicyAttrs;
	}
	unsigned getPolicyAttrsBits() const {
	// CGBuiltin.cpp
	// The 0th bit simulates the `vta` of RVV
	// The 1st bit simulates the `vma` of RVV
	// int PolicyAttrs = 0;

	if (PolicyAttrs.isTUMAPolicy())
	return 2;
	if (PolicyAttrs.isTAMAPolicy())
	return 3;
	if (PolicyAttrs.isTUMUPolicy())
	return 0;
	if (PolicyAttrs.isTAMUPolicy())
	return 1;

	llvm_unreachable("unsupport policy");
	return 0;
	}

	// Return the type string for a BUILTIN() macro in Builtins.def.
	std::string getBuiltinTypeStr() const;

	static std::string
	getSuffixStr(RVVTypeCache &TypeCache, BasicType Type, int Log2LMUL,
	llvm::ArrayRef<PrototypeDescriptor> PrototypeDescriptors);

	static llvm::SmallVector<PrototypeDescriptor>
	computeBuiltinTypes(llvm::ArrayRef<PrototypeDescriptor> Prototype,
	bool IsMasked, bool HasMaskedOffOperand, bool HasVL,
	unsigned NF, PolicyScheme DefaultScheme,
	Policy PolicyAttrs, bool IsTuple);

	static llvm::SmallVector<Policy> getSupportedUnMaskedPolicies();
	static llvm::SmallVector<Policy>
	getSupportedMaskedPolicies(bool HasTailPolicy, bool HasMaskPolicy);

	static void updateNamesAndPolicy(bool IsMasked, bool HasPolicy,
	std::string &Name, std::string &BuiltinName,
	std::string &OverloadedName,
	Policy &PolicyAttrs, bool HasFRMRoundModeOp);
	};

	// RVVRequire should be sync'ed with target features, but only
	// required features used in riscv_vector.td.
	enum RVVRequire : uint32_t {
	RVV_REQ_None = 0,
	RVV_REQ_RV64 = 1 << 0,
	RVV_REQ_Zvfhmin = 1 << 1,
	RVV_REQ_Xsfvcp = 1 << 2,
	RVV_REQ_Xsfvfnrclipxfqf = 1 << 3,
	RVV_REQ_Xsfvfwmaccqqq = 1 << 4,
	RVV_REQ_Xsfvqmaccdod = 1 << 5,
	RVV_REQ_Xsfvqmaccqoq = 1 << 6,
	RVV_REQ_Zvbb = 1 << 7,
	RVV_REQ_Zvbc = 1 << 8,
	RVV_REQ_Zvkb = 1 << 9,
	RVV_REQ_Zvkg = 1 << 10,
	RVV_REQ_Zvkned = 1 << 11,
	RVV_REQ_Zvknha = 1 << 12,
	RVV_REQ_Zvknhb = 1 << 13,
	RVV_REQ_Zvksed = 1 << 14,
	RVV_REQ_Zvksh = 1 << 15,
	RVV_REQ_Zvfbfwma = 1 << 16,
	RVV_REQ_Zvfbfmin = 1 << 17,
	RVV_REQ_Experimental = 1 << 18,

	LLVM_MARK_AS_BITMASK_ENUM(RVV_REQ_Experimental)
	};

	// Raw RVV intrinsic info, used to expand later.
	// This struct is highly compact for minimized code size.
	struct RVVIntrinsicRecord {
	// Intrinsic name, e.g. vadd_vv
	const char *Name;

	// Overloaded intrinsic name, could be empty if it can be computed from Name.
	// e.g. vadd
	const char *OverloadedName;

	// Prototype for this intrinsic, index of RVVSignatureTable.
	uint16_t PrototypeIndex;

	// Suffix of intrinsic name, index of RVVSignatureTable.
	uint16_t SuffixIndex;

	// Suffix of overloaded intrinsic name, index of RVVSignatureTable.
	uint16_t OverloadedSuffixIndex;

	// Length of the prototype.
	uint8_t PrototypeLength;

	// Length of intrinsic name suffix.
	uint8_t SuffixLength;

	// Length of overloaded intrinsic suffix.
	uint8_t OverloadedSuffixSize;

	// Required target features for this intrinsic.
	uint32_t RequiredExtensions;

	// Supported type, mask of BasicType.
	uint8_t TypeRangeMask;

	// Supported LMUL.
	uint8_t Log2LMULMask;

	// Number of fields, greater than 1 if it's segment load/store.
	uint8_t NF;

	bool HasMasked : 1;
	bool HasVL : 1;
	bool HasMaskedOffOperand : 1;
	bool HasTailPolicy : 1;
	bool HasMaskPolicy : 1;
	bool HasFRMRoundModeOp : 1;
	bool IsTuple : 1;
	LLVM_PREFERRED_TYPE(PolicyScheme)
	uint8_t UnMaskedPolicyScheme : 2;
	LLVM_PREFERRED_TYPE(PolicyScheme)
	uint8_t MaskedPolicyScheme : 2;
	};

	llvm::raw_ostream &operator<<(llvm::raw_ostream &OS,
	const RVVIntrinsicRecord &RVVInstrRecord);

	LLVM_ENABLE_BITMASK_ENUMS_IN_NAMESPACE();
	} // end namespace RISCV

	} // end namespace clang

	#endif // CLANG_SUPPORT_RISCVVINTRINSICUTILS_H