//===- llvm/TableGen/Record.h - Classes for Table Records -------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file defines the main TableGen data structures, including the TableGen // types, values, and high-level data structures. // //===----------------------------------------------------------------------===// #ifndef LLVM_TABLEGEN_RECORD_H #define LLVM_TABLEGEN_RECORD_H #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/FoldingSet.h" #include "llvm/Support/Allocator.h" #include "llvm/Support/Casting.h" #include "llvm/Support/DataTypes.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/SourceMgr.h" #include "llvm/Support/raw_ostream.h" #include namespace llvm { class raw_ostream; // RecTy subclasses. class BitRecTy; class BitsRecTy; class IntRecTy; class StringRecTy; class ListRecTy; class DagRecTy; class RecordRecTy; // Init subclasses. class Init; class UnsetInit; class BitInit; class BitsInit; class IntInit; class StringInit; class ListInit; class UnOpInit; class BinOpInit; class TernOpInit; class DefInit; class DagInit; class TypedInit; class VarInit; class FieldInit; class VarBitInit; class VarListElementInit; // Other classes. class Record; class RecordVal; struct MultiClass; class RecordKeeper; //===----------------------------------------------------------------------===// // Type Classes //===----------------------------------------------------------------------===// class RecTy { public: /// \brief Subclass discriminator (for dyn_cast<> et al.) enum RecTyKind { BitRecTyKind, BitsRecTyKind, IntRecTyKind, StringRecTyKind, ListRecTyKind, DagRecTyKind, RecordRecTyKind }; private: RecTyKind Kind; ListRecTy *ListTy; virtual void anchor(); public: RecTyKind getRecTyKind() const { return Kind; } RecTy(RecTyKind K) : Kind(K), ListTy(nullptr) {} virtual ~RecTy() {} virtual std::string getAsString() const = 0; void print(raw_ostream &OS) const { OS << getAsString(); } void dump() const; /// typeIsConvertibleTo - Return true if all values of 'this' type can be /// converted to the specified type. virtual bool typeIsConvertibleTo(const RecTy *RHS) const = 0; /// getListTy - Returns the type representing list. ListRecTy *getListTy(); public: // These methods should only be called from subclasses of Init virtual Init *convertValue( UnsetInit *UI) { return nullptr; } virtual Init *convertValue( BitInit *BI) { return nullptr; } virtual Init *convertValue( BitsInit *BI) { return nullptr; } virtual Init *convertValue( IntInit *II) { return nullptr; } virtual Init *convertValue(StringInit *SI) { return nullptr; } virtual Init *convertValue( ListInit *LI) { return nullptr; } virtual Init *convertValue( UnOpInit *UI) { return convertValue((TypedInit*)UI); } virtual Init *convertValue( BinOpInit *UI) { return convertValue((TypedInit*)UI); } virtual Init *convertValue( TernOpInit *UI) { return convertValue((TypedInit*)UI); } virtual Init *convertValue(VarBitInit *VB) { return nullptr; } virtual Init *convertValue( DefInit *DI) { return nullptr; } virtual Init *convertValue( DagInit *DI) { return nullptr; } virtual Init *convertValue( TypedInit *TI) { return nullptr; } virtual Init *convertValue( VarInit *VI) { return convertValue((TypedInit*)VI); } virtual Init *convertValue( FieldInit *FI) { return convertValue((TypedInit*)FI); } public: virtual bool baseClassOf(const RecTy*) const; }; inline raw_ostream &operator<<(raw_ostream &OS, const RecTy &Ty) { Ty.print(OS); return OS; } /// BitRecTy - 'bit' - Represent a single bit /// class BitRecTy : public RecTy { static BitRecTy Shared; BitRecTy() : RecTy(BitRecTyKind) {} public: static bool classof(const RecTy *RT) { return RT->getRecTyKind() == BitRecTyKind; } static BitRecTy *get() { return &Shared; } Init *convertValue( UnsetInit *UI) override { return (Init*)UI; } Init *convertValue( BitInit *BI) override { return (Init*)BI; } Init *convertValue( BitsInit *BI) override; Init *convertValue( IntInit *II) override; Init *convertValue(StringInit *SI) override { return nullptr; } Init *convertValue( ListInit *LI) override { return nullptr; } Init *convertValue(VarBitInit *VB) override { return (Init*)VB; } Init *convertValue( DefInit *DI) override { return nullptr; } Init *convertValue( DagInit *DI) override { return nullptr; } Init *convertValue( UnOpInit *UI) override { return RecTy::convertValue(UI);} Init *convertValue( BinOpInit *UI) override { return RecTy::convertValue(UI);} Init *convertValue( TernOpInit *UI) override {return RecTy::convertValue(UI);} Init *convertValue( TypedInit *TI) override; Init *convertValue( VarInit *VI) override { return RecTy::convertValue(VI);} Init *convertValue( FieldInit *FI) override { return RecTy::convertValue(FI);} std::string getAsString() const override { return "bit"; } bool typeIsConvertibleTo(const RecTy *RHS) const override { return RHS->baseClassOf(this); } bool baseClassOf(const RecTy*) const override; }; /// BitsRecTy - 'bits' - Represent a fixed number of bits /// class BitsRecTy : public RecTy { unsigned Size; explicit BitsRecTy(unsigned Sz) : RecTy(BitsRecTyKind), Size(Sz) {} public: static bool classof(const RecTy *RT) { return RT->getRecTyKind() == BitsRecTyKind; } static BitsRecTy *get(unsigned Sz); unsigned getNumBits() const { return Size; } Init *convertValue( UnsetInit *UI) override; Init *convertValue( BitInit *UI) override; Init *convertValue( BitsInit *BI) override; Init *convertValue( IntInit *II) override; Init *convertValue(StringInit *SI) override { return nullptr; } Init *convertValue( ListInit *LI) override { return nullptr; } Init *convertValue(VarBitInit *VB) override { return nullptr; } Init *convertValue( DefInit *DI) override { return nullptr; } Init *convertValue( DagInit *DI) override { return nullptr; } Init *convertValue( UnOpInit *UI) override { return RecTy::convertValue(UI);} Init *convertValue( BinOpInit *UI) override { return RecTy::convertValue(UI);} Init *convertValue(TernOpInit *UI) override { return RecTy::convertValue(UI);} Init *convertValue( TypedInit *TI) override; Init *convertValue( VarInit *VI) override { return RecTy::convertValue(VI);} Init *convertValue( FieldInit *FI) override { return RecTy::convertValue(FI);} std::string getAsString() const override; bool typeIsConvertibleTo(const RecTy *RHS) const override { return RHS->baseClassOf(this); } bool baseClassOf(const RecTy*) const override; }; /// IntRecTy - 'int' - Represent an integer value of no particular size /// class IntRecTy : public RecTy { static IntRecTy Shared; IntRecTy() : RecTy(IntRecTyKind) {} public: static bool classof(const RecTy *RT) { return RT->getRecTyKind() == IntRecTyKind; } static IntRecTy *get() { return &Shared; } Init *convertValue( UnsetInit *UI) override { return (Init*)UI; } Init *convertValue( BitInit *BI) override; Init *convertValue( BitsInit *BI) override; Init *convertValue( IntInit *II) override { return (Init*)II; } Init *convertValue(StringInit *SI) override { return nullptr; } Init *convertValue( ListInit *LI) override { return nullptr; } Init *convertValue(VarBitInit *VB) override { return nullptr; } Init *convertValue( DefInit *DI) override { return nullptr; } Init *convertValue( DagInit *DI) override { return nullptr; } Init *convertValue( UnOpInit *UI) override { return RecTy::convertValue(UI);} Init *convertValue( BinOpInit *UI) override { return RecTy::convertValue(UI);} Init *convertValue( TernOpInit *UI) override {return RecTy::convertValue(UI);} Init *convertValue( TypedInit *TI) override; Init *convertValue( VarInit *VI) override { return RecTy::convertValue(VI);} Init *convertValue( FieldInit *FI) override { return RecTy::convertValue(FI);} std::string getAsString() const override { return "int"; } bool typeIsConvertibleTo(const RecTy *RHS) const override { return RHS->baseClassOf(this); } bool baseClassOf(const RecTy*) const override; }; /// StringRecTy - 'string' - Represent an string value /// class StringRecTy : public RecTy { static StringRecTy Shared; StringRecTy() : RecTy(StringRecTyKind) {} public: static bool classof(const RecTy *RT) { return RT->getRecTyKind() == StringRecTyKind; } static StringRecTy *get() { return &Shared; } Init *convertValue( UnsetInit *UI) override { return (Init*)UI; } Init *convertValue( BitInit *BI) override { return nullptr; } Init *convertValue( BitsInit *BI) override { return nullptr; } Init *convertValue( IntInit *II) override { return nullptr; } Init *convertValue(StringInit *SI) override { return (Init*)SI; } Init *convertValue( ListInit *LI) override { return nullptr; } Init *convertValue( UnOpInit *BO) override; Init *convertValue( BinOpInit *BO) override; Init *convertValue( TernOpInit *BO) override {return RecTy::convertValue(BO);} Init *convertValue(VarBitInit *VB) override { return nullptr; } Init *convertValue( DefInit *DI) override { return nullptr; } Init *convertValue( DagInit *DI) override { return nullptr; } Init *convertValue( TypedInit *TI) override; Init *convertValue( VarInit *VI) override { return RecTy::convertValue(VI);} Init *convertValue( FieldInit *FI) override { return RecTy::convertValue(FI);} std::string getAsString() const override { return "string"; } bool typeIsConvertibleTo(const RecTy *RHS) const override { return RHS->baseClassOf(this); } }; /// ListRecTy - 'list' - Represent a list of values, all of which must be of /// the specified type. /// class ListRecTy : public RecTy { RecTy *Ty; explicit ListRecTy(RecTy *T) : RecTy(ListRecTyKind), Ty(T) {} friend ListRecTy *RecTy::getListTy(); public: static bool classof(const RecTy *RT) { return RT->getRecTyKind() == ListRecTyKind; } static ListRecTy *get(RecTy *T) { return T->getListTy(); } RecTy *getElementType() const { return Ty; } Init *convertValue( UnsetInit *UI) override { return (Init*)UI; } Init *convertValue( BitInit *BI) override { return nullptr; } Init *convertValue( BitsInit *BI) override { return nullptr; } Init *convertValue( IntInit *II) override { return nullptr; } Init *convertValue(StringInit *SI) override { return nullptr; } Init *convertValue( ListInit *LI) override; Init *convertValue(VarBitInit *VB) override { return nullptr; } Init *convertValue( DefInit *DI) override { return nullptr; } Init *convertValue( DagInit *DI) override { return nullptr; } Init *convertValue( UnOpInit *UI) override { return RecTy::convertValue(UI);} Init *convertValue( BinOpInit *UI) override { return RecTy::convertValue(UI);} Init *convertValue(TernOpInit *UI) override { return RecTy::convertValue(UI);} Init *convertValue( TypedInit *TI) override; Init *convertValue( VarInit *VI) override { return RecTy::convertValue(VI);} Init *convertValue( FieldInit *FI) override { return RecTy::convertValue(FI);} std::string getAsString() const override; bool typeIsConvertibleTo(const RecTy *RHS) const override { return RHS->baseClassOf(this); } bool baseClassOf(const RecTy*) const override; }; /// DagRecTy - 'dag' - Represent a dag fragment /// class DagRecTy : public RecTy { static DagRecTy Shared; DagRecTy() : RecTy(DagRecTyKind) {} public: static bool classof(const RecTy *RT) { return RT->getRecTyKind() == DagRecTyKind; } static DagRecTy *get() { return &Shared; } Init *convertValue( UnsetInit *UI) override { return (Init*)UI; } Init *convertValue( BitInit *BI) override { return nullptr; } Init *convertValue( BitsInit *BI) override { return nullptr; } Init *convertValue( IntInit *II) override { return nullptr; } Init *convertValue(StringInit *SI) override { return nullptr; } Init *convertValue( ListInit *LI) override { return nullptr; } Init *convertValue(VarBitInit *VB) override { return nullptr; } Init *convertValue( DefInit *DI) override { return nullptr; } Init *convertValue( UnOpInit *BO) override; Init *convertValue( BinOpInit *BO) override; Init *convertValue( TernOpInit *BO) override {return RecTy::convertValue(BO);} Init *convertValue( DagInit *CI) override { return (Init*)CI; } Init *convertValue( TypedInit *TI) override; Init *convertValue( VarInit *VI) override { return RecTy::convertValue(VI);} Init *convertValue( FieldInit *FI) override { return RecTy::convertValue(FI);} std::string getAsString() const override { return "dag"; } bool typeIsConvertibleTo(const RecTy *RHS) const override { return RHS->baseClassOf(this); } }; /// RecordRecTy - '[classname]' - Represent an instance of a class, such as: /// (R32 X = EAX). /// class RecordRecTy : public RecTy { Record *Rec; explicit RecordRecTy(Record *R) : RecTy(RecordRecTyKind), Rec(R) {} friend class Record; public: static bool classof(const RecTy *RT) { return RT->getRecTyKind() == RecordRecTyKind; } static RecordRecTy *get(Record *R); Record *getRecord() const { return Rec; } Init *convertValue( UnsetInit *UI) override { return (Init*)UI; } Init *convertValue( BitInit *BI) override { return nullptr; } Init *convertValue( BitsInit *BI) override { return nullptr; } Init *convertValue( IntInit *II) override { return nullptr; } Init *convertValue(StringInit *SI) override { return nullptr; } Init *convertValue( ListInit *LI) override { return nullptr; } Init *convertValue(VarBitInit *VB) override { return nullptr; } Init *convertValue( UnOpInit *UI) override { return RecTy::convertValue(UI);} Init *convertValue( BinOpInit *UI) override { return RecTy::convertValue(UI);} Init *convertValue( TernOpInit *UI) override {return RecTy::convertValue(UI);} Init *convertValue( DefInit *DI) override; Init *convertValue( DagInit *DI) override { return nullptr; } Init *convertValue( TypedInit *VI) override; Init *convertValue( VarInit *VI) override { return RecTy::convertValue(VI);} Init *convertValue( FieldInit *FI) override { return RecTy::convertValue(FI);} std::string getAsString() const override; bool typeIsConvertibleTo(const RecTy *RHS) const override { return RHS->baseClassOf(this); } bool baseClassOf(const RecTy*) const override; }; /// resolveTypes - Find a common type that T1 and T2 convert to. /// Return 0 if no such type exists. /// RecTy *resolveTypes(RecTy *T1, RecTy *T2); //===----------------------------------------------------------------------===// // Initializer Classes //===----------------------------------------------------------------------===// class Init { protected: /// \brief Discriminator enum (for isa<>, dyn_cast<>, et al.) /// /// This enum is laid out by a preorder traversal of the inheritance /// hierarchy, and does not contain an entry for abstract classes, as per /// the recommendation in docs/HowToSetUpLLVMStyleRTTI.rst. /// /// We also explicitly include "first" and "last" values for each /// interior node of the inheritance tree, to make it easier to read the /// corresponding classof(). /// /// We could pack these a bit tighter by not having the IK_FirstXXXInit /// and IK_LastXXXInit be their own values, but that would degrade /// readability for really no benefit. enum InitKind { IK_BitInit, IK_FirstTypedInit, IK_BitsInit, IK_DagInit, IK_DefInit, IK_FieldInit, IK_IntInit, IK_ListInit, IK_FirstOpInit, IK_BinOpInit, IK_TernOpInit, IK_UnOpInit, IK_LastOpInit, IK_StringInit, IK_VarInit, IK_VarListElementInit, IK_LastTypedInit, IK_UnsetInit, IK_VarBitInit }; private: const InitKind Kind; Init(const Init &) = delete; Init &operator=(const Init &) = delete; virtual void anchor(); public: InitKind getKind() const { return Kind; } protected: explicit Init(InitKind K) : Kind(K) {} public: virtual ~Init() {} /// isComplete - This virtual method should be overridden by values that may /// not be completely specified yet. virtual bool isComplete() const { return true; } /// print - Print out this value. void print(raw_ostream &OS) const { OS << getAsString(); } /// getAsString - Convert this value to a string form. virtual std::string getAsString() const = 0; /// getAsUnquotedString - Convert this value to a string form, /// without adding quote markers. This primaruly affects /// StringInits where we will not surround the string value with /// quotes. virtual std::string getAsUnquotedString() const { return getAsString(); } /// dump - Debugging method that may be called through a debugger, just /// invokes print on stderr. void dump() const; /// convertInitializerTo - This virtual function is a simple call-back /// function that should be overridden to call the appropriate /// RecTy::convertValue method. /// virtual Init *convertInitializerTo(RecTy *Ty) const = 0; /// convertInitializerBitRange - This method is used to implement the bitrange /// selection operator. Given an initializer, it selects the specified bits /// out, returning them as a new init of bits type. If it is not legal to use /// the bit subscript operator on this initializer, return null. /// virtual Init * convertInitializerBitRange(const std::vector &Bits) const { return nullptr; } /// convertInitListSlice - This method is used to implement the list slice /// selection operator. Given an initializer, it selects the specified list /// elements, returning them as a new init of list type. If it is not legal /// to take a slice of this, return null. /// virtual Init * convertInitListSlice(const std::vector &Elements) const { return nullptr; } /// getFieldType - This method is used to implement the FieldInit class. /// Implementors of this method should return the type of the named field if /// they are of record type. /// virtual RecTy *getFieldType(const std::string &FieldName) const { return nullptr; } /// getFieldInit - This method complements getFieldType to return the /// initializer for the specified field. If getFieldType returns non-null /// this method should return non-null, otherwise it returns null. /// virtual Init *getFieldInit(Record &R, const RecordVal *RV, const std::string &FieldName) const { return nullptr; } /// resolveReferences - This method is used by classes that refer to other /// variables which may not be defined at the time the expression is formed. /// If a value is set for the variable later, this method will be called on /// users of the value to allow the value to propagate out. /// virtual Init *resolveReferences(Record &R, const RecordVal *RV) const { return const_cast(this); } /// getBit - This method is used to return the initializer for the specified /// bit. virtual Init *getBit(unsigned Bit) const = 0; /// getBitVar - This method is used to retrieve the initializer for bit /// reference. For non-VarBitInit, it simply returns itself. virtual Init *getBitVar() const { return const_cast(this); } /// getBitNum - This method is used to retrieve the bit number of a bit /// reference. For non-VarBitInit, it simply returns 0. virtual unsigned getBitNum() const { return 0; } }; inline raw_ostream &operator<<(raw_ostream &OS, const Init &I) { I.print(OS); return OS; } /// TypedInit - This is the common super-class of types that have a specific, /// explicit, type. /// class TypedInit : public Init { RecTy *Ty; TypedInit(const TypedInit &Other) = delete; TypedInit &operator=(const TypedInit &Other) = delete; protected: explicit TypedInit(InitKind K, RecTy *T) : Init(K), Ty(T) {} public: static bool classof(const Init *I) { return I->getKind() >= IK_FirstTypedInit && I->getKind() <= IK_LastTypedInit; } RecTy *getType() const { return Ty; } Init * convertInitializerBitRange(const std::vector &Bits) const override; Init * convertInitListSlice(const std::vector &Elements) const override; /// getFieldType - This method is used to implement the FieldInit class. /// Implementors of this method should return the type of the named field if /// they are of record type. /// RecTy *getFieldType(const std::string &FieldName) const override; /// resolveListElementReference - This method is used to implement /// VarListElementInit::resolveReferences. If the list element is resolvable /// now, we return the resolved value, otherwise we return null. virtual Init *resolveListElementReference(Record &R, const RecordVal *RV, unsigned Elt) const = 0; }; /// UnsetInit - ? - Represents an uninitialized value /// class UnsetInit : public Init { UnsetInit() : Init(IK_UnsetInit) {} UnsetInit(const UnsetInit &) = delete; UnsetInit &operator=(const UnsetInit &Other) = delete; void anchor() override; public: static bool classof(const Init *I) { return I->getKind() == IK_UnsetInit; } static UnsetInit *get(); Init *convertInitializerTo(RecTy *Ty) const override { return Ty->convertValue(const_cast(this)); } Init *getBit(unsigned Bit) const override { return const_cast(this); } bool isComplete() const override { return false; } std::string getAsString() const override { return "?"; } }; /// BitInit - true/false - Represent a concrete initializer for a bit. /// class BitInit : public Init { bool Value; explicit BitInit(bool V) : Init(IK_BitInit), Value(V) {} BitInit(const BitInit &Other) = delete; BitInit &operator=(BitInit &Other) = delete; void anchor() override; public: static bool classof(const Init *I) { return I->getKind() == IK_BitInit; } static BitInit *get(bool V); bool getValue() const { return Value; } Init *convertInitializerTo(RecTy *Ty) const override { return Ty->convertValue(const_cast(this)); } Init *getBit(unsigned Bit) const override { assert(Bit < 1 && "Bit index out of range!"); return const_cast(this); } std::string getAsString() const override { return Value ? "1" : "0"; } }; /// BitsInit - { a, b, c } - Represents an initializer for a BitsRecTy value. /// It contains a vector of bits, whose size is determined by the type. /// class BitsInit : public TypedInit, public FoldingSetNode { std::vector Bits; BitsInit(ArrayRef Range) : TypedInit(IK_BitsInit, BitsRecTy::get(Range.size())), Bits(Range.begin(), Range.end()) {} BitsInit(const BitsInit &Other) = delete; BitsInit &operator=(const BitsInit &Other) = delete; public: static bool classof(const Init *I) { return I->getKind() == IK_BitsInit; } static BitsInit *get(ArrayRef Range); void Profile(FoldingSetNodeID &ID) const; unsigned getNumBits() const { return Bits.size(); } Init *convertInitializerTo(RecTy *Ty) const override { return Ty->convertValue(const_cast(this)); } Init * convertInitializerBitRange(const std::vector &Bits) const override; bool isComplete() const override { for (unsigned i = 0; i != getNumBits(); ++i) if (!getBit(i)->isComplete()) return false; return true; } bool allInComplete() const { for (unsigned i = 0; i != getNumBits(); ++i) if (getBit(i)->isComplete()) return false; return true; } std::string getAsString() const override; /// resolveListElementReference - This method is used to implement /// VarListElementInit::resolveReferences. If the list element is resolvable /// now, we return the resolved value, otherwise we return null. Init *resolveListElementReference(Record &R, const RecordVal *RV, unsigned Elt) const override { llvm_unreachable("Illegal element reference off bits"); } Init *resolveReferences(Record &R, const RecordVal *RV) const override; Init *getBit(unsigned Bit) const override { assert(Bit < Bits.size() && "Bit index out of range!"); return Bits[Bit]; } }; /// IntInit - 7 - Represent an initialization by a literal integer value. /// class IntInit : public TypedInit { int64_t Value; explicit IntInit(int64_t V) : TypedInit(IK_IntInit, IntRecTy::get()), Value(V) {} IntInit(const IntInit &Other) = delete; IntInit &operator=(const IntInit &Other) = delete; public: static bool classof(const Init *I) { return I->getKind() == IK_IntInit; } static IntInit *get(int64_t V); int64_t getValue() const { return Value; } Init *convertInitializerTo(RecTy *Ty) const override { return Ty->convertValue(const_cast(this)); } Init * convertInitializerBitRange(const std::vector &Bits) const override; std::string getAsString() const override; /// resolveListElementReference - This method is used to implement /// VarListElementInit::resolveReferences. If the list element is resolvable /// now, we return the resolved value, otherwise we return null. Init *resolveListElementReference(Record &R, const RecordVal *RV, unsigned Elt) const override { llvm_unreachable("Illegal element reference off int"); } Init *getBit(unsigned Bit) const override { return BitInit::get((Value & (1ULL << Bit)) != 0); } }; /// StringInit - "foo" - Represent an initialization by a string value. /// class StringInit : public TypedInit { std::string Value; explicit StringInit(const std::string &V) : TypedInit(IK_StringInit, StringRecTy::get()), Value(V) {} StringInit(const StringInit &Other) = delete; StringInit &operator=(const StringInit &Other) = delete; void anchor() override; public: static bool classof(const Init *I) { return I->getKind() == IK_StringInit; } static StringInit *get(StringRef); const std::string &getValue() const { return Value; } Init *convertInitializerTo(RecTy *Ty) const override { return Ty->convertValue(const_cast(this)); } std::string getAsString() const override { return "\"" + Value + "\""; } std::string getAsUnquotedString() const override { return Value; } /// resolveListElementReference - This method is used to implement /// VarListElementInit::resolveReferences. If the list element is resolvable /// now, we return the resolved value, otherwise we return null. Init *resolveListElementReference(Record &R, const RecordVal *RV, unsigned Elt) const override { llvm_unreachable("Illegal element reference off string"); } Init *getBit(unsigned Bit) const override { llvm_unreachable("Illegal bit reference off string"); } }; /// ListInit - [AL, AH, CL] - Represent a list of defs /// class ListInit : public TypedInit, public FoldingSetNode { std::vector Values; public: typedef std::vector::const_iterator const_iterator; private: explicit ListInit(ArrayRef Range, RecTy *EltTy) : TypedInit(IK_ListInit, ListRecTy::get(EltTy)), Values(Range.begin(), Range.end()) {} ListInit(const ListInit &Other) = delete; ListInit &operator=(const ListInit &Other) = delete; public: static bool classof(const Init *I) { return I->getKind() == IK_ListInit; } static ListInit *get(ArrayRef Range, RecTy *EltTy); void Profile(FoldingSetNodeID &ID) const; unsigned getSize() const { return Values.size(); } Init *getElement(unsigned i) const { assert(i < Values.size() && "List element index out of range!"); return Values[i]; } Record *getElementAsRecord(unsigned i) const; Init * convertInitListSlice(const std::vector &Elements) const override; Init *convertInitializerTo(RecTy *Ty) const override { return Ty->convertValue(const_cast(this)); } /// resolveReferences - This method is used by classes that refer to other /// variables which may not be defined at the time they expression is formed. /// If a value is set for the variable later, this method will be called on /// users of the value to allow the value to propagate out. /// Init *resolveReferences(Record &R, const RecordVal *RV) const override; std::string getAsString() const override; ArrayRef getValues() const { return Values; } inline const_iterator begin() const { return Values.begin(); } inline const_iterator end () const { return Values.end(); } inline size_t size () const { return Values.size(); } inline bool empty() const { return Values.empty(); } /// resolveListElementReference - This method is used to implement /// VarListElementInit::resolveReferences. If the list element is resolvable /// now, we return the resolved value, otherwise we return null. Init *resolveListElementReference(Record &R, const RecordVal *RV, unsigned Elt) const override; Init *getBit(unsigned Bit) const override { llvm_unreachable("Illegal bit reference off list"); } }; /// OpInit - Base class for operators /// class OpInit : public TypedInit { OpInit(const OpInit &Other) = delete; OpInit &operator=(OpInit &Other) = delete; protected: explicit OpInit(InitKind K, RecTy *Type) : TypedInit(K, Type) {} public: static bool classof(const Init *I) { return I->getKind() >= IK_FirstOpInit && I->getKind() <= IK_LastOpInit; } // Clone - Clone this operator, replacing arguments with the new list virtual OpInit *clone(std::vector &Operands) const = 0; virtual int getNumOperands() const = 0; virtual Init *getOperand(int i) const = 0; // Fold - If possible, fold this to a simpler init. Return this if not // possible to fold. virtual Init *Fold(Record *CurRec, MultiClass *CurMultiClass) const = 0; Init *convertInitializerTo(RecTy *Ty) const override { return Ty->convertValue(const_cast(this)); } Init *resolveListElementReference(Record &R, const RecordVal *RV, unsigned Elt) const override; Init *getBit(unsigned Bit) const override; }; /// UnOpInit - !op (X) - Transform an init. /// class UnOpInit : public OpInit { public: enum UnaryOp { CAST, HEAD, TAIL, EMPTY }; private: UnaryOp Opc; Init *LHS; UnOpInit(UnaryOp opc, Init *lhs, RecTy *Type) : OpInit(IK_UnOpInit, Type), Opc(opc), LHS(lhs) {} UnOpInit(const UnOpInit &Other) = delete; UnOpInit &operator=(const UnOpInit &Other) = delete; public: static bool classof(const Init *I) { return I->getKind() == IK_UnOpInit; } static UnOpInit *get(UnaryOp opc, Init *lhs, RecTy *Type); // Clone - Clone this operator, replacing arguments with the new list OpInit *clone(std::vector &Operands) const override { assert(Operands.size() == 1 && "Wrong number of operands for unary operation"); return UnOpInit::get(getOpcode(), *Operands.begin(), getType()); } int getNumOperands() const override { return 1; } Init *getOperand(int i) const override { assert(i == 0 && "Invalid operand id for unary operator"); return getOperand(); } UnaryOp getOpcode() const { return Opc; } Init *getOperand() const { return LHS; } // Fold - If possible, fold this to a simpler init. Return this if not // possible to fold. Init *Fold(Record *CurRec, MultiClass *CurMultiClass) const override; Init *resolveReferences(Record &R, const RecordVal *RV) const override; std::string getAsString() const override; }; /// BinOpInit - !op (X, Y) - Combine two inits. /// class BinOpInit : public OpInit { public: enum BinaryOp { ADD, AND, SHL, SRA, SRL, LISTCONCAT, STRCONCAT, CONCAT, EQ }; private: BinaryOp Opc; Init *LHS, *RHS; BinOpInit(BinaryOp opc, Init *lhs, Init *rhs, RecTy *Type) : OpInit(IK_BinOpInit, Type), Opc(opc), LHS(lhs), RHS(rhs) {} BinOpInit(const BinOpInit &Other) = delete; BinOpInit &operator=(const BinOpInit &Other) = delete; public: static bool classof(const Init *I) { return I->getKind() == IK_BinOpInit; } static BinOpInit *get(BinaryOp opc, Init *lhs, Init *rhs, RecTy *Type); // Clone - Clone this operator, replacing arguments with the new list OpInit *clone(std::vector &Operands) const override { assert(Operands.size() == 2 && "Wrong number of operands for binary operation"); return BinOpInit::get(getOpcode(), Operands[0], Operands[1], getType()); } int getNumOperands() const override { return 2; } Init *getOperand(int i) const override { assert((i == 0 || i == 1) && "Invalid operand id for binary operator"); if (i == 0) { return getLHS(); } else { return getRHS(); } } BinaryOp getOpcode() const { return Opc; } Init *getLHS() const { return LHS; } Init *getRHS() const { return RHS; } // Fold - If possible, fold this to a simpler init. Return this if not // possible to fold. Init *Fold(Record *CurRec, MultiClass *CurMultiClass) const override; Init *resolveReferences(Record &R, const RecordVal *RV) const override; std::string getAsString() const override; }; /// TernOpInit - !op (X, Y, Z) - Combine two inits. /// class TernOpInit : public OpInit { public: enum TernaryOp { SUBST, FOREACH, IF }; private: TernaryOp Opc; Init *LHS, *MHS, *RHS; TernOpInit(TernaryOp opc, Init *lhs, Init *mhs, Init *rhs, RecTy *Type) : OpInit(IK_TernOpInit, Type), Opc(opc), LHS(lhs), MHS(mhs), RHS(rhs) {} TernOpInit(const TernOpInit &Other) = delete; TernOpInit &operator=(const TernOpInit &Other) = delete; public: static bool classof(const Init *I) { return I->getKind() == IK_TernOpInit; } static TernOpInit *get(TernaryOp opc, Init *lhs, Init *mhs, Init *rhs, RecTy *Type); // Clone - Clone this operator, replacing arguments with the new list OpInit *clone(std::vector &Operands) const override { assert(Operands.size() == 3 && "Wrong number of operands for ternary operation"); return TernOpInit::get(getOpcode(), Operands[0], Operands[1], Operands[2], getType()); } int getNumOperands() const override { return 3; } Init *getOperand(int i) const override { assert((i == 0 || i == 1 || i == 2) && "Invalid operand id for ternary operator"); if (i == 0) { return getLHS(); } else if (i == 1) { return getMHS(); } else { return getRHS(); } } TernaryOp getOpcode() const { return Opc; } Init *getLHS() const { return LHS; } Init *getMHS() const { return MHS; } Init *getRHS() const { return RHS; } // Fold - If possible, fold this to a simpler init. Return this if not // possible to fold. Init *Fold(Record *CurRec, MultiClass *CurMultiClass) const override; bool isComplete() const override { return false; } Init *resolveReferences(Record &R, const RecordVal *RV) const override; std::string getAsString() const override; }; /// VarInit - 'Opcode' - Represent a reference to an entire variable object. /// class VarInit : public TypedInit { Init *VarName; explicit VarInit(const std::string &VN, RecTy *T) : TypedInit(IK_VarInit, T), VarName(StringInit::get(VN)) {} explicit VarInit(Init *VN, RecTy *T) : TypedInit(IK_VarInit, T), VarName(VN) {} VarInit(const VarInit &Other) = delete; VarInit &operator=(const VarInit &Other) = delete; public: static bool classof(const Init *I) { return I->getKind() == IK_VarInit; } static VarInit *get(const std::string &VN, RecTy *T); static VarInit *get(Init *VN, RecTy *T); Init *convertInitializerTo(RecTy *Ty) const override { return Ty->convertValue(const_cast(this)); } const std::string &getName() const; Init *getNameInit() const { return VarName; } std::string getNameInitAsString() const { return getNameInit()->getAsUnquotedString(); } Init *resolveListElementReference(Record &R, const RecordVal *RV, unsigned Elt) const override; RecTy *getFieldType(const std::string &FieldName) const override; Init *getFieldInit(Record &R, const RecordVal *RV, const std::string &FieldName) const override; /// resolveReferences - This method is used by classes that refer to other /// variables which may not be defined at the time they expression is formed. /// If a value is set for the variable later, this method will be called on /// users of the value to allow the value to propagate out. /// Init *resolveReferences(Record &R, const RecordVal *RV) const override; Init *getBit(unsigned Bit) const override; std::string getAsString() const override { return getName(); } }; /// VarBitInit - Opcode{0} - Represent access to one bit of a variable or field. /// class VarBitInit : public Init { TypedInit *TI; unsigned Bit; VarBitInit(TypedInit *T, unsigned B) : Init(IK_VarBitInit), TI(T), Bit(B) { assert(T->getType() && (isa(T->getType()) || (isa(T->getType()) && cast(T->getType())->getNumBits() > B)) && "Illegal VarBitInit expression!"); } VarBitInit(const VarBitInit &Other) = delete; VarBitInit &operator=(const VarBitInit &Other) = delete; public: static bool classof(const Init *I) { return I->getKind() == IK_VarBitInit; } static VarBitInit *get(TypedInit *T, unsigned B); Init *convertInitializerTo(RecTy *Ty) const override { return Ty->convertValue(const_cast(this)); } Init *getBitVar() const override { return TI; } unsigned getBitNum() const override { return Bit; } std::string getAsString() const override; Init *resolveReferences(Record &R, const RecordVal *RV) const override; Init *getBit(unsigned B) const override { assert(B < 1 && "Bit index out of range!"); return const_cast(this); } }; /// VarListElementInit - List[4] - Represent access to one element of a var or /// field. class VarListElementInit : public TypedInit { TypedInit *TI; unsigned Element; VarListElementInit(TypedInit *T, unsigned E) : TypedInit(IK_VarListElementInit, cast(T->getType())->getElementType()), TI(T), Element(E) { assert(T->getType() && isa(T->getType()) && "Illegal VarBitInit expression!"); } VarListElementInit(const VarListElementInit &Other) = delete; void operator=(const VarListElementInit &Other) = delete; public: static bool classof(const Init *I) { return I->getKind() == IK_VarListElementInit; } static VarListElementInit *get(TypedInit *T, unsigned E); Init *convertInitializerTo(RecTy *Ty) const override { return Ty->convertValue(const_cast(this)); } TypedInit *getVariable() const { return TI; } unsigned getElementNum() const { return Element; } /// resolveListElementReference - This method is used to implement /// VarListElementInit::resolveReferences. If the list element is resolvable /// now, we return the resolved value, otherwise we return null. Init *resolveListElementReference(Record &R, const RecordVal *RV, unsigned Elt) const override; std::string getAsString() const override; Init *resolveReferences(Record &R, const RecordVal *RV) const override; Init *getBit(unsigned Bit) const override; }; /// DefInit - AL - Represent a reference to a 'def' in the description /// class DefInit : public TypedInit { Record *Def; DefInit(Record *D, RecordRecTy *T) : TypedInit(IK_DefInit, T), Def(D) {} friend class Record; DefInit(const DefInit &Other) = delete; DefInit &operator=(const DefInit &Other) = delete; public: static bool classof(const Init *I) { return I->getKind() == IK_DefInit; } static DefInit *get(Record*); Init *convertInitializerTo(RecTy *Ty) const override { return Ty->convertValue(const_cast(this)); } Record *getDef() const { return Def; } //virtual Init *convertInitializerBitRange(const std::vector &Bits); RecTy *getFieldType(const std::string &FieldName) const override; Init *getFieldInit(Record &R, const RecordVal *RV, const std::string &FieldName) const override; std::string getAsString() const override; Init *getBit(unsigned Bit) const override { llvm_unreachable("Illegal bit reference off def"); } /// resolveListElementReference - This method is used to implement /// VarListElementInit::resolveReferences. If the list element is resolvable /// now, we return the resolved value, otherwise we return null. Init *resolveListElementReference(Record &R, const RecordVal *RV, unsigned Elt) const override { llvm_unreachable("Illegal element reference off def"); } }; /// FieldInit - X.Y - Represent a reference to a subfield of a variable /// class FieldInit : public TypedInit { Init *Rec; // Record we are referring to std::string FieldName; // Field we are accessing FieldInit(Init *R, const std::string &FN) : TypedInit(IK_FieldInit, R->getFieldType(FN)), Rec(R), FieldName(FN) { assert(getType() && "FieldInit with non-record type!"); } FieldInit(const FieldInit &Other) = delete; FieldInit &operator=(const FieldInit &Other) = delete; public: static bool classof(const Init *I) { return I->getKind() == IK_FieldInit; } static FieldInit *get(Init *R, const std::string &FN); static FieldInit *get(Init *R, const Init *FN); Init *convertInitializerTo(RecTy *Ty) const override { return Ty->convertValue(const_cast(this)); } Init *getBit(unsigned Bit) const override; Init *resolveListElementReference(Record &R, const RecordVal *RV, unsigned Elt) const override; Init *resolveReferences(Record &R, const RecordVal *RV) const override; std::string getAsString() const override { return Rec->getAsString() + "." + FieldName; } }; /// DagInit - (v a, b) - Represent a DAG tree value. DAG inits are required /// to have at least one value then a (possibly empty) list of arguments. Each /// argument can have a name associated with it. /// class DagInit : public TypedInit, public FoldingSetNode { Init *Val; std::string ValName; std::vector Args; std::vector ArgNames; DagInit(Init *V, const std::string &VN, ArrayRef ArgRange, ArrayRef NameRange) : TypedInit(IK_DagInit, DagRecTy::get()), Val(V), ValName(VN), Args(ArgRange.begin(), ArgRange.end()), ArgNames(NameRange.begin(), NameRange.end()) {} DagInit(const DagInit &Other) = delete; DagInit &operator=(const DagInit &Other) = delete; public: static bool classof(const Init *I) { return I->getKind() == IK_DagInit; } static DagInit *get(Init *V, const std::string &VN, ArrayRef ArgRange, ArrayRef NameRange); static DagInit *get(Init *V, const std::string &VN, const std::vector< std::pair > &args); void Profile(FoldingSetNodeID &ID) const; Init *convertInitializerTo(RecTy *Ty) const override { return Ty->convertValue(const_cast(this)); } Init *getOperator() const { return Val; } const std::string &getName() const { return ValName; } unsigned getNumArgs() const { return Args.size(); } Init *getArg(unsigned Num) const { assert(Num < Args.size() && "Arg number out of range!"); return Args[Num]; } const std::string &getArgName(unsigned Num) const { assert(Num < ArgNames.size() && "Arg number out of range!"); return ArgNames[Num]; } Init *resolveReferences(Record &R, const RecordVal *RV) const override; std::string getAsString() const override; typedef std::vector::const_iterator const_arg_iterator; typedef std::vector::const_iterator const_name_iterator; inline const_arg_iterator arg_begin() const { return Args.begin(); } inline const_arg_iterator arg_end () const { return Args.end(); } inline size_t arg_size () const { return Args.size(); } inline bool arg_empty() const { return Args.empty(); } inline const_name_iterator name_begin() const { return ArgNames.begin(); } inline const_name_iterator name_end () const { return ArgNames.end(); } inline size_t name_size () const { return ArgNames.size(); } inline bool name_empty() const { return ArgNames.empty(); } Init *getBit(unsigned Bit) const override { llvm_unreachable("Illegal bit reference off dag"); } Init *resolveListElementReference(Record &R, const RecordVal *RV, unsigned Elt) const override { llvm_unreachable("Illegal element reference off dag"); } }; //===----------------------------------------------------------------------===// // High-Level Classes //===----------------------------------------------------------------------===// class RecordVal { Init *Name; RecTy *Ty; unsigned Prefix; Init *Value; public: RecordVal(Init *N, RecTy *T, unsigned P); RecordVal(const std::string &N, RecTy *T, unsigned P); const std::string &getName() const; const Init *getNameInit() const { return Name; } std::string getNameInitAsString() const { return getNameInit()->getAsUnquotedString(); } unsigned getPrefix() const { return Prefix; } RecTy *getType() const { return Ty; } Init *getValue() const { return Value; } bool setValue(Init *V) { if (V) { Value = V->convertInitializerTo(Ty); return Value == nullptr; } Value = nullptr; return false; } void dump() const; void print(raw_ostream &OS, bool PrintSem = true) const; }; inline raw_ostream &operator<<(raw_ostream &OS, const RecordVal &RV) { RV.print(OS << " "); return OS; } class Record { static unsigned LastID; // Unique record ID. unsigned ID; Init *Name; // Location where record was instantiated, followed by the location of // multiclass prototypes used. SmallVector Locs; std::vector TemplateArgs; std::vector Values; std::vector SuperClasses; std::vector SuperClassRanges; // Tracks Record instances. Not owned by Record. RecordKeeper &TrackedRecords; DefInit *TheInit; bool IsAnonymous; // Class-instance values can be used by other defs. For example, Struct // is used here as a template argument to another class: // // multiclass MultiClass { // def Def : Class>; // // These need to get fully resolved before instantiating any other // definitions that usie them (e.g. Def). However, inside a multiclass they // can't be immediately resolved so we mark them ResolveFirst to fully // resolve them later as soon as the multiclass is instantiated. bool ResolveFirst; void init(); void checkName(); public: // Constructs a record. explicit Record(const std::string &N, ArrayRef locs, RecordKeeper &records, bool Anonymous = false) : ID(LastID++), Name(StringInit::get(N)), Locs(locs.begin(), locs.end()), TrackedRecords(records), TheInit(nullptr), IsAnonymous(Anonymous), ResolveFirst(false) { init(); } explicit Record(Init *N, ArrayRef locs, RecordKeeper &records, bool Anonymous = false) : ID(LastID++), Name(N), Locs(locs.begin(), locs.end()), TrackedRecords(records), TheInit(nullptr), IsAnonymous(Anonymous), ResolveFirst(false) { init(); } // When copy-constructing a Record, we must still guarantee a globally unique // ID number. All other fields can be copied normally. Record(const Record &O) : ID(LastID++), Name(O.Name), Locs(O.Locs), TemplateArgs(O.TemplateArgs), Values(O.Values), SuperClasses(O.SuperClasses), SuperClassRanges(O.SuperClassRanges), TrackedRecords(O.TrackedRecords), TheInit(O.TheInit), IsAnonymous(O.IsAnonymous), ResolveFirst(O.ResolveFirst) { } static unsigned getNewUID() { return LastID++; } unsigned getID() const { return ID; } const std::string &getName() const; Init *getNameInit() const { return Name; } const std::string getNameInitAsString() const { return getNameInit()->getAsUnquotedString(); } void setName(Init *Name); // Also updates RecordKeeper. void setName(const std::string &Name); // Also updates RecordKeeper. ArrayRef getLoc() const { return Locs; } /// get the corresponding DefInit. DefInit *getDefInit(); const std::vector &getTemplateArgs() const { return TemplateArgs; } const std::vector &getValues() const { return Values; } const std::vector &getSuperClasses() const { return SuperClasses; } ArrayRef getSuperClassRanges() const { return SuperClassRanges; } bool isTemplateArg(Init *Name) const { for (unsigned i = 0, e = TemplateArgs.size(); i != e; ++i) if (TemplateArgs[i] == Name) return true; return false; } bool isTemplateArg(StringRef Name) const { return isTemplateArg(StringInit::get(Name)); } const RecordVal *getValue(const Init *Name) const { for (unsigned i = 0, e = Values.size(); i != e; ++i) if (Values[i].getNameInit() == Name) return &Values[i]; return nullptr; } const RecordVal *getValue(StringRef Name) const { return getValue(StringInit::get(Name)); } RecordVal *getValue(const Init *Name) { for (unsigned i = 0, e = Values.size(); i != e; ++i) if (Values[i].getNameInit() == Name) return &Values[i]; return nullptr; } RecordVal *getValue(StringRef Name) { return getValue(StringInit::get(Name)); } void addTemplateArg(Init *Name) { assert(!isTemplateArg(Name) && "Template arg already defined!"); TemplateArgs.push_back(Name); } void addTemplateArg(StringRef Name) { addTemplateArg(StringInit::get(Name)); } void addValue(const RecordVal &RV) { assert(getValue(RV.getNameInit()) == nullptr && "Value already added!"); Values.push_back(RV); if (Values.size() > 1) // Keep NAME at the end of the list. It makes record dumps a // bit prettier and allows TableGen tests to be written more // naturally. Tests can use CHECK-NEXT to look for Record // fields they expect to see after a def. They can't do that if // NAME is the first Record field. std::swap(Values[Values.size() - 2], Values[Values.size() - 1]); } void removeValue(Init *Name) { for (unsigned i = 0, e = Values.size(); i != e; ++i) if (Values[i].getNameInit() == Name) { Values.erase(Values.begin()+i); return; } llvm_unreachable("Cannot remove an entry that does not exist!"); } void removeValue(StringRef Name) { removeValue(StringInit::get(Name)); } bool isSubClassOf(const Record *R) const { for (unsigned i = 0, e = SuperClasses.size(); i != e; ++i) if (SuperClasses[i] == R) return true; return false; } bool isSubClassOf(StringRef Name) const { for (unsigned i = 0, e = SuperClasses.size(); i != e; ++i) if (SuperClasses[i]->getNameInitAsString() == Name) return true; return false; } void addSuperClass(Record *R, SMRange Range) { assert(!isSubClassOf(R) && "Already subclassing record!"); SuperClasses.push_back(R); SuperClassRanges.push_back(Range); } /// resolveReferences - If there are any field references that refer to fields /// that have been filled in, we can propagate the values now. /// void resolveReferences() { resolveReferencesTo(nullptr); } /// resolveReferencesTo - If anything in this record refers to RV, replace the /// reference to RV with the RHS of RV. If RV is null, we resolve all /// possible references. void resolveReferencesTo(const RecordVal *RV); RecordKeeper &getRecords() const { return TrackedRecords; } bool isAnonymous() const { return IsAnonymous; } bool isResolveFirst() const { return ResolveFirst; } void setResolveFirst(bool b) { ResolveFirst = b; } void dump() const; //===--------------------------------------------------------------------===// // High-level methods useful to tablegen back-ends // /// getValueInit - Return the initializer for a value with the specified name, /// or throw an exception if the field does not exist. /// Init *getValueInit(StringRef FieldName) const; /// Return true if the named field is unset. bool isValueUnset(StringRef FieldName) const { return getValueInit(FieldName) == UnsetInit::get(); } /// getValueAsString - This method looks up the specified field and returns /// its value as a string, throwing an exception if the field does not exist /// or if the value is not a string. /// std::string getValueAsString(StringRef FieldName) const; /// getValueAsBitsInit - This method looks up the specified field and returns /// its value as a BitsInit, throwing an exception if the field does not exist /// or if the value is not the right type. /// BitsInit *getValueAsBitsInit(StringRef FieldName) const; /// getValueAsListInit - This method looks up the specified field and returns /// its value as a ListInit, throwing an exception if the field does not exist /// or if the value is not the right type. /// ListInit *getValueAsListInit(StringRef FieldName) const; /// getValueAsListOfDefs - This method looks up the specified field and /// returns its value as a vector of records, throwing an exception if the /// field does not exist or if the value is not the right type. /// std::vector getValueAsListOfDefs(StringRef FieldName) const; /// getValueAsListOfInts - This method looks up the specified field and /// returns its value as a vector of integers, throwing an exception if the /// field does not exist or if the value is not the right type. /// std::vector getValueAsListOfInts(StringRef FieldName) const; /// getValueAsListOfStrings - This method looks up the specified field and /// returns its value as a vector of strings, throwing an exception if the /// field does not exist or if the value is not the right type. /// std::vector getValueAsListOfStrings(StringRef FieldName) const; /// getValueAsDef - This method looks up the specified field and returns its /// value as a Record, throwing an exception if the field does not exist or if /// the value is not the right type. /// Record *getValueAsDef(StringRef FieldName) const; /// getValueAsBit - This method looks up the specified field and returns its /// value as a bit, throwing an exception if the field does not exist or if /// the value is not the right type. /// bool getValueAsBit(StringRef FieldName) const; /// getValueAsBitOrUnset - This method looks up the specified field and /// returns its value as a bit. If the field is unset, sets Unset to true and /// returns false. /// bool getValueAsBitOrUnset(StringRef FieldName, bool &Unset) const; /// getValueAsInt - This method looks up the specified field and returns its /// value as an int64_t, throwing an exception if the field does not exist or /// if the value is not the right type. /// int64_t getValueAsInt(StringRef FieldName) const; /// getValueAsDag - This method looks up the specified field and returns its /// value as an Dag, throwing an exception if the field does not exist or if /// the value is not the right type. /// DagInit *getValueAsDag(StringRef FieldName) const; }; raw_ostream &operator<<(raw_ostream &OS, const Record &R); struct MultiClass { Record Rec; // Placeholder for template args and Name. typedef std::vector> RecordVector; RecordVector DefPrototypes; void dump() const; MultiClass(const std::string &Name, SMLoc Loc, RecordKeeper &Records) : Rec(Name, Loc, Records) {} }; class RecordKeeper { typedef std::map> RecordMap; RecordMap Classes, Defs; public: const RecordMap &getClasses() const { return Classes; } const RecordMap &getDefs() const { return Defs; } Record *getClass(const std::string &Name) const { auto I = Classes.find(Name); return I == Classes.end() ? nullptr : I->second.get(); } Record *getDef(const std::string &Name) const { auto I = Defs.find(Name); return I == Defs.end() ? nullptr : I->second.get(); } void addClass(std::unique_ptr R) { bool Ins = Classes.insert(std::make_pair(R->getName(), std::move(R))).second; (void)Ins; assert(Ins && "Class already exists"); } void addDef(std::unique_ptr R) { bool Ins = Defs.insert(std::make_pair(R->getName(), std::move(R))).second; (void)Ins; assert(Ins && "Record already exists"); } //===--------------------------------------------------------------------===// // High-level helper methods, useful for tablegen backends... /// getAllDerivedDefinitions - This method returns all concrete definitions /// that derive from the specified class name. If a class with the specified /// name does not exist, an exception is thrown. std::vector getAllDerivedDefinitions(const std::string &ClassName) const; void dump() const; }; /// LessRecord - Sorting predicate to sort record pointers by name. /// struct LessRecord { bool operator()(const Record *Rec1, const Record *Rec2) const { return StringRef(Rec1->getName()).compare_numeric(Rec2->getName()) < 0; } }; /// LessRecordByID - Sorting predicate to sort record pointers by their /// unique ID. If you just need a deterministic order, use this, since it /// just compares two `unsigned`; the other sorting predicates require /// string manipulation. struct LessRecordByID { bool operator()(const Record *LHS, const Record *RHS) const { return LHS->getID() < RHS->getID(); } }; /// LessRecordFieldName - Sorting predicate to sort record pointers by their /// name field. /// struct LessRecordFieldName { bool operator()(const Record *Rec1, const Record *Rec2) const { return Rec1->getValueAsString("Name") < Rec2->getValueAsString("Name"); } }; struct LessRecordRegister { static size_t min(size_t a, size_t b) { return a < b ? a : b; } static bool ascii_isdigit(char x) { return x >= '0' && x <= '9'; } struct RecordParts { SmallVector, 4> Parts; RecordParts(StringRef Rec) { if (Rec.empty()) return; size_t Len = 0; const char *Start = Rec.data(); const char *Curr = Start; bool isDigitPart = ascii_isdigit(Curr[0]); for (size_t I = 0, E = Rec.size(); I != E; ++I, ++Len) { bool isDigit = ascii_isdigit(Curr[I]); if (isDigit != isDigitPart) { Parts.push_back(std::make_pair(isDigitPart, StringRef(Start, Len))); Len = 0; Start = &Curr[I]; isDigitPart = ascii_isdigit(Curr[I]); } } // Push the last part. Parts.push_back(std::make_pair(isDigitPart, StringRef(Start, Len))); } size_t size() { return Parts.size(); } std::pair getPart(size_t i) { assert (i < Parts.size() && "Invalid idx!"); return Parts[i]; } }; bool operator()(const Record *Rec1, const Record *Rec2) const { RecordParts LHSParts(StringRef(Rec1->getName())); RecordParts RHSParts(StringRef(Rec2->getName())); size_t LHSNumParts = LHSParts.size(); size_t RHSNumParts = RHSParts.size(); assert (LHSNumParts && RHSNumParts && "Expected at least one part!"); if (LHSNumParts != RHSNumParts) return LHSNumParts < RHSNumParts; // We expect the registers to be of the form [_a-zA-z]+([0-9]*[_a-zA-Z]*)*. for (size_t I = 0, E = LHSNumParts; I < E; I+=2) { std::pair LHSPart = LHSParts.getPart(I); std::pair RHSPart = RHSParts.getPart(I); // Expect even part to always be alpha. assert (LHSPart.first == false && RHSPart.first == false && "Expected both parts to be alpha."); if (int Res = LHSPart.second.compare(RHSPart.second)) return Res < 0; } for (size_t I = 1, E = LHSNumParts; I < E; I+=2) { std::pair LHSPart = LHSParts.getPart(I); std::pair RHSPart = RHSParts.getPart(I); // Expect odd part to always be numeric. assert (LHSPart.first == true && RHSPart.first == true && "Expected both parts to be numeric."); if (LHSPart.second.size() != RHSPart.second.size()) return LHSPart.second.size() < RHSPart.second.size(); unsigned LHSVal, RHSVal; bool LHSFailed = LHSPart.second.getAsInteger(10, LHSVal); (void)LHSFailed; assert(!LHSFailed && "Unable to convert LHS to integer."); bool RHSFailed = RHSPart.second.getAsInteger(10, RHSVal); (void)RHSFailed; assert(!RHSFailed && "Unable to convert RHS to integer."); if (LHSVal != RHSVal) return LHSVal < RHSVal; } return LHSNumParts < RHSNumParts; } }; raw_ostream &operator<<(raw_ostream &OS, const RecordKeeper &RK); /// QualifyName - Return an Init with a qualifier prefix referring /// to CurRec's name. Init *QualifyName(Record &CurRec, MultiClass *CurMultiClass, Init *Name, const std::string &Scoper); /// QualifyName - Return an Init with a qualifier prefix referring /// to CurRec's name. Init *QualifyName(Record &CurRec, MultiClass *CurMultiClass, const std::string &Name, const std::string &Scoper); } // End llvm namespace #endif