//===- llvm/InstrTypes.h - Important Instruction subclasses -----*- 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 defines various meta classes of instructions that exist in the VM // representation. Specific concrete subclasses of these may be found in the // i*.h files... // //===----------------------------------------------------------------------===// #ifndef LLVM_IR_INSTRTYPES_H #define LLVM_IR_INSTRTYPES_H #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/Sequence.h" #include "llvm/ADT/StringMap.h" #include "llvm/ADT/Twine.h" #include "llvm/ADT/iterator_range.h" #include "llvm/IR/Attributes.h" #include "llvm/IR/CallingConv.h" #include "llvm/IR/DerivedTypes.h" #include "llvm/IR/Function.h" #include "llvm/IR/Instruction.h" #include "llvm/IR/LLVMContext.h" #include "llvm/IR/OperandTraits.h" #include "llvm/IR/User.h" #include #include #include #include #include #include #include #include namespace llvm { class StringRef; class Type; class Value; namespace Intrinsic { typedef unsigned ID; } //===----------------------------------------------------------------------===// // UnaryInstruction Class //===----------------------------------------------------------------------===// class UnaryInstruction : public Instruction { protected: UnaryInstruction(Type *Ty, unsigned iType, Value *V, Instruction *IB = nullptr) : Instruction(Ty, iType, &Op<0>(), 1, IB) { Op<0>() = V; } UnaryInstruction(Type *Ty, unsigned iType, Value *V, BasicBlock *IAE) : Instruction(Ty, iType, &Op<0>(), 1, IAE) { Op<0>() = V; } public: // allocate space for exactly one operand void *operator new(size_t S) { return User::operator new(S, 1); } void operator delete(void *Ptr) { User::operator delete(Ptr); } /// Transparently provide more efficient getOperand methods. DECLARE_TRANSPARENT_OPERAND_ACCESSORS(Value); // Methods for support type inquiry through isa, cast, and dyn_cast: static bool classof(const Instruction *I) { return I->isUnaryOp() || I->getOpcode() == Instruction::Alloca || I->getOpcode() == Instruction::Load || I->getOpcode() == Instruction::VAArg || I->getOpcode() == Instruction::ExtractValue || (I->getOpcode() >= CastOpsBegin && I->getOpcode() < CastOpsEnd); } static bool classof(const Value *V) { return isa(V) && classof(cast(V)); } }; template <> struct OperandTraits : public FixedNumOperandTraits { }; DEFINE_TRANSPARENT_OPERAND_ACCESSORS(UnaryInstruction, Value) //===----------------------------------------------------------------------===// // UnaryOperator Class //===----------------------------------------------------------------------===// class UnaryOperator : public UnaryInstruction { void AssertOK(); protected: UnaryOperator(UnaryOps iType, Value *S, Type *Ty, const Twine &Name, Instruction *InsertBefore); UnaryOperator(UnaryOps iType, Value *S, Type *Ty, const Twine &Name, BasicBlock *InsertAtEnd); // Note: Instruction needs to be a friend here to call cloneImpl. friend class Instruction; UnaryOperator *cloneImpl() const; public: /// Construct a unary instruction, given the opcode and an operand. /// Optionally (if InstBefore is specified) insert the instruction /// into a BasicBlock right before the specified instruction. The specified /// Instruction is allowed to be a dereferenced end iterator. /// static UnaryOperator *Create(UnaryOps Op, Value *S, const Twine &Name = Twine(), Instruction *InsertBefore = nullptr); /// Construct a unary instruction, given the opcode and an operand. /// Also automatically insert this instruction to the end of the /// BasicBlock specified. /// static UnaryOperator *Create(UnaryOps Op, Value *S, const Twine &Name, BasicBlock *InsertAtEnd); /// These methods just forward to Create, and are useful when you /// statically know what type of instruction you're going to create. These /// helpers just save some typing. #define HANDLE_UNARY_INST(N, OPC, CLASS) \ static UnaryOperator *Create##OPC(Value *V, const Twine &Name = "") {\ return Create(Instruction::OPC, V, Name);\ } #include "llvm/IR/Instruction.def" #define HANDLE_UNARY_INST(N, OPC, CLASS) \ static UnaryOperator *Create##OPC(Value *V, const Twine &Name, \ BasicBlock *BB) {\ return Create(Instruction::OPC, V, Name, BB);\ } #include "llvm/IR/Instruction.def" #define HANDLE_UNARY_INST(N, OPC, CLASS) \ static UnaryOperator *Create##OPC(Value *V, const Twine &Name, \ Instruction *I) {\ return Create(Instruction::OPC, V, Name, I);\ } #include "llvm/IR/Instruction.def" static UnaryOperator * CreateWithCopiedFlags(UnaryOps Opc, Value *V, Instruction *CopyO, const Twine &Name = "", Instruction *InsertBefore = nullptr) { UnaryOperator *UO = Create(Opc, V, Name, InsertBefore); UO->copyIRFlags(CopyO); return UO; } static UnaryOperator *CreateFNegFMF(Value *Op, Instruction *FMFSource, const Twine &Name = "", Instruction *InsertBefore = nullptr) { return CreateWithCopiedFlags(Instruction::FNeg, Op, FMFSource, Name, InsertBefore); } UnaryOps getOpcode() const { return static_cast(Instruction::getOpcode()); } // Methods for support type inquiry through isa, cast, and dyn_cast: static bool classof(const Instruction *I) { return I->isUnaryOp(); } static bool classof(const Value *V) { return isa(V) && classof(cast(V)); } }; //===----------------------------------------------------------------------===// // BinaryOperator Class //===----------------------------------------------------------------------===// class BinaryOperator : public Instruction { void AssertOK(); protected: BinaryOperator(BinaryOps iType, Value *S1, Value *S2, Type *Ty, const Twine &Name, Instruction *InsertBefore); BinaryOperator(BinaryOps iType, Value *S1, Value *S2, Type *Ty, const Twine &Name, BasicBlock *InsertAtEnd); // Note: Instruction needs to be a friend here to call cloneImpl. friend class Instruction; BinaryOperator *cloneImpl() const; public: // allocate space for exactly two operands void *operator new(size_t S) { return User::operator new(S, 2); } void operator delete(void *Ptr) { User::operator delete(Ptr); } /// Transparently provide more efficient getOperand methods. DECLARE_TRANSPARENT_OPERAND_ACCESSORS(Value); /// Construct a binary instruction, given the opcode and the two /// operands. Optionally (if InstBefore is specified) insert the instruction /// into a BasicBlock right before the specified instruction. The specified /// Instruction is allowed to be a dereferenced end iterator. /// static BinaryOperator *Create(BinaryOps Op, Value *S1, Value *S2, const Twine &Name = Twine(), Instruction *InsertBefore = nullptr); /// Construct a binary instruction, given the opcode and the two /// operands. Also automatically insert this instruction to the end of the /// BasicBlock specified. /// static BinaryOperator *Create(BinaryOps Op, Value *S1, Value *S2, const Twine &Name, BasicBlock *InsertAtEnd); /// These methods just forward to Create, and are useful when you /// statically know what type of instruction you're going to create. These /// helpers just save some typing. #define HANDLE_BINARY_INST(N, OPC, CLASS) \ static BinaryOperator *Create##OPC(Value *V1, Value *V2, \ const Twine &Name = "") {\ return Create(Instruction::OPC, V1, V2, Name);\ } #include "llvm/IR/Instruction.def" #define HANDLE_BINARY_INST(N, OPC, CLASS) \ static BinaryOperator *Create##OPC(Value *V1, Value *V2, \ const Twine &Name, BasicBlock *BB) {\ return Create(Instruction::OPC, V1, V2, Name, BB);\ } #include "llvm/IR/Instruction.def" #define HANDLE_BINARY_INST(N, OPC, CLASS) \ static BinaryOperator *Create##OPC(Value *V1, Value *V2, \ const Twine &Name, Instruction *I) {\ return Create(Instruction::OPC, V1, V2, Name, I);\ } #include "llvm/IR/Instruction.def" static BinaryOperator * CreateWithCopiedFlags(BinaryOps Opc, Value *V1, Value *V2, Instruction *CopyO, const Twine &Name = "", Instruction *InsertBefore = nullptr) { BinaryOperator *BO = Create(Opc, V1, V2, Name, InsertBefore); BO->copyIRFlags(CopyO); return BO; } static BinaryOperator *CreateFAddFMF(Value *V1, Value *V2, Instruction *FMFSource, const Twine &Name = "") { return CreateWithCopiedFlags(Instruction::FAdd, V1, V2, FMFSource, Name); } static BinaryOperator *CreateFSubFMF(Value *V1, Value *V2, Instruction *FMFSource, const Twine &Name = "") { return CreateWithCopiedFlags(Instruction::FSub, V1, V2, FMFSource, Name); } static BinaryOperator *CreateFMulFMF(Value *V1, Value *V2, Instruction *FMFSource, const Twine &Name = "") { return CreateWithCopiedFlags(Instruction::FMul, V1, V2, FMFSource, Name); } static BinaryOperator *CreateFDivFMF(Value *V1, Value *V2, Instruction *FMFSource, const Twine &Name = "") { return CreateWithCopiedFlags(Instruction::FDiv, V1, V2, FMFSource, Name); } static BinaryOperator *CreateFRemFMF(Value *V1, Value *V2, Instruction *FMFSource, const Twine &Name = "") { return CreateWithCopiedFlags(Instruction::FRem, V1, V2, FMFSource, Name); } static BinaryOperator *CreateNSW(BinaryOps Opc, Value *V1, Value *V2, const Twine &Name = "") { BinaryOperator *BO = Create(Opc, V1, V2, Name); BO->setHasNoSignedWrap(true); return BO; } static BinaryOperator *CreateNSW(BinaryOps Opc, Value *V1, Value *V2, const Twine &Name, BasicBlock *BB) { BinaryOperator *BO = Create(Opc, V1, V2, Name, BB); BO->setHasNoSignedWrap(true); return BO; } static BinaryOperator *CreateNSW(BinaryOps Opc, Value *V1, Value *V2, const Twine &Name, Instruction *I) { BinaryOperator *BO = Create(Opc, V1, V2, Name, I); BO->setHasNoSignedWrap(true); return BO; } static BinaryOperator *CreateNUW(BinaryOps Opc, Value *V1, Value *V2, const Twine &Name = "") { BinaryOperator *BO = Create(Opc, V1, V2, Name); BO->setHasNoUnsignedWrap(true); return BO; } static BinaryOperator *CreateNUW(BinaryOps Opc, Value *V1, Value *V2, const Twine &Name, BasicBlock *BB) { BinaryOperator *BO = Create(Opc, V1, V2, Name, BB); BO->setHasNoUnsignedWrap(true); return BO; } static BinaryOperator *CreateNUW(BinaryOps Opc, Value *V1, Value *V2, const Twine &Name, Instruction *I) { BinaryOperator *BO = Create(Opc, V1, V2, Name, I); BO->setHasNoUnsignedWrap(true); return BO; } static BinaryOperator *CreateExact(BinaryOps Opc, Value *V1, Value *V2, const Twine &Name = "") { BinaryOperator *BO = Create(Opc, V1, V2, Name); BO->setIsExact(true); return BO; } static BinaryOperator *CreateExact(BinaryOps Opc, Value *V1, Value *V2, const Twine &Name, BasicBlock *BB) { BinaryOperator *BO = Create(Opc, V1, V2, Name, BB); BO->setIsExact(true); return BO; } static BinaryOperator *CreateExact(BinaryOps Opc, Value *V1, Value *V2, const Twine &Name, Instruction *I) { BinaryOperator *BO = Create(Opc, V1, V2, Name, I); BO->setIsExact(true); return BO; } #define DEFINE_HELPERS(OPC, NUWNSWEXACT) \ static BinaryOperator *Create##NUWNSWEXACT##OPC(Value *V1, Value *V2, \ const Twine &Name = "") { \ return Create##NUWNSWEXACT(Instruction::OPC, V1, V2, Name); \ } \ static BinaryOperator *Create##NUWNSWEXACT##OPC( \ Value *V1, Value *V2, const Twine &Name, BasicBlock *BB) { \ return Create##NUWNSWEXACT(Instruction::OPC, V1, V2, Name, BB); \ } \ static BinaryOperator *Create##NUWNSWEXACT##OPC( \ Value *V1, Value *V2, const Twine &Name, Instruction *I) { \ return Create##NUWNSWEXACT(Instruction::OPC, V1, V2, Name, I); \ } DEFINE_HELPERS(Add, NSW) // CreateNSWAdd DEFINE_HELPERS(Add, NUW) // CreateNUWAdd DEFINE_HELPERS(Sub, NSW) // CreateNSWSub DEFINE_HELPERS(Sub, NUW) // CreateNUWSub DEFINE_HELPERS(Mul, NSW) // CreateNSWMul DEFINE_HELPERS(Mul, NUW) // CreateNUWMul DEFINE_HELPERS(Shl, NSW) // CreateNSWShl DEFINE_HELPERS(Shl, NUW) // CreateNUWShl DEFINE_HELPERS(SDiv, Exact) // CreateExactSDiv DEFINE_HELPERS(UDiv, Exact) // CreateExactUDiv DEFINE_HELPERS(AShr, Exact) // CreateExactAShr DEFINE_HELPERS(LShr, Exact) // CreateExactLShr #undef DEFINE_HELPERS /// Helper functions to construct and inspect unary operations (NEG and NOT) /// via binary operators SUB and XOR: /// /// Create the NEG and NOT instructions out of SUB and XOR instructions. /// static BinaryOperator *CreateNeg(Value *Op, const Twine &Name = "", Instruction *InsertBefore = nullptr); static BinaryOperator *CreateNeg(Value *Op, const Twine &Name, BasicBlock *InsertAtEnd); static BinaryOperator *CreateNSWNeg(Value *Op, const Twine &Name = "", Instruction *InsertBefore = nullptr); static BinaryOperator *CreateNSWNeg(Value *Op, const Twine &Name, BasicBlock *InsertAtEnd); static BinaryOperator *CreateNUWNeg(Value *Op, const Twine &Name = "", Instruction *InsertBefore = nullptr); static BinaryOperator *CreateNUWNeg(Value *Op, const Twine &Name, BasicBlock *InsertAtEnd); static BinaryOperator *CreateNot(Value *Op, const Twine &Name = "", Instruction *InsertBefore = nullptr); static BinaryOperator *CreateNot(Value *Op, const Twine &Name, BasicBlock *InsertAtEnd); BinaryOps getOpcode() const { return static_cast(Instruction::getOpcode()); } /// Exchange the two operands to this instruction. /// This instruction is safe to use on any binary instruction and /// does not modify the semantics of the instruction. If the instruction /// cannot be reversed (ie, it's a Div), then return true. /// bool swapOperands(); // Methods for support type inquiry through isa, cast, and dyn_cast: static bool classof(const Instruction *I) { return I->isBinaryOp(); } static bool classof(const Value *V) { return isa(V) && classof(cast(V)); } }; template <> struct OperandTraits : public FixedNumOperandTraits { }; DEFINE_TRANSPARENT_OPERAND_ACCESSORS(BinaryOperator, Value) //===----------------------------------------------------------------------===// // CastInst Class //===----------------------------------------------------------------------===// /// This is the base class for all instructions that perform data /// casts. It is simply provided so that instruction category testing /// can be performed with code like: /// /// if (isa(Instr)) { ... } /// Base class of casting instructions. class CastInst : public UnaryInstruction { protected: /// Constructor with insert-before-instruction semantics for subclasses CastInst(Type *Ty, unsigned iType, Value *S, const Twine &NameStr = "", Instruction *InsertBefore = nullptr) : UnaryInstruction(Ty, iType, S, InsertBefore) { setName(NameStr); } /// Constructor with insert-at-end-of-block semantics for subclasses CastInst(Type *Ty, unsigned iType, Value *S, const Twine &NameStr, BasicBlock *InsertAtEnd) : UnaryInstruction(Ty, iType, S, InsertAtEnd) { setName(NameStr); } public: /// Provides a way to construct any of the CastInst subclasses using an /// opcode instead of the subclass's constructor. The opcode must be in the /// CastOps category (Instruction::isCast(opcode) returns true). This /// constructor has insert-before-instruction semantics to automatically /// insert the new CastInst before InsertBefore (if it is non-null). /// Construct any of the CastInst subclasses static CastInst *Create( Instruction::CastOps, ///< The opcode of the cast instruction Value *S, ///< The value to be casted (operand 0) Type *Ty, ///< The type to which cast should be made const Twine &Name = "", ///< Name for the instruction Instruction *InsertBefore = nullptr ///< Place to insert the instruction ); /// Provides a way to construct any of the CastInst subclasses using an /// opcode instead of the subclass's constructor. The opcode must be in the /// CastOps category. This constructor has insert-at-end-of-block semantics /// to automatically insert the new CastInst at the end of InsertAtEnd (if /// its non-null). /// Construct any of the CastInst subclasses static CastInst *Create( Instruction::CastOps, ///< The opcode for the cast instruction Value *S, ///< The value to be casted (operand 0) Type *Ty, ///< The type to which operand is casted const Twine &Name, ///< The name for the instruction BasicBlock *InsertAtEnd ///< The block to insert the instruction into ); /// Create a ZExt or BitCast cast instruction static CastInst *CreateZExtOrBitCast( Value *S, ///< The value to be casted (operand 0) Type *Ty, ///< The type to which cast should be made const Twine &Name = "", ///< Name for the instruction Instruction *InsertBefore = nullptr ///< Place to insert the instruction ); /// Create a ZExt or BitCast cast instruction static CastInst *CreateZExtOrBitCast( Value *S, ///< The value to be casted (operand 0) Type *Ty, ///< The type to which operand is casted const Twine &Name, ///< The name for the instruction BasicBlock *InsertAtEnd ///< The block to insert the instruction into ); /// Create a SExt or BitCast cast instruction static CastInst *CreateSExtOrBitCast( Value *S, ///< The value to be casted (operand 0) Type *Ty, ///< The type to which cast should be made const Twine &Name = "", ///< Name for the instruction Instruction *InsertBefore = nullptr ///< Place to insert the instruction ); /// Create a SExt or BitCast cast instruction static CastInst *CreateSExtOrBitCast( Value *S, ///< The value to be casted (operand 0) Type *Ty, ///< The type to which operand is casted const Twine &Name, ///< The name for the instruction BasicBlock *InsertAtEnd ///< The block to insert the instruction into ); /// Create a BitCast AddrSpaceCast, or a PtrToInt cast instruction. static CastInst *CreatePointerCast( Value *S, ///< The pointer value to be casted (operand 0) Type *Ty, ///< The type to which operand is casted const Twine &Name, ///< The name for the instruction BasicBlock *InsertAtEnd ///< The block to insert the instruction into ); /// Create a BitCast, AddrSpaceCast or a PtrToInt cast instruction. static CastInst *CreatePointerCast( Value *S, ///< The pointer value to be casted (operand 0) Type *Ty, ///< The type to which cast should be made const Twine &Name = "", ///< Name for the instruction Instruction *InsertBefore = nullptr ///< Place to insert the instruction ); /// Create a BitCast or an AddrSpaceCast cast instruction. static CastInst *CreatePointerBitCastOrAddrSpaceCast( Value *S, ///< The pointer value to be casted (operand 0) Type *Ty, ///< The type to which operand is casted const Twine &Name, ///< The name for the instruction BasicBlock *InsertAtEnd ///< The block to insert the instruction into ); /// Create a BitCast or an AddrSpaceCast cast instruction. static CastInst *CreatePointerBitCastOrAddrSpaceCast( Value *S, ///< The pointer value to be casted (operand 0) Type *Ty, ///< The type to which cast should be made const Twine &Name = "", ///< Name for the instruction Instruction *InsertBefore = nullptr ///< Place to insert the instruction ); /// Create a BitCast, a PtrToInt, or an IntToPTr cast instruction. /// /// If the value is a pointer type and the destination an integer type, /// creates a PtrToInt cast. If the value is an integer type and the /// destination a pointer type, creates an IntToPtr cast. Otherwise, creates /// a bitcast. static CastInst *CreateBitOrPointerCast( Value *S, ///< The pointer value to be casted (operand 0) Type *Ty, ///< The type to which cast should be made const Twine &Name = "", ///< Name for the instruction Instruction *InsertBefore = nullptr ///< Place to insert the instruction ); /// Create a ZExt, BitCast, or Trunc for int -> int casts. static CastInst *CreateIntegerCast( Value *S, ///< The pointer value to be casted (operand 0) Type *Ty, ///< The type to which cast should be made bool isSigned, ///< Whether to regard S as signed or not const Twine &Name = "", ///< Name for the instruction Instruction *InsertBefore = nullptr ///< Place to insert the instruction ); /// Create a ZExt, BitCast, or Trunc for int -> int casts. static CastInst *CreateIntegerCast( Value *S, ///< The integer value to be casted (operand 0) Type *Ty, ///< The integer type to which operand is casted bool isSigned, ///< Whether to regard S as signed or not const Twine &Name, ///< The name for the instruction BasicBlock *InsertAtEnd ///< The block to insert the instruction into ); /// Create an FPExt, BitCast, or FPTrunc for fp -> fp casts static CastInst *CreateFPCast( Value *S, ///< The floating point value to be casted Type *Ty, ///< The floating point type to cast to const Twine &Name = "", ///< Name for the instruction Instruction *InsertBefore = nullptr ///< Place to insert the instruction ); /// Create an FPExt, BitCast, or FPTrunc for fp -> fp casts static CastInst *CreateFPCast( Value *S, ///< The floating point value to be casted Type *Ty, ///< The floating point type to cast to const Twine &Name, ///< The name for the instruction BasicBlock *InsertAtEnd ///< The block to insert the instruction into ); /// Create a Trunc or BitCast cast instruction static CastInst *CreateTruncOrBitCast( Value *S, ///< The value to be casted (operand 0) Type *Ty, ///< The type to which cast should be made const Twine &Name = "", ///< Name for the instruction Instruction *InsertBefore = nullptr ///< Place to insert the instruction ); /// Create a Trunc or BitCast cast instruction static CastInst *CreateTruncOrBitCast( Value *S, ///< The value to be casted (operand 0) Type *Ty, ///< The type to which operand is casted const Twine &Name, ///< The name for the instruction BasicBlock *InsertAtEnd ///< The block to insert the instruction into ); /// Check whether a bitcast between these types is valid static bool isBitCastable( Type *SrcTy, ///< The Type from which the value should be cast. Type *DestTy ///< The Type to which the value should be cast. ); /// Check whether a bitcast, inttoptr, or ptrtoint cast between these /// types is valid and a no-op. /// /// This ensures that any pointer<->integer cast has enough bits in the /// integer and any other cast is a bitcast. static bool isBitOrNoopPointerCastable( Type *SrcTy, ///< The Type from which the value should be cast. Type *DestTy, ///< The Type to which the value should be cast. const DataLayout &DL); /// Returns the opcode necessary to cast Val into Ty using usual casting /// rules. /// Infer the opcode for cast operand and type static Instruction::CastOps getCastOpcode( const Value *Val, ///< The value to cast bool SrcIsSigned, ///< Whether to treat the source as signed Type *Ty, ///< The Type to which the value should be casted bool DstIsSigned ///< Whether to treate the dest. as signed ); /// There are several places where we need to know if a cast instruction /// only deals with integer source and destination types. To simplify that /// logic, this method is provided. /// @returns true iff the cast has only integral typed operand and dest type. /// Determine if this is an integer-only cast. bool isIntegerCast() const; /// A lossless cast is one that does not alter the basic value. It implies /// a no-op cast but is more stringent, preventing things like int->float, /// long->double, or int->ptr. /// @returns true iff the cast is lossless. /// Determine if this is a lossless cast. bool isLosslessCast() const; /// A no-op cast is one that can be effected without changing any bits. /// It implies that the source and destination types are the same size. The /// DataLayout argument is to determine the pointer size when examining casts /// involving Integer and Pointer types. They are no-op casts if the integer /// is the same size as the pointer. However, pointer size varies with /// platform. Note that a precondition of this method is that the cast is /// legal - i.e. the instruction formed with these operands would verify. static bool isNoopCast( Instruction::CastOps Opcode, ///< Opcode of cast Type *SrcTy, ///< SrcTy of cast Type *DstTy, ///< DstTy of cast const DataLayout &DL ///< DataLayout to get the Int Ptr type from. ); /// Determine if this cast is a no-op cast. /// /// \param DL is the DataLayout to determine pointer size. bool isNoopCast(const DataLayout &DL) const; /// Determine how a pair of casts can be eliminated, if they can be at all. /// This is a helper function for both CastInst and ConstantExpr. /// @returns 0 if the CastInst pair can't be eliminated, otherwise /// returns Instruction::CastOps value for a cast that can replace /// the pair, casting SrcTy to DstTy. /// Determine if a cast pair is eliminable static unsigned isEliminableCastPair( Instruction::CastOps firstOpcode, ///< Opcode of first cast Instruction::CastOps secondOpcode, ///< Opcode of second cast Type *SrcTy, ///< SrcTy of 1st cast Type *MidTy, ///< DstTy of 1st cast & SrcTy of 2nd cast Type *DstTy, ///< DstTy of 2nd cast Type *SrcIntPtrTy, ///< Integer type corresponding to Ptr SrcTy, or null Type *MidIntPtrTy, ///< Integer type corresponding to Ptr MidTy, or null Type *DstIntPtrTy ///< Integer type corresponding to Ptr DstTy, or null ); /// Return the opcode of this CastInst Instruction::CastOps getOpcode() const { return Instruction::CastOps(Instruction::getOpcode()); } /// Return the source type, as a convenience Type* getSrcTy() const { return getOperand(0)->getType(); } /// Return the destination type, as a convenience Type* getDestTy() const { return getType(); } /// This method can be used to determine if a cast from SrcTy to DstTy using /// Opcode op is valid or not. /// @returns true iff the proposed cast is valid. /// Determine if a cast is valid without creating one. static bool castIsValid(Instruction::CastOps op, Type *SrcTy, Type *DstTy); static bool castIsValid(Instruction::CastOps op, Value *S, Type *DstTy) { return castIsValid(op, S->getType(), DstTy); } /// Methods for support type inquiry through isa, cast, and dyn_cast: static bool classof(const Instruction *I) { return I->isCast(); } static bool classof(const Value *V) { return isa(V) && classof(cast(V)); } }; //===----------------------------------------------------------------------===// // CmpInst Class //===----------------------------------------------------------------------===// /// This class is the base class for the comparison instructions. /// Abstract base class of comparison instructions. class CmpInst : public Instruction { public: /// This enumeration lists the possible predicates for CmpInst subclasses. /// Values in the range 0-31 are reserved for FCmpInst, while values in the /// range 32-64 are reserved for ICmpInst. This is necessary to ensure the /// predicate values are not overlapping between the classes. /// /// Some passes (e.g. InstCombine) depend on the bit-wise characteristics of /// FCMP_* values. Changing the bit patterns requires a potential change to /// those passes. enum Predicate : unsigned { // Opcode U L G E Intuitive operation FCMP_FALSE = 0, ///< 0 0 0 0 Always false (always folded) FCMP_OEQ = 1, ///< 0 0 0 1 True if ordered and equal FCMP_OGT = 2, ///< 0 0 1 0 True if ordered and greater than FCMP_OGE = 3, ///< 0 0 1 1 True if ordered and greater than or equal FCMP_OLT = 4, ///< 0 1 0 0 True if ordered and less than FCMP_OLE = 5, ///< 0 1 0 1 True if ordered and less than or equal FCMP_ONE = 6, ///< 0 1 1 0 True if ordered and operands are unequal FCMP_ORD = 7, ///< 0 1 1 1 True if ordered (no nans) FCMP_UNO = 8, ///< 1 0 0 0 True if unordered: isnan(X) | isnan(Y) FCMP_UEQ = 9, ///< 1 0 0 1 True if unordered or equal FCMP_UGT = 10, ///< 1 0 1 0 True if unordered or greater than FCMP_UGE = 11, ///< 1 0 1 1 True if unordered, greater than, or equal FCMP_ULT = 12, ///< 1 1 0 0 True if unordered or less than FCMP_ULE = 13, ///< 1 1 0 1 True if unordered, less than, or equal FCMP_UNE = 14, ///< 1 1 1 0 True if unordered or not equal FCMP_TRUE = 15, ///< 1 1 1 1 Always true (always folded) FIRST_FCMP_PREDICATE = FCMP_FALSE, LAST_FCMP_PREDICATE = FCMP_TRUE, BAD_FCMP_PREDICATE = FCMP_TRUE + 1, ICMP_EQ = 32, ///< equal ICMP_NE = 33, ///< not equal ICMP_UGT = 34, ///< unsigned greater than ICMP_UGE = 35, ///< unsigned greater or equal ICMP_ULT = 36, ///< unsigned less than ICMP_ULE = 37, ///< unsigned less or equal ICMP_SGT = 38, ///< signed greater than ICMP_SGE = 39, ///< signed greater or equal ICMP_SLT = 40, ///< signed less than ICMP_SLE = 41, ///< signed less or equal FIRST_ICMP_PREDICATE = ICMP_EQ, LAST_ICMP_PREDICATE = ICMP_SLE, BAD_ICMP_PREDICATE = ICMP_SLE + 1 }; using PredicateField = Bitfield::Element; /// Returns the sequence of all FCmp predicates. static auto FCmpPredicates() { return enum_seq_inclusive(Predicate::FIRST_FCMP_PREDICATE, Predicate::LAST_FCMP_PREDICATE, force_iteration_on_noniterable_enum); } /// Returns the sequence of all ICmp predicates. static auto ICmpPredicates() { return enum_seq_inclusive(Predicate::FIRST_ICMP_PREDICATE, Predicate::LAST_ICMP_PREDICATE, force_iteration_on_noniterable_enum); } protected: CmpInst(Type *ty, Instruction::OtherOps op, Predicate pred, Value *LHS, Value *RHS, const Twine &Name = "", Instruction *InsertBefore = nullptr, Instruction *FlagsSource = nullptr); CmpInst(Type *ty, Instruction::OtherOps op, Predicate pred, Value *LHS, Value *RHS, const Twine &Name, BasicBlock *InsertAtEnd); public: // allocate space for exactly two operands void *operator new(size_t S) { return User::operator new(S, 2); } void operator delete(void *Ptr) { User::operator delete(Ptr); } /// Construct a compare instruction, given the opcode, the predicate and /// the two operands. Optionally (if InstBefore is specified) insert the /// instruction into a BasicBlock right before the specified instruction. /// The specified Instruction is allowed to be a dereferenced end iterator. /// Create a CmpInst static CmpInst *Create(OtherOps Op, Predicate predicate, Value *S1, Value *S2, const Twine &Name = "", Instruction *InsertBefore = nullptr); /// Construct a compare instruction, given the opcode, the predicate and the /// two operands. Also automatically insert this instruction to the end of /// the BasicBlock specified. /// Create a CmpInst static CmpInst *Create(OtherOps Op, Predicate predicate, Value *S1, Value *S2, const Twine &Name, BasicBlock *InsertAtEnd); /// Get the opcode casted to the right type OtherOps getOpcode() const { return static_cast(Instruction::getOpcode()); } /// Return the predicate for this instruction. Predicate getPredicate() const { return getSubclassData(); } /// Set the predicate for this instruction to the specified value. void setPredicate(Predicate P) { setSubclassData(P); } static bool isFPPredicate(Predicate P) { static_assert(FIRST_FCMP_PREDICATE == 0, "FIRST_FCMP_PREDICATE is required to be 0"); return P <= LAST_FCMP_PREDICATE; } static bool isIntPredicate(Predicate P) { return P >= FIRST_ICMP_PREDICATE && P <= LAST_ICMP_PREDICATE; } static StringRef getPredicateName(Predicate P); bool isFPPredicate() const { return isFPPredicate(getPredicate()); } bool isIntPredicate() const { return isIntPredicate(getPredicate()); } /// For example, EQ -> NE, UGT -> ULE, SLT -> SGE, /// OEQ -> UNE, UGT -> OLE, OLT -> UGE, etc. /// @returns the inverse predicate for the instruction's current predicate. /// Return the inverse of the instruction's predicate. Predicate getInversePredicate() const { return getInversePredicate(getPredicate()); } /// Returns the ordered variant of a floating point compare. /// /// For example, UEQ -> OEQ, ULT -> OLT, OEQ -> OEQ static Predicate getOrderedPredicate(Predicate Pred) { return static_cast(Pred & FCMP_ORD); } Predicate getOrderedPredicate() const { return getOrderedPredicate(getPredicate()); } /// For example, EQ -> NE, UGT -> ULE, SLT -> SGE, /// OEQ -> UNE, UGT -> OLE, OLT -> UGE, etc. /// @returns the inverse predicate for predicate provided in \p pred. /// Return the inverse of a given predicate static Predicate getInversePredicate(Predicate pred); /// For example, EQ->EQ, SLE->SGE, ULT->UGT, /// OEQ->OEQ, ULE->UGE, OLT->OGT, etc. /// @returns the predicate that would be the result of exchanging the two /// operands of the CmpInst instruction without changing the result /// produced. /// Return the predicate as if the operands were swapped Predicate getSwappedPredicate() const { return getSwappedPredicate(getPredicate()); } /// This is a static version that you can use without an instruction /// available. /// Return the predicate as if the operands were swapped. static Predicate getSwappedPredicate(Predicate pred); /// This is a static version that you can use without an instruction /// available. /// @returns true if the comparison predicate is strict, false otherwise. static bool isStrictPredicate(Predicate predicate); /// @returns true if the comparison predicate is strict, false otherwise. /// Determine if this instruction is using an strict comparison predicate. bool isStrictPredicate() const { return isStrictPredicate(getPredicate()); } /// This is a static version that you can use without an instruction /// available. /// @returns true if the comparison predicate is non-strict, false otherwise. static bool isNonStrictPredicate(Predicate predicate); /// @returns true if the comparison predicate is non-strict, false otherwise. /// Determine if this instruction is using an non-strict comparison predicate. bool isNonStrictPredicate() const { return isNonStrictPredicate(getPredicate()); } /// For example, SGE -> SGT, SLE -> SLT, ULE -> ULT, UGE -> UGT. /// Returns the strict version of non-strict comparisons. Predicate getStrictPredicate() const { return getStrictPredicate(getPredicate()); } /// This is a static version that you can use without an instruction /// available. /// @returns the strict version of comparison provided in \p pred. /// If \p pred is not a strict comparison predicate, returns \p pred. /// Returns the strict version of non-strict comparisons. static Predicate getStrictPredicate(Predicate pred); /// For example, SGT -> SGE, SLT -> SLE, ULT -> ULE, UGT -> UGE. /// Returns the non-strict version of strict comparisons. Predicate getNonStrictPredicate() const { return getNonStrictPredicate(getPredicate()); } /// This is a static version that you can use without an instruction /// available. /// @returns the non-strict version of comparison provided in \p pred. /// If \p pred is not a strict comparison predicate, returns \p pred. /// Returns the non-strict version of strict comparisons. static Predicate getNonStrictPredicate(Predicate pred); /// This is a static version that you can use without an instruction /// available. /// Return the flipped strictness of predicate static Predicate getFlippedStrictnessPredicate(Predicate pred); /// For predicate of kind "is X or equal to 0" returns the predicate "is X". /// For predicate of kind "is X" returns the predicate "is X or equal to 0". /// does not support other kind of predicates. /// @returns the predicate that does not contains is equal to zero if /// it had and vice versa. /// Return the flipped strictness of predicate Predicate getFlippedStrictnessPredicate() const { return getFlippedStrictnessPredicate(getPredicate()); } /// Provide more efficient getOperand methods. DECLARE_TRANSPARENT_OPERAND_ACCESSORS(Value); /// This is just a convenience that dispatches to the subclasses. /// Swap the operands and adjust predicate accordingly to retain /// the same comparison. void swapOperands(); /// This is just a convenience that dispatches to the subclasses. /// Determine if this CmpInst is commutative. bool isCommutative() const; /// Determine if this is an equals/not equals predicate. /// This is a static version that you can use without an instruction /// available. static bool isEquality(Predicate pred); /// Determine if this is an equals/not equals predicate. bool isEquality() const { return isEquality(getPredicate()); } /// Return true if the predicate is relational (not EQ or NE). static bool isRelational(Predicate P) { return !isEquality(P); } /// Return true if the predicate is relational (not EQ or NE). bool isRelational() const { return !isEquality(); } /// @returns true if the comparison is signed, false otherwise. /// Determine if this instruction is using a signed comparison. bool isSigned() const { return isSigned(getPredicate()); } /// @returns true if the comparison is unsigned, false otherwise. /// Determine if this instruction is using an unsigned comparison. bool isUnsigned() const { return isUnsigned(getPredicate()); } /// For example, ULT->SLT, ULE->SLE, UGT->SGT, UGE->SGE, SLT->Failed assert /// @returns the signed version of the unsigned predicate pred. /// return the signed version of a predicate static Predicate getSignedPredicate(Predicate pred); /// For example, ULT->SLT, ULE->SLE, UGT->SGT, UGE->SGE, SLT->Failed assert /// @returns the signed version of the predicate for this instruction (which /// has to be an unsigned predicate). /// return the signed version of a predicate Predicate getSignedPredicate() { return getSignedPredicate(getPredicate()); } /// For example, SLT->ULT, SLE->ULE, SGT->UGT, SGE->UGE, ULT->Failed assert /// @returns the unsigned version of the signed predicate pred. static Predicate getUnsignedPredicate(Predicate pred); /// For example, SLT->ULT, SLE->ULE, SGT->UGT, SGE->UGE, ULT->Failed assert /// @returns the unsigned version of the predicate for this instruction (which /// has to be an signed predicate). /// return the unsigned version of a predicate Predicate getUnsignedPredicate() { return getUnsignedPredicate(getPredicate()); } /// For example, SLT->ULT, ULT->SLT, SLE->ULE, ULE->SLE, EQ->Failed assert /// @returns the unsigned version of the signed predicate pred or /// the signed version of the signed predicate pred. static Predicate getFlippedSignednessPredicate(Predicate pred); /// For example, SLT->ULT, ULT->SLT, SLE->ULE, ULE->SLE, EQ->Failed assert /// @returns the unsigned version of the signed predicate pred or /// the signed version of the signed predicate pred. Predicate getFlippedSignednessPredicate() { return getFlippedSignednessPredicate(getPredicate()); } /// This is just a convenience. /// Determine if this is true when both operands are the same. bool isTrueWhenEqual() const { return isTrueWhenEqual(getPredicate()); } /// This is just a convenience. /// Determine if this is false when both operands are the same. bool isFalseWhenEqual() const { return isFalseWhenEqual(getPredicate()); } /// @returns true if the predicate is unsigned, false otherwise. /// Determine if the predicate is an unsigned operation. static bool isUnsigned(Predicate predicate); /// @returns true if the predicate is signed, false otherwise. /// Determine if the predicate is an signed operation. static bool isSigned(Predicate predicate); /// Determine if the predicate is an ordered operation. static bool isOrdered(Predicate predicate); /// Determine if the predicate is an unordered operation. static bool isUnordered(Predicate predicate); /// Determine if the predicate is true when comparing a value with itself. static bool isTrueWhenEqual(Predicate predicate); /// Determine if the predicate is false when comparing a value with itself. static bool isFalseWhenEqual(Predicate predicate); /// Determine if Pred1 implies Pred2 is true when two compares have matching /// operands. static bool isImpliedTrueByMatchingCmp(Predicate Pred1, Predicate Pred2); /// Determine if Pred1 implies Pred2 is false when two compares have matching /// operands. static bool isImpliedFalseByMatchingCmp(Predicate Pred1, Predicate Pred2); /// Methods for support type inquiry through isa, cast, and dyn_cast: static bool classof(const Instruction *I) { return I->getOpcode() == Instruction::ICmp || I->getOpcode() == Instruction::FCmp; } static bool classof(const Value *V) { return isa(V) && classof(cast(V)); } /// Create a result type for fcmp/icmp static Type* makeCmpResultType(Type* opnd_type) { if (VectorType* vt = dyn_cast(opnd_type)) { return VectorType::get(Type::getInt1Ty(opnd_type->getContext()), vt->getElementCount()); } return Type::getInt1Ty(opnd_type->getContext()); } private: // Shadow Value::setValueSubclassData with a private forwarding method so that // subclasses cannot accidentally use it. void setValueSubclassData(unsigned short D) { Value::setValueSubclassData(D); } }; // FIXME: these are redundant if CmpInst < BinaryOperator template <> struct OperandTraits : public FixedNumOperandTraits { }; DEFINE_TRANSPARENT_OPERAND_ACCESSORS(CmpInst, Value) /// A lightweight accessor for an operand bundle meant to be passed /// around by value. struct OperandBundleUse { ArrayRef Inputs; OperandBundleUse() = default; explicit OperandBundleUse(StringMapEntry *Tag, ArrayRef Inputs) : Inputs(Inputs), Tag(Tag) {} /// Return true if the operand at index \p Idx in this operand bundle /// has the attribute A. bool operandHasAttr(unsigned Idx, Attribute::AttrKind A) const { if (isDeoptOperandBundle()) if (A == Attribute::ReadOnly || A == Attribute::NoCapture) return Inputs[Idx]->getType()->isPointerTy(); // Conservative answer: no operands have any attributes. return false; } /// Return the tag of this operand bundle as a string. StringRef getTagName() const { return Tag->getKey(); } /// Return the tag of this operand bundle as an integer. /// /// Operand bundle tags are interned by LLVMContextImpl::getOrInsertBundleTag, /// and this function returns the unique integer getOrInsertBundleTag /// associated the tag of this operand bundle to. uint32_t getTagID() const { return Tag->getValue(); } /// Return true if this is a "deopt" operand bundle. bool isDeoptOperandBundle() const { return getTagID() == LLVMContext::OB_deopt; } /// Return true if this is a "funclet" operand bundle. bool isFuncletOperandBundle() const { return getTagID() == LLVMContext::OB_funclet; } /// Return true if this is a "cfguardtarget" operand bundle. bool isCFGuardTargetOperandBundle() const { return getTagID() == LLVMContext::OB_cfguardtarget; } private: /// Pointer to an entry in LLVMContextImpl::getOrInsertBundleTag. StringMapEntry *Tag; }; /// A container for an operand bundle being viewed as a set of values /// rather than a set of uses. /// /// Unlike OperandBundleUse, OperandBundleDefT owns the memory it carries, and /// so it is possible to create and pass around "self-contained" instances of /// OperandBundleDef and ConstOperandBundleDef. template class OperandBundleDefT { std::string Tag; std::vector Inputs; public: explicit OperandBundleDefT(std::string Tag, std::vector Inputs) : Tag(std::move(Tag)), Inputs(std::move(Inputs)) {} explicit OperandBundleDefT(std::string Tag, ArrayRef Inputs) : Tag(std::move(Tag)), Inputs(Inputs) {} explicit OperandBundleDefT(const OperandBundleUse &OBU) { Tag = std::string(OBU.getTagName()); llvm::append_range(Inputs, OBU.Inputs); } ArrayRef inputs() const { return Inputs; } using input_iterator = typename std::vector::const_iterator; size_t input_size() const { return Inputs.size(); } input_iterator input_begin() const { return Inputs.begin(); } input_iterator input_end() const { return Inputs.end(); } StringRef getTag() const { return Tag; } }; using OperandBundleDef = OperandBundleDefT; using ConstOperandBundleDef = OperandBundleDefT; //===----------------------------------------------------------------------===// // CallBase Class //===----------------------------------------------------------------------===// /// Base class for all callable instructions (InvokeInst and CallInst) /// Holds everything related to calling a function. /// /// All call-like instructions are required to use a common operand layout: /// - Zero or more arguments to the call, /// - Zero or more operand bundles with zero or more operand inputs each /// bundle, /// - Zero or more subclass controlled operands /// - The called function. /// /// This allows this base class to easily access the called function and the /// start of the arguments without knowing how many other operands a particular /// subclass requires. Note that accessing the end of the argument list isn't /// as cheap as most other operations on the base class. class CallBase : public Instruction { protected: // The first two bits are reserved by CallInst for fast retrieval, using CallInstReservedField = Bitfield::Element; using CallingConvField = Bitfield::Element; static_assert( Bitfield::areContiguous(), "Bitfields must be contiguous"); /// The last operand is the called operand. static constexpr int CalledOperandOpEndIdx = -1; AttributeList Attrs; ///< parameter attributes for callable FunctionType *FTy; template CallBase(AttributeList const &A, FunctionType *FT, ArgsTy &&... Args) : Instruction(std::forward(Args)...), Attrs(A), FTy(FT) {} using Instruction::Instruction; bool hasDescriptor() const { return Value::HasDescriptor; } unsigned getNumSubclassExtraOperands() const { switch (getOpcode()) { case Instruction::Call: return 0; case Instruction::Invoke: return 2; case Instruction::CallBr: return getNumSubclassExtraOperandsDynamic(); } llvm_unreachable("Invalid opcode!"); } /// Get the number of extra operands for instructions that don't have a fixed /// number of extra operands. unsigned getNumSubclassExtraOperandsDynamic() const; public: using Instruction::getContext; /// Create a clone of \p CB with a different set of operand bundles and /// insert it before \p InsertPt. /// /// The returned call instruction is identical \p CB in every way except that /// the operand bundles for the new instruction are set to the operand bundles /// in \p Bundles. static CallBase *Create(CallBase *CB, ArrayRef Bundles, Instruction *InsertPt = nullptr); /// Create a clone of \p CB with the operand bundle with the tag matching /// \p Bundle's tag replaced with Bundle, and insert it before \p InsertPt. /// /// The returned call instruction is identical \p CI in every way except that /// the specified operand bundle has been replaced. static CallBase *Create(CallBase *CB, OperandBundleDef Bundle, Instruction *InsertPt = nullptr); /// Create a clone of \p CB with operand bundle \p OB added. static CallBase *addOperandBundle(CallBase *CB, uint32_t ID, OperandBundleDef OB, Instruction *InsertPt = nullptr); /// Create a clone of \p CB with operand bundle \p ID removed. static CallBase *removeOperandBundle(CallBase *CB, uint32_t ID, Instruction *InsertPt = nullptr); static bool classof(const Instruction *I) { return I->getOpcode() == Instruction::Call || I->getOpcode() == Instruction::Invoke || I->getOpcode() == Instruction::CallBr; } static bool classof(const Value *V) { return isa(V) && classof(cast(V)); } FunctionType *getFunctionType() const { return FTy; } void mutateFunctionType(FunctionType *FTy) { Value::mutateType(FTy->getReturnType()); this->FTy = FTy; } DECLARE_TRANSPARENT_OPERAND_ACCESSORS(Value); /// data_operands_begin/data_operands_end - Return iterators iterating over /// the call / invoke argument list and bundle operands. For invokes, this is /// the set of instruction operands except the invoke target and the two /// successor blocks; and for calls this is the set of instruction operands /// except the call target. User::op_iterator data_operands_begin() { return op_begin(); } User::const_op_iterator data_operands_begin() const { return const_cast(this)->data_operands_begin(); } User::op_iterator data_operands_end() { // Walk from the end of the operands over the called operand and any // subclass operands. return op_end() - getNumSubclassExtraOperands() - 1; } User::const_op_iterator data_operands_end() const { return const_cast(this)->data_operands_end(); } iterator_range data_ops() { return make_range(data_operands_begin(), data_operands_end()); } iterator_range data_ops() const { return make_range(data_operands_begin(), data_operands_end()); } bool data_operands_empty() const { return data_operands_end() == data_operands_begin(); } unsigned data_operands_size() const { return std::distance(data_operands_begin(), data_operands_end()); } bool isDataOperand(const Use *U) const { assert(this == U->getUser() && "Only valid to query with a use of this instruction!"); return data_operands_begin() <= U && U < data_operands_end(); } bool isDataOperand(Value::const_user_iterator UI) const { return isDataOperand(&UI.getUse()); } /// Given a value use iterator, return the data operand corresponding to it. /// Iterator must actually correspond to a data operand. unsigned getDataOperandNo(Value::const_user_iterator UI) const { return getDataOperandNo(&UI.getUse()); } /// Given a use for a data operand, get the data operand number that /// corresponds to it. unsigned getDataOperandNo(const Use *U) const { assert(isDataOperand(U) && "Data operand # out of range!"); return U - data_operands_begin(); } /// Return the iterator pointing to the beginning of the argument list. User::op_iterator arg_begin() { return op_begin(); } User::const_op_iterator arg_begin() const { return const_cast(this)->arg_begin(); } /// Return the iterator pointing to the end of the argument list. User::op_iterator arg_end() { // From the end of the data operands, walk backwards past the bundle // operands. return data_operands_end() - getNumTotalBundleOperands(); } User::const_op_iterator arg_end() const { return const_cast(this)->arg_end(); } /// Iteration adapter for range-for loops. iterator_range args() { return make_range(arg_begin(), arg_end()); } iterator_range args() const { return make_range(arg_begin(), arg_end()); } bool arg_empty() const { return arg_end() == arg_begin(); } unsigned arg_size() const { return arg_end() - arg_begin(); } Value *getArgOperand(unsigned i) const { assert(i < arg_size() && "Out of bounds!"); return getOperand(i); } void setArgOperand(unsigned i, Value *v) { assert(i < arg_size() && "Out of bounds!"); setOperand(i, v); } /// Wrappers for getting the \c Use of a call argument. const Use &getArgOperandUse(unsigned i) const { assert(i < arg_size() && "Out of bounds!"); return User::getOperandUse(i); } Use &getArgOperandUse(unsigned i) { assert(i < arg_size() && "Out of bounds!"); return User::getOperandUse(i); } bool isArgOperand(const Use *U) const { assert(this == U->getUser() && "Only valid to query with a use of this instruction!"); return arg_begin() <= U && U < arg_end(); } bool isArgOperand(Value::const_user_iterator UI) const { return isArgOperand(&UI.getUse()); } /// Given a use for a arg operand, get the arg operand number that /// corresponds to it. unsigned getArgOperandNo(const Use *U) const { assert(isArgOperand(U) && "Arg operand # out of range!"); return U - arg_begin(); } /// Given a value use iterator, return the arg operand number corresponding to /// it. Iterator must actually correspond to a data operand. unsigned getArgOperandNo(Value::const_user_iterator UI) const { return getArgOperandNo(&UI.getUse()); } /// Returns true if this CallSite passes the given Value* as an argument to /// the called function. bool hasArgument(const Value *V) const { return llvm::is_contained(args(), V); } Value *getCalledOperand() const { return Op(); } const Use &getCalledOperandUse() const { return Op(); } Use &getCalledOperandUse() { return Op(); } /// Returns the function called, or null if this is an indirect function /// invocation or the function signature does not match the call signature. Function *getCalledFunction() const { if (auto *F = dyn_cast_or_null(getCalledOperand())) if (F->getValueType() == getFunctionType()) return F; return nullptr; } /// Return true if the callsite is an indirect call. bool isIndirectCall() const; /// Determine whether the passed iterator points to the callee operand's Use. bool isCallee(Value::const_user_iterator UI) const { return isCallee(&UI.getUse()); } /// Determine whether this Use is the callee operand's Use. bool isCallee(const Use *U) const { return &getCalledOperandUse() == U; } /// Helper to get the caller (the parent function). Function *getCaller(); const Function *getCaller() const { return const_cast(this)->getCaller(); } /// Tests if this call site must be tail call optimized. Only a CallInst can /// be tail call optimized. bool isMustTailCall() const; /// Tests if this call site is marked as a tail call. bool isTailCall() const; /// Returns the intrinsic ID of the intrinsic called or /// Intrinsic::not_intrinsic if the called function is not an intrinsic, or if /// this is an indirect call. Intrinsic::ID getIntrinsicID() const; void setCalledOperand(Value *V) { Op() = V; } /// Sets the function called, including updating the function type. void setCalledFunction(Function *Fn) { setCalledFunction(Fn->getFunctionType(), Fn); } /// Sets the function called, including updating the function type. void setCalledFunction(FunctionCallee Fn) { setCalledFunction(Fn.getFunctionType(), Fn.getCallee()); } /// Sets the function called, including updating to the specified function /// type. void setCalledFunction(FunctionType *FTy, Value *Fn) { this->FTy = FTy; assert(cast(Fn->getType())->isOpaqueOrPointeeTypeMatches(FTy)); // This function doesn't mutate the return type, only the function // type. Seems broken, but I'm just gonna stick an assert in for now. assert(getType() == FTy->getReturnType()); setCalledOperand(Fn); } CallingConv::ID getCallingConv() const { return getSubclassData(); } void setCallingConv(CallingConv::ID CC) { setSubclassData(CC); } /// Check if this call is an inline asm statement. bool isInlineAsm() const { return isa(getCalledOperand()); } /// \name Attribute API /// /// These methods access and modify attributes on this call (including /// looking through to the attributes on the called function when necessary). ///@{ /// Return the parameter attributes for this call. /// AttributeList getAttributes() const { return Attrs; } /// Set the parameter attributes for this call. /// void setAttributes(AttributeList A) { Attrs = A; } /// Determine whether this call has the given attribute. If it does not /// then determine if the called function has the attribute, but only if /// the attribute is allowed for the call. bool hasFnAttr(Attribute::AttrKind Kind) const { assert(Kind != Attribute::NoBuiltin && "Use CallBase::isNoBuiltin() to check for Attribute::NoBuiltin"); return hasFnAttrImpl(Kind); } /// Determine whether this call has the given attribute. If it does not /// then determine if the called function has the attribute, but only if /// the attribute is allowed for the call. bool hasFnAttr(StringRef Kind) const { return hasFnAttrImpl(Kind); } // TODO: remove non-AtIndex versions of these methods. /// adds the attribute to the list of attributes. void addAttributeAtIndex(unsigned i, Attribute::AttrKind Kind) { Attrs = Attrs.addAttributeAtIndex(getContext(), i, Kind); } /// adds the attribute to the list of attributes. void addAttributeAtIndex(unsigned i, Attribute Attr) { Attrs = Attrs.addAttributeAtIndex(getContext(), i, Attr); } /// Adds the attribute to the function. void addFnAttr(Attribute::AttrKind Kind) { Attrs = Attrs.addFnAttribute(getContext(), Kind); } /// Adds the attribute to the function. void addFnAttr(Attribute Attr) { Attrs = Attrs.addFnAttribute(getContext(), Attr); } /// Adds the attribute to the return value. void addRetAttr(Attribute::AttrKind Kind) { Attrs = Attrs.addRetAttribute(getContext(), Kind); } /// Adds the attribute to the return value. void addRetAttr(Attribute Attr) { Attrs = Attrs.addRetAttribute(getContext(), Attr); } /// Adds the attribute to the indicated argument void addParamAttr(unsigned ArgNo, Attribute::AttrKind Kind) { assert(ArgNo < arg_size() && "Out of bounds"); Attrs = Attrs.addParamAttribute(getContext(), ArgNo, Kind); } /// Adds the attribute to the indicated argument void addParamAttr(unsigned ArgNo, Attribute Attr) { assert(ArgNo < arg_size() && "Out of bounds"); Attrs = Attrs.addParamAttribute(getContext(), ArgNo, Attr); } /// removes the attribute from the list of attributes. void removeAttributeAtIndex(unsigned i, Attribute::AttrKind Kind) { Attrs = Attrs.removeAttributeAtIndex(getContext(), i, Kind); } /// removes the attribute from the list of attributes. void removeAttributeAtIndex(unsigned i, StringRef Kind) { Attrs = Attrs.removeAttributeAtIndex(getContext(), i, Kind); } /// Removes the attributes from the function void removeFnAttrs(const AttributeMask &AttrsToRemove) { Attrs = Attrs.removeFnAttributes(getContext(), AttrsToRemove); } /// Removes the attribute from the function void removeFnAttr(Attribute::AttrKind Kind) { Attrs = Attrs.removeFnAttribute(getContext(), Kind); } /// Removes the attribute from the return value void removeRetAttr(Attribute::AttrKind Kind) { Attrs = Attrs.removeRetAttribute(getContext(), Kind); } /// Removes the attributes from the return value void removeRetAttrs(const AttributeMask &AttrsToRemove) { Attrs = Attrs.removeRetAttributes(getContext(), AttrsToRemove); } /// Removes the attribute from the given argument void removeParamAttr(unsigned ArgNo, Attribute::AttrKind Kind) { assert(ArgNo < arg_size() && "Out of bounds"); Attrs = Attrs.removeParamAttribute(getContext(), ArgNo, Kind); } /// Removes the attribute from the given argument void removeParamAttr(unsigned ArgNo, StringRef Kind) { assert(ArgNo < arg_size() && "Out of bounds"); Attrs = Attrs.removeParamAttribute(getContext(), ArgNo, Kind); } /// Removes the attributes from the given argument void removeParamAttrs(unsigned ArgNo, const AttributeMask &AttrsToRemove) { Attrs = Attrs.removeParamAttributes(getContext(), ArgNo, AttrsToRemove); } /// adds the dereferenceable attribute to the list of attributes. void addDereferenceableParamAttr(unsigned i, uint64_t Bytes) { Attrs = Attrs.addDereferenceableParamAttr(getContext(), i, Bytes); } /// adds the dereferenceable attribute to the list of attributes. void addDereferenceableRetAttr(uint64_t Bytes) { Attrs = Attrs.addDereferenceableRetAttr(getContext(), Bytes); } /// Determine whether the return value has the given attribute. bool hasRetAttr(Attribute::AttrKind Kind) const { return hasRetAttrImpl(Kind); } /// Determine whether the return value has the given attribute. bool hasRetAttr(StringRef Kind) const { return hasRetAttrImpl(Kind); } /// Determine whether the argument or parameter has the given attribute. bool paramHasAttr(unsigned ArgNo, Attribute::AttrKind Kind) const; /// Get the attribute of a given kind at a position. Attribute getAttributeAtIndex(unsigned i, Attribute::AttrKind Kind) const { return getAttributes().getAttributeAtIndex(i, Kind); } /// Get the attribute of a given kind at a position. Attribute getAttributeAtIndex(unsigned i, StringRef Kind) const { return getAttributes().getAttributeAtIndex(i, Kind); } /// Get the attribute of a given kind for the function. Attribute getFnAttr(StringRef Kind) const { Attribute Attr = getAttributes().getFnAttr(Kind); if (Attr.isValid()) return Attr; return getFnAttrOnCalledFunction(Kind); } /// Get the attribute of a given kind for the function. Attribute getFnAttr(Attribute::AttrKind Kind) const { Attribute A = getAttributes().getFnAttr(Kind); if (A.isValid()) return A; return getFnAttrOnCalledFunction(Kind); } /// Get the attribute of a given kind from a given arg Attribute getParamAttr(unsigned ArgNo, Attribute::AttrKind Kind) const { assert(ArgNo < arg_size() && "Out of bounds"); return getAttributes().getParamAttr(ArgNo, Kind); } /// Get the attribute of a given kind from a given arg Attribute getParamAttr(unsigned ArgNo, StringRef Kind) const { assert(ArgNo < arg_size() && "Out of bounds"); return getAttributes().getParamAttr(ArgNo, Kind); } /// Return true if the data operand at index \p i has the attribute \p /// A. /// /// Data operands include call arguments and values used in operand bundles, /// but does not include the callee operand. /// /// The index \p i is interpreted as /// /// \p i in [0, arg_size) -> argument number (\p i) /// \p i in [arg_size, data_operand_size) -> bundle operand at index /// (\p i) in the operand list. bool dataOperandHasImpliedAttr(unsigned i, Attribute::AttrKind Kind) const { // Note that we have to add one because `i` isn't zero-indexed. assert(i < arg_size() + getNumTotalBundleOperands() && "Data operand index out of bounds!"); // The attribute A can either be directly specified, if the operand in // question is a call argument; or be indirectly implied by the kind of its // containing operand bundle, if the operand is a bundle operand. if (i < arg_size()) return paramHasAttr(i, Kind); assert(hasOperandBundles() && i >= getBundleOperandsStartIndex() && "Must be either a call argument or an operand bundle!"); return bundleOperandHasAttr(i, Kind); } /// Determine whether this data operand is not captured. // FIXME: Once this API is no longer duplicated in `CallSite`, rename this to // better indicate that this may return a conservative answer. bool doesNotCapture(unsigned OpNo) const { return dataOperandHasImpliedAttr(OpNo, Attribute::NoCapture); } /// Determine whether this argument is passed by value. bool isByValArgument(unsigned ArgNo) const { return paramHasAttr(ArgNo, Attribute::ByVal); } /// Determine whether this argument is passed in an alloca. bool isInAllocaArgument(unsigned ArgNo) const { return paramHasAttr(ArgNo, Attribute::InAlloca); } /// Determine whether this argument is passed by value, in an alloca, or is /// preallocated. bool isPassPointeeByValueArgument(unsigned ArgNo) const { return paramHasAttr(ArgNo, Attribute::ByVal) || paramHasAttr(ArgNo, Attribute::InAlloca) || paramHasAttr(ArgNo, Attribute::Preallocated); } /// Determine whether passing undef to this argument is undefined behavior. /// If passing undef to this argument is UB, passing poison is UB as well /// because poison is more undefined than undef. bool isPassingUndefUB(unsigned ArgNo) const { return paramHasAttr(ArgNo, Attribute::NoUndef) || // dereferenceable implies noundef. paramHasAttr(ArgNo, Attribute::Dereferenceable) || // dereferenceable implies noundef, and null is a well-defined value. paramHasAttr(ArgNo, Attribute::DereferenceableOrNull); } /// Determine if there are is an inalloca argument. Only the last argument can /// have the inalloca attribute. bool hasInAllocaArgument() const { return !arg_empty() && paramHasAttr(arg_size() - 1, Attribute::InAlloca); } // FIXME: Once this API is no longer duplicated in `CallSite`, rename this to // better indicate that this may return a conservative answer. bool doesNotAccessMemory(unsigned OpNo) const { return dataOperandHasImpliedAttr(OpNo, Attribute::ReadNone); } // FIXME: Once this API is no longer duplicated in `CallSite`, rename this to // better indicate that this may return a conservative answer. bool onlyReadsMemory(unsigned OpNo) const { return dataOperandHasImpliedAttr(OpNo, Attribute::ReadOnly) || dataOperandHasImpliedAttr(OpNo, Attribute::ReadNone); } // FIXME: Once this API is no longer duplicated in `CallSite`, rename this to // better indicate that this may return a conservative answer. bool onlyWritesMemory(unsigned OpNo) const { return dataOperandHasImpliedAttr(OpNo, Attribute::WriteOnly) || dataOperandHasImpliedAttr(OpNo, Attribute::ReadNone); } /// Extract the alignment of the return value. MaybeAlign getRetAlign() const { if (auto Align = Attrs.getRetAlignment()) return Align; if (const Function *F = getCalledFunction()) return F->getAttributes().getRetAlignment(); return std::nullopt; } /// Extract the alignment for a call or parameter (0=unknown). MaybeAlign getParamAlign(unsigned ArgNo) const { return Attrs.getParamAlignment(ArgNo); } MaybeAlign getParamStackAlign(unsigned ArgNo) const { return Attrs.getParamStackAlignment(ArgNo); } /// Extract the byval type for a call or parameter. Type *getParamByValType(unsigned ArgNo) const { if (auto *Ty = Attrs.getParamByValType(ArgNo)) return Ty; if (const Function *F = getCalledFunction()) return F->getAttributes().getParamByValType(ArgNo); return nullptr; } /// Extract the preallocated type for a call or parameter. Type *getParamPreallocatedType(unsigned ArgNo) const { if (auto *Ty = Attrs.getParamPreallocatedType(ArgNo)) return Ty; if (const Function *F = getCalledFunction()) return F->getAttributes().getParamPreallocatedType(ArgNo); return nullptr; } /// Extract the inalloca type for a call or parameter. Type *getParamInAllocaType(unsigned ArgNo) const { if (auto *Ty = Attrs.getParamInAllocaType(ArgNo)) return Ty; if (const Function *F = getCalledFunction()) return F->getAttributes().getParamInAllocaType(ArgNo); return nullptr; } /// Extract the sret type for a call or parameter. Type *getParamStructRetType(unsigned ArgNo) const { if (auto *Ty = Attrs.getParamStructRetType(ArgNo)) return Ty; if (const Function *F = getCalledFunction()) return F->getAttributes().getParamStructRetType(ArgNo); return nullptr; } /// Extract the elementtype type for a parameter. /// Note that elementtype() can only be applied to call arguments, not /// function declaration parameters. Type *getParamElementType(unsigned ArgNo) const { return Attrs.getParamElementType(ArgNo); } /// Extract the number of dereferenceable bytes for a call or /// parameter (0=unknown). uint64_t getRetDereferenceableBytes() const { return Attrs.getRetDereferenceableBytes(); } /// Extract the number of dereferenceable bytes for a call or /// parameter (0=unknown). uint64_t getParamDereferenceableBytes(unsigned i) const { return Attrs.getParamDereferenceableBytes(i); } /// Extract the number of dereferenceable_or_null bytes for a call /// (0=unknown). uint64_t getRetDereferenceableOrNullBytes() const { return Attrs.getRetDereferenceableOrNullBytes(); } /// Extract the number of dereferenceable_or_null bytes for a /// parameter (0=unknown). uint64_t getParamDereferenceableOrNullBytes(unsigned i) const { return Attrs.getParamDereferenceableOrNullBytes(i); } /// Return true if the return value is known to be not null. /// This may be because it has the nonnull attribute, or because at least /// one byte is dereferenceable and the pointer is in addrspace(0). bool isReturnNonNull() const; /// Determine if the return value is marked with NoAlias attribute. bool returnDoesNotAlias() const { return Attrs.hasRetAttr(Attribute::NoAlias); } /// If one of the arguments has the 'returned' attribute, returns its /// operand value. Otherwise, return nullptr. Value *getReturnedArgOperand() const { return getArgOperandWithAttribute(Attribute::Returned); } /// If one of the arguments has the specified attribute, returns its /// operand value. Otherwise, return nullptr. Value *getArgOperandWithAttribute(Attribute::AttrKind Kind) const; /// Return true if the call should not be treated as a call to a /// builtin. bool isNoBuiltin() const { return hasFnAttrImpl(Attribute::NoBuiltin) && !hasFnAttrImpl(Attribute::Builtin); } /// Determine if the call requires strict floating point semantics. bool isStrictFP() const { return hasFnAttr(Attribute::StrictFP); } /// Return true if the call should not be inlined. bool isNoInline() const { return hasFnAttr(Attribute::NoInline); } void setIsNoInline() { addFnAttr(Attribute::NoInline); } MemoryEffects getMemoryEffects() const; void setMemoryEffects(MemoryEffects ME); /// Determine if the call does not access memory. bool doesNotAccessMemory() const; void setDoesNotAccessMemory(); /// Determine if the call does not access or only reads memory. bool onlyReadsMemory() const; void setOnlyReadsMemory(); /// Determine if the call does not access or only writes memory. bool onlyWritesMemory() const; void setOnlyWritesMemory(); /// Determine if the call can access memmory only using pointers based /// on its arguments. bool onlyAccessesArgMemory() const; void setOnlyAccessesArgMemory(); /// Determine if the function may only access memory that is /// inaccessible from the IR. bool onlyAccessesInaccessibleMemory() const; void setOnlyAccessesInaccessibleMemory(); /// Determine if the function may only access memory that is /// either inaccessible from the IR or pointed to by its arguments. bool onlyAccessesInaccessibleMemOrArgMem() const; void setOnlyAccessesInaccessibleMemOrArgMem(); /// Determine if the call cannot return. bool doesNotReturn() const { return hasFnAttr(Attribute::NoReturn); } void setDoesNotReturn() { addFnAttr(Attribute::NoReturn); } /// Determine if the call should not perform indirect branch tracking. bool doesNoCfCheck() const { return hasFnAttr(Attribute::NoCfCheck); } /// Determine if the call cannot unwind. bool doesNotThrow() const { return hasFnAttr(Attribute::NoUnwind); } void setDoesNotThrow() { addFnAttr(Attribute::NoUnwind); } /// Determine if the invoke cannot be duplicated. bool cannotDuplicate() const { return hasFnAttr(Attribute::NoDuplicate); } void setCannotDuplicate() { addFnAttr(Attribute::NoDuplicate); } /// Determine if the call cannot be tail merged. bool cannotMerge() const { return hasFnAttr(Attribute::NoMerge); } void setCannotMerge() { addFnAttr(Attribute::NoMerge); } /// Determine if the invoke is convergent bool isConvergent() const { return hasFnAttr(Attribute::Convergent); } void setConvergent() { addFnAttr(Attribute::Convergent); } void setNotConvergent() { removeFnAttr(Attribute::Convergent); } /// Determine if the call returns a structure through first /// pointer argument. bool hasStructRetAttr() const { if (arg_empty()) return false; // Be friendly and also check the callee. return paramHasAttr(0, Attribute::StructRet); } /// Determine if any call argument is an aggregate passed by value. bool hasByValArgument() const { return Attrs.hasAttrSomewhere(Attribute::ByVal); } ///@{ // End of attribute API. /// \name Operand Bundle API /// /// This group of methods provides the API to access and manipulate operand /// bundles on this call. /// @{ /// Return the number of operand bundles associated with this User. unsigned getNumOperandBundles() const { return std::distance(bundle_op_info_begin(), bundle_op_info_end()); } /// Return true if this User has any operand bundles. bool hasOperandBundles() const { return getNumOperandBundles() != 0; } /// Return the index of the first bundle operand in the Use array. unsigned getBundleOperandsStartIndex() const { assert(hasOperandBundles() && "Don't call otherwise!"); return bundle_op_info_begin()->Begin; } /// Return the index of the last bundle operand in the Use array. unsigned getBundleOperandsEndIndex() const { assert(hasOperandBundles() && "Don't call otherwise!"); return bundle_op_info_end()[-1].End; } /// Return true if the operand at index \p Idx is a bundle operand. bool isBundleOperand(unsigned Idx) const { return hasOperandBundles() && Idx >= getBundleOperandsStartIndex() && Idx < getBundleOperandsEndIndex(); } /// Return true if the operand at index \p Idx is a bundle operand that has /// tag ID \p ID. bool isOperandBundleOfType(uint32_t ID, unsigned Idx) const { return isBundleOperand(Idx) && getOperandBundleForOperand(Idx).getTagID() == ID; } /// Returns true if the use is a bundle operand. bool isBundleOperand(const Use *U) const { assert(this == U->getUser() && "Only valid to query with a use of this instruction!"); return hasOperandBundles() && isBundleOperand(U - op_begin()); } bool isBundleOperand(Value::const_user_iterator UI) const { return isBundleOperand(&UI.getUse()); } /// Return the total number operands (not operand bundles) used by /// every operand bundle in this OperandBundleUser. unsigned getNumTotalBundleOperands() const { if (!hasOperandBundles()) return 0; unsigned Begin = getBundleOperandsStartIndex(); unsigned End = getBundleOperandsEndIndex(); assert(Begin <= End && "Should be!"); return End - Begin; } /// Return the operand bundle at a specific index. OperandBundleUse getOperandBundleAt(unsigned Index) const { assert(Index < getNumOperandBundles() && "Index out of bounds!"); return operandBundleFromBundleOpInfo(*(bundle_op_info_begin() + Index)); } /// Return the number of operand bundles with the tag Name attached to /// this instruction. unsigned countOperandBundlesOfType(StringRef Name) const { unsigned Count = 0; for (unsigned i = 0, e = getNumOperandBundles(); i != e; ++i) if (getOperandBundleAt(i).getTagName() == Name) Count++; return Count; } /// Return the number of operand bundles with the tag ID attached to /// this instruction. unsigned countOperandBundlesOfType(uint32_t ID) const { unsigned Count = 0; for (unsigned i = 0, e = getNumOperandBundles(); i != e; ++i) if (getOperandBundleAt(i).getTagID() == ID) Count++; return Count; } /// Return an operand bundle by name, if present. /// /// It is an error to call this for operand bundle types that may have /// multiple instances of them on the same instruction. std::optional getOperandBundle(StringRef Name) const { assert(countOperandBundlesOfType(Name) < 2 && "Precondition violated!"); for (unsigned i = 0, e = getNumOperandBundles(); i != e; ++i) { OperandBundleUse U = getOperandBundleAt(i); if (U.getTagName() == Name) return U; } return std::nullopt; } /// Return an operand bundle by tag ID, if present. /// /// It is an error to call this for operand bundle types that may have /// multiple instances of them on the same instruction. std::optional getOperandBundle(uint32_t ID) const { assert(countOperandBundlesOfType(ID) < 2 && "Precondition violated!"); for (unsigned i = 0, e = getNumOperandBundles(); i != e; ++i) { OperandBundleUse U = getOperandBundleAt(i); if (U.getTagID() == ID) return U; } return std::nullopt; } /// Return the list of operand bundles attached to this instruction as /// a vector of OperandBundleDefs. /// /// This function copies the OperandBundeUse instances associated with this /// OperandBundleUser to a vector of OperandBundleDefs. Note: /// OperandBundeUses and OperandBundleDefs are non-trivially *different* /// representations of operand bundles (see documentation above). void getOperandBundlesAsDefs(SmallVectorImpl &Defs) const; /// Return the operand bundle for the operand at index OpIdx. /// /// It is an error to call this with an OpIdx that does not correspond to an /// bundle operand. OperandBundleUse getOperandBundleForOperand(unsigned OpIdx) const { return operandBundleFromBundleOpInfo(getBundleOpInfoForOperand(OpIdx)); } /// Return true if this operand bundle user has operand bundles that /// may read from the heap. bool hasReadingOperandBundles() const; /// Return true if this operand bundle user has operand bundles that /// may write to the heap. bool hasClobberingOperandBundles() const; /// Return true if the bundle operand at index \p OpIdx has the /// attribute \p A. bool bundleOperandHasAttr(unsigned OpIdx, Attribute::AttrKind A) const { auto &BOI = getBundleOpInfoForOperand(OpIdx); auto OBU = operandBundleFromBundleOpInfo(BOI); return OBU.operandHasAttr(OpIdx - BOI.Begin, A); } /// Return true if \p Other has the same sequence of operand bundle /// tags with the same number of operands on each one of them as this /// OperandBundleUser. bool hasIdenticalOperandBundleSchema(const CallBase &Other) const { if (getNumOperandBundles() != Other.getNumOperandBundles()) return false; return std::equal(bundle_op_info_begin(), bundle_op_info_end(), Other.bundle_op_info_begin()); } /// Return true if this operand bundle user contains operand bundles /// with tags other than those specified in \p IDs. bool hasOperandBundlesOtherThan(ArrayRef IDs) const { for (unsigned i = 0, e = getNumOperandBundles(); i != e; ++i) { uint32_t ID = getOperandBundleAt(i).getTagID(); if (!is_contained(IDs, ID)) return true; } return false; } /// Used to keep track of an operand bundle. See the main comment on /// OperandBundleUser above. struct BundleOpInfo { /// The operand bundle tag, interned by /// LLVMContextImpl::getOrInsertBundleTag. StringMapEntry *Tag; /// The index in the Use& vector where operands for this operand /// bundle starts. uint32_t Begin; /// The index in the Use& vector where operands for this operand /// bundle ends. uint32_t End; bool operator==(const BundleOpInfo &Other) const { return Tag == Other.Tag && Begin == Other.Begin && End == Other.End; } }; /// Simple helper function to map a BundleOpInfo to an /// OperandBundleUse. OperandBundleUse operandBundleFromBundleOpInfo(const BundleOpInfo &BOI) const { auto begin = op_begin(); ArrayRef Inputs(begin + BOI.Begin, begin + BOI.End); return OperandBundleUse(BOI.Tag, Inputs); } using bundle_op_iterator = BundleOpInfo *; using const_bundle_op_iterator = const BundleOpInfo *; /// Return the start of the list of BundleOpInfo instances associated /// with this OperandBundleUser. /// /// OperandBundleUser uses the descriptor area co-allocated with the host User /// to store some meta information about which operands are "normal" operands, /// and which ones belong to some operand bundle. /// /// The layout of an operand bundle user is /// /// +-----------uint32_t End-------------------------------------+ /// | | /// | +--------uint32_t Begin--------------------+ | /// | | | | /// ^ ^ v v /// |------|------|----|----|----|----|----|---------|----|---------|----|----- /// | BOI0 | BOI1 | .. | DU | U0 | U1 | .. | BOI0_U0 | .. | BOI1_U0 | .. | Un /// |------|------|----|----|----|----|----|---------|----|---------|----|----- /// v v ^ ^ /// | | | | /// | +--------uint32_t Begin------------+ | /// | | /// +-----------uint32_t End-----------------------------+ /// /// /// BOI0, BOI1 ... are descriptions of operand bundles in this User's use /// list. These descriptions are installed and managed by this class, and /// they're all instances of OperandBundleUser::BundleOpInfo. /// /// DU is an additional descriptor installed by User's 'operator new' to keep /// track of the 'BOI0 ... BOIN' co-allocation. OperandBundleUser does not /// access or modify DU in any way, it's an implementation detail private to /// User. /// /// The regular Use& vector for the User starts at U0. The operand bundle /// uses are part of the Use& vector, just like normal uses. In the diagram /// above, the operand bundle uses start at BOI0_U0. Each instance of /// BundleOpInfo has information about a contiguous set of uses constituting /// an operand bundle, and the total set of operand bundle uses themselves /// form a contiguous set of uses (i.e. there are no gaps between uses /// corresponding to individual operand bundles). /// /// This class does not know the location of the set of operand bundle uses /// within the use list -- that is decided by the User using this class via /// the BeginIdx argument in populateBundleOperandInfos. /// /// Currently operand bundle users with hung-off operands are not supported. bundle_op_iterator bundle_op_info_begin() { if (!hasDescriptor()) return nullptr; uint8_t *BytesBegin = getDescriptor().begin(); return reinterpret_cast(BytesBegin); } /// Return the start of the list of BundleOpInfo instances associated /// with this OperandBundleUser. const_bundle_op_iterator bundle_op_info_begin() const { auto *NonConstThis = const_cast(this); return NonConstThis->bundle_op_info_begin(); } /// Return the end of the list of BundleOpInfo instances associated /// with this OperandBundleUser. bundle_op_iterator bundle_op_info_end() { if (!hasDescriptor()) return nullptr; uint8_t *BytesEnd = getDescriptor().end(); return reinterpret_cast(BytesEnd); } /// Return the end of the list of BundleOpInfo instances associated /// with this OperandBundleUser. const_bundle_op_iterator bundle_op_info_end() const { auto *NonConstThis = const_cast(this); return NonConstThis->bundle_op_info_end(); } /// Return the range [\p bundle_op_info_begin, \p bundle_op_info_end). iterator_range bundle_op_infos() { return make_range(bundle_op_info_begin(), bundle_op_info_end()); } /// Return the range [\p bundle_op_info_begin, \p bundle_op_info_end). iterator_range bundle_op_infos() const { return make_range(bundle_op_info_begin(), bundle_op_info_end()); } /// Populate the BundleOpInfo instances and the Use& vector from \p /// Bundles. Return the op_iterator pointing to the Use& one past the last /// last bundle operand use. /// /// Each \p OperandBundleDef instance is tracked by a OperandBundleInfo /// instance allocated in this User's descriptor. op_iterator populateBundleOperandInfos(ArrayRef Bundles, const unsigned BeginIndex); public: /// Return the BundleOpInfo for the operand at index OpIdx. /// /// It is an error to call this with an OpIdx that does not correspond to an /// bundle operand. BundleOpInfo &getBundleOpInfoForOperand(unsigned OpIdx); const BundleOpInfo &getBundleOpInfoForOperand(unsigned OpIdx) const { return const_cast(this)->getBundleOpInfoForOperand(OpIdx); } protected: /// Return the total number of values used in \p Bundles. static unsigned CountBundleInputs(ArrayRef Bundles) { unsigned Total = 0; for (const auto &B : Bundles) Total += B.input_size(); return Total; } /// @} // End of operand bundle API. private: bool hasFnAttrOnCalledFunction(Attribute::AttrKind Kind) const; bool hasFnAttrOnCalledFunction(StringRef Kind) const; template bool hasFnAttrImpl(AttrKind Kind) const { if (Attrs.hasFnAttr(Kind)) return true; return hasFnAttrOnCalledFunction(Kind); } template Attribute getFnAttrOnCalledFunction(AK Kind) const; /// Determine whether the return value has the given attribute. Supports /// Attribute::AttrKind and StringRef as \p AttrKind types. template bool hasRetAttrImpl(AttrKind Kind) const { if (Attrs.hasRetAttr(Kind)) return true; // Look at the callee, if available. if (const Function *F = getCalledFunction()) return F->getAttributes().hasRetAttr(Kind); return false; } }; template <> struct OperandTraits : public VariadicOperandTraits {}; DEFINE_TRANSPARENT_OPERAND_ACCESSORS(CallBase, Value) //===----------------------------------------------------------------------===// // FuncletPadInst Class //===----------------------------------------------------------------------===// class FuncletPadInst : public Instruction { private: FuncletPadInst(const FuncletPadInst &CPI); explicit FuncletPadInst(Instruction::FuncletPadOps Op, Value *ParentPad, ArrayRef Args, unsigned Values, const Twine &NameStr, Instruction *InsertBefore); explicit FuncletPadInst(Instruction::FuncletPadOps Op, Value *ParentPad, ArrayRef Args, unsigned Values, const Twine &NameStr, BasicBlock *InsertAtEnd); void init(Value *ParentPad, ArrayRef Args, const Twine &NameStr); protected: // Note: Instruction needs to be a friend here to call cloneImpl. friend class Instruction; friend class CatchPadInst; friend class CleanupPadInst; FuncletPadInst *cloneImpl() const; public: /// Provide fast operand accessors DECLARE_TRANSPARENT_OPERAND_ACCESSORS(Value); /// arg_size - Return the number of funcletpad arguments. /// unsigned arg_size() const { return getNumOperands() - 1; } /// Convenience accessors /// Return the outer EH-pad this funclet is nested within. /// /// Note: This returns the associated CatchSwitchInst if this FuncletPadInst /// is a CatchPadInst. Value *getParentPad() const { return Op<-1>(); } void setParentPad(Value *ParentPad) { assert(ParentPad); Op<-1>() = ParentPad; } /// getArgOperand/setArgOperand - Return/set the i-th funcletpad argument. /// Value *getArgOperand(unsigned i) const { return getOperand(i); } void setArgOperand(unsigned i, Value *v) { setOperand(i, v); } /// arg_operands - iteration adapter for range-for loops. op_range arg_operands() { return op_range(op_begin(), op_end() - 1); } /// arg_operands - iteration adapter for range-for loops. const_op_range arg_operands() const { return const_op_range(op_begin(), op_end() - 1); } // Methods for support type inquiry through isa, cast, and dyn_cast: static bool classof(const Instruction *I) { return I->isFuncletPad(); } static bool classof(const Value *V) { return isa(V) && classof(cast(V)); } }; template <> struct OperandTraits : public VariadicOperandTraits {}; DEFINE_TRANSPARENT_OPERAND_ACCESSORS(FuncletPadInst, Value) } // end namespace llvm #endif // LLVM_IR_INSTRTYPES_H