//===-- SparcInstrInfo.cpp ------------------------------------------------===// // //===----------------------------------------------------------------------===// #include "SparcInternals.h" #include "SparcInstrSelectionSupport.h" #include "llvm/CodeGen/InstrSelection.h" #include "llvm/CodeGen/InstrSelectionSupport.h" #include "llvm/CodeGen/MachineFunction.h" #include "llvm/CodeGen/MachineFunctionInfo.h" #include "llvm/CodeGen/MachineCodeForInstruction.h" #include "llvm/CodeGen/MachineInstrBuilder.h" #include "llvm/Function.h" #include "llvm/Constants.h" #include "llvm/DerivedTypes.h" #include static const uint32_t MAXLO = (1 << 10) - 1; // set bits set by %lo(*) static const uint32_t MAXSIMM = (1 << 12) - 1; // set bits in simm13 field of OR //--------------------------------------------------------------------------- // Function GetConstantValueAsUnsignedInt // Function GetConstantValueAsSignedInt // // Convenience functions to get the value of an integral constant, for an // appropriate integer or non-integer type that can be held in a signed // or unsigned integer respectively. The type of the argument must be // the following: // Signed or unsigned integer // Boolean // Pointer // // isValidConstant is set to true if a valid constant was found. //--------------------------------------------------------------------------- static uint64_t GetConstantValueAsUnsignedInt(const Value *V, bool &isValidConstant) { isValidConstant = true; if (isa(V)) if (const ConstantBool *CB = dyn_cast(V)) return (int64_t)CB->getValue(); else if (const ConstantSInt *CS = dyn_cast(V)) return (uint64_t)CS->getValue(); else if (const ConstantUInt *CU = dyn_cast(V)) return CU->getValue(); isValidConstant = false; return 0; } int64_t GetConstantValueAsSignedInt(const Value *V, bool &isValidConstant) { uint64_t C = GetConstantValueAsUnsignedInt(V, isValidConstant); if (isValidConstant) { if (V->getType()->isSigned() || C < INT64_MAX) // safe to cast to signed return (int64_t) C; else isValidConstant = false; } return 0; } //---------------------------------------------------------------------------- // Function: CreateSETUWConst // // Set a 32-bit unsigned constant in the register `dest', using // SETHI, OR in the worst case. This function correctly emulates // the SETUW pseudo-op for SPARC v9 (if argument isSigned == false). // // The isSigned=true case is used to implement SETSW without duplicating code. // // Optimize some common cases: // (1) Small value that fits in simm13 field of OR: don't need SETHI. // (2) isSigned = true and C is a small negative signed value, i.e., // high bits are 1, and the remaining bits fit in simm13(OR). //---------------------------------------------------------------------------- static inline void CreateSETUWConst(const TargetMachine& target, uint32_t C, Instruction* dest, std::vector& mvec, bool isSigned = false) { MachineInstr *miSETHI = NULL, *miOR = NULL; // In order to get efficient code, we should not generate the SETHI if // all high bits are 1 (i.e., this is a small signed value that fits in // the simm13 field of OR). So we check for and handle that case specially. // NOTE: The value C = 0x80000000 is bad: sC < 0 *and* -sC < 0. // In fact, sC == -sC, so we have to check for this explicitly. int32_t sC = (int32_t) C; bool smallNegValue =isSigned && sC < 0 && sC != -sC && -sC < (int32_t)MAXSIMM; // Set the high 22 bits in dest if non-zero and simm13 field of OR not enough if (!smallNegValue && (C & ~MAXLO) && C > MAXSIMM) { miSETHI = BuildMI(V9::SETHI, 2).addZImm(C).addRegDef(dest); miSETHI->setOperandHi32(0); mvec.push_back(miSETHI); } // Set the low 10 or 12 bits in dest. This is necessary if no SETHI // was generated, or if the low 10 bits are non-zero. if (miSETHI==NULL || C & MAXLO) { if (miSETHI) { // unsigned value with high-order bits set using SETHI miOR = BuildMI(V9::OR,3).addReg(dest).addZImm(C).addRegDef(dest); miOR->setOperandLo32(1); } else { // unsigned or small signed value that fits in simm13 field of OR assert(smallNegValue || (C & ~MAXSIMM) == 0); miOR = BuildMI(V9::OR, 3).addMReg(target.getRegInfo() .getZeroRegNum()) .addSImm(sC).addRegDef(dest); } mvec.push_back(miOR); } assert((miSETHI || miOR) && "Oops, no code was generated!"); } //---------------------------------------------------------------------------- // Function: CreateSETSWConst // // Set a 32-bit signed constant in the register `dest', with sign-extension // to 64 bits. This uses SETHI, OR, SRA in the worst case. // This function correctly emulates the SETSW pseudo-op for SPARC v9. // // Optimize the same cases as SETUWConst, plus: // (1) SRA is not needed for positive or small negative values. //---------------------------------------------------------------------------- static inline void CreateSETSWConst(const TargetMachine& target, int32_t C, Instruction* dest, std::vector& mvec) { // Set the low 32 bits of dest CreateSETUWConst(target, (uint32_t) C, dest, mvec, /*isSigned*/true); // Sign-extend to the high 32 bits if needed. // NOTE: The value C = 0x80000000 is bad: -C == C and so -C is < MAXSIMM if (C < 0 && (C == -C || -C > (int32_t) MAXSIMM)) mvec.push_back(BuildMI(V9::SRA, 3).addReg(dest).addZImm(0).addRegDef(dest)); } //---------------------------------------------------------------------------- // Function: CreateSETXConst // // Set a 64-bit signed or unsigned constant in the register `dest'. // Use SETUWConst for each 32 bit word, plus a left-shift-by-32 in between. // This function correctly emulates the SETX pseudo-op for SPARC v9. // // Optimize the same cases as SETUWConst for each 32 bit word. //---------------------------------------------------------------------------- static inline void CreateSETXConst(const TargetMachine& target, uint64_t C, Instruction* tmpReg, Instruction* dest, std::vector& mvec) { assert(C > (unsigned int) ~0 && "Use SETUW/SETSW for 32-bit values!"); MachineInstr* MI; // Code to set the upper 32 bits of the value in register `tmpReg' CreateSETUWConst(target, (C >> 32), tmpReg, mvec); // Shift tmpReg left by 32 bits mvec.push_back(BuildMI(V9::SLLX, 3).addReg(tmpReg).addZImm(32) .addRegDef(tmpReg)); // Code to set the low 32 bits of the value in register `dest' CreateSETUWConst(target, C, dest, mvec); // dest = OR(tmpReg, dest) mvec.push_back(BuildMI(V9::OR,3).addReg(dest).addReg(tmpReg).addRegDef(dest)); } //---------------------------------------------------------------------------- // Function: CreateSETUWLabel // // Set a 32-bit constant (given by a symbolic label) in the register `dest'. //---------------------------------------------------------------------------- static inline void CreateSETUWLabel(const TargetMachine& target, Value* val, Instruction* dest, std::vector& mvec) { MachineInstr* MI; // Set the high 22 bits in dest MI = BuildMI(V9::SETHI, 2).addReg(val).addRegDef(dest); MI->setOperandHi32(0); mvec.push_back(MI); // Set the low 10 bits in dest MI = BuildMI(V9::OR, 3).addReg(dest).addReg(val).addRegDef(dest); MI->setOperandLo32(1); mvec.push_back(MI); } //---------------------------------------------------------------------------- // Function: CreateSETXLabel // // Set a 64-bit constant (given by a symbolic label) in the register `dest'. //---------------------------------------------------------------------------- static inline void CreateSETXLabel(const TargetMachine& target, Value* val, Instruction* tmpReg, Instruction* dest, std::vector& mvec) { assert(isa(val) || isa(val) && "I only know about constant values and global addresses"); MachineInstr* MI; MI = BuildMI(V9::SETHI, 2).addPCDisp(val).addRegDef(tmpReg); MI->setOperandHi64(0); mvec.push_back(MI); MI = BuildMI(V9::OR, 3).addReg(tmpReg).addPCDisp(val).addRegDef(tmpReg); MI->setOperandLo64(1); mvec.push_back(MI); mvec.push_back(BuildMI(V9::SLLX, 3).addReg(tmpReg).addZImm(32) .addRegDef(tmpReg)); MI = BuildMI(V9::SETHI, 2).addPCDisp(val).addRegDef(dest); MI->setOperandHi32(0); mvec.push_back(MI); MI = BuildMI(V9::OR, 3).addReg(dest).addReg(tmpReg).addRegDef(dest); mvec.push_back(MI); MI = BuildMI(V9::OR, 3).addReg(dest).addPCDisp(val).addRegDef(dest); MI->setOperandLo32(1); mvec.push_back(MI); } //---------------------------------------------------------------------------- // Function: CreateUIntSetInstruction // // Create code to Set an unsigned constant in the register `dest'. // Uses CreateSETUWConst, CreateSETSWConst or CreateSETXConst as needed. // CreateSETSWConst is an optimization for the case that the unsigned value // has all ones in the 33 high bits (so that sign-extension sets them all). //---------------------------------------------------------------------------- static inline void CreateUIntSetInstruction(const TargetMachine& target, uint64_t C, Instruction* dest, std::vector& mvec, MachineCodeForInstruction& mcfi) { static const uint64_t lo32 = (uint32_t) ~0; if (C <= lo32) // High 32 bits are 0. Set low 32 bits. CreateSETUWConst(target, (uint32_t) C, dest, mvec); else if ((C & ~lo32) == ~lo32 && (C & (1 << 31))) { // All high 33 (not 32) bits are 1s: sign-extension will take care // of high 32 bits, so use the sequence for signed int CreateSETSWConst(target, (int32_t) C, dest, mvec); } else if (C > lo32) { // C does not fit in 32 bits TmpInstruction* tmpReg = new TmpInstruction(Type::IntTy); mcfi.addTemp(tmpReg); CreateSETXConst(target, C, tmpReg, dest, mvec); } } //---------------------------------------------------------------------------- // Function: CreateIntSetInstruction // // Create code to Set a signed constant in the register `dest'. // Really the same as CreateUIntSetInstruction. //---------------------------------------------------------------------------- static inline void CreateIntSetInstruction(const TargetMachine& target, int64_t C, Instruction* dest, std::vector& mvec, MachineCodeForInstruction& mcfi) { CreateUIntSetInstruction(target, (uint64_t) C, dest, mvec, mcfi); } //--------------------------------------------------------------------------- // Create a table of LLVM opcode -> max. immediate constant likely to // be usable for that operation. //--------------------------------------------------------------------------- // Entry == 0 ==> no immediate constant field exists at all. // Entry > 0 ==> abs(immediate constant) <= Entry // std::vector MaxConstantsTable(Instruction::OtherOpsEnd); static int MaxConstantForInstr(unsigned llvmOpCode) { int modelOpCode = -1; if (llvmOpCode >= Instruction::BinaryOpsBegin && llvmOpCode < Instruction::BinaryOpsEnd) modelOpCode = V9::ADD; else switch(llvmOpCode) { case Instruction::Ret: modelOpCode = V9::JMPLCALL; break; case Instruction::Malloc: case Instruction::Alloca: case Instruction::GetElementPtr: case Instruction::PHINode: case Instruction::Cast: case Instruction::Call: modelOpCode = V9::ADD; break; case Instruction::Shl: case Instruction::Shr: modelOpCode = V9::SLLX; break; default: break; }; return (modelOpCode < 0)? 0: SparcMachineInstrDesc[modelOpCode].maxImmedConst; } static void InitializeMaxConstantsTable() { unsigned op; assert(MaxConstantsTable.size() == Instruction::OtherOpsEnd && "assignments below will be illegal!"); for (op = Instruction::TermOpsBegin; op < Instruction::TermOpsEnd; ++op) MaxConstantsTable[op] = MaxConstantForInstr(op); for (op = Instruction::BinaryOpsBegin; op < Instruction::BinaryOpsEnd; ++op) MaxConstantsTable[op] = MaxConstantForInstr(op); for (op = Instruction::MemoryOpsBegin; op < Instruction::MemoryOpsEnd; ++op) MaxConstantsTable[op] = MaxConstantForInstr(op); for (op = Instruction::OtherOpsBegin; op < Instruction::OtherOpsEnd; ++op) MaxConstantsTable[op] = MaxConstantForInstr(op); } //--------------------------------------------------------------------------- // class UltraSparcInstrInfo // // Purpose: // Information about individual instructions. // Most information is stored in the SparcMachineInstrDesc array above. // Other information is computed on demand, and most such functions // default to member functions in base class TargetInstrInfo. //--------------------------------------------------------------------------- /*ctor*/ UltraSparcInstrInfo::UltraSparcInstrInfo() : TargetInstrInfo(SparcMachineInstrDesc, /*descSize = */ V9::NUM_TOTAL_OPCODES, /*numRealOpCodes = */ V9::NUM_REAL_OPCODES) { InitializeMaxConstantsTable(); } bool UltraSparcInstrInfo::ConstantMayNotFitInImmedField(const Constant* CV, const Instruction* I) const { if (I->getOpcode() >= MaxConstantsTable.size()) // user-defined op (or bug!) return true; if (isa(CV)) // can always use %g0 return false; if (const ConstantUInt* U = dyn_cast(CV)) /* Large unsigned longs may really just be small negative signed longs */ return (labs((int64_t) U->getValue()) > MaxConstantsTable[I->getOpcode()]); if (const ConstantSInt* S = dyn_cast(CV)) return (labs(S->getValue()) > MaxConstantsTable[I->getOpcode()]); if (isa(CV)) return (1 > MaxConstantsTable[I->getOpcode()]); return true; } // // Create an instruction sequence to put the constant `val' into // the virtual register `dest'. `val' may be a Constant or a // GlobalValue, viz., the constant address of a global variable or function. // The generated instructions are returned in `mvec'. // Any temp. registers (TmpInstruction) created are recorded in mcfi. // Any stack space required is allocated via MachineFunction. // void UltraSparcInstrInfo::CreateCodeToLoadConst(const TargetMachine& target, Function* F, Value* val, Instruction* dest, std::vector& mvec, MachineCodeForInstruction& mcfi) const { assert(isa(val) || isa(val) && "I only know about constant values and global addresses"); // Use a "set" instruction for known constants or symbolic constants (labels) // that can go in an integer reg. // We have to use a "load" instruction for all other constants, // in particular, floating point constants. // const Type* valType = val->getType(); // Unfortunate special case: a ConstantPointerRef is just a // reference to GlobalValue. if (isa(val)) val = cast(val)->getValue(); if (isa(val)) { TmpInstruction* tmpReg = new TmpInstruction(PointerType::get(val->getType()), val); mcfi.addTemp(tmpReg); CreateSETXLabel(target, val, tmpReg, dest, mvec); } else if (valType->isIntegral()) { bool isValidConstant; unsigned opSize = target.getTargetData().getTypeSize(val->getType()); unsigned destSize = target.getTargetData().getTypeSize(dest->getType()); if (! dest->getType()->isSigned()) { uint64_t C = GetConstantValueAsUnsignedInt(val, isValidConstant); assert(isValidConstant && "Unrecognized constant"); if (opSize > destSize || (val->getType()->isSigned() && destSize < 8)) { // operand is larger than dest, // OR both are equal but smaller than the full register size // AND operand is signed, so it may have extra sign bits: // mask high bits C = C & ((1U << 8*destSize) - 1); } CreateUIntSetInstruction(target, C, dest, mvec, mcfi); } else { int64_t C = GetConstantValueAsSignedInt(val, isValidConstant); assert(isValidConstant && "Unrecognized constant"); if (opSize > destSize) // operand is larger than dest: mask high bits C = C & ((1U << 8*destSize) - 1); if (opSize > destSize || (opSize == destSize && !val->getType()->isSigned())) // sign-extend from destSize to 64 bits C = ((C & (1U << (8*destSize - 1))) ? C | ~((1U << 8*destSize) - 1) : C); CreateIntSetInstruction(target, C, dest, mvec, mcfi); } } else { // Make an instruction sequence to load the constant, viz: // SETX , tmpReg, addrReg // LOAD /*addr*/ addrReg, /*offset*/ 0, dest // First, create a tmp register to be used by the SETX sequence. TmpInstruction* tmpReg = new TmpInstruction(PointerType::get(val->getType()), val); mcfi.addTemp(tmpReg); // Create another TmpInstruction for the address register TmpInstruction* addrReg = new TmpInstruction(PointerType::get(val->getType()), val); mcfi.addTemp(addrReg); // Put the address (a symbolic name) into a register CreateSETXLabel(target, val, tmpReg, addrReg, mvec); // Generate the load instruction int64_t zeroOffset = 0; // to avoid ambiguity with (Value*) 0 unsigned Opcode = ChooseLoadInstruction(val->getType()); mvec.push_back(BuildMI(Opcode, 3).addReg(addrReg). addSImm(zeroOffset).addRegDef(dest)); // Make sure constant is emitted to constant pool in assembly code. MachineFunction::get(F).getInfo()->addToConstantPool(cast(val)); } } // Create an instruction sequence to copy an integer register `val' // to a floating point register `dest' by copying to memory and back. // val must be an integral type. dest must be a Float or Double. // The generated instructions are returned in `mvec'. // Any temp. registers (TmpInstruction) created are recorded in mcfi. // Any stack space required is allocated via MachineFunction. // void UltraSparcInstrInfo::CreateCodeToCopyIntToFloat(const TargetMachine& target, Function* F, Value* val, Instruction* dest, std::vector& mvec, MachineCodeForInstruction& mcfi) const { assert((val->getType()->isIntegral() || isa(val->getType())) && "Source type must be integral (integer or bool) or pointer"); assert(dest->getType()->isFloatingPoint() && "Dest type must be float/double"); // Get a stack slot to use for the copy int offset = MachineFunction::get(F).getInfo()->allocateLocalVar(val); // Get the size of the source value being copied. size_t srcSize = target.getTargetData().getTypeSize(val->getType()); // Store instruction stores `val' to [%fp+offset]. // The store and load opCodes are based on the size of the source value. // If the value is smaller than 32 bits, we must sign- or zero-extend it // to 32 bits since the load-float will load 32 bits. // Note that the store instruction is the same for signed and unsigned ints. const Type* storeType = (srcSize <= 4)? Type::IntTy : Type::LongTy; Value* storeVal = val; if (srcSize < target.getTargetData().getTypeSize(Type::FloatTy)) { // sign- or zero-extend respectively storeVal = new TmpInstruction(storeType, val); if (val->getType()->isSigned()) CreateSignExtensionInstructions(target, F, val, storeVal, 8*srcSize, mvec, mcfi); else CreateZeroExtensionInstructions(target, F, val, storeVal, 8*srcSize, mvec, mcfi); } unsigned FPReg = target.getRegInfo().getFramePointer(); mvec.push_back(BuildMI(ChooseStoreInstruction(storeType), 3) .addReg(storeVal).addMReg(FPReg).addSImm(offset)); // Load instruction loads [%fp+offset] to `dest'. // The type of the load opCode is the floating point type that matches the // stored type in size: // On SparcV9: float for int or smaller, double for long. // const Type* loadType = (srcSize <= 4)? Type::FloatTy : Type::DoubleTy; mvec.push_back(BuildMI(ChooseLoadInstruction(loadType), 3) .addMReg(FPReg).addSImm(offset).addRegDef(dest)); } // Similarly, create an instruction sequence to copy an FP register // `val' to an integer register `dest' by copying to memory and back. // The generated instructions are returned in `mvec'. // Any temp. registers (TmpInstruction) created are recorded in mcfi. // Any stack space required is allocated via MachineFunction. // void UltraSparcInstrInfo::CreateCodeToCopyFloatToInt(const TargetMachine& target, Function* F, Value* val, Instruction* dest, std::vector& mvec, MachineCodeForInstruction& mcfi) const { const Type* opTy = val->getType(); const Type* destTy = dest->getType(); assert(opTy->isFloatingPoint() && "Source type must be float/double"); assert((destTy->isIntegral() || isa(destTy)) && "Dest type must be integer, bool or pointer"); int offset = MachineFunction::get(F).getInfo()->allocateLocalVar(val); unsigned FPReg = target.getRegInfo().getFramePointer(); // Store instruction stores `val' to [%fp+offset]. // The store opCode is based only the source value being copied. // mvec.push_back(BuildMI(ChooseStoreInstruction(opTy), 3) .addReg(val).addMReg(FPReg).addSImm(offset)); // Load instruction loads [%fp+offset] to `dest'. // The type of the load opCode is the integer type that matches the // source type in size: // On SparcV9: int for float, long for double. // Note that we *must* use signed loads even for unsigned dest types, to // ensure correct sign-extension for UByte, UShort or UInt: // const Type* loadTy = (opTy == Type::FloatTy)? Type::IntTy : Type::LongTy; mvec.push_back(BuildMI(ChooseLoadInstruction(loadTy), 3).addMReg(FPReg) .addSImm(offset).addRegDef(dest)); } // Create instruction(s) to copy src to dest, for arbitrary types // The generated instructions are returned in `mvec'. // Any temp. registers (TmpInstruction) created are recorded in mcfi. // Any stack space required is allocated via MachineFunction. // void UltraSparcInstrInfo::CreateCopyInstructionsByType(const TargetMachine& target, Function *F, Value* src, Instruction* dest, std::vector& mvec, MachineCodeForInstruction& mcfi) const { bool loadConstantToReg = false; const Type* resultType = dest->getType(); MachineOpCode opCode = ChooseAddInstructionByType(resultType); if (opCode == V9::INVALID_OPCODE) { assert(0 && "Unsupported result type in CreateCopyInstructionsByType()"); return; } // if `src' is a constant that doesn't fit in the immed field or if it is // a global variable (i.e., a constant address), generate a load // instruction instead of an add // if (isa(src)) { unsigned int machineRegNum; int64_t immedValue; MachineOperand::MachineOperandType opType = ChooseRegOrImmed(src, opCode, target, /*canUseImmed*/ true, machineRegNum, immedValue); if (opType == MachineOperand::MO_VirtualRegister) loadConstantToReg = true; } else if (isa(src)) loadConstantToReg = true; if (loadConstantToReg) { // `src' is constant and cannot fit in immed field for the ADD // Insert instructions to "load" the constant into a register target.getInstrInfo().CreateCodeToLoadConst(target, F, src, dest, mvec, mcfi); } else { // Create an add-with-0 instruction of the appropriate type. // Make `src' the second operand, in case it is a constant // Use (unsigned long) 0 for a NULL pointer value. // const Type* Ty =isa(resultType) ? Type::ULongTy : resultType; MachineInstr* MI = BuildMI(opCode, 3).addReg(Constant::getNullValue(Ty)) .addReg(src).addRegDef(dest); mvec.push_back(MI); } } // Helper function for sign-extension and zero-extension. // For SPARC v9, we sign-extend the given operand using SLL; SRA/SRL. inline void CreateBitExtensionInstructions(bool signExtend, const TargetMachine& target, Function* F, Value* srcVal, Value* destVal, unsigned int numLowBits, std::vector& mvec, MachineCodeForInstruction& mcfi) { MachineInstr* M; assert(numLowBits <= 32 && "Otherwise, nothing should be done here!"); if (numLowBits < 32) { // SLL is needed since operand size is < 32 bits. TmpInstruction *tmpI = new TmpInstruction(destVal->getType(), srcVal, destVal, "make32"); mcfi.addTemp(tmpI); mvec.push_back(BuildMI(V9::SLLX, 3).addReg(srcVal) .addZImm(32-numLowBits).addRegDef(tmpI)); srcVal = tmpI; } mvec.push_back(BuildMI(signExtend? V9::SRA : V9::SRL, 3) .addReg(srcVal).addZImm(32-numLowBits).addRegDef(destVal)); } // Create instruction sequence to produce a sign-extended register value // from an arbitrary-sized integer value (sized in bits, not bytes). // The generated instructions are returned in `mvec'. // Any temp. registers (TmpInstruction) created are recorded in mcfi. // Any stack space required is allocated via MachineFunction. // void UltraSparcInstrInfo::CreateSignExtensionInstructions( const TargetMachine& target, Function* F, Value* srcVal, Value* destVal, unsigned int numLowBits, std::vector& mvec, MachineCodeForInstruction& mcfi) const { CreateBitExtensionInstructions(/*signExtend*/ true, target, F, srcVal, destVal, numLowBits, mvec, mcfi); } // Create instruction sequence to produce a zero-extended register value // from an arbitrary-sized integer value (sized in bits, not bytes). // For SPARC v9, we sign-extend the given operand using SLL; SRL. // The generated instructions are returned in `mvec'. // Any temp. registers (TmpInstruction) created are recorded in mcfi. // Any stack space required is allocated via MachineFunction. // void UltraSparcInstrInfo::CreateZeroExtensionInstructions( const TargetMachine& target, Function* F, Value* srcVal, Value* destVal, unsigned int numLowBits, std::vector& mvec, MachineCodeForInstruction& mcfi) const { CreateBitExtensionInstructions(/*signExtend*/ false, target, F, srcVal, destVal, numLowBits, mvec, mcfi); }