//===-- M68kInstrInfo.td - Main M68k Instruction Definition -*- tablegen -*-==// // // 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 // //===----------------------------------------------------------------------===// /// /// \file /// This file describes the M68k instruction set, defining the instructions /// and properties of the instructions which are needed for code generation, /// machine code emission, and analysis. /// //===----------------------------------------------------------------------===// include "M68kInstrFormats.td" //===----------------------------------------------------------------------===// // Profiles //===----------------------------------------------------------------------===// def MxSDT_CallSeqStart : SDCallSeqStart<[SDTCisVT<0, i32>, SDTCisVT<1, i32>]>; def MxSDT_CallSeqEnd : SDCallSeqEnd<[SDTCisVT<0, i32>, SDTCisVT<1, i32>]>; def MxSDT_Call : SDTypeProfile<0, -1, [SDTCisVT<0, iPTR>]>; def MxSDT_Ret : SDTypeProfile<0, -1, [ /* ADJ */ SDTCisVT<0, i32> ]>; def MxSDT_TCRet : SDTypeProfile<0, 2, [SDTCisPtrTy<0>, SDTCisVT<1, i32>]>; def MxSDT_Wrapper : SDTypeProfile<1, 1, [SDTCisSameAs<0, 1>, SDTCisPtrTy<0>]>; def MxSDT_UnArithCCROut : SDTypeProfile<2, 1, [ /* RES */ SDTCisInt<0>, /* CCR */ SDTCisVT<1, i8>, /* OPD */ SDTCisSameAs<0, 2> ]>; // RES, CCR <- op LHS, RHS def MxSDT_BiArithCCROut : SDTypeProfile<2, 2, [ /* RES */ SDTCisInt<0>, /* CCR */ SDTCisVT<1, i8>, /* LHS */ SDTCisSameAs<0, 2>, /* RHS */ SDTCisSameAs<0, 3> ]>; // RES, CCR <- op LHS, RHS, CCR def MxSDT_BiArithCCRInOut : SDTypeProfile<2, 3, [ /* RES 1 */ SDTCisInt<0>, /* CCR */ SDTCisVT<1, i8>, /* LHS */ SDTCisSameAs<0, 2>, /* RHS */ SDTCisSameAs<0, 3>, /* CCR */ SDTCisSameAs<1, 4> ]>; // RES1, RES2, CCR <- op LHS, RHS def MxSDT_2BiArithCCROut : SDTypeProfile<3, 2, [ /* RES 1 */ SDTCisInt<0>, /* RES 2 */ SDTCisSameAs<0, 1>, /* CCR */ SDTCisVT<1, i8>, /* LHS */ SDTCisSameAs<0, 2>, /* RHS */ SDTCisSameAs<0, 3> ]>; def MxSDT_CmpTest : SDTypeProfile<1, 2, [ /* CCR */ SDTCisVT<0, i8>, /* Ops */ SDTCisSameAs<1, 2> ]>; def MxSDT_Cmov : SDTypeProfile<1, 4, [ /* ARG */ SDTCisSameAs<0, 1>, /* ARG */ SDTCisSameAs<1, 2>, /* Cond */ SDTCisVT<3, i8>, /* CCR */ SDTCisVT<4, i8> ]>; def MxSDT_BrCond : SDTypeProfile<0, 3, [ /* Dest */ SDTCisVT<0, OtherVT>, /* Cond */ SDTCisVT<1, i8>, /* CCR */ SDTCisVT<2, i8> ]>; def MxSDT_SetCC : SDTypeProfile<1, 2, [ /* BOOL */ SDTCisVT<0, i8>, /* Cond */ SDTCisVT<1, i8>, /* CCR */ SDTCisVT<2, i8> ]>; def MxSDT_SetCC_C : SDTypeProfile<1, 2, [ /* BOOL */ SDTCisInt<0>, /* Cond */ SDTCisVT<1, i8>, /* CCR */ SDTCisVT<2, i8> ]>; def MxSDT_SEG_ALLOCA : SDTypeProfile<1, 1,[ /* MEM */ SDTCisVT<0, iPTR>, /* SIZE */ SDTCisVT<1, iPTR> ]>; //===----------------------------------------------------------------------===// // Nodes //===----------------------------------------------------------------------===// def MxCallSeqStart : SDNode<"ISD::CALLSEQ_START", MxSDT_CallSeqStart, [SDNPHasChain, SDNPOutGlue]>; def MxCallSeqEnd : SDNode<"ISD::CALLSEQ_END", MxSDT_CallSeqEnd, [SDNPHasChain, SDNPOptInGlue, SDNPOutGlue]>; def MxCall : SDNode<"M68kISD::CALL", MxSDT_Call, [SDNPHasChain, SDNPOutGlue, SDNPOptInGlue, SDNPVariadic]>; def MxRet : SDNode<"M68kISD::RET", MxSDT_Ret, [SDNPHasChain, SDNPOptInGlue, SDNPVariadic]>; def MxTCRet : SDNode<"M68kISD::TC_RETURN", MxSDT_TCRet, [SDNPHasChain, SDNPOptInGlue, SDNPVariadic]>; def MxWrapper : SDNode<"M68kISD::Wrapper", MxSDT_Wrapper>; def MxWrapperPC : SDNode<"M68kISD::WrapperPC", MxSDT_Wrapper>; def MxAdd : SDNode<"M68kISD::ADD", MxSDT_BiArithCCROut, [SDNPCommutative]>; def MxSub : SDNode<"M68kISD::SUB", MxSDT_BiArithCCROut>; def MxOr : SDNode<"M68kISD::OR", MxSDT_BiArithCCROut, [SDNPCommutative]>; def MxXor : SDNode<"M68kISD::XOR", MxSDT_BiArithCCROut, [SDNPCommutative]>; def MxAnd : SDNode<"M68kISD::AND", MxSDT_BiArithCCROut, [SDNPCommutative]>; def MxAddX : SDNode<"M68kISD::ADDX", MxSDT_BiArithCCRInOut>; def MxSubX : SDNode<"M68kISD::SUBX", MxSDT_BiArithCCRInOut>; def MxSMul : SDNode<"M68kISD::SMUL", MxSDT_BiArithCCROut, [SDNPCommutative]>; def MxUMul : SDNode<"M68kISD::UMUL", MxSDT_2BiArithCCROut, [SDNPCommutative]>; def MxCmp : SDNode<"M68kISD::CMP", MxSDT_CmpTest>; def MxBtst : SDNode<"M68kISD::BTST", MxSDT_CmpTest>; def MxCmov : SDNode<"M68kISD::CMOV", MxSDT_Cmov>; def MxBrCond : SDNode<"M68kISD::BRCOND", MxSDT_BrCond, [SDNPHasChain]>; def MxSetCC : SDNode<"M68kISD::SETCC", MxSDT_SetCC>; def MxSetCC_C : SDNode<"M68kISD::SETCC_CARRY", MxSDT_SetCC_C>; def MxSegAlloca : SDNode<"M68kISD::SEG_ALLOCA", MxSDT_SEG_ALLOCA, [SDNPHasChain]>; //===----------------------------------------------------------------------===// // Operands //===----------------------------------------------------------------------===// /// Size is the size of the data, either bits of a register or number of bits /// addressed in memory. Size id is a letter that identifies size. class MxSize { int Num = num; string Id = id; string Full = full; } def MxSize8 : MxSize<8, "b", "byte">; def MxSize16 : MxSize<16, "w", "word">; def MxSize32 : MxSize<32, "l", "long">; def MxSizeF32 : MxSize<32, "s", "f32">; def MxSizeF64 : MxSize<64, "d", "f64">; def MxSizeF80 : MxSize<80, "x", "f80">; class MxOpClass superClasses = []> : AsmOperandClass { let Name = name; let ParserMethod = "parseMemOp"; let SuperClasses = superClasses; } def MxRegClass : MxOpClass<"Reg">; // Splitting asm register class to avoid ambiguous on operands' // MatchClassKind. For instance, without this separation, // both ADD32dd and ADD32dr has {MCK_RegClass, MCK_RegClass} for // their operands, which makes AsmParser unable to pick the correct // one in a deterministic way. let RenderMethod = "addRegOperands", SuperClasses = [MxRegClass]in { def MxARegClass : MxOpClass<"AReg">; def MxDRegClass : MxOpClass<"DReg">; def MxFPDRegClass : MxOpClass<"FPDReg">; } class MxOperand { ValueType VT = vt; string Letter = letter; MxSize Size = size; RegisterClass RC = rc; dag Pat = pat; } class MxRegOp : RegisterOperand, MxOperand { let ParserMatchClass = MxRegClass; } // REGISTER DIRECT. The operand is in the data register specified by // the effective address register field. def MxXRD16 : MxRegOp; def MxXRD32 : MxRegOp; def MxXRD16_TC : MxRegOp; def MxXRD32_TC : MxRegOp; // DATA REGISTER DIRECT. The operand is in the data register specified by // the effective address register field. let ParserMatchClass = MxDRegClass in { def MxDRD8 : MxRegOp; def MxDRD16 : MxRegOp; def MxDRD32 : MxRegOp; def MxDRD16_TC : MxRegOp; def MxDRD32_TC : MxRegOp; } // ADDRESS REGISTER DIRECT. The operand is in the address register specified by // the effective address register field. let ParserMatchClass = MxARegClass in { def MxARD16 : MxRegOp; def MxARD32 : MxRegOp; def MxARD16_TC : MxRegOp; def MxARD32_TC : MxRegOp; } // FLOATING POINT DATA REGISTER. let ParserMatchClass = MxFPDRegClass in { def MxFPR32 : MxRegOp; def MxFPR64 : MxRegOp; def MxFPR80 : MxRegOp; } class MxMemOp : Operand, MxOperand { let PrintMethod = printMethod; let MIOperandInfo = ops; let ParserMatchClass = parserMatchClass; let OperandType = "OPERAND_MEMORY"; } // ADDRESS REGISTER INDIRECT. The address of the operand is in the address // register specified by the register field. The reference is classified as // a data reference with the exception of the jump and jump-to-subroutine // instructions. def MxARI : MxOpClass<"ARI">; def MxARI8 : MxMemOp<(ops AR32), MxSize8, "j", "printARI8Mem", MxARI>; def MxARI16 : MxMemOp<(ops AR32), MxSize16, "j", "printARI16Mem", MxARI>; def MxARI32 : MxMemOp<(ops AR32), MxSize32, "j", "printARI32Mem", MxARI>; def MxARI8_TC : MxMemOp<(ops AR32_TC), MxSize8, "j", "printARI8Mem", MxARI>; def MxARI16_TC : MxMemOp<(ops AR32_TC), MxSize16, "j", "printARI16Mem", MxARI>; def MxARI32_TC : MxMemOp<(ops AR32_TC), MxSize32, "j", "printARI32Mem", MxARI>; // ADDRESS REGISTER INDIRECT WITH POSTINCREMENT. The address of the operand is // in the address register specified by the register field. After the operand // address is used, it is incremented by one, two, or four depending upon whether // the size of the operand is byte, word, or long word. If the address register // is the stack pointer and the operand size is byte, the address is incremented // by two rather than one to keep the stack pointer on a word boundary. // The reference is classified as a data reference. def MxARIPI : MxOpClass<"ARIPI">; def MxARIPI8 : MxMemOp<(ops AR32), MxSize8, "o", "printARIPI8Mem", MxARIPI>; def MxARIPI16 : MxMemOp<(ops AR32), MxSize16, "o", "printARIPI16Mem", MxARIPI>; def MxARIPI32 : MxMemOp<(ops AR32), MxSize32, "o", "printARIPI32Mem", MxARIPI>; def MxARIPI8_TC : MxMemOp<(ops AR32_TC), MxSize8, "o", "printARIPI8Mem", MxARIPI>; def MxARIPI16_TC : MxMemOp<(ops AR32_TC), MxSize16, "o", "printARIPI16Mem", MxARIPI>; def MxARIPI32_TC : MxMemOp<(ops AR32_TC), MxSize32, "o", "printARIPI32Mem", MxARIPI>; // ADDRESS REGISTER INDIRECT WITH PREDECREMENT. The address of the operand is in // the address register specified by the register field. Before the operand // address is used, it is decremented by one, two, or four depending upon whether // the operand size is byte, word, or long word. If the address register is // the stack pointer and the operand size is byte, the address is decremented by // two rather than one to keep the stack pointer on a word boundary. // The reference is classified as a data reference. def MxARIPD : MxOpClass<"ARIPD">; def MxARIPD8 : MxMemOp<(ops AR32), MxSize8, "e", "printARIPD8Mem", MxARIPD>; def MxARIPD16 : MxMemOp<(ops AR32), MxSize16, "e", "printARIPD16Mem", MxARIPD>; def MxARIPD32 : MxMemOp<(ops AR32), MxSize32, "e", "printARIPD32Mem", MxARIPD>; def MxARIPD8_TC : MxMemOp<(ops AR32_TC), MxSize8, "e", "printARIPD8Mem", MxARIPD>; def MxARIPD16_TC : MxMemOp<(ops AR32_TC), MxSize16, "e", "printARIPD16Mem", MxARIPD>; def MxARIPD32_TC : MxMemOp<(ops AR32_TC), MxSize32, "e", "printARIPD32Mem", MxARIPD>; // ADDRESS REGISTER INDIRECT WITH DISPLACEMENT. This addressing mode requires one // word of extension. The address of the operand is the sum of the address in // the address register and the sign-extended 16-bit displacement integer in the // extension word. The reference is classified as a data reference with the // exception of the jump and jump-to-subroutine instructions. def MxARID : MxOpClass<"ARID">; def MxARID8 : MxMemOp<(ops i16imm:$disp, AR32:$reg), MxSize8, "p", "printARID8Mem", MxARID>; def MxARID16 : MxMemOp<(ops i16imm:$disp, AR32:$reg), MxSize16, "p", "printARID16Mem", MxARID>; def MxARID32 : MxMemOp<(ops i16imm:$disp, AR32:$reg), MxSize32, "p", "printARID32Mem", MxARID>; def MxARID8_TC : MxMemOp<(ops i16imm:$disp, AR32_TC:$reg), MxSize8, "p", "printARID8Mem", MxARID>; def MxARID16_TC : MxMemOp<(ops i16imm:$disp, AR32_TC:$reg), MxSize16, "p", "printARID16Mem", MxARID>; def MxARID32_TC : MxMemOp<(ops i16imm:$disp, AR32_TC:$reg), MxSize32, "p", "printARID32Mem", MxARID>; // ADDRESS REGISTER INDIRECT WITH INDEX. This addressing mode requires one word // of extension. The address of the operand is the sum of the address in the // address register, the signextended displacement integer in the low order eight // bits of the extension word, and the contents of the index register. // The reference is classified as a data reference with the exception of the // jump and jump-to-subroutine instructions def MxARII : MxOpClass<"ARII">; def MxARII8 : MxMemOp<(ops i8imm:$disp, AR32:$reg, XR32:$index), MxSize8, "f", "printARII8Mem", MxARII>; def MxARII16 : MxMemOp<(ops i8imm:$disp, AR32:$reg, XR32:$index), MxSize16, "f", "printARII16Mem", MxARII>; def MxARII32 : MxMemOp<(ops i8imm:$disp, AR32:$reg, XR32:$index), MxSize32, "f", "printARII32Mem", MxARII>; def MxARII8_TC : MxMemOp<(ops i8imm:$disp, AR32_TC:$reg, XR32_TC:$index), MxSize8, "f", "printARII8Mem", MxARII>; def MxARII16_TC : MxMemOp<(ops i8imm:$disp, AR32_TC:$reg, XR32_TC:$index), MxSize16, "f", "printARII16Mem", MxARII>; def MxARII32_TC : MxMemOp<(ops i8imm:$disp, AR32_TC:$reg, XR32_TC:$index), MxSize32, "f", "printARII32Mem", MxARII>; // ABSOLUTE SHORT ADDRESS. This addressing mode requires one word of extension. // The address of the operand is the extension word. The 16-bit address is sign // extended before it is used. The reference is classified as a data reference // with the exception of the jump and jump-tosubroutine instructions. def MxAddr : MxOpClass<"Addr">; let RenderMethod = "addAddrOperands" in { // This hierarchy ensures Addr8 will always be parsed // before other larger-width variants. def MxAddr32 : MxOpClass<"Addr32", [MxAddr]>; def MxAddr16 : MxOpClass<"Addr16", [MxAddr32]>; def MxAddr8 : MxOpClass<"Addr8", [MxAddr16]>; } def MxAS8 : MxMemOp<(ops OtherVT), MxSize8, "B", "printAS8Mem", MxAddr8>; def MxAS16 : MxMemOp<(ops OtherVT), MxSize16, "B", "printAS16Mem", MxAddr16>; def MxAS32 : MxMemOp<(ops OtherVT), MxSize32, "B", "printAS32Mem", MxAddr32>; // ABSOLUTE LONG ADDRESS. This addressing mode requires two words of extension. // The address of the operand is developed by the concatenation of the extension // words. The high order part of the address is the first extension word; the low // order part of the address is the second extension word. The reference is // classified as a data reference with the exception of the jump and jump // to-subroutine instructions. def MxAL8 : MxMemOp<(ops OtherVT), MxSize8, "b", "printAL8Mem", MxAddr8>; def MxAL16 : MxMemOp<(ops OtherVT), MxSize16, "b", "printAL16Mem", MxAddr16>; def MxAL32 : MxMemOp<(ops OtherVT), MxSize32, "b", "printAL32Mem", MxAddr32>; def MxPCD : MxOpClass<"PCD">; def MxPCI : MxOpClass<"PCI">; let OperandType = "OPERAND_PCREL" in { // PROGRAM COUNTER WITH DISPLACEMENT. This addressing mode requires one word of // extension. The address of the operand is the sum of the address in the program // counter and the Sign-extended 16-bit displacement integer in the extension // word. The value in the program counter is the address of the extension word. // The reference is classified as a program reference. def MxPCD8 : MxMemOp<(ops i16imm), MxSize8, "q", "printPCD8Mem", MxPCD>; def MxPCD16 : MxMemOp<(ops i16imm), MxSize16, "q", "printPCD16Mem", MxPCD>; def MxPCD32 : MxMemOp<(ops i16imm), MxSize32, "q", "printPCD32Mem", MxPCD>; // PROGRAM COUNTER WITH INDEX. This addressing mode requires one word of // extension. The address is the sum of the address in the program counter, the // sign-extended displacement integer in the lower eight bits of the extension // word, and the contents of the index register. The value in the program // counter is the address of the extension word. This reference is classified as // a program reference. def MxPCI8 : MxMemOp<(ops i8imm:$disp, XR32:$index), MxSize8, "k", "printPCI8Mem", MxPCI>; def MxPCI16 : MxMemOp<(ops i8imm:$disp, XR32:$index), MxSize16, "k", "printPCI16Mem", MxPCI>; def MxPCI32 : MxMemOp<(ops i8imm:$disp, XR32:$index), MxSize32, "k", "printPCI32Mem", MxPCI>; } // OPERAND_PCREL def MxImm : AsmOperandClass { let Name = "MxImm"; let PredicateMethod = "isImm"; let RenderMethod = "addImmOperands"; let ParserMethod = "parseImm"; } class MxOp : Operand, MxOperand { let ParserMatchClass = MxImm; } let OperandType = "OPERAND_IMMEDIATE", PrintMethod = "printImmediate" in { // IMMEDIATE DATA. This addressing mode requires either one or two words of // extension depending on the size of the operation. // Byte Operation - operand is low order byte of extension word // Word Operation - operand is extension word // Long Word Operation - operand is in the two extension words, // high order 16 bits are in the first // extension word, low order 16 bits are // in the second extension word. def Mxi8imm : MxOp; def Mxi16imm : MxOp; def Mxi32imm : MxOp; } // OPERAND_IMMEDIATE class MxBrTargetOperand : Operand { let OperandType = "OPERAND_PCREL"; let PrintMethod = "printPCRelImm"; let ParserMatchClass = !cast("MxAddr"#N); } // Branch targets have OtherVT type and print as pc-relative values. def MxBrTarget8 : MxBrTargetOperand<8>; def MxBrTarget16 : MxBrTargetOperand<16>; def MxBrTarget32 : MxBrTargetOperand<32>; // Used with MOVEM def MxMoveMaskClass : MxOpClass<"MoveMask">; def MxMoveMask : MxOp { let OperandType = "OPERAND_IMMEDIATE"; let PrintMethod = "printMoveMask"; let ParserMatchClass = MxMoveMaskClass; } //===----------------------------------------------------------------------===// // Predicates //===----------------------------------------------------------------------===// def SmallCode : Predicate<"TM.getCodeModel() == CodeModel::Small">; def KernelCode : Predicate<"TM.getCodeModel() == CodeModel::Kernel">; def FarData : Predicate<"TM.getCodeModel() != CodeModel::Small &&" "TM.getCodeModel() != CodeModel::Kernel">; def NearData : Predicate<"TM.getCodeModel() == CodeModel::Small ||" "TM.getCodeModel() == CodeModel::Kernel">; def IsPIC : Predicate<"TM.isPositionIndependent()">; def IsNotPIC : Predicate<"!TM.isPositionIndependent()">; // ISA versions foreach i = [0,1,2,4,6] in def AtLeastM680 # i # "0" : Predicate<"Subtarget->atLeastM680"#i#"0()">, AssemblerPredicate<(all_of !cast("FeatureISA"#i#"0"))>; def AtLeastM68881 : Predicate<"Subtarget->atLeastM68881()">, AssemblerPredicate<(all_of FeatureISA881)>; def AtLeastM68882 : Predicate<"Subtarget->atLeastM68882()">, AssemblerPredicate<(all_of FeatureISA882)>; //===----------------------------------------------------------------------===// // Condition Codes // // These MUST be kept in sync with codes enum in M68kInstrInfo.h //===----------------------------------------------------------------------===// def MxCONDt : PatLeaf<(i8 0)>; // True def MxCONDf : PatLeaf<(i8 1)>; // False def MxCONDhi : PatLeaf<(i8 2)>; // High def MxCONDls : PatLeaf<(i8 3)>; // Less or Same def MxCONDcc : PatLeaf<(i8 4)>; // Carry Clear def MxCONDcs : PatLeaf<(i8 5)>; // Carry Set def MxCONDne : PatLeaf<(i8 6)>; // Not Equal def MxCONDeq : PatLeaf<(i8 7)>; // Equal def MxCONDvc : PatLeaf<(i8 8)>; // Overflow Clear def MxCONDvs : PatLeaf<(i8 9)>; // Overflow Set def MxCONDpl : PatLeaf<(i8 10)>; // Plus def MxCONDmi : PatLeaf<(i8 11)>; // Minus def MxCONDge : PatLeaf<(i8 12)>; // Greater or Equal def MxCONDlt : PatLeaf<(i8 13)>; // Less Than def MxCONDgt : PatLeaf<(i8 14)>; // Greater Than def MxCONDle : PatLeaf<(i8 15)>; // Less or Equal //===----------------------------------------------------------------------===// // Complex Patterns //===----------------------------------------------------------------------===// // NOTE Though this CP is not strictly necessarily it will simplify instruciton // definitions def MxCP_ARI : ComplexPattern; def MxCP_ARIPI : ComplexPattern; def MxCP_ARIPD : ComplexPattern; def MxCP_ARID : ComplexPattern; def MxCP_ARII : ComplexPattern; def MxCP_AL : ComplexPattern; def MxCP_PCD : ComplexPattern; def MxCP_PCI : ComplexPattern; //===----------------------------------------------------------------------===// // Pattern Fragments //===----------------------------------------------------------------------===// def MximmSExt8 : PatLeaf<(i8 imm)>; def MximmSExt16 : PatLeaf<(i16 imm)>; def MximmSExt32 : PatLeaf<(i32 imm)>; // Used for Shifts and Rotations, since M68k immediates in these instructions // are 1 <= i <= 8. Generally, if immediate is bigger than 8 it will be moved // to a register and then an operation is performed. // // TODO Need to evaluate whether splitting one big shift(or rotate) // into a few smaller is faster than doing a move, if so do custom lowering def Mximm8_1to8 : ImmLeaf= 1 && Imm <= 8; }]>; def Mximm16_1to8 : ImmLeaf= 1 && Imm <= 8; }]>; def Mximm32_1to8 : ImmLeaf= 1 && Imm <= 8; }]>; // Helper fragments for loads. // It's always safe to treat a anyext i16 load as a i32 load if the i16 is // known to be 32-bit aligned or better. Ditto for i8 to i16. def Mxloadi16 : PatFrag<(ops node:$ptr), (i16 (unindexedload node:$ptr)), [{ LoadSDNode *LD = cast(N); ISD::LoadExtType ExtType = LD->getExtensionType(); if (ExtType == ISD::NON_EXTLOAD) return true; if (ExtType == ISD::EXTLOAD) return LD->getAlign() >= 2 && !LD->isSimple(); return false; }]>; def Mxloadi32 : PatFrag<(ops node:$ptr), (i32 (unindexedload node:$ptr)), [{ LoadSDNode *LD = cast(N); ISD::LoadExtType ExtType = LD->getExtensionType(); if (ExtType == ISD::NON_EXTLOAD) return true; if (ExtType == ISD::EXTLOAD) return LD->getAlign() >= 4 && !LD->isSimple(); return false; }]>; def Mxloadi8 : PatFrag<(ops node:$ptr), (i8 (load node:$ptr))>; def MxSExtLoadi16i8 : PatFrag<(ops node:$ptr), (i16 (sextloadi8 node:$ptr))>; def MxSExtLoadi32i8 : PatFrag<(ops node:$ptr), (i32 (sextloadi8 node:$ptr))>; def MxSExtLoadi32i16 : PatFrag<(ops node:$ptr), (i32 (sextloadi16 node:$ptr))>; def MxZExtLoadi8i1 : PatFrag<(ops node:$ptr), (i8 (zextloadi1 node:$ptr))>; def MxZExtLoadi16i1 : PatFrag<(ops node:$ptr), (i16 (zextloadi1 node:$ptr))>; def MxZExtLoadi32i1 : PatFrag<(ops node:$ptr), (i32 (zextloadi1 node:$ptr))>; def MxZExtLoadi16i8 : PatFrag<(ops node:$ptr), (i16 (zextloadi8 node:$ptr))>; def MxZExtLoadi32i8 : PatFrag<(ops node:$ptr), (i32 (zextloadi8 node:$ptr))>; def MxZExtLoadi32i16 : PatFrag<(ops node:$ptr), (i32 (zextloadi16 node:$ptr))>; def MxExtLoadi8i1 : PatFrag<(ops node:$ptr), (i8 (extloadi1 node:$ptr))>; def MxExtLoadi16i1 : PatFrag<(ops node:$ptr), (i16 (extloadi1 node:$ptr))>; def MxExtLoadi32i1 : PatFrag<(ops node:$ptr), (i32 (extloadi1 node:$ptr))>; def MxExtLoadi16i8 : PatFrag<(ops node:$ptr), (i16 (extloadi8 node:$ptr))>; def MxExtLoadi32i8 : PatFrag<(ops node:$ptr), (i32 (extloadi8 node:$ptr))>; def MxExtLoadi32i16 : PatFrag<(ops node:$ptr), (i32 (extloadi16 node:$ptr))>; //===----------------------------------------------------------------------===// // Type Fixtures // // Type Fixtures are ValueType related information sets that usually go together //===----------------------------------------------------------------------===// // TODO make it folded like MxType8.F.Op nad MxType8.F.Pat // TODO move strings into META subclass // vt: Type of data this fixture refers to // prefix: Prefix used to identify type // postfix: Prefix used to qualify type class MxType { int Size = vt.Size; ValueType VT = vt; string Prefix = prefix; string Postfix = postfix; string RLet = rLet; MxOperand ROp = rOp; MxOperand JOp = jOp; ComplexPattern JPat = jPat; MxOperand OOp = oOp; ComplexPattern OPat = oPat; MxOperand EOp = eOp; ComplexPattern EPat = ePat; MxOperand POp = pOp; ComplexPattern PPat = pPat; MxOperand FOp = fOp; ComplexPattern FPat = fPat; MxOperand BOp = bOp; ComplexPattern BPat = bPat; MxOperand QOp = qOp; ComplexPattern QPat = qPat; MxOperand KOp = kOp; ComplexPattern KPat = kPat; MxOperand IOp = iOp; PatFrag IPat = iPat; PatFrag Load = load; } // Provides an alternative way to access the MxOperand and // patterns w.r.t a specific addressing mode. class MxOpBundle { int Size = size; MxOperand Op = op; ComplexPattern Pat = pat; } class MxImmOpBundle : MxOpBundle { PatFrag ImmPat = pat; } // TODO: We can use MxOpAddrMode_ in more places to // replace MxType-based operand factoring. foreach size = [8, 16, 32] in { // Dn def MxOp#size#AddrMode_d : MxOpBundle("MxDRD"#size), ?>; // (An) def MxOp#size#AddrMode_j : MxOpBundle("MxARI"#size), MxCP_ARI>; // (An)+ def MxOp#size#AddrMode_o : MxOpBundle("MxARIPI"#size), MxCP_ARIPI>; // -(An) def MxOp#size#AddrMode_e : MxOpBundle("MxARIPD"#size), MxCP_ARIPD>; // (i,An) def MxOp#size#AddrMode_p : MxOpBundle("MxARID"#size), MxCP_ARID>; // (i,An,Xn) def MxOp#size#AddrMode_f : MxOpBundle("MxARII"#size), MxCP_ARII>; // (ABS).L def MxOp#size#AddrMode_b : MxOpBundle("MxAL"#size), MxCP_AL>; // (i,PC) def MxOp#size#AddrMode_q : MxOpBundle("MxPCD"#size), MxCP_PCD>; // (i,PC,Xn) def MxOp#size#AddrMode_k : MxOpBundle("MxPCI"#size), MxCP_PCI>; // #imm def MxOp#size#AddrMode_i : MxImmOpBundle("Mxi"#size#"imm"), !cast("MximmSExt"#size)>; } // foreach size = [8, 16, 32] foreach size = [16, 32] in { // An def MxOp#size#AddrMode_a : MxOpBundle("MxARD"#size), ?>; // Xn def MxOp#size#AddrMode_r : MxOpBundle("MxXRD"#size), ?>; } // foreach size = [16, 32] foreach size = [32, 64, 80] in def MxOp#size#AddrMode_fpr : MxOpBundle("MxFPR"#size), ?>; class MxType8Class : MxType; def MxType8 : MxType8Class; class MxType16Class : MxType; def MxType16 : MxType16Class; class MxType32Class : MxType; def MxType32 : MxType32Class; def MxType8d : MxType8Class<"d", MxDRD8>; def MxType16d : MxType16Class<"d", MxDRD16>; def MxType16a : MxType16Class<"a", MxARD16>; def MxType16r : MxType16Class<"r", MxXRD16>; def MxType32d : MxType32Class<"d", MxDRD32>; def MxType32a : MxType32Class<"a", MxARD32>; def MxType32r : MxType32Class<"r", MxXRD32>; let Postfix = "_TC" in { def MxType16d_TC : MxType16Class<"d", MxDRD16_TC>; def MxType16a_TC : MxType16Class<"a", MxARD16_TC>; def MxType16r_TC : MxType16Class<"r", MxXRD16_TC>; def MxType32d_TC : MxType32Class<"d", MxDRD32_TC>; def MxType32a_TC : MxType32Class<"a", MxARD32_TC>; def MxType32r_TC : MxType32Class<"r", MxXRD32_TC>; } //===----------------------------------------------------------------------===// // Subsystems //===----------------------------------------------------------------------===// include "M68kInstrData.td" include "M68kInstrShiftRotate.td" include "M68kInstrBits.td" include "M68kInstrArithmetic.td" include "M68kInstrControl.td" include "M68kInstrAtomics.td" include "M68kInstrCompiler.td"