//===-- ARMInstrFormats.td - ARM Instruction Formats -------*- 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 // //===----------------------------------------------------------------------===// //===----------------------------------------------------------------------===// // // ARM Instruction Format Definitions. // // Format specifies the encoding used by the instruction. This is part of the // ad-hoc solution used to emit machine instruction encodings by our machine // code emitter. class Format val> { bits<6> Value = val; } def Pseudo : Format<0>; def MulFrm : Format<1>; def BrFrm : Format<2>; def BrMiscFrm : Format<3>; def DPFrm : Format<4>; def DPSoRegRegFrm : Format<5>; def LdFrm : Format<6>; def StFrm : Format<7>; def LdMiscFrm : Format<8>; def StMiscFrm : Format<9>; def LdStMulFrm : Format<10>; def LdStExFrm : Format<11>; def ArithMiscFrm : Format<12>; def SatFrm : Format<13>; def ExtFrm : Format<14>; def VFPUnaryFrm : Format<15>; def VFPBinaryFrm : Format<16>; def VFPConv1Frm : Format<17>; def VFPConv2Frm : Format<18>; def VFPConv3Frm : Format<19>; def VFPConv4Frm : Format<20>; def VFPConv5Frm : Format<21>; def VFPLdStFrm : Format<22>; def VFPLdStMulFrm : Format<23>; def VFPMiscFrm : Format<24>; def ThumbFrm : Format<25>; def MiscFrm : Format<26>; def NGetLnFrm : Format<27>; def NSetLnFrm : Format<28>; def NDupFrm : Format<29>; def NLdStFrm : Format<30>; def N1RegModImmFrm: Format<31>; def N2RegFrm : Format<32>; def NVCVTFrm : Format<33>; def NVDupLnFrm : Format<34>; def N2RegVShLFrm : Format<35>; def N2RegVShRFrm : Format<36>; def N3RegFrm : Format<37>; def N3RegVShFrm : Format<38>; def NVExtFrm : Format<39>; def NVMulSLFrm : Format<40>; def NVTBLFrm : Format<41>; def DPSoRegImmFrm : Format<42>; def N3RegCplxFrm : Format<43>; // Misc flags. // The instruction has an Rn register operand. // UnaryDP - Indicates this is a unary data processing instruction, i.e. // it doesn't have a Rn operand. class UnaryDP { bit isUnaryDataProc = 1; } // Xform16Bit - Indicates this Thumb2 instruction may be transformed into // a 16-bit Thumb instruction if certain conditions are met. class Xform16Bit { bit canXformTo16Bit = 1; } //===----------------------------------------------------------------------===// // ARM Instruction flags. These need to match ARMBaseInstrInfo.h. // // FIXME: Once the JIT is MC-ized, these can go away. // Addressing mode. class AddrMode val> { bits<5> Value = val; } def AddrModeNone : AddrMode<0>; def AddrMode1 : AddrMode<1>; def AddrMode2 : AddrMode<2>; def AddrMode3 : AddrMode<3>; def AddrMode4 : AddrMode<4>; def AddrMode5 : AddrMode<5>; def AddrMode6 : AddrMode<6>; def AddrModeT1_1 : AddrMode<7>; def AddrModeT1_2 : AddrMode<8>; def AddrModeT1_4 : AddrMode<9>; def AddrModeT1_s : AddrMode<10>; def AddrModeT2_i12 : AddrMode<11>; def AddrModeT2_i8 : AddrMode<12>; def AddrModeT2_i8pos : AddrMode<13>; def AddrModeT2_i8neg : AddrMode<14>; def AddrModeT2_so : AddrMode<15>; def AddrModeT2_pc : AddrMode<16>; def AddrModeT2_i8s4 : AddrMode<17>; def AddrMode_i12 : AddrMode<18>; def AddrMode5FP16 : AddrMode<19>; def AddrModeT2_ldrex : AddrMode<20>; def AddrModeT2_i7s4 : AddrMode<21>; def AddrModeT2_i7s2 : AddrMode<22>; def AddrModeT2_i7 : AddrMode<23>; // Load / store index mode. class IndexMode val> { bits<2> Value = val; } def IndexModeNone : IndexMode<0>; def IndexModePre : IndexMode<1>; def IndexModePost : IndexMode<2>; def IndexModeUpd : IndexMode<3>; // Instruction execution domain. class Domain val> { bits<4> Value = val; } def GenericDomain : Domain<0>; def VFPDomain : Domain<1>; // Instructions in VFP domain only def NeonDomain : Domain<2>; // Instructions in Neon domain only def VFPNeonDomain : Domain<3>; // Instructions in both VFP & Neon domains def VFPNeonA8Domain : Domain<5>; // Instructions in VFP & Neon under A8 def MVEDomain : Domain<8>; // Instructions in MVE and ARMv8.1m //===----------------------------------------------------------------------===// // ARM special operands. // // ARM imod and iflag operands, used only by the CPS instruction. def imod_op : Operand { let PrintMethod = "printCPSIMod"; } def ProcIFlagsOperand : AsmOperandClass { let Name = "ProcIFlags"; let ParserMethod = "parseProcIFlagsOperand"; } def iflags_op : Operand { let PrintMethod = "printCPSIFlag"; let ParserMatchClass = ProcIFlagsOperand; } // ARM Predicate operand. Default to 14 = always (AL). Second part is CC // register whose default is 0 (no register). def CondCodeOperand : AsmOperandClass { let Name = "CondCode"; } def pred : PredicateOperand { let PrintMethod = "printPredicateOperand"; let ParserMatchClass = CondCodeOperand; let DecoderMethod = "DecodePredicateOperand"; } // Selectable predicate operand for CMOV instructions. We can't use a normal // predicate because the default values interfere with instruction selection. In // all other respects it is identical though: pseudo-instruction expansion // relies on the MachineOperands being compatible. def cmovpred : Operand, PredicateOp, ComplexPattern { let MIOperandInfo = (ops i32imm, i32imm); let PrintMethod = "printPredicateOperand"; } // Conditional code result for instructions whose 's' bit is set, e.g. subs. def CCOutOperand : AsmOperandClass { let Name = "CCOut"; } def cc_out : OptionalDefOperand { let EncoderMethod = "getCCOutOpValue"; let PrintMethod = "printSBitModifierOperand"; let ParserMatchClass = CCOutOperand; let DecoderMethod = "DecodeCCOutOperand"; } // Same as cc_out except it defaults to setting CPSR. def s_cc_out : OptionalDefOperand { let EncoderMethod = "getCCOutOpValue"; let PrintMethod = "printSBitModifierOperand"; let ParserMatchClass = CCOutOperand; let DecoderMethod = "DecodeCCOutOperand"; } // Transform to generate the inverse of a condition code during ISel def inv_cond_XFORM : SDNodeXForm(N->getZExtValue()); return CurDAG->getTargetConstant(ARMCC::getOppositeCondition(CC), SDLoc(N), MVT::i32); }]>; // VPT predicate def VPTPredNOperand : AsmOperandClass { let Name = "VPTPredN"; let PredicateMethod = "isVPTPred"; } def VPTPredROperand : AsmOperandClass { let Name = "VPTPredR"; let PredicateMethod = "isVPTPred"; } // Operand classes for the cluster of MC operands describing a // VPT-predicated MVE instruction. // // There are two of these classes. Both of them have the same first // two options: // // $cond (an integer) indicates the instruction's predication status: // * ARMVCC::None means it's unpredicated // * ARMVCC::Then means it's in a VPT block and appears with the T suffix // * ARMVCC::Else means it's in a VPT block and appears with the E suffix. // During code generation, unpredicated and predicated instructions // are indicated by setting this parameter to 'None' or to 'Then'; the // third value 'Else' is only used for assembly and disassembly. // // $cond_reg (type VCCR) gives the input predicate register. This is // always either zero_reg or VPR, but needs to be modelled as an // explicit operand so that it can be register-allocated and spilled // when these operands are used in code generation). // // For 'vpred_r', there's an extra operand $inactive, which specifies // the vector register which will supply any lanes of the output // register that the predication mask prevents from being written by // this instruction. It's always tied to the actual output register // (i.e. must be allocated into the same physical reg), but again, // code generation will need to model it as a separate input value. // // 'vpred_n' doesn't have that extra operand: it only has $cond and // $cond_reg. This variant is used for any instruction that can't, or // doesn't want to, tie $inactive to the output register. Sometimes // that's because another input parameter is already tied to it (e.g. // instructions that both read and write their Qd register even when // unpredicated, either because they only partially overwrite it like // a narrowing integer conversion, or simply because the instruction // encoding doesn't have enough register fields to make the output // independent of all inputs). It can also be because the instruction // is defined to set disabled output lanes to zero rather than leaving // them unchanged (vector loads), or because it doesn't output a // vector register at all (stores, compares). In any of these // situations it's unnecessary to have an extra operand tied to the // output, and inconvenient to leave it there unused. // Base class for both kinds of vpred. class vpred_ops : OperandWithDefaultOps { let PrintMethod = "printVPTPredicateOperand"; let OperandNamespace = "ARM"; let MIOperandInfo = !con((ops i32imm:$cond, VCCR:$cond_reg, GPRlr:$tp_reg), extra_mi); // For convenience, we provide a string value that can be appended // to the constraints string. It's empty for vpred_n, and for // vpred_r it ties the $inactive operand to the output q-register // (which by convention will be called $Qd). string vpred_constraint; } def vpred_r : vpred_ops<(ops (v4i32 undef_tied_input)), (ops MQPR:$inactive)> { let ParserMatchClass = VPTPredROperand; let OperandType = "OPERAND_VPRED_R"; let DecoderMethod = "DecodeVpredROperand"; let vpred_constraint = ",$Qd = $vp.inactive"; } def vpred_n : vpred_ops<(ops), (ops)> { let ParserMatchClass = VPTPredNOperand; let OperandType = "OPERAND_VPRED_N"; let vpred_constraint = ""; } // ARM special operands for disassembly only. // def SetEndAsmOperand : ImmAsmOperand<0,1> { let Name = "SetEndImm"; let ParserMethod = "parseSetEndImm"; } def setend_op : Operand { let PrintMethod = "printSetendOperand"; let ParserMatchClass = SetEndAsmOperand; } def MSRMaskOperand : AsmOperandClass { let Name = "MSRMask"; let ParserMethod = "parseMSRMaskOperand"; } def msr_mask : Operand { let PrintMethod = "printMSRMaskOperand"; let DecoderMethod = "DecodeMSRMask"; let ParserMatchClass = MSRMaskOperand; } def BankedRegOperand : AsmOperandClass { let Name = "BankedReg"; let ParserMethod = "parseBankedRegOperand"; } def banked_reg : Operand { let PrintMethod = "printBankedRegOperand"; let DecoderMethod = "DecodeBankedReg"; let ParserMatchClass = BankedRegOperand; } // Shift Right Immediate - A shift right immediate is encoded differently from // other shift immediates. The imm6 field is encoded like so: // // Offset Encoding // 8 imm6<5:3> = '001', 8 - is encoded in imm6<2:0> // 16 imm6<5:4> = '01', 16 - is encoded in imm6<3:0> // 32 imm6<5> = '1', 32 - is encoded in imm6<4:0> // 64 64 - is encoded in imm6<5:0> def shr_imm8_asm_operand : ImmAsmOperand<1,8> { let Name = "ShrImm8"; } def shr_imm8 : Operand, ImmLeaf 0 && Imm <= 8; }]> { let EncoderMethod = "getShiftRight8Imm"; let DecoderMethod = "DecodeShiftRight8Imm"; let ParserMatchClass = shr_imm8_asm_operand; } def shr_imm16_asm_operand : ImmAsmOperand<1,16> { let Name = "ShrImm16"; } def shr_imm16 : Operand, ImmLeaf 0 && Imm <= 16; }]> { let EncoderMethod = "getShiftRight16Imm"; let DecoderMethod = "DecodeShiftRight16Imm"; let ParserMatchClass = shr_imm16_asm_operand; } def shr_imm32_asm_operand : ImmAsmOperand<1,32> { let Name = "ShrImm32"; } def shr_imm32 : Operand, ImmLeaf 0 && Imm <= 32; }]> { let EncoderMethod = "getShiftRight32Imm"; let DecoderMethod = "DecodeShiftRight32Imm"; let ParserMatchClass = shr_imm32_asm_operand; } def shr_imm64_asm_operand : ImmAsmOperand<1,64> { let Name = "ShrImm64"; } def shr_imm64 : Operand, ImmLeaf 0 && Imm <= 64; }]> { let EncoderMethod = "getShiftRight64Imm"; let DecoderMethod = "DecodeShiftRight64Imm"; let ParserMatchClass = shr_imm64_asm_operand; } // ARM Assembler operand for ldr Rd, =expression which generates an offset // to a constant pool entry or a MOV depending on the value of expression def const_pool_asm_operand : AsmOperandClass { let Name = "ConstPoolAsmImm"; } def const_pool_asm_imm : Operand { let ParserMatchClass = const_pool_asm_operand; } //===----------------------------------------------------------------------===// // ARM Assembler alias templates. // // Note: When EmitPriority == 1, the alias will be used for printing class ARMInstAlias : InstAlias, Requires<[IsARM]>; class ARMInstSubst : InstAlias, Requires<[IsARM,UseNegativeImmediates]>; class tInstAlias : InstAlias, Requires<[IsThumb]>; class tInstSubst : InstAlias, Requires<[IsThumb,UseNegativeImmediates]>; class t2InstAlias : InstAlias, Requires<[IsThumb2]>; class t2InstSubst : InstAlias, Requires<[IsThumb2,UseNegativeImmediates]>; class VFP2InstAlias : InstAlias, Requires<[HasVFP2]>; class VFP2DPInstAlias : InstAlias, Requires<[HasVFP2,HasDPVFP]>; class VFP3InstAlias : InstAlias, Requires<[HasVFP3]>; class NEONInstAlias : InstAlias, Requires<[HasNEON]>; class MVEInstAlias : InstAlias, Requires<[HasMVEInt, IsThumb]>; class VFP2MnemonicAlias : MnemonicAlias, Requires<[HasVFP2]>; class NEONMnemonicAlias : MnemonicAlias, Requires<[HasNEON]>; //===----------------------------------------------------------------------===// // ARM Instruction templates. // class InstTemplate : Instruction { let Namespace = "ARM"; AddrMode AM = am; int Size = sz; IndexMode IM = im; bits<2> IndexModeBits = IM.Value; Format F = f; bits<6> Form = F.Value; Domain D = d; bit isUnaryDataProc = 0; bit canXformTo16Bit = 0; // The instruction is a 16-bit flag setting Thumb instruction. Used // by the parser and if-converter to determine whether to require the 'S' // suffix on the mnemonic (when not in an IT block) or preclude it (when // in an IT block). bit thumbArithFlagSetting = 0; bits<2> VecSize = 0; bit validForTailPredication = 0; bit retainsPreviousHalfElement = 0; bit horizontalReduction = 0; bit doubleWidthResult = 0; // If this is a pseudo instruction, mark it isCodeGenOnly. let isCodeGenOnly = !eq(!cast(f), "Pseudo"); // The layout of TSFlags should be kept in sync with ARMBaseInfo.h. let TSFlags{4-0} = AM.Value; let TSFlags{6-5} = IndexModeBits; let TSFlags{12-7} = Form; let TSFlags{13} = isUnaryDataProc; let TSFlags{14} = canXformTo16Bit; let TSFlags{18-15} = D.Value; let TSFlags{19} = thumbArithFlagSetting; let TSFlags{20} = validForTailPredication; let TSFlags{21} = retainsPreviousHalfElement; let TSFlags{22} = horizontalReduction; let TSFlags{23} = doubleWidthResult; let TSFlags{25-24} = VecSize; let Constraints = cstr; let Itinerary = itin; } class Encoding { field bits<32> Inst; // Mask of bits that cause an encoding to be UNPREDICTABLE. // If a bit is set, then if the corresponding bit in the // target encoding differs from its value in the "Inst" field, // the instruction is UNPREDICTABLE (SoftFail in abstract parlance). field bits<32> Unpredictable = 0; // SoftFail is the generic name for this field, but we alias it so // as to make it more obvious what it means in ARM-land. field bits<32> SoftFail = Unpredictable; } class InstARM : InstTemplate, Encoding { let DecoderNamespace = "ARM"; } // This Encoding-less class is used by Thumb1 to specify the encoding bits later // on by adding flavors to specific instructions. class InstThumb : InstTemplate { let DecoderNamespace = "Thumb"; } // Pseudo-instructions for alternate assembly syntax (never used by codegen). // These are aliases that require C++ handling to convert to the target // instruction, while InstAliases can be handled directly by tblgen. class AsmPseudoInst : InstTemplate { let OutOperandList = oops; let InOperandList = iops; let Pattern = []; let isCodeGenOnly = 0; // So we get asm matcher for it. let AsmString = asm; let isPseudo = 1; let hasNoSchedulingInfo = 1; } class ARMAsmPseudo : AsmPseudoInst, Requires<[IsARM]>; class tAsmPseudo : AsmPseudoInst, Requires<[IsThumb]>; class t2AsmPseudo : AsmPseudoInst, Requires<[IsThumb2]>; class VFP2AsmPseudo : AsmPseudoInst, Requires<[HasVFP2]>; class NEONAsmPseudo : AsmPseudoInst, Requires<[HasNEON]>; class MVEAsmPseudo : AsmPseudoInst, Requires<[HasMVEInt]>; // Pseudo instructions for the code generator. class PseudoInst pattern> : InstTemplate { let OutOperandList = oops; let InOperandList = iops; let Pattern = pattern; let isCodeGenOnly = 1; let isPseudo = 1; } // PseudoInst that's ARM-mode only. class ARMPseudoInst pattern> : PseudoInst { let Size = sz; list Predicates = [IsARM]; } // PseudoInst that's Thumb-mode only. class tPseudoInst pattern> : PseudoInst { let Size = sz; list Predicates = [IsThumb]; } // PseudoInst that's in ARMv8-M baseline (Somewhere between Thumb and Thumb2) class t2basePseudoInst pattern> : PseudoInst { let Size = sz; list Predicates = [IsThumb,HasV8MBaseline]; } // PseudoInst that's Thumb2-mode only. class t2PseudoInst pattern> : PseudoInst { let Size = sz; list Predicates = [IsThumb2]; } class ARMPseudoExpand pattern, dag Result> : ARMPseudoInst, PseudoInstExpansion; class tPseudoExpand pattern, dag Result> : tPseudoInst, PseudoInstExpansion; class t2PseudoExpand pattern, dag Result> : t2PseudoInst, PseudoInstExpansion; // Almost all ARM instructions are predicable. class I pattern> : InstARM { bits<4> p; let Inst{31-28} = p; let OutOperandList = oops; let InOperandList = !con(iops, (ins pred:$p)); let AsmString = !strconcat(opc, "${p}", asm); let Pattern = pattern; list Predicates = [IsARM]; } // A few are not predicable class InoP pattern> : InstARM { let OutOperandList = oops; let InOperandList = iops; let AsmString = !strconcat(opc, asm); let Pattern = pattern; let isPredicable = 0; list Predicates = [IsARM]; } // Same as I except it can optionally modify CPSR. Note it's modeled as an input // operand since by default it's a zero register. It will become an implicit def // once it's "flipped". class sI pattern> : InstARM { bits<4> p; // Predicate operand bits<1> s; // condition-code set flag ('1' if the insn should set the flags) let Inst{31-28} = p; let Inst{20} = s; let OutOperandList = oops; let InOperandList = !con(iops, (ins pred:$p, cc_out:$s)); let AsmString = !strconcat(opc, "${s}${p}", asm); let Pattern = pattern; list Predicates = [IsARM]; } // Special cases class XI pattern> : InstARM { let OutOperandList = oops; let InOperandList = iops; let AsmString = asm; let Pattern = pattern; list Predicates = [IsARM]; } class AI pattern> : I; class AsI pattern> : sI; class AXI pattern> : XI; class AXIM pattern> : XI; class AInoP pattern> : InoP; // Ctrl flow instructions class ABI opcod, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : I { let Inst{27-24} = opcod; } class ABXI opcod, dag oops, dag iops, InstrItinClass itin, string asm, list pattern> : XI { let Inst{27-24} = opcod; } // BR_JT instructions class JTI pattern> : XI; class AIldr_ex_or_acq opcod, bits<2> opcod2, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : I { bits<4> Rt; bits<4> addr; let Inst{27-23} = 0b00011; let Inst{22-21} = opcod; let Inst{20} = 1; let Inst{19-16} = addr; let Inst{15-12} = Rt; let Inst{11-10} = 0b11; let Inst{9-8} = opcod2; let Inst{7-0} = 0b10011111; } class AIstr_ex_or_rel opcod, bits<2> opcod2, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : I { bits<4> Rt; bits<4> addr; let Inst{27-23} = 0b00011; let Inst{22-21} = opcod; let Inst{20} = 0; let Inst{19-16} = addr; let Inst{11-10} = 0b11; let Inst{9-8} = opcod2; let Inst{7-4} = 0b1001; let Inst{3-0} = Rt; } // Atomic load/store instructions class AIldrex opcod, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AIldr_ex_or_acq; class AIstrex opcod, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AIstr_ex_or_rel { bits<4> Rd; let Inst{15-12} = Rd; } // Exclusive load/store instructions class AIldaex opcod, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AIldr_ex_or_acq, Requires<[IsARM, HasAcquireRelease, HasV7Clrex]>; class AIstlex opcod, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AIstr_ex_or_rel, Requires<[IsARM, HasAcquireRelease, HasV7Clrex]> { bits<4> Rd; let Inst{15-12} = Rd; } class AIswp pattern> : AI { bits<4> Rt; bits<4> Rt2; bits<4> addr; let Inst{27-23} = 0b00010; let Inst{22} = b; let Inst{21-20} = 0b00; let Inst{19-16} = addr; let Inst{15-12} = Rt; let Inst{11-4} = 0b00001001; let Inst{3-0} = Rt2; let Unpredictable{11-8} = 0b1111; let DecoderMethod = "DecodeSwap"; } // Acquire/Release load/store instructions class AIldracq opcod, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AIldr_ex_or_acq, Requires<[IsARM, HasAcquireRelease]>; class AIstrrel opcod, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AIstr_ex_or_rel, Requires<[IsARM, HasAcquireRelease]> { let Inst{15-12} = 0b1111; } // addrmode1 instructions class AI1 opcod, dag oops, dag iops, Format f, InstrItinClass itin, string opc, string asm, list pattern> : I { let Inst{24-21} = opcod; let Inst{27-26} = 0b00; } class AsI1 opcod, dag oops, dag iops, Format f, InstrItinClass itin, string opc, string asm, list pattern> : sI { let Inst{24-21} = opcod; let Inst{27-26} = 0b00; } class AXI1 opcod, dag oops, dag iops, Format f, InstrItinClass itin, string asm, list pattern> : XI { let Inst{24-21} = opcod; let Inst{27-26} = 0b00; } // loads // LDR/LDRB/STR/STRB/... class AI2ldst op, bit isLd, bit isByte, dag oops, dag iops, AddrMode am, Format f, InstrItinClass itin, string opc, string asm, list pattern> : I { let Inst{27-25} = op; let Inst{24} = 1; // 24 == P // 23 == U let Inst{22} = isByte; let Inst{21} = 0; // 21 == W let Inst{20} = isLd; } // Indexed load/stores class AI2ldstidx pattern> : I { bits<4> Rt; let Inst{27-26} = 0b01; let Inst{24} = isPre; // P bit let Inst{22} = isByte; // B bit let Inst{21} = isPre; // W bit let Inst{20} = isLd; // L bit let Inst{15-12} = Rt; } class AI2stridx_reg pattern> : AI2ldstidx<0, isByte, isPre, oops, iops, im, f, itin, opc, asm, cstr, pattern> { // AM2 store w/ two operands: (GPR, am2offset) // {12} isAdd // {11-0} imm12/Rm bits<14> offset; bits<4> Rn; let Inst{25} = 1; let Inst{23} = offset{12}; let Inst{19-16} = Rn; let Inst{11-5} = offset{11-5}; let Inst{4} = 0; let Inst{3-0} = offset{3-0}; } class AI2stridx_imm pattern> : AI2ldstidx<0, isByte, isPre, oops, iops, im, f, itin, opc, asm, cstr, pattern> { // AM2 store w/ two operands: (GPR, am2offset) // {12} isAdd // {11-0} imm12/Rm bits<14> offset; bits<4> Rn; let Inst{25} = 0; let Inst{23} = offset{12}; let Inst{19-16} = Rn; let Inst{11-0} = offset{11-0}; } // FIXME: Merge with the above class when addrmode2 gets used for STR, STRB // but for now use this class for STRT and STRBT. class AI2stridxT pattern> : AI2ldstidx<0, isByte, isPre, oops, iops, im, f, itin, opc, asm, cstr, pattern> { // AM2 store w/ two operands: (GPR, am2offset) // {17-14} Rn // {13} 1 == Rm, 0 == imm12 // {12} isAdd // {11-0} imm12/Rm bits<18> addr; let Inst{25} = addr{13}; let Inst{23} = addr{12}; let Inst{19-16} = addr{17-14}; let Inst{11-0} = addr{11-0}; } // addrmode3 instructions class AI3ld op, bit op20, dag oops, dag iops, Format f, InstrItinClass itin, string opc, string asm, list pattern> : I { bits<14> addr; bits<4> Rt; let Inst{27-25} = 0b000; let Inst{24} = 1; // P bit let Inst{23} = addr{8}; // U bit let Inst{22} = addr{13}; // 1 == imm8, 0 == Rm let Inst{21} = 0; // W bit let Inst{20} = op20; // L bit let Inst{19-16} = addr{12-9}; // Rn let Inst{15-12} = Rt; // Rt let Inst{11-8} = addr{7-4}; // imm7_4/zero let Inst{7-4} = op; let Inst{3-0} = addr{3-0}; // imm3_0/Rm let DecoderMethod = "DecodeAddrMode3Instruction"; } class AI3ldstidx op, bit op20, bit isPre, dag oops, dag iops, IndexMode im, Format f, InstrItinClass itin, string opc, string asm, string cstr, list pattern> : I { bits<4> Rt; let Inst{27-25} = 0b000; let Inst{24} = isPre; // P bit let Inst{21} = isPre; // W bit let Inst{20} = op20; // L bit let Inst{15-12} = Rt; // Rt let Inst{7-4} = op; } // FIXME: Merge with the above class when addrmode2 gets used for LDR, LDRB // but for now use this class for LDRSBT, LDRHT, LDSHT. class AI3ldstidxT op, bit isLoad, dag oops, dag iops, IndexMode im, Format f, InstrItinClass itin, string opc, string asm, string cstr, list pattern> : I { // {13} 1 == imm8, 0 == Rm // {12-9} Rn // {8} isAdd // {7-4} imm7_4/zero // {3-0} imm3_0/Rm bits<4> addr; bits<4> Rt; let Inst{27-25} = 0b000; let Inst{24} = 0; // P bit let Inst{21} = 1; let Inst{20} = isLoad; // L bit let Inst{19-16} = addr; // Rn let Inst{15-12} = Rt; // Rt let Inst{7-4} = op; } // stores class AI3str op, dag oops, dag iops, Format f, InstrItinClass itin, string opc, string asm, list pattern> : I { bits<14> addr; bits<4> Rt; let Inst{27-25} = 0b000; let Inst{24} = 1; // P bit let Inst{23} = addr{8}; // U bit let Inst{22} = addr{13}; // 1 == imm8, 0 == Rm let Inst{21} = 0; // W bit let Inst{20} = 0; // L bit let Inst{19-16} = addr{12-9}; // Rn let Inst{15-12} = Rt; // Rt let Inst{11-8} = addr{7-4}; // imm7_4/zero let Inst{7-4} = op; let Inst{3-0} = addr{3-0}; // imm3_0/Rm let DecoderMethod = "DecodeAddrMode3Instruction"; } // addrmode4 instructions class AXI4 pattern> : XI { bits<4> p; bits<16> regs; bits<4> Rn; let Inst{31-28} = p; let Inst{27-25} = 0b100; let Inst{22} = 0; // S bit let Inst{19-16} = Rn; let Inst{15-0} = regs; } // Unsigned multiply, multiply-accumulate instructions. class AMul1I opcod, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : I { let Inst{7-4} = 0b1001; let Inst{20} = 0; // S bit let Inst{27-21} = opcod; } class AsMul1I opcod, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : sI { let Inst{7-4} = 0b1001; let Inst{27-21} = opcod; } // Most significant word multiply class AMul2I opcod, bits<4> opc7_4, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : I { bits<4> Rd; bits<4> Rn; bits<4> Rm; let Inst{7-4} = opc7_4; let Inst{20} = 1; let Inst{27-21} = opcod; let Inst{19-16} = Rd; let Inst{11-8} = Rm; let Inst{3-0} = Rn; } // MSW multiple w/ Ra operand class AMul2Ia opcod, bits<4> opc7_4, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AMul2I { bits<4> Ra; let Inst{15-12} = Ra; } // SMUL / SMULW / SMLA / SMLAW class AMulxyIbase opcod, bits<2> bit6_5, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : I { bits<4> Rn; bits<4> Rm; let Inst{4} = 0; let Inst{7} = 1; let Inst{20} = 0; let Inst{27-21} = opcod; let Inst{6-5} = bit6_5; let Inst{11-8} = Rm; let Inst{3-0} = Rn; } class AMulxyI opcod, bits<2> bit6_5, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AMulxyIbase { bits<4> Rd; let Inst{19-16} = Rd; } // AMulxyI with Ra operand class AMulxyIa opcod, bits<2> bit6_5, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AMulxyI { bits<4> Ra; let Inst{15-12} = Ra; } // SMLAL* class AMulxyI64 opcod, bits<2> bit6_5, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AMulxyIbase { bits<4> RdLo; bits<4> RdHi; let Inst{19-16} = RdHi; let Inst{15-12} = RdLo; } // Extend instructions. class AExtI opcod, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : I { // All AExtI instructions have Rd and Rm register operands. bits<4> Rd; bits<4> Rm; let Inst{15-12} = Rd; let Inst{3-0} = Rm; let Inst{7-4} = 0b0111; let Inst{9-8} = 0b00; let Inst{27-20} = opcod; let Unpredictable{9-8} = 0b11; } // Misc Arithmetic instructions. class AMiscA1I opcod, bits<4> opc7_4, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : I { bits<4> Rd; bits<4> Rm; let Inst{27-20} = opcod; let Inst{19-16} = 0b1111; let Inst{15-12} = Rd; let Inst{11-8} = 0b1111; let Inst{7-4} = opc7_4; let Inst{3-0} = Rm; } // Division instructions. class ADivA1I opcod, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : I { bits<4> Rd; bits<4> Rn; bits<4> Rm; let Inst{27-23} = 0b01110; let Inst{22-20} = opcod; let Inst{19-16} = Rd; let Inst{15-12} = 0b1111; let Inst{11-8} = Rm; let Inst{7-4} = 0b0001; let Inst{3-0} = Rn; } // PKH instructions def PKHLSLAsmOperand : ImmAsmOperand<0,31> { let Name = "PKHLSLImm"; let ParserMethod = "parsePKHLSLImm"; } def pkh_lsl_amt: Operand, ImmLeaf= 0 && Imm < 32; }]>{ let PrintMethod = "printPKHLSLShiftImm"; let ParserMatchClass = PKHLSLAsmOperand; } def PKHASRAsmOperand : AsmOperandClass { let Name = "PKHASRImm"; let ParserMethod = "parsePKHASRImm"; } def pkh_asr_amt: Operand, ImmLeaf 0 && Imm <= 32; }]>{ let PrintMethod = "printPKHASRShiftImm"; let ParserMatchClass = PKHASRAsmOperand; } class APKHI opcod, bit tb, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : I { bits<4> Rd; bits<4> Rn; bits<4> Rm; bits<5> sh; let Inst{27-20} = opcod; let Inst{19-16} = Rn; let Inst{15-12} = Rd; let Inst{11-7} = sh; let Inst{6} = tb; let Inst{5-4} = 0b01; let Inst{3-0} = Rm; } //===----------------------------------------------------------------------===// // ARMPat - Same as Pat<>, but requires that the compiler be in ARM mode. class ARMPat : Pat { list Predicates = [IsARM]; } class ARMV5TPat : Pat { list Predicates = [IsARM, HasV5T]; } class ARMV5TEPat : Pat { list Predicates = [IsARM, HasV5TE]; } // ARMV5MOPat - Same as ARMV5TEPat with UseMulOps. class ARMV5MOPat : Pat { list Predicates = [IsARM, HasV5TE, UseMulOps]; } class ARMV6Pat : Pat { list Predicates = [IsARM, HasV6]; } class VFPPat : Pat { list Predicates = [HasVFP2]; } class VFPNoNEONPat : Pat { list Predicates = [HasVFP2, DontUseNEONForFP]; } class Thumb2DSPPat : Pat { list Predicates = [IsThumb2, HasDSP]; } class Thumb2DSPMulPat : Pat { list Predicates = [IsThumb2, UseMulOps, HasDSP]; } class FPRegs16Pat : Pat { list Predicates = [HasFPRegs16]; } class FP16Pat : Pat { list Predicates = [HasFP16]; } class FullFP16Pat : Pat { list Predicates = [HasFullFP16]; } //===----------------------------------------------------------------------===// // Thumb Instruction Format Definitions. // class ThumbI pattern> : InstThumb { let OutOperandList = oops; let InOperandList = iops; let AsmString = asm; let Pattern = pattern; list Predicates = [IsThumb]; } // TI - Thumb instruction. class TI pattern> : ThumbI; // Two-address instructions class TIt pattern> : ThumbI; // tBL, tBX 32-bit instructions class TIx2 opcod1, bits<2> opcod2, bit opcod3, dag oops, dag iops, InstrItinClass itin, string asm, list pattern> : ThumbI, Encoding { let Inst{31-27} = opcod1; let Inst{15-14} = opcod2; let Inst{12} = opcod3; } // BR_JT instructions class TJTI pattern> : ThumbI; // Thumb1 only class Thumb1I pattern> : InstThumb { let OutOperandList = oops; let InOperandList = iops; let AsmString = asm; let Pattern = pattern; list Predicates = [IsThumb, IsThumb1Only]; } class T1I pattern> : Thumb1I; class T1Ix2 pattern> : Thumb1I; // Two-address instructions class T1It pattern> : Thumb1I; // Thumb1 instruction that can either be predicated or set CPSR. class Thumb1sI pattern> : InstThumb { let OutOperandList = !con(oops, (outs s_cc_out:$s)); let InOperandList = !con(iops, (ins pred:$p)); let AsmString = !strconcat(opc, "${s}${p}", asm); let Pattern = pattern; let thumbArithFlagSetting = 1; list Predicates = [IsThumb, IsThumb1Only]; let DecoderNamespace = "ThumbSBit"; } class T1sI pattern> : Thumb1sI; // Two-address instructions class T1sIt pattern> : Thumb1sI; // Thumb1 instruction that can be predicated. class Thumb1pI pattern> : InstThumb { let OutOperandList = oops; let InOperandList = !con(iops, (ins pred:$p)); let AsmString = !strconcat(opc, "${p}", asm); let Pattern = pattern; list Predicates = [IsThumb, IsThumb1Only]; } class T1pI pattern> : Thumb1pI; // Two-address instructions class T1pIt pattern> : Thumb1pI; class T1pIs pattern> : Thumb1pI; class Encoding16 : Encoding { let Inst{31-16} = 0x0000; } // A6.2 16-bit Thumb instruction encoding class T1Encoding opcode> : Encoding16 { let Inst{15-10} = opcode; } // A6.2.1 Shift (immediate), add, subtract, move, and compare encoding. class T1General opcode> : Encoding16 { let Inst{15-14} = 0b00; let Inst{13-9} = opcode; } // A6.2.2 Data-processing encoding. class T1DataProcessing opcode> : Encoding16 { let Inst{15-10} = 0b010000; let Inst{9-6} = opcode; } // A6.2.3 Special data instructions and branch and exchange encoding. class T1Special opcode> : Encoding16 { let Inst{15-10} = 0b010001; let Inst{9-6} = opcode; } // A6.2.4 Load/store single data item encoding. class T1LoadStore opA, bits<3> opB> : Encoding16 { let Inst{15-12} = opA; let Inst{11-9} = opB; } class T1LdStSP opB> : T1LoadStore<0b1001, opB>; // SP relative class T1BranchCond opcode> : Encoding16 { let Inst{15-12} = opcode; } // Helper classes to encode Thumb1 loads and stores. For immediates, the // following bits are used for "opA" (see A6.2.4): // // 0b0110 => Immediate, 4 bytes // 0b1000 => Immediate, 2 bytes // 0b0111 => Immediate, 1 byte class T1pILdStEncode opcode, dag oops, dag iops, AddrMode am, InstrItinClass itin, string opc, string asm, list pattern> : Thumb1pI, T1LoadStore<0b0101, opcode> { bits<3> Rt; bits<8> addr; let Inst{8-6} = addr{5-3}; // Rm let Inst{5-3} = addr{2-0}; // Rn let Inst{2-0} = Rt; } class T1pILdStEncodeImm opA, bit opB, dag oops, dag iops, AddrMode am, InstrItinClass itin, string opc, string asm, list pattern> : Thumb1pI, T1LoadStore { bits<3> Rt; bits<8> addr; let Inst{10-6} = addr{7-3}; // imm5 let Inst{5-3} = addr{2-0}; // Rn let Inst{2-0} = Rt; } // A6.2.5 Miscellaneous 16-bit instructions encoding. class T1Misc opcode> : Encoding16 { let Inst{15-12} = 0b1011; let Inst{11-5} = opcode; } // Thumb2I - Thumb2 instruction. Almost all Thumb2 instructions are predicable. class Thumb2I pattern> : InstARM { let OutOperandList = oops; let InOperandList = !con(iops, (ins pred:$p)); let AsmString = !strconcat(opc, "${p}", asm); let Pattern = pattern; list Predicates = [IsThumb2]; let DecoderNamespace = "Thumb2"; } // Same as Thumb2I except it can optionally modify CPSR. Note it's modeled as an // input operand since by default it's a zero register. It will become an // implicit def once it's "flipped". // // FIXME: This uses unified syntax so {s} comes before {p}. We should make it // more consistent. class Thumb2sI pattern> : InstARM { bits<1> s; // condition-code set flag ('1' if the insn should set the flags) let Inst{20} = s; let OutOperandList = oops; let InOperandList = !con(iops, (ins pred:$p, cc_out:$s)); let AsmString = !strconcat(opc, "${s}${p}", asm); let Pattern = pattern; list Predicates = [IsThumb2]; let DecoderNamespace = "Thumb2"; } // Special cases class Thumb2XI pattern> : InstARM { let OutOperandList = oops; let InOperandList = iops; let AsmString = asm; let Pattern = pattern; list Predicates = [IsThumb2]; let DecoderNamespace = "Thumb2"; } class ThumbXI pattern> : InstARM { let OutOperandList = oops; let InOperandList = iops; let AsmString = asm; let Pattern = pattern; list Predicates = [IsThumb, IsThumb1Only]; let DecoderNamespace = "Thumb"; } class T2I pattern, AddrMode am = AddrModeNone> : Thumb2I; class T2Ii12 pattern> : Thumb2I; class T2Ii8p pattern> : Thumb2I; class T2Ii8n pattern> : Thumb2I; class T2Iso pattern> : Thumb2I; class T2Ipc pattern> : Thumb2I; class T2Ii8s4 pattern> : Thumb2I { bits<4> Rt; bits<4> Rt2; bits<13> addr; let Inst{31-25} = 0b1110100; let Inst{24} = P; let Inst{23} = addr{8}; let Inst{22} = 1; let Inst{21} = W; let Inst{20} = isLoad; let Inst{19-16} = addr{12-9}; let Inst{15-12} = Rt{3-0}; let Inst{11-8} = Rt2{3-0}; let Inst{7-0} = addr{7-0}; } class T2Ii8s4post pattern> : Thumb2I { bits<4> Rt; bits<4> Rt2; bits<4> addr; bits<9> imm; let Inst{31-25} = 0b1110100; let Inst{24} = P; let Inst{23} = imm{8}; let Inst{22} = 1; let Inst{21} = W; let Inst{20} = isLoad; let Inst{19-16} = addr; let Inst{15-12} = Rt{3-0}; let Inst{11-8} = Rt2{3-0}; let Inst{7-0} = imm{7-0}; } class T2sI pattern> : Thumb2sI; class T2XI pattern> : Thumb2XI; class T2JTI pattern> : Thumb2XI; // Move to/from coprocessor instructions class T2Cop opc, dag oops, dag iops, string opcstr, string asm, list pattern> : T2I , Requires<[IsThumb2]> { let Inst{31-28} = opc; } // Two-address instructions class T2XIt pattern> : Thumb2XI; // T2Ipreldst - Thumb2 pre-indexed load / store instructions. class T2Ipreldst opcod, bit load, bit pre, dag oops, dag iops, AddrMode am, IndexMode im, InstrItinClass itin, string opc, string asm, string cstr, list pattern> : InstARM { let OutOperandList = oops; let InOperandList = !con(iops, (ins pred:$p)); let AsmString = !strconcat(opc, "${p}", asm); let Pattern = pattern; list Predicates = [IsThumb2]; let DecoderNamespace = "Thumb2"; bits<4> Rt; bits<13> addr; let Inst{31-27} = 0b11111; let Inst{26-25} = 0b00; let Inst{24} = signed; let Inst{23} = 0; let Inst{22-21} = opcod; let Inst{20} = load; let Inst{19-16} = addr{12-9}; let Inst{15-12} = Rt{3-0}; let Inst{11} = 1; // (P, W) = (1, 1) Pre-indexed or (0, 1) Post-indexed let Inst{10} = pre; // The P bit. let Inst{9} = addr{8}; // Sign bit let Inst{8} = 1; // The W bit. let Inst{7-0} = addr{7-0}; let DecoderMethod = "DecodeT2LdStPre"; } // T2Ipostldst - Thumb2 post-indexed load / store instructions. class T2Ipostldst opcod, bit load, bit pre, dag oops, dag iops, AddrMode am, IndexMode im, InstrItinClass itin, string opc, string asm, string cstr, list pattern> : InstARM { let OutOperandList = oops; let InOperandList = !con(iops, (ins pred:$p)); let AsmString = !strconcat(opc, "${p}", asm); let Pattern = pattern; list Predicates = [IsThumb2]; let DecoderNamespace = "Thumb2"; bits<4> Rt; bits<4> Rn; bits<9> offset; let Inst{31-27} = 0b11111; let Inst{26-25} = 0b00; let Inst{24} = signed; let Inst{23} = 0; let Inst{22-21} = opcod; let Inst{20} = load; let Inst{19-16} = Rn; let Inst{15-12} = Rt{3-0}; let Inst{11} = 1; // (P, W) = (1, 1) Pre-indexed or (0, 1) Post-indexed let Inst{10} = pre; // The P bit. let Inst{9} = offset{8}; // Sign bit let Inst{8} = 1; // The W bit. let Inst{7-0} = offset{7-0}; let DecoderMethod = "DecodeT2LdStPre"; } // T1Pat - Same as Pat<>, but requires that the compiler be in Thumb1 mode. class T1Pat : Pat { list Predicates = [IsThumb, IsThumb1Only]; } // T2v6Pat - Same as Pat<>, but requires V6T2 Thumb2 mode. class T2v6Pat : Pat { list Predicates = [IsThumb2, HasV6T2]; } // T2Pat - Same as Pat<>, but requires that the compiler be in Thumb2 mode. class T2Pat : Pat { list Predicates = [IsThumb2]; } //===----------------------------------------------------------------------===// //===----------------------------------------------------------------------===// // ARM VFP Instruction templates. // // Almost all VFP instructions are predicable. class VFPI pattern> : InstARM { bits<4> p; let Inst{31-28} = p; let OutOperandList = oops; let InOperandList = !con(iops, (ins pred:$p)); let AsmString = !strconcat(opc, "${p}", asm); let Pattern = pattern; let PostEncoderMethod = "VFPThumb2PostEncoder"; let DecoderNamespace = "VFP"; list Predicates = [HasVFP2]; } // Special cases class VFPXI pattern> : InstARM { bits<4> p; let Inst{31-28} = p; let OutOperandList = oops; let InOperandList = iops; let AsmString = asm; let Pattern = pattern; let PostEncoderMethod = "VFPThumb2PostEncoder"; let DecoderNamespace = "VFP"; list Predicates = [HasVFP2]; } class VFPAI pattern> : VFPI { let PostEncoderMethod = "VFPThumb2PostEncoder"; } // ARM VFP addrmode5 loads and stores class ADI5 opcod1, bits<2> opcod2, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : VFPI { // Instruction operands. bits<5> Dd; bits<13> addr; // Encode instruction operands. let Inst{23} = addr{8}; // U (add = (U == '1')) let Inst{22} = Dd{4}; let Inst{19-16} = addr{12-9}; // Rn let Inst{15-12} = Dd{3-0}; let Inst{7-0} = addr{7-0}; // imm8 let Inst{27-24} = opcod1; let Inst{21-20} = opcod2; let Inst{11-9} = 0b101; let Inst{8} = 1; // Double precision // Loads & stores operate on both NEON and VFP pipelines. let D = VFPNeonDomain; } class ASI5 opcod1, bits<2> opcod2, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : VFPI { // Instruction operands. bits<5> Sd; bits<13> addr; // Encode instruction operands. let Inst{23} = addr{8}; // U (add = (U == '1')) let Inst{22} = Sd{0}; let Inst{19-16} = addr{12-9}; // Rn let Inst{15-12} = Sd{4-1}; let Inst{7-0} = addr{7-0}; // imm8 let Inst{27-24} = opcod1; let Inst{21-20} = opcod2; let Inst{11-9} = 0b101; let Inst{8} = 0; // Single precision // Loads & stores operate on both NEON and VFP pipelines. let D = VFPNeonDomain; } class AHI5 opcod1, bits<2> opcod2, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : VFPI { list Predicates = [HasFullFP16]; // Instruction operands. bits<5> Sd; bits<13> addr; // Encode instruction operands. let Inst{23} = addr{8}; // U (add = (U == '1')) let Inst{22} = Sd{0}; let Inst{19-16} = addr{12-9}; // Rn let Inst{15-12} = Sd{4-1}; let Inst{7-0} = addr{7-0}; // imm8 let Inst{27-24} = opcod1; let Inst{21-20} = opcod2; let Inst{11-8} = 0b1001; // Half precision // Loads & stores operate on both NEON and VFP pipelines. let D = VFPNeonDomain; let isUnpredicable = 1; // FP16 instructions cannot in general be conditional } // VFP Load / store multiple pseudo instructions. class PseudoVFPLdStM pattern> : InstARM { let OutOperandList = oops; let InOperandList = !con(iops, (ins pred:$p)); let Pattern = pattern; list Predicates = [HasVFP2]; } // Load / store multiple // Unknown precision class AXXI4 pattern> : VFPXI { // Instruction operands. bits<4> Rn; bits<13> regs; // Encode instruction operands. let Inst{19-16} = Rn; let Inst{22} = 0; let Inst{15-12} = regs{11-8}; let Inst{7-1} = regs{7-1}; let Inst{27-25} = 0b110; let Inst{11-8} = 0b1011; let Inst{0} = 1; } // Double precision class AXDI4 pattern> : VFPXI { // Instruction operands. bits<4> Rn; bits<13> regs; // Encode instruction operands. let Inst{19-16} = Rn; let Inst{22} = regs{12}; let Inst{15-12} = regs{11-8}; let Inst{7-1} = regs{7-1}; let Inst{27-25} = 0b110; let Inst{11-9} = 0b101; let Inst{8} = 1; // Double precision let Inst{0} = 0; } // Single Precision class AXSI4 pattern> : VFPXI { // Instruction operands. bits<4> Rn; bits<13> regs; // Encode instruction operands. let Inst{19-16} = Rn; let Inst{22} = regs{8}; let Inst{15-12} = regs{12-9}; let Inst{7-0} = regs{7-0}; let Inst{27-25} = 0b110; let Inst{11-9} = 0b101; let Inst{8} = 0; // Single precision } // Double precision, unary class ADuI opcod1, bits<2> opcod2, bits<4> opcod3, bits<2> opcod4, bit opcod5, dag oops, dag iops, InstrItinClass itin, string opc, string asm, string cstr, list pattern> : VFPAI { // Instruction operands. bits<5> Dd; bits<5> Dm; // Encode instruction operands. let Inst{3-0} = Dm{3-0}; let Inst{5} = Dm{4}; let Inst{15-12} = Dd{3-0}; let Inst{22} = Dd{4}; let Inst{27-23} = opcod1; let Inst{21-20} = opcod2; let Inst{19-16} = opcod3; let Inst{11-9} = 0b101; let Inst{8} = 1; // Double precision let Inst{7-6} = opcod4; let Inst{4} = opcod5; let Predicates = [HasVFP2, HasDPVFP]; } // Double precision, unary, not-predicated class ADuInp opcod1, bits<2> opcod2, bits<4> opcod3, bits<2> opcod4, bit opcod5, dag oops, dag iops, InstrItinClass itin, string asm, list pattern> : VFPXI { // Instruction operands. bits<5> Dd; bits<5> Dm; let Inst{31-28} = 0b1111; // Encode instruction operands. let Inst{3-0} = Dm{3-0}; let Inst{5} = Dm{4}; let Inst{15-12} = Dd{3-0}; let Inst{22} = Dd{4}; let Inst{27-23} = opcod1; let Inst{21-20} = opcod2; let Inst{19-16} = opcod3; let Inst{11-9} = 0b101; let Inst{8} = 1; // Double precision let Inst{7-6} = opcod4; let Inst{4} = opcod5; } // Double precision, binary class ADbI opcod1, bits<2> opcod2, bit op6, bit op4, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : VFPAI { // Instruction operands. bits<5> Dd; bits<5> Dn; bits<5> Dm; // Encode instruction operands. let Inst{3-0} = Dm{3-0}; let Inst{5} = Dm{4}; let Inst{19-16} = Dn{3-0}; let Inst{7} = Dn{4}; let Inst{15-12} = Dd{3-0}; let Inst{22} = Dd{4}; let Inst{27-23} = opcod1; let Inst{21-20} = opcod2; let Inst{11-9} = 0b101; let Inst{8} = 1; // Double precision let Inst{6} = op6; let Inst{4} = op4; let Predicates = [HasVFP2, HasDPVFP]; } // FP, binary, not predicated class ADbInp opcod1, bits<2> opcod2, bit opcod3, dag oops, dag iops, InstrItinClass itin, string asm, list pattern> : VFPXI { // Instruction operands. bits<5> Dd; bits<5> Dn; bits<5> Dm; let Inst{31-28} = 0b1111; // Encode instruction operands. let Inst{3-0} = Dm{3-0}; let Inst{5} = Dm{4}; let Inst{19-16} = Dn{3-0}; let Inst{7} = Dn{4}; let Inst{15-12} = Dd{3-0}; let Inst{22} = Dd{4}; let Inst{27-23} = opcod1; let Inst{21-20} = opcod2; let Inst{11-9} = 0b101; let Inst{8} = 1; // double precision let Inst{6} = opcod3; let Inst{4} = 0; let Predicates = [HasVFP2, HasDPVFP]; } // Single precision, unary, predicated class ASuI opcod1, bits<2> opcod2, bits<4> opcod3, bits<2> opcod4, bit opcod5, dag oops, dag iops, InstrItinClass itin, string opc, string asm, string cstr, list pattern> : VFPAI { // Instruction operands. bits<5> Sd; bits<5> Sm; // Encode instruction operands. let Inst{3-0} = Sm{4-1}; let Inst{5} = Sm{0}; let Inst{15-12} = Sd{4-1}; let Inst{22} = Sd{0}; let Inst{27-23} = opcod1; let Inst{21-20} = opcod2; let Inst{19-16} = opcod3; let Inst{11-9} = 0b101; let Inst{8} = 0; // Single precision let Inst{7-6} = opcod4; let Inst{4} = opcod5; } // Single precision, unary, non-predicated class ASuInp opcod1, bits<2> opcod2, bits<4> opcod3, bits<2> opcod4, bit opcod5, dag oops, dag iops, InstrItinClass itin, string asm, list pattern> : VFPXI { // Instruction operands. bits<5> Sd; bits<5> Sm; let Inst{31-28} = 0b1111; // Encode instruction operands. let Inst{3-0} = Sm{4-1}; let Inst{5} = Sm{0}; let Inst{15-12} = Sd{4-1}; let Inst{22} = Sd{0}; let Inst{27-23} = opcod1; let Inst{21-20} = opcod2; let Inst{19-16} = opcod3; let Inst{11-9} = 0b101; let Inst{8} = 0; // Single precision let Inst{7-6} = opcod4; let Inst{4} = opcod5; } // Single precision unary, if no NEON. Same as ASuI except not available if // NEON is enabled. class ASuIn opcod1, bits<2> opcod2, bits<4> opcod3, bits<2> opcod4, bit opcod5, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : ASuI { list Predicates = [HasVFP2,DontUseNEONForFP]; } // Single precision, binary class ASbI opcod1, bits<2> opcod2, bit op6, bit op4, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : VFPAI { // Instruction operands. bits<5> Sd; bits<5> Sn; bits<5> Sm; // Encode instruction operands. let Inst{3-0} = Sm{4-1}; let Inst{5} = Sm{0}; let Inst{19-16} = Sn{4-1}; let Inst{7} = Sn{0}; let Inst{15-12} = Sd{4-1}; let Inst{22} = Sd{0}; let Inst{27-23} = opcod1; let Inst{21-20} = opcod2; let Inst{11-9} = 0b101; let Inst{8} = 0; // Single precision let Inst{6} = op6; let Inst{4} = op4; } // Single precision, binary, not predicated class ASbInp opcod1, bits<2> opcod2, bit opcod3, dag oops, dag iops, InstrItinClass itin, string asm, list pattern> : VFPXI { // Instruction operands. bits<5> Sd; bits<5> Sn; bits<5> Sm; let Inst{31-28} = 0b1111; // Encode instruction operands. let Inst{3-0} = Sm{4-1}; let Inst{5} = Sm{0}; let Inst{19-16} = Sn{4-1}; let Inst{7} = Sn{0}; let Inst{15-12} = Sd{4-1}; let Inst{22} = Sd{0}; let Inst{27-23} = opcod1; let Inst{21-20} = opcod2; let Inst{11-9} = 0b101; let Inst{8} = 0; // Single precision let Inst{6} = opcod3; let Inst{4} = 0; } // Single precision binary, if no NEON. Same as ASbI except not available if // NEON is enabled. class ASbIn opcod1, bits<2> opcod2, bit op6, bit op4, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : ASbI { list Predicates = [HasVFP2,DontUseNEONForFP]; // Instruction operands. bits<5> Sd; bits<5> Sn; bits<5> Sm; // Encode instruction operands. let Inst{3-0} = Sm{4-1}; let Inst{5} = Sm{0}; let Inst{19-16} = Sn{4-1}; let Inst{7} = Sn{0}; let Inst{15-12} = Sd{4-1}; let Inst{22} = Sd{0}; } // Half precision, unary, predicated class AHuI opcod1, bits<2> opcod2, bits<4> opcod3, bits<2> opcod4, bit opcod5, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : VFPAI { list Predicates = [HasFullFP16]; // Instruction operands. bits<5> Sd; bits<5> Sm; // Encode instruction operands. let Inst{3-0} = Sm{4-1}; let Inst{5} = Sm{0}; let Inst{15-12} = Sd{4-1}; let Inst{22} = Sd{0}; let Inst{27-23} = opcod1; let Inst{21-20} = opcod2; let Inst{19-16} = opcod3; let Inst{11-8} = 0b1001; // Half precision let Inst{7-6} = opcod4; let Inst{4} = opcod5; let isUnpredicable = 1; // FP16 instructions cannot in general be conditional } // Half precision, unary, non-predicated class AHuInp opcod1, bits<2> opcod2, bits<4> opcod3, bits<2> opcod4, bit opcod5, dag oops, dag iops, InstrItinClass itin, string asm, list pattern> : VFPXI { list Predicates = [HasFullFP16]; // Instruction operands. bits<5> Sd; bits<5> Sm; let Inst{31-28} = 0b1111; // Encode instruction operands. let Inst{3-0} = Sm{4-1}; let Inst{5} = Sm{0}; let Inst{15-12} = Sd{4-1}; let Inst{22} = Sd{0}; let Inst{27-23} = opcod1; let Inst{21-20} = opcod2; let Inst{19-16} = opcod3; let Inst{11-8} = 0b1001; // Half precision let Inst{7-6} = opcod4; let Inst{4} = opcod5; let isUnpredicable = 1; // FP16 instructions cannot in general be conditional } // Half precision, binary class AHbI opcod1, bits<2> opcod2, bit op6, bit op4, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : VFPAI { list Predicates = [HasFullFP16]; // Instruction operands. bits<5> Sd; bits<5> Sn; bits<5> Sm; // Encode instruction operands. let Inst{3-0} = Sm{4-1}; let Inst{5} = Sm{0}; let Inst{19-16} = Sn{4-1}; let Inst{7} = Sn{0}; let Inst{15-12} = Sd{4-1}; let Inst{22} = Sd{0}; let Inst{27-23} = opcod1; let Inst{21-20} = opcod2; let Inst{11-8} = 0b1001; // Half precision let Inst{6} = op6; let Inst{4} = op4; let isUnpredicable = 1; // FP16 instructions cannot in general be conditional } // Half precision, binary, not predicated class AHbInp opcod1, bits<2> opcod2, bit opcod3, dag oops, dag iops, InstrItinClass itin, string asm, list pattern> : VFPXI { list Predicates = [HasFullFP16]; // Instruction operands. bits<5> Sd; bits<5> Sn; bits<5> Sm; let Inst{31-28} = 0b1111; // Encode instruction operands. let Inst{3-0} = Sm{4-1}; let Inst{5} = Sm{0}; let Inst{19-16} = Sn{4-1}; let Inst{7} = Sn{0}; let Inst{15-12} = Sd{4-1}; let Inst{22} = Sd{0}; let Inst{27-23} = opcod1; let Inst{21-20} = opcod2; let Inst{11-8} = 0b1001; // Half precision let Inst{6} = opcod3; let Inst{4} = 0; let isUnpredicable = 1; // FP16 instructions cannot in general be conditional } // VFP conversion instructions class AVConv1I opcod1, bits<2> opcod2, bits<4> opcod3, bits<4> opcod4, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : VFPAI { let Inst{27-23} = opcod1; let Inst{21-20} = opcod2; let Inst{19-16} = opcod3; let Inst{11-8} = opcod4; let Inst{6} = 1; let Inst{4} = 0; } // VFP conversion between floating-point and fixed-point class AVConv1XI op1, bits<2> op2, bits<4> op3, bits<4> op4, bit op5, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AVConv1I { bits<5> fbits; // size (fixed-point number): sx == 0 ? 16 : 32 let Inst{7} = op5; // sx let Inst{5} = fbits{0}; let Inst{3-0} = fbits{4-1}; } // VFP conversion instructions, if no NEON class AVConv1In opcod1, bits<2> opcod2, bits<4> opcod3, bits<4> opcod4, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AVConv1I { list Predicates = [HasVFP2,DontUseNEONForFP]; } class AVConvXI opcod1, bits<4> opcod2, dag oops, dag iops, Format f, InstrItinClass itin, string opc, string asm, list pattern> : VFPAI { let Inst{27-20} = opcod1; let Inst{11-8} = opcod2; let Inst{4} = 1; } class AVConv2I opcod1, bits<4> opcod2, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AVConvXI; class AVConv3I opcod1, bits<4> opcod2, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AVConvXI; class AVConv4I opcod1, bits<4> opcod2, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AVConvXI; class AVConv5I opcod1, bits<4> opcod2, dag oops, dag iops, InstrItinClass itin, string opc, string asm, list pattern> : AVConvXI; //===----------------------------------------------------------------------===// //===----------------------------------------------------------------------===// // ARM NEON Instruction templates. // class NeonI pattern> : InstARM { let OutOperandList = oops; let InOperandList = !con(iops, (ins pred:$p)); let AsmString = !strconcat(opc, "${p}", ".", dt, "\t", asm); let Pattern = pattern; list Predicates = [HasNEON]; let DecoderNamespace = "NEON"; } // Same as NeonI except it does not have a "data type" specifier. class NeonXI pattern> : InstARM { let OutOperandList = oops; let InOperandList = !con(iops, (ins pred:$p)); let AsmString = !strconcat(opc, "${p}", "\t", asm); let Pattern = pattern; list Predicates = [HasNEON]; let DecoderNamespace = "NEON"; } // Same as NeonI except it is not predicated class NeonInp pattern> : InstARM { let OutOperandList = oops; let InOperandList = iops; let AsmString = !strconcat(opc, ".", dt, "\t", asm); let Pattern = pattern; list Predicates = [HasNEON]; let DecoderNamespace = "NEON"; let Inst{31-28} = 0b1111; } class NLdSt op21_20, bits<4> op11_8, bits<4> op7_4, dag oops, dag iops, InstrItinClass itin, string opc, string dt, string asm, string cstr, list pattern> : NeonI { let Inst{31-24} = 0b11110100; let Inst{23} = op23; let Inst{21-20} = op21_20; let Inst{11-8} = op11_8; let Inst{7-4} = op7_4; let PostEncoderMethod = "NEONThumb2LoadStorePostEncoder"; let DecoderNamespace = "NEONLoadStore"; bits<5> Vd; bits<6> Rn; bits<4> Rm; let Inst{22} = Vd{4}; let Inst{15-12} = Vd{3-0}; let Inst{19-16} = Rn{3-0}; let Inst{3-0} = Rm{3-0}; } class NLdStLn op21_20, bits<4> op11_8, bits<4> op7_4, dag oops, dag iops, InstrItinClass itin, string opc, string dt, string asm, string cstr, list pattern> : NLdSt { bits<3> lane; } class PseudoNLdSt : InstARM { let OutOperandList = oops; let InOperandList = !con(iops, (ins pred:$p)); list Predicates = [HasNEON]; } class PseudoNeonI pattern> : InstARM { let OutOperandList = oops; let InOperandList = !con(iops, (ins pred:$p)); let Pattern = pattern; list Predicates = [HasNEON]; } class NDataI pattern> : NeonI { let Inst{31-25} = 0b1111001; let PostEncoderMethod = "NEONThumb2DataIPostEncoder"; let DecoderNamespace = "NEONData"; } class NDataXI pattern> : NeonXI { let Inst{31-25} = 0b1111001; let PostEncoderMethod = "NEONThumb2DataIPostEncoder"; let DecoderNamespace = "NEONData"; } // NEON "one register and a modified immediate" format. class N1ModImm op21_19, bits<4> op11_8, bit op7, bit op6, bit op5, bit op4, dag oops, dag iops, InstrItinClass itin, string opc, string dt, string asm, string cstr, list pattern> : NDataI { let Inst{23} = op23; let Inst{21-19} = op21_19; let Inst{11-8} = op11_8; let Inst{7} = op7; let Inst{6} = op6; let Inst{5} = op5; let Inst{4} = op4; // Instruction operands. bits<5> Vd; bits<13> SIMM; let Inst{15-12} = Vd{3-0}; let Inst{22} = Vd{4}; let Inst{24} = SIMM{7}; let Inst{18-16} = SIMM{6-4}; let Inst{3-0} = SIMM{3-0}; let DecoderMethod = "DecodeVMOVModImmInstruction"; } // NEON 2 vector register format. class N2V op24_23, bits<2> op21_20, bits<2> op19_18, bits<2> op17_16, bits<5> op11_7, bit op6, bit op4, dag oops, dag iops, InstrItinClass itin, string opc, string dt, string asm, string cstr, list pattern> : NDataI { let Inst{24-23} = op24_23; let Inst{21-20} = op21_20; let Inst{19-18} = op19_18; let Inst{17-16} = op17_16; let Inst{11-7} = op11_7; let Inst{6} = op6; let Inst{4} = op4; // Instruction operands. bits<5> Vd; bits<5> Vm; let Inst{15-12} = Vd{3-0}; let Inst{22} = Vd{4}; let Inst{3-0} = Vm{3-0}; let Inst{5} = Vm{4}; } // Same as N2V but not predicated. class N2Vnp op19_18, bits<2> op17_16, bits<3> op10_8, bit op7, bit op6, dag oops, dag iops, InstrItinClass itin, string OpcodeStr, string Dt, list pattern> : NeonInp { bits<5> Vd; bits<5> Vm; // Encode instruction operands let Inst{22} = Vd{4}; let Inst{15-12} = Vd{3-0}; let Inst{5} = Vm{4}; let Inst{3-0} = Vm{3-0}; // Encode constant bits let Inst{27-23} = 0b00111; let Inst{21-20} = 0b11; let Inst{19-18} = op19_18; let Inst{17-16} = op17_16; let Inst{11} = 0; let Inst{10-8} = op10_8; let Inst{7} = op7; let Inst{6} = op6; let Inst{4} = 0; let DecoderNamespace = "NEON"; } // Same as N2V except it doesn't have a datatype suffix. class N2VX op24_23, bits<2> op21_20, bits<2> op19_18, bits<2> op17_16, bits<5> op11_7, bit op6, bit op4, dag oops, dag iops, InstrItinClass itin, string opc, string asm, string cstr, list pattern> : NDataXI { let Inst{24-23} = op24_23; let Inst{21-20} = op21_20; let Inst{19-18} = op19_18; let Inst{17-16} = op17_16; let Inst{11-7} = op11_7; let Inst{6} = op6; let Inst{4} = op4; // Instruction operands. bits<5> Vd; bits<5> Vm; let Inst{15-12} = Vd{3-0}; let Inst{22} = Vd{4}; let Inst{3-0} = Vm{3-0}; let Inst{5} = Vm{4}; } // NEON 2 vector register with immediate. class N2VImm op11_8, bit op7, bit op6, bit op4, dag oops, dag iops, Format f, InstrItinClass itin, string opc, string dt, string asm, string cstr, list pattern> : NDataI { let Inst{24} = op24; let Inst{23} = op23; let Inst{11-8} = op11_8; let Inst{7} = op7; let Inst{6} = op6; let Inst{4} = op4; // Instruction operands. bits<5> Vd; bits<5> Vm; bits<6> SIMM; let Inst{15-12} = Vd{3-0}; let Inst{22} = Vd{4}; let Inst{3-0} = Vm{3-0}; let Inst{5} = Vm{4}; let Inst{21-16} = SIMM{5-0}; } // NEON 3 vector register format. class N3VCommon op21_20, bits<4> op11_8, bit op6, bit op4, dag oops, dag iops, Format f, InstrItinClass itin, string opc, string dt, string asm, string cstr, list pattern> : NDataI { let Inst{24} = op24; let Inst{23} = op23; let Inst{21-20} = op21_20; let Inst{11-8} = op11_8; let Inst{6} = op6; let Inst{4} = op4; } class N3V op21_20, bits<4> op11_8, bit op6, bit op4, dag oops, dag iops, Format f, InstrItinClass itin, string opc, string dt, string asm, string cstr, list pattern> : N3VCommon { // Instruction operands. bits<5> Vd; bits<5> Vn; bits<5> Vm; let Inst{15-12} = Vd{3-0}; let Inst{22} = Vd{4}; let Inst{19-16} = Vn{3-0}; let Inst{7} = Vn{4}; let Inst{3-0} = Vm{3-0}; let Inst{5} = Vm{4}; } class N3Vnp op27_23, bits<2> op21_20, bits<4> op11_8, bit op6, bit op4, dag oops, dag iops,Format f, InstrItinClass itin, string OpcodeStr, string Dt, list pattern> : NeonInp { bits<5> Vd; bits<5> Vn; bits<5> Vm; // Encode instruction operands let Inst{22} = Vd{4}; let Inst{15-12} = Vd{3-0}; let Inst{19-16} = Vn{3-0}; let Inst{7} = Vn{4}; let Inst{5} = Vm{4}; let Inst{3-0} = Vm{3-0}; // Encode constant bits let Inst{27-23} = op27_23; let Inst{21-20} = op21_20; let Inst{11-8} = op11_8; let Inst{6} = op6; let Inst{4} = op4; } class N3VLane32 op21_20, bits<4> op11_8, bit op6, bit op4, dag oops, dag iops, Format f, InstrItinClass itin, string opc, string dt, string asm, string cstr, list pattern> : N3VCommon { // Instruction operands. bits<5> Vd; bits<5> Vn; bits<5> Vm; bit lane; let Inst{15-12} = Vd{3-0}; let Inst{22} = Vd{4}; let Inst{19-16} = Vn{3-0}; let Inst{7} = Vn{4}; let Inst{3-0} = Vm{3-0}; let Inst{5} = lane; } class N3VLane16 op21_20, bits<4> op11_8, bit op6, bit op4, dag oops, dag iops, Format f, InstrItinClass itin, string opc, string dt, string asm, string cstr, list pattern> : N3VCommon { // Instruction operands. bits<5> Vd; bits<5> Vn; bits<5> Vm; bits<2> lane; let Inst{15-12} = Vd{3-0}; let Inst{22} = Vd{4}; let Inst{19-16} = Vn{3-0}; let Inst{7} = Vn{4}; let Inst{2-0} = Vm{2-0}; let Inst{5} = lane{1}; let Inst{3} = lane{0}; } // Same as N3V except it doesn't have a data type suffix. class N3VX op21_20, bits<4> op11_8, bit op6, bit op4, dag oops, dag iops, Format f, InstrItinClass itin, string opc, string asm, string cstr, list pattern> : NDataXI { let Inst{24} = op24; let Inst{23} = op23; let Inst{21-20} = op21_20; let Inst{11-8} = op11_8; let Inst{6} = op6; let Inst{4} = op4; // Instruction operands. bits<5> Vd; bits<5> Vn; bits<5> Vm; let Inst{15-12} = Vd{3-0}; let Inst{22} = Vd{4}; let Inst{19-16} = Vn{3-0}; let Inst{7} = Vn{4}; let Inst{3-0} = Vm{3-0}; let Inst{5} = Vm{4}; } // NEON VMOVs between scalar and core registers. class NVLaneOp opcod1, bits<4> opcod2, bits<2> opcod3, dag oops, dag iops, Format f, InstrItinClass itin, string opc, string dt, string asm, list pattern> : InstARM { let Inst{27-20} = opcod1; let Inst{11-8} = opcod2; let Inst{6-5} = opcod3; let Inst{4} = 1; // A8.6.303, A8.6.328, A8.6.329 let Inst{3-0} = 0b0000; let OutOperandList = oops; let InOperandList = !con(iops, (ins pred:$p)); let AsmString = !strconcat(opc, "${p}", ".", dt, "\t", asm); let Pattern = pattern; list Predicates = [HasNEON]; let PostEncoderMethod = "NEONThumb2DupPostEncoder"; let DecoderNamespace = "NEONDup"; bits<5> V; bits<4> R; bits<4> p; bits<4> lane; let Inst{31-28} = p{3-0}; let Inst{7} = V{4}; let Inst{19-16} = V{3-0}; let Inst{15-12} = R{3-0}; } class NVGetLane opcod1, bits<4> opcod2, bits<2> opcod3, dag oops, dag iops, InstrItinClass itin, string opc, string dt, string asm, list pattern> : NVLaneOp; class NVSetLane opcod1, bits<4> opcod2, bits<2> opcod3, dag oops, dag iops, InstrItinClass itin, string opc, string dt, string asm, list pattern> : NVLaneOp; class NVDup opcod1, bits<4> opcod2, bits<2> opcod3, dag oops, dag iops, InstrItinClass itin, string opc, string dt, string asm, list pattern> : NVLaneOp; // Vector Duplicate Lane (from scalar to all elements) class NVDupLane op19_16, bit op6, dag oops, dag iops, InstrItinClass itin, string opc, string dt, string asm, list pattern> : NDataI { let Inst{24-23} = 0b11; let Inst{21-20} = 0b11; let Inst{19-16} = op19_16; let Inst{11-7} = 0b11000; let Inst{6} = op6; let Inst{4} = 0; bits<5> Vd; bits<5> Vm; let Inst{22} = Vd{4}; let Inst{15-12} = Vd{3-0}; let Inst{5} = Vm{4}; let Inst{3-0} = Vm{3-0}; } // NEONFPPat - Same as Pat<>, but requires that the compiler be using NEON // for single-precision FP. class NEONFPPat : Pat { list Predicates = [HasNEON,UseNEONForFP]; } // VFP/NEON Instruction aliases for type suffices. // Note: When EmitPriority == 1, the alias will be used for printing class VFPDataTypeInstAlias : InstAlias, Requires<[HasFPRegs]>; // Note: When EmitPriority == 1, the alias will be used for printing multiclass VFPDTAnyInstAlias { def : VFPDataTypeInstAlias; def : VFPDataTypeInstAlias; def : VFPDataTypeInstAlias; def : VFPDataTypeInstAlias; } // Note: When EmitPriority == 1, the alias will be used for printing multiclass NEONDTAnyInstAlias { let Predicates = [HasNEON] in { def : VFPDataTypeInstAlias; def : VFPDataTypeInstAlias; def : VFPDataTypeInstAlias; def : VFPDataTypeInstAlias; } } // The same alias classes using AsmPseudo instead, for the more complex // stuff in NEON that InstAlias can't quite handle. // Note that we can't use anonymous defm references here like we can // above, as we care about the ultimate instruction enum names generated, unlike // for instalias defs. class NEONDataTypeAsmPseudoInst : AsmPseudoInst, Requires<[HasNEON]>; // Extension of NEON 3-vector data processing instructions in coprocessor 8 // encoding space, introduced in ARMv8.3-A. class N3VCP8 op24_23, bits<2> op21_20, bit op6, bit op4, dag oops, dag iops, InstrItinClass itin, string opc, string dt, string asm, string cstr, list pattern> : NeonInp { bits<5> Vd; bits<5> Vn; bits<5> Vm; let DecoderNamespace = "VFPV8"; // These have the same encodings in ARM and Thumb2 let PostEncoderMethod = ""; let Inst{31-25} = 0b1111110; let Inst{24-23} = op24_23; let Inst{22} = Vd{4}; let Inst{21-20} = op21_20; let Inst{19-16} = Vn{3-0}; let Inst{15-12} = Vd{3-0}; let Inst{11-8} = 0b1000; let Inst{7} = Vn{4}; let Inst{6} = op6; let Inst{5} = Vm{4}; let Inst{4} = op4; let Inst{3-0} = Vm{3-0}; } // Extension of NEON 2-vector-and-scalar data processing instructions in // coprocessor 8 encoding space, introduced in ARMv8.3-A. class N3VLaneCP8 op21_20, bit op6, bit op4, dag oops, dag iops, InstrItinClass itin, string opc, string dt, string asm, string cstr, list pattern> : NeonInp { bits<5> Vd; bits<5> Vn; bits<5> Vm; let DecoderNamespace = "VFPV8"; // These have the same encodings in ARM and Thumb2 let PostEncoderMethod = ""; let Inst{31-24} = 0b11111110; let Inst{23} = op23; let Inst{22} = Vd{4}; let Inst{21-20} = op21_20; let Inst{19-16} = Vn{3-0}; let Inst{15-12} = Vd{3-0}; let Inst{11-8} = 0b1000; let Inst{7} = Vn{4}; let Inst{6} = op6; // Bit 5 set by sub-classes let Inst{4} = op4; let Inst{3-0} = Vm{3-0}; } // In Armv8.2-A, some NEON instructions are added that encode Vn and Vm // differently: // if Q == ‘1’ then UInt(N:Vn) else UInt(Vn:N); // if Q == ‘1’ then UInt(M:Vm) else UInt(Vm:M); // Class N3VCP8 above describes the Q=1 case, and this class the Q=0 case. class N3VCP8Q0 op24_23, bits<2> op21_20, bit op6, bit op4, dag oops, dag iops, InstrItinClass itin, string opc, string dt, string asm, string cstr, list pattern> : NeonInp { bits<5> Vd; bits<5> Vn; bits<5> Vm; let DecoderNamespace = "VFPV8"; // These have the same encodings in ARM and Thumb2 let PostEncoderMethod = ""; let Inst{31-25} = 0b1111110; let Inst{24-23} = op24_23; let Inst{22} = Vd{4}; let Inst{21-20} = op21_20; let Inst{19-16} = Vn{4-1}; let Inst{15-12} = Vd{3-0}; let Inst{11-8} = 0b1000; let Inst{7} = Vn{0}; let Inst{6} = op6; let Inst{5} = Vm{0}; let Inst{4} = op4; let Inst{3-0} = Vm{4-1}; } // Operand types for complex instructions class ComplexRotationOperand : AsmOperandClass { let PredicateMethod = "isComplexRotation<" # Angle # ", " # Remainder # ">"; let DiagnosticString = "complex rotation must be " # Diag; let Name = "ComplexRotation" # Type; } def complexrotateop : Operand { let ParserMatchClass = ComplexRotationOperand<90, 0, "Even", "0, 90, 180 or 270">; let PrintMethod = "printComplexRotationOp<90, 0>"; } def complexrotateopodd : Operand { let ParserMatchClass = ComplexRotationOperand<180, 90, "Odd", "90 or 270">; let PrintMethod = "printComplexRotationOp<180, 90>"; } def MveSaturateOperand : AsmOperandClass { let PredicateMethod = "isMveSaturateOp"; let DiagnosticString = "saturate operand must be 48 or 64"; let Name = "MveSaturate"; } def saturateop : Operand { let ParserMatchClass = MveSaturateOperand; let PrintMethod = "printMveSaturateOp"; } // Data type suffix token aliases. Implements Table A7-3 in the ARM ARM. def : TokenAlias<".s8", ".i8">; def : TokenAlias<".u8", ".i8">; def : TokenAlias<".s16", ".i16">; def : TokenAlias<".u16", ".i16">; def : TokenAlias<".s32", ".i32">; def : TokenAlias<".u32", ".i32">; def : TokenAlias<".s64", ".i64">; def : TokenAlias<".u64", ".i64">; def : TokenAlias<".i8", ".8">; def : TokenAlias<".i16", ".16">; def : TokenAlias<".i32", ".32">; def : TokenAlias<".i64", ".64">; def : TokenAlias<".p8", ".8">; def : TokenAlias<".p16", ".16">; def : TokenAlias<".f32", ".32">; def : TokenAlias<".f64", ".64">; def : TokenAlias<".f", ".f32">; def : TokenAlias<".d", ".f64">;