//===- AArch64InstrFormats.td - AArch64 Instruction Formats --*- tblgen -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// //===----------------------------------------------------------------------===// // Describe AArch64 instructions format here // // 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<2> Value = val; } def PseudoFrm : Format<0>; def NormalFrm : Format<1>; // Do we need any others? // AArch64 Instruction Format class AArch64Inst : Instruction { field bits<32> Inst; // Instruction encoding. // 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; let Namespace = "AArch64"; Format F = f; bits<2> Form = F.Value; let Pattern = []; let Constraints = cstr; } // Pseudo instructions (don't have encoding information) class Pseudo pattern, string cstr = ""> : AArch64Inst { dag OutOperandList = oops; dag InOperandList = iops; let Pattern = pattern; let isCodeGenOnly = 1; } // Real instructions (have encoding information) class EncodedI pattern> : AArch64Inst { let Pattern = pattern; let Size = 4; } // Normal instructions class I pattern> : EncodedI { dag OutOperandList = oops; dag InOperandList = iops; let AsmString = !strconcat(asm, operands); } class TriOpFrag : PatFrag<(ops node:$LHS, node:$MHS, node:$RHS), res>; class BinOpFrag : PatFrag<(ops node:$LHS, node:$RHS), res>; class UnOpFrag : PatFrag<(ops node:$LHS), res>; // Helper fragment for an extract of the high portion of a 128-bit vector. def extract_high_v16i8 : UnOpFrag<(extract_subvector (v16i8 node:$LHS), (i64 8))>; def extract_high_v8i16 : UnOpFrag<(extract_subvector (v8i16 node:$LHS), (i64 4))>; def extract_high_v4i32 : UnOpFrag<(extract_subvector (v4i32 node:$LHS), (i64 2))>; def extract_high_v2i64 : UnOpFrag<(extract_subvector (v2i64 node:$LHS), (i64 1))>; //===----------------------------------------------------------------------===// // Asm Operand Classes. // // Shifter operand for arithmetic shifted encodings. def ShifterOperand : AsmOperandClass { let Name = "Shifter"; } // Shifter operand for mov immediate encodings. def MovImm32ShifterOperand : AsmOperandClass { let SuperClasses = [ShifterOperand]; let Name = "MovImm32Shifter"; let RenderMethod = "addShifterOperands"; let DiagnosticType = "InvalidMovImm32Shift"; } def MovImm64ShifterOperand : AsmOperandClass { let SuperClasses = [ShifterOperand]; let Name = "MovImm64Shifter"; let RenderMethod = "addShifterOperands"; let DiagnosticType = "InvalidMovImm64Shift"; } // Shifter operand for arithmetic register shifted encodings. class ArithmeticShifterOperand : AsmOperandClass { let SuperClasses = [ShifterOperand]; let Name = "ArithmeticShifter" # width; let PredicateMethod = "isArithmeticShifter<" # width # ">"; let RenderMethod = "addShifterOperands"; let DiagnosticType = "AddSubRegShift" # width; } def ArithmeticShifterOperand32 : ArithmeticShifterOperand<32>; def ArithmeticShifterOperand64 : ArithmeticShifterOperand<64>; // Shifter operand for logical register shifted encodings. class LogicalShifterOperand : AsmOperandClass { let SuperClasses = [ShifterOperand]; let Name = "LogicalShifter" # width; let PredicateMethod = "isLogicalShifter<" # width # ">"; let RenderMethod = "addShifterOperands"; let DiagnosticType = "AddSubRegShift" # width; } def LogicalShifterOperand32 : LogicalShifterOperand<32>; def LogicalShifterOperand64 : LogicalShifterOperand<64>; // Shifter operand for logical vector 128/64-bit shifted encodings. def LogicalVecShifterOperand : AsmOperandClass { let SuperClasses = [ShifterOperand]; let Name = "LogicalVecShifter"; let RenderMethod = "addShifterOperands"; } def LogicalVecHalfWordShifterOperand : AsmOperandClass { let SuperClasses = [LogicalVecShifterOperand]; let Name = "LogicalVecHalfWordShifter"; let RenderMethod = "addShifterOperands"; } // The "MSL" shifter on the vector MOVI instruction. def MoveVecShifterOperand : AsmOperandClass { let SuperClasses = [ShifterOperand]; let Name = "MoveVecShifter"; let RenderMethod = "addShifterOperands"; } // Extend operand for arithmetic encodings. def ExtendOperand : AsmOperandClass { let Name = "Extend"; let DiagnosticType = "AddSubRegExtendLarge"; } def ExtendOperand64 : AsmOperandClass { let SuperClasses = [ExtendOperand]; let Name = "Extend64"; let DiagnosticType = "AddSubRegExtendSmall"; } // 'extend' that's a lsl of a 64-bit register. def ExtendOperandLSL64 : AsmOperandClass { let SuperClasses = [ExtendOperand]; let Name = "ExtendLSL64"; let RenderMethod = "addExtend64Operands"; let DiagnosticType = "AddSubRegExtendLarge"; } // 8-bit floating-point immediate encodings. def FPImmOperand : AsmOperandClass { let Name = "FPImm"; let ParserMethod = "tryParseFPImm"; let DiagnosticType = "InvalidFPImm"; } def CondCode : AsmOperandClass { let Name = "CondCode"; let DiagnosticType = "InvalidCondCode"; } // A 32-bit register pasrsed as 64-bit def GPR32as64Operand : AsmOperandClass { let Name = "GPR32as64"; } def GPR32as64 : RegisterOperand { let ParserMatchClass = GPR32as64Operand; } // 8-bit immediate for AdvSIMD where 64-bit values of the form: // aaaaaaaa bbbbbbbb cccccccc dddddddd eeeeeeee ffffffff gggggggg hhhhhhhh // are encoded as the eight bit value 'abcdefgh'. def SIMDImmType10Operand : AsmOperandClass { let Name = "SIMDImmType10"; } //===----------------------------------------------------------------------===// // Operand Definitions. // // ADR[P] instruction labels. def AdrpOperand : AsmOperandClass { let Name = "AdrpLabel"; let ParserMethod = "tryParseAdrpLabel"; let DiagnosticType = "InvalidLabel"; } def adrplabel : Operand { let EncoderMethod = "getAdrLabelOpValue"; let PrintMethod = "printAdrpLabel"; let ParserMatchClass = AdrpOperand; } def AdrOperand : AsmOperandClass { let Name = "AdrLabel"; let ParserMethod = "tryParseAdrLabel"; let DiagnosticType = "InvalidLabel"; } def adrlabel : Operand { let EncoderMethod = "getAdrLabelOpValue"; let ParserMatchClass = AdrOperand; } // simm9 predicate - True if the immediate is in the range [-256, 255]. def SImm9Operand : AsmOperandClass { let Name = "SImm9"; let DiagnosticType = "InvalidMemoryIndexedSImm9"; } def simm9 : Operand, ImmLeaf= -256 && Imm < 256; }]> { let ParserMatchClass = SImm9Operand; } // simm7sN predicate - True if the immediate is a multiple of N in the range // [-64 * N, 63 * N]. class SImm7Scaled : AsmOperandClass { let Name = "SImm7s" # Scale; let DiagnosticType = "InvalidMemoryIndexed" # Scale # "SImm7"; } def SImm7s4Operand : SImm7Scaled<4>; def SImm7s8Operand : SImm7Scaled<8>; def SImm7s16Operand : SImm7Scaled<16>; def simm7s4 : Operand { let ParserMatchClass = SImm7s4Operand; let PrintMethod = "printImmScale<4>"; } def simm7s8 : Operand { let ParserMatchClass = SImm7s8Operand; let PrintMethod = "printImmScale<8>"; } def simm7s16 : Operand { let ParserMatchClass = SImm7s16Operand; let PrintMethod = "printImmScale<16>"; } class AsmImmRange : AsmOperandClass { let Name = "Imm" # Low # "_" # High; let DiagnosticType = "InvalidImm" # Low # "_" # High; } def Imm1_8Operand : AsmImmRange<1, 8>; def Imm1_16Operand : AsmImmRange<1, 16>; def Imm1_32Operand : AsmImmRange<1, 32>; def Imm1_64Operand : AsmImmRange<1, 64>; def MovZSymbolG3AsmOperand : AsmOperandClass { let Name = "MovZSymbolG3"; let RenderMethod = "addImmOperands"; } def movz_symbol_g3 : Operand { let ParserMatchClass = MovZSymbolG3AsmOperand; } def MovZSymbolG2AsmOperand : AsmOperandClass { let Name = "MovZSymbolG2"; let RenderMethod = "addImmOperands"; } def movz_symbol_g2 : Operand { let ParserMatchClass = MovZSymbolG2AsmOperand; } def MovZSymbolG1AsmOperand : AsmOperandClass { let Name = "MovZSymbolG1"; let RenderMethod = "addImmOperands"; } def movz_symbol_g1 : Operand { let ParserMatchClass = MovZSymbolG1AsmOperand; } def MovZSymbolG0AsmOperand : AsmOperandClass { let Name = "MovZSymbolG0"; let RenderMethod = "addImmOperands"; } def movz_symbol_g0 : Operand { let ParserMatchClass = MovZSymbolG0AsmOperand; } def MovKSymbolG3AsmOperand : AsmOperandClass { let Name = "MovKSymbolG3"; let RenderMethod = "addImmOperands"; } def movk_symbol_g3 : Operand { let ParserMatchClass = MovKSymbolG3AsmOperand; } def MovKSymbolG2AsmOperand : AsmOperandClass { let Name = "MovKSymbolG2"; let RenderMethod = "addImmOperands"; } def movk_symbol_g2 : Operand { let ParserMatchClass = MovKSymbolG2AsmOperand; } def MovKSymbolG1AsmOperand : AsmOperandClass { let Name = "MovKSymbolG1"; let RenderMethod = "addImmOperands"; } def movk_symbol_g1 : Operand { let ParserMatchClass = MovKSymbolG1AsmOperand; } def MovKSymbolG0AsmOperand : AsmOperandClass { let Name = "MovKSymbolG0"; let RenderMethod = "addImmOperands"; } def movk_symbol_g0 : Operand { let ParserMatchClass = MovKSymbolG0AsmOperand; } class fixedpoint_i32 : Operand, ComplexPattern", [fpimm, ld]> { let EncoderMethod = "getFixedPointScaleOpValue"; let DecoderMethod = "DecodeFixedPointScaleImm32"; let ParserMatchClass = Imm1_32Operand; } class fixedpoint_i64 : Operand, ComplexPattern", [fpimm, ld]> { let EncoderMethod = "getFixedPointScaleOpValue"; let DecoderMethod = "DecodeFixedPointScaleImm64"; let ParserMatchClass = Imm1_64Operand; } def fixedpoint_f32_i32 : fixedpoint_i32; def fixedpoint_f64_i32 : fixedpoint_i32; def fixedpoint_f32_i64 : fixedpoint_i64; def fixedpoint_f64_i64 : fixedpoint_i64; def vecshiftR8 : Operand, ImmLeaf 0) && (((uint32_t)Imm) < 9); }]> { let EncoderMethod = "getVecShiftR8OpValue"; let DecoderMethod = "DecodeVecShiftR8Imm"; let ParserMatchClass = Imm1_8Operand; } def vecshiftR16 : Operand, ImmLeaf 0) && (((uint32_t)Imm) < 17); }]> { let EncoderMethod = "getVecShiftR16OpValue"; let DecoderMethod = "DecodeVecShiftR16Imm"; let ParserMatchClass = Imm1_16Operand; } def vecshiftR16Narrow : Operand, ImmLeaf 0) && (((uint32_t)Imm) < 9); }]> { let EncoderMethod = "getVecShiftR16OpValue"; let DecoderMethod = "DecodeVecShiftR16ImmNarrow"; let ParserMatchClass = Imm1_8Operand; } def vecshiftR32 : Operand, ImmLeaf 0) && (((uint32_t)Imm) < 33); }]> { let EncoderMethod = "getVecShiftR32OpValue"; let DecoderMethod = "DecodeVecShiftR32Imm"; let ParserMatchClass = Imm1_32Operand; } def vecshiftR32Narrow : Operand, ImmLeaf 0) && (((uint32_t)Imm) < 17); }]> { let EncoderMethod = "getVecShiftR32OpValue"; let DecoderMethod = "DecodeVecShiftR32ImmNarrow"; let ParserMatchClass = Imm1_16Operand; } def vecshiftR64 : Operand, ImmLeaf 0) && (((uint32_t)Imm) < 65); }]> { let EncoderMethod = "getVecShiftR64OpValue"; let DecoderMethod = "DecodeVecShiftR64Imm"; let ParserMatchClass = Imm1_64Operand; } def vecshiftR64Narrow : Operand, ImmLeaf 0) && (((uint32_t)Imm) < 33); }]> { let EncoderMethod = "getVecShiftR64OpValue"; let DecoderMethod = "DecodeVecShiftR64ImmNarrow"; let ParserMatchClass = Imm1_32Operand; } def Imm0_7Operand : AsmImmRange<0, 7>; def Imm0_15Operand : AsmImmRange<0, 15>; def Imm0_31Operand : AsmImmRange<0, 31>; def Imm0_63Operand : AsmImmRange<0, 63>; def vecshiftL8 : Operand, ImmLeaf { let EncoderMethod = "getVecShiftL8OpValue"; let DecoderMethod = "DecodeVecShiftL8Imm"; let ParserMatchClass = Imm0_7Operand; } def vecshiftL16 : Operand, ImmLeaf { let EncoderMethod = "getVecShiftL16OpValue"; let DecoderMethod = "DecodeVecShiftL16Imm"; let ParserMatchClass = Imm0_15Operand; } def vecshiftL32 : Operand, ImmLeaf { let EncoderMethod = "getVecShiftL32OpValue"; let DecoderMethod = "DecodeVecShiftL32Imm"; let ParserMatchClass = Imm0_31Operand; } def vecshiftL64 : Operand, ImmLeaf { let EncoderMethod = "getVecShiftL64OpValue"; let DecoderMethod = "DecodeVecShiftL64Imm"; let ParserMatchClass = Imm0_63Operand; } // Crazy immediate formats used by 32-bit and 64-bit logical immediate // instructions for splatting repeating bit patterns across the immediate. def logical_imm32_XFORM : SDNodeXFormgetZExtValue(), 32); return CurDAG->getTargetConstant(enc, MVT::i32); }]>; def logical_imm64_XFORM : SDNodeXFormgetZExtValue(), 64); return CurDAG->getTargetConstant(enc, MVT::i32); }]>; def LogicalImm32Operand : AsmOperandClass { let Name = "LogicalImm32"; let DiagnosticType = "LogicalSecondSource"; } def LogicalImm64Operand : AsmOperandClass { let Name = "LogicalImm64"; let DiagnosticType = "LogicalSecondSource"; } def logical_imm32 : Operand, PatLeaf<(imm), [{ return AArch64_AM::isLogicalImmediate(N->getZExtValue(), 32); }], logical_imm32_XFORM> { let PrintMethod = "printLogicalImm32"; let ParserMatchClass = LogicalImm32Operand; } def logical_imm64 : Operand, PatLeaf<(imm), [{ return AArch64_AM::isLogicalImmediate(N->getZExtValue(), 64); }], logical_imm64_XFORM> { let PrintMethod = "printLogicalImm64"; let ParserMatchClass = LogicalImm64Operand; } // imm0_65535 predicate - True if the immediate is in the range [0,65535]. def Imm0_65535Operand : AsmImmRange<0, 65535>; def imm0_65535 : Operand, ImmLeaf { let ParserMatchClass = Imm0_65535Operand; let PrintMethod = "printHexImm"; } // imm0_255 predicate - True if the immediate is in the range [0,255]. def Imm0_255Operand : AsmOperandClass { let Name = "Imm0_255"; } def imm0_255 : Operand, ImmLeaf { let ParserMatchClass = Imm0_255Operand; let PrintMethod = "printHexImm"; } // imm0_127 predicate - True if the immediate is in the range [0,127] def Imm0_127Operand : AsmImmRange<0, 127>; def imm0_127 : Operand, ImmLeaf { let ParserMatchClass = Imm0_127Operand; let PrintMethod = "printHexImm"; } // NOTE: These imm0_N operands have to be of type i64 because i64 is the size // for all shift-amounts. // imm0_63 predicate - True if the immediate is in the range [0,63] def imm0_63 : Operand, ImmLeaf { let ParserMatchClass = Imm0_63Operand; } // imm0_31 predicate - True if the immediate is in the range [0,31] def imm0_31 : Operand, ImmLeaf { let ParserMatchClass = Imm0_31Operand; } // imm0_15 predicate - True if the immediate is in the range [0,15] def imm0_15 : Operand, ImmLeaf { let ParserMatchClass = Imm0_15Operand; } // imm0_7 predicate - True if the immediate is in the range [0,7] def imm0_7 : Operand, ImmLeaf { let ParserMatchClass = Imm0_7Operand; } // An arithmetic shifter operand: // {7-6} - shift type: 00 = lsl, 01 = lsr, 10 = asr // {5-0} - imm6 class arith_shift : Operand { let PrintMethod = "printShifter"; let ParserMatchClass = !cast( "ArithmeticShifterOperand" # width); } def arith_shift32 : arith_shift; def arith_shift64 : arith_shift; class arith_shifted_reg : Operand, ComplexPattern { let PrintMethod = "printShiftedRegister"; let MIOperandInfo = (ops regclass, !cast("arith_shift" # width)); } def arith_shifted_reg32 : arith_shifted_reg; def arith_shifted_reg64 : arith_shifted_reg; // An arithmetic shifter operand: // {7-6} - shift type: 00 = lsl, 01 = lsr, 10 = asr, 11 = ror // {5-0} - imm6 class logical_shift : Operand { let PrintMethod = "printShifter"; let ParserMatchClass = !cast( "LogicalShifterOperand" # width); } def logical_shift32 : logical_shift<32>; def logical_shift64 : logical_shift<64>; class logical_shifted_reg : Operand, ComplexPattern { let PrintMethod = "printShiftedRegister"; let MIOperandInfo = (ops regclass, shiftop); } def logical_shifted_reg32 : logical_shifted_reg; def logical_shifted_reg64 : logical_shifted_reg; // A logical vector shifter operand: // {7-6} - shift type: 00 = lsl // {5-0} - imm6: #0, #8, #16, or #24 def logical_vec_shift : Operand { let PrintMethod = "printShifter"; let EncoderMethod = "getVecShifterOpValue"; let ParserMatchClass = LogicalVecShifterOperand; } // A logical vector half-word shifter operand: // {7-6} - shift type: 00 = lsl // {5-0} - imm6: #0 or #8 def logical_vec_hw_shift : Operand { let PrintMethod = "printShifter"; let EncoderMethod = "getVecShifterOpValue"; let ParserMatchClass = LogicalVecHalfWordShifterOperand; } // A vector move shifter operand: // {0} - imm1: #8 or #16 def move_vec_shift : Operand { let PrintMethod = "printShifter"; let EncoderMethod = "getMoveVecShifterOpValue"; let ParserMatchClass = MoveVecShifterOperand; } def AddSubImmOperand : AsmOperandClass { let Name = "AddSubImm"; let ParserMethod = "tryParseAddSubImm"; let DiagnosticType = "AddSubSecondSource"; } // An ADD/SUB immediate shifter operand: // second operand: // {7-6} - shift type: 00 = lsl // {5-0} - imm6: #0 or #12 class addsub_shifted_imm : Operand, ComplexPattern { let PrintMethod = "printAddSubImm"; let EncoderMethod = "getAddSubImmOpValue"; let ParserMatchClass = AddSubImmOperand; let MIOperandInfo = (ops i32imm, i32imm); } def addsub_shifted_imm32 : addsub_shifted_imm; def addsub_shifted_imm64 : addsub_shifted_imm; class neg_addsub_shifted_imm : Operand, ComplexPattern { let PrintMethod = "printAddSubImm"; let EncoderMethod = "getAddSubImmOpValue"; let ParserMatchClass = AddSubImmOperand; let MIOperandInfo = (ops i32imm, i32imm); } def neg_addsub_shifted_imm32 : neg_addsub_shifted_imm; def neg_addsub_shifted_imm64 : neg_addsub_shifted_imm; // An extend operand: // {5-3} - extend type // {2-0} - imm3 def arith_extend : Operand { let PrintMethod = "printArithExtend"; let ParserMatchClass = ExtendOperand; } def arith_extend64 : Operand { let PrintMethod = "printArithExtend"; let ParserMatchClass = ExtendOperand64; } // 'extend' that's a lsl of a 64-bit register. def arith_extendlsl64 : Operand { let PrintMethod = "printArithExtend"; let ParserMatchClass = ExtendOperandLSL64; } class arith_extended_reg32 : Operand, ComplexPattern { let PrintMethod = "printExtendedRegister"; let MIOperandInfo = (ops GPR32, arith_extend); } class arith_extended_reg32to64 : Operand, ComplexPattern { let PrintMethod = "printExtendedRegister"; let MIOperandInfo = (ops GPR32, arith_extend64); } // Floating-point immediate. def fpimm32 : Operand, PatLeaf<(f32 fpimm), [{ return AArch64_AM::getFP32Imm(N->getValueAPF()) != -1; }], SDNodeXFormgetValueAPF(); uint32_t enc = AArch64_AM::getFP32Imm(InVal); return CurDAG->getTargetConstant(enc, MVT::i32); }]>> { let ParserMatchClass = FPImmOperand; let PrintMethod = "printFPImmOperand"; } def fpimm64 : Operand, PatLeaf<(f64 fpimm), [{ return AArch64_AM::getFP64Imm(N->getValueAPF()) != -1; }], SDNodeXFormgetValueAPF(); uint32_t enc = AArch64_AM::getFP64Imm(InVal); return CurDAG->getTargetConstant(enc, MVT::i32); }]>> { let ParserMatchClass = FPImmOperand; let PrintMethod = "printFPImmOperand"; } def fpimm8 : Operand { let ParserMatchClass = FPImmOperand; let PrintMethod = "printFPImmOperand"; } def fpimm0 : PatLeaf<(fpimm), [{ return N->isExactlyValue(+0.0); }]>; // Vector lane operands class AsmVectorIndex : AsmOperandClass { let Name = "VectorIndex" # Suffix; let DiagnosticType = "InvalidIndex" # Suffix; } def VectorIndex1Operand : AsmVectorIndex<"1">; def VectorIndexBOperand : AsmVectorIndex<"B">; def VectorIndexHOperand : AsmVectorIndex<"H">; def VectorIndexSOperand : AsmVectorIndex<"S">; def VectorIndexDOperand : AsmVectorIndex<"D">; def VectorIndex1 : Operand, ImmLeaf { let ParserMatchClass = VectorIndex1Operand; let PrintMethod = "printVectorIndex"; let MIOperandInfo = (ops i64imm); } def VectorIndexB : Operand, ImmLeaf { let ParserMatchClass = VectorIndexBOperand; let PrintMethod = "printVectorIndex"; let MIOperandInfo = (ops i64imm); } def VectorIndexH : Operand, ImmLeaf { let ParserMatchClass = VectorIndexHOperand; let PrintMethod = "printVectorIndex"; let MIOperandInfo = (ops i64imm); } def VectorIndexS : Operand, ImmLeaf { let ParserMatchClass = VectorIndexSOperand; let PrintMethod = "printVectorIndex"; let MIOperandInfo = (ops i64imm); } def VectorIndexD : Operand, ImmLeaf { let ParserMatchClass = VectorIndexDOperand; let PrintMethod = "printVectorIndex"; let MIOperandInfo = (ops i64imm); } // 8-bit immediate for AdvSIMD where 64-bit values of the form: // aaaaaaaa bbbbbbbb cccccccc dddddddd eeeeeeee ffffffff gggggggg hhhhhhhh // are encoded as the eight bit value 'abcdefgh'. def simdimmtype10 : Operand, PatLeaf<(f64 fpimm), [{ return AArch64_AM::isAdvSIMDModImmType10(N->getValueAPF() .bitcastToAPInt() .getZExtValue()); }], SDNodeXFormgetValueAPF(); uint32_t enc = AArch64_AM::encodeAdvSIMDModImmType10(N->getValueAPF() .bitcastToAPInt() .getZExtValue()); return CurDAG->getTargetConstant(enc, MVT::i32); }]>> { let ParserMatchClass = SIMDImmType10Operand; let PrintMethod = "printSIMDType10Operand"; } //--- // System management //--- // Base encoding for system instruction operands. let mayLoad = 0, mayStore = 0, hasSideEffects = 1 in class BaseSystemI : I { let Inst{31-22} = 0b1101010100; let Inst{21} = L; } // System instructions which do not have an Rt register. class SimpleSystemI : BaseSystemI { let Inst{4-0} = 0b11111; } // System instructions which have an Rt register. class RtSystemI : BaseSystemI, Sched<[WriteSys]> { bits<5> Rt; let Inst{4-0} = Rt; } // Hint instructions that take both a CRm and a 3-bit immediate. class HintI : SimpleSystemI<0, (ins imm0_127:$imm), mnemonic#" $imm", "">, Sched<[WriteHint]> { bits <7> imm; let Inst{20-12} = 0b000110010; let Inst{11-5} = imm; } // System instructions taking a single literal operand which encodes into // CRm. op2 differentiates the opcodes. def BarrierAsmOperand : AsmOperandClass { let Name = "Barrier"; let ParserMethod = "tryParseBarrierOperand"; } def barrier_op : Operand { let PrintMethod = "printBarrierOption"; let ParserMatchClass = BarrierAsmOperand; } class CRmSystemI opc, string asm> : SimpleSystemI<0, (ins crmtype:$CRm), asm, "\t$CRm">, Sched<[WriteBarrier]> { bits<4> CRm; let Inst{20-12} = 0b000110011; let Inst{11-8} = CRm; let Inst{7-5} = opc; } // MRS/MSR system instructions. These have different operand classes because // a different subset of registers can be accessed through each instruction. def MRSSystemRegisterOperand : AsmOperandClass { let Name = "MRSSystemRegister"; let ParserMethod = "tryParseSysReg"; let DiagnosticType = "MRS"; } // concatenation of 1, op0, op1, CRn, CRm, op2. 16-bit immediate. def mrs_sysreg_op : Operand { let ParserMatchClass = MRSSystemRegisterOperand; let DecoderMethod = "DecodeMRSSystemRegister"; let PrintMethod = "printMRSSystemRegister"; } def MSRSystemRegisterOperand : AsmOperandClass { let Name = "MSRSystemRegister"; let ParserMethod = "tryParseSysReg"; let DiagnosticType = "MSR"; } def msr_sysreg_op : Operand { let ParserMatchClass = MSRSystemRegisterOperand; let DecoderMethod = "DecodeMSRSystemRegister"; let PrintMethod = "printMSRSystemRegister"; } class MRSI : RtSystemI<1, (outs GPR64:$Rt), (ins mrs_sysreg_op:$systemreg), "mrs", "\t$Rt, $systemreg"> { bits<15> systemreg; let Inst{20} = 1; let Inst{19-5} = systemreg; } // FIXME: Some of these def NZCV, others don't. Best way to model that? // Explicitly modeling each of the system register as a register class // would do it, but feels like overkill at this point. class MSRI : RtSystemI<0, (outs), (ins msr_sysreg_op:$systemreg, GPR64:$Rt), "msr", "\t$systemreg, $Rt"> { bits<15> systemreg; let Inst{20} = 1; let Inst{19-5} = systemreg; } def SystemPStateFieldOperand : AsmOperandClass { let Name = "SystemPStateField"; let ParserMethod = "tryParseSysReg"; } def pstatefield_op : Operand { let ParserMatchClass = SystemPStateFieldOperand; let PrintMethod = "printSystemPStateField"; } let Defs = [NZCV] in class MSRpstateI : SimpleSystemI<0, (ins pstatefield_op:$pstate_field, imm0_15:$imm), "msr", "\t$pstate_field, $imm">, Sched<[WriteSys]> { bits<6> pstatefield; bits<4> imm; let Inst{20-19} = 0b00; let Inst{18-16} = pstatefield{5-3}; let Inst{15-12} = 0b0100; let Inst{11-8} = imm; let Inst{7-5} = pstatefield{2-0}; let DecoderMethod = "DecodeSystemPStateInstruction"; } // SYS and SYSL generic system instructions. def SysCRAsmOperand : AsmOperandClass { let Name = "SysCR"; let ParserMethod = "tryParseSysCROperand"; } def sys_cr_op : Operand { let PrintMethod = "printSysCROperand"; let ParserMatchClass = SysCRAsmOperand; } class SystemXtI : RtSystemI { bits<3> op1; bits<4> Cn; bits<4> Cm; bits<3> op2; let Inst{20-19} = 0b01; let Inst{18-16} = op1; let Inst{15-12} = Cn; let Inst{11-8} = Cm; let Inst{7-5} = op2; } class SystemLXtI : RtSystemI { bits<3> op1; bits<4> Cn; bits<4> Cm; bits<3> op2; let Inst{20-19} = 0b01; let Inst{18-16} = op1; let Inst{15-12} = Cn; let Inst{11-8} = Cm; let Inst{7-5} = op2; } // Branch (register) instructions: // // case opc of // 0001 blr // 0000 br // 0101 dret // 0100 eret // 0010 ret // otherwise UNDEFINED class BaseBranchReg opc, dag oops, dag iops, string asm, string operands, list pattern> : I, Sched<[WriteBrReg]> { let Inst{31-25} = 0b1101011; let Inst{24-21} = opc; let Inst{20-16} = 0b11111; let Inst{15-10} = 0b000000; let Inst{4-0} = 0b00000; } class BranchReg opc, string asm, list pattern> : BaseBranchReg { bits<5> Rn; let Inst{9-5} = Rn; } let mayLoad = 0, mayStore = 0, hasSideEffects = 1, isReturn = 1 in class SpecialReturn opc, string asm> : BaseBranchReg { let Inst{9-5} = 0b11111; } //--- // Conditional branch instruction. //--- // Condition code. // 4-bit immediate. Pretty-printed as def ccode : Operand { let PrintMethod = "printCondCode"; let ParserMatchClass = CondCode; } def inv_ccode : Operand { // AL and NV are invalid in the aliases which use inv_ccode let PrintMethod = "printInverseCondCode"; let ParserMatchClass = CondCode; let MCOperandPredicate = [{ return MCOp.isImm() && MCOp.getImm() != AArch64CC::AL && MCOp.getImm() != AArch64CC::NV; }]; } // Conditional branch target. 19-bit immediate. The low two bits of the target // offset are implied zero and so are not part of the immediate. def PCRelLabel19Operand : AsmOperandClass { let Name = "PCRelLabel19"; let DiagnosticType = "InvalidLabel"; } def am_brcond : Operand { let EncoderMethod = "getCondBranchTargetOpValue"; let DecoderMethod = "DecodePCRelLabel19"; let PrintMethod = "printAlignedLabel"; let ParserMatchClass = PCRelLabel19Operand; } class BranchCond : I<(outs), (ins ccode:$cond, am_brcond:$target), "b", ".$cond\t$target", "", [(AArch64brcond bb:$target, imm:$cond, NZCV)]>, Sched<[WriteBr]> { let isBranch = 1; let isTerminator = 1; let Uses = [NZCV]; bits<4> cond; bits<19> target; let Inst{31-24} = 0b01010100; let Inst{23-5} = target; let Inst{4} = 0; let Inst{3-0} = cond; } //--- // Compare-and-branch instructions. //--- class BaseCmpBranch : I<(outs), (ins regtype:$Rt, am_brcond:$target), asm, "\t$Rt, $target", "", [(node regtype:$Rt, bb:$target)]>, Sched<[WriteBr]> { let isBranch = 1; let isTerminator = 1; bits<5> Rt; bits<19> target; let Inst{30-25} = 0b011010; let Inst{24} = op; let Inst{23-5} = target; let Inst{4-0} = Rt; } multiclass CmpBranch { def W : BaseCmpBranch { let Inst{31} = 0; } def X : BaseCmpBranch { let Inst{31} = 1; } } //--- // Test-bit-and-branch instructions. //--- // Test-and-branch target. 14-bit sign-extended immediate. The low two bits of // the target offset are implied zero and so are not part of the immediate. def BranchTarget14Operand : AsmOperandClass { let Name = "BranchTarget14"; } def am_tbrcond : Operand { let EncoderMethod = "getTestBranchTargetOpValue"; let PrintMethod = "printAlignedLabel"; let ParserMatchClass = BranchTarget14Operand; } // AsmOperand classes to emit (or not) special diagnostics def TBZImm0_31Operand : AsmOperandClass { let Name = "TBZImm0_31"; let PredicateMethod = "isImm0_31"; let RenderMethod = "addImm0_31Operands"; } def TBZImm32_63Operand : AsmOperandClass { let Name = "Imm32_63"; let DiagnosticType = "InvalidImm0_63"; } class tbz_imm0_31 : Operand, ImmLeaf { let ParserMatchClass = matcher; } def tbz_imm0_31_diag : tbz_imm0_31; def tbz_imm0_31_nodiag : tbz_imm0_31; def tbz_imm32_63 : Operand, ImmLeaf 31) && (((uint32_t)Imm) < 64); }]> { let ParserMatchClass = TBZImm32_63Operand; } class BaseTestBranch : I<(outs), (ins regtype:$Rt, immtype:$bit_off, am_tbrcond:$target), asm, "\t$Rt, $bit_off, $target", "", [(node regtype:$Rt, immtype:$bit_off, bb:$target)]>, Sched<[WriteBr]> { let isBranch = 1; let isTerminator = 1; bits<5> Rt; bits<6> bit_off; bits<14> target; let Inst{30-25} = 0b011011; let Inst{24} = op; let Inst{23-19} = bit_off{4-0}; let Inst{18-5} = target; let Inst{4-0} = Rt; let DecoderMethod = "DecodeTestAndBranch"; } multiclass TestBranch { def W : BaseTestBranch { let Inst{31} = 0; } def X : BaseTestBranch { let Inst{31} = 1; } // Alias X-reg with 0-31 imm to W-Reg. def : InstAlias(NAME#"W") GPR32as64:$Rd, tbz_imm0_31_nodiag:$imm, am_tbrcond:$target), 0>; def : Pat<(node GPR64:$Rn, tbz_imm0_31_diag:$imm, bb:$target), (!cast(NAME#"W") (EXTRACT_SUBREG GPR64:$Rn, sub_32), tbz_imm0_31_diag:$imm, bb:$target)>; } //--- // Unconditional branch (immediate) instructions. //--- def BranchTarget26Operand : AsmOperandClass { let Name = "BranchTarget26"; let DiagnosticType = "InvalidLabel"; } def am_b_target : Operand { let EncoderMethod = "getBranchTargetOpValue"; let PrintMethod = "printAlignedLabel"; let ParserMatchClass = BranchTarget26Operand; } def am_bl_target : Operand { let EncoderMethod = "getBranchTargetOpValue"; let PrintMethod = "printAlignedLabel"; let ParserMatchClass = BranchTarget26Operand; } class BImm pattern> : I<(outs), iops, asm, "\t$addr", "", pattern>, Sched<[WriteBr]> { bits<26> addr; let Inst{31} = op; let Inst{30-26} = 0b00101; let Inst{25-0} = addr; let DecoderMethod = "DecodeUnconditionalBranch"; } class BranchImm pattern> : BImm; class CallImm pattern> : BImm; //--- // Basic one-operand data processing instructions. //--- let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in class BaseOneOperandData opc, RegisterClass regtype, string asm, SDPatternOperator node> : I<(outs regtype:$Rd), (ins regtype:$Rn), asm, "\t$Rd, $Rn", "", [(set regtype:$Rd, (node regtype:$Rn))]>, Sched<[WriteI, ReadI]> { bits<5> Rd; bits<5> Rn; let Inst{30-13} = 0b101101011000000000; let Inst{12-10} = opc; let Inst{9-5} = Rn; let Inst{4-0} = Rd; } let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in multiclass OneOperandData opc, string asm, SDPatternOperator node = null_frag> { def Wr : BaseOneOperandData { let Inst{31} = 0; } def Xr : BaseOneOperandData { let Inst{31} = 1; } } class OneWRegData opc, string asm, SDPatternOperator node> : BaseOneOperandData { let Inst{31} = 0; } class OneXRegData opc, string asm, SDPatternOperator node> : BaseOneOperandData { let Inst{31} = 1; } //--- // Basic two-operand data processing instructions. //--- class BaseBaseAddSubCarry pattern> : I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm), asm, "\t$Rd, $Rn, $Rm", "", pattern>, Sched<[WriteI, ReadI, ReadI]> { let Uses = [NZCV]; bits<5> Rd; bits<5> Rn; bits<5> Rm; let Inst{30} = isSub; let Inst{28-21} = 0b11010000; let Inst{20-16} = Rm; let Inst{15-10} = 0; let Inst{9-5} = Rn; let Inst{4-0} = Rd; } class BaseAddSubCarry : BaseBaseAddSubCarry; class BaseAddSubCarrySetFlags : BaseBaseAddSubCarry { let Defs = [NZCV]; } multiclass AddSubCarry { def Wr : BaseAddSubCarry { let Inst{31} = 0; let Inst{29} = 0; } def Xr : BaseAddSubCarry { let Inst{31} = 1; let Inst{29} = 0; } // Sets flags. def SWr : BaseAddSubCarrySetFlags { let Inst{31} = 0; let Inst{29} = 1; } def SXr : BaseAddSubCarrySetFlags { let Inst{31} = 1; let Inst{29} = 1; } } class BaseTwoOperand opc, RegisterClass regtype, string asm, SDPatternOperator OpNode> : I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm), asm, "\t$Rd, $Rn, $Rm", "", [(set regtype:$Rd, (OpNode regtype:$Rn, regtype:$Rm))]> { bits<5> Rd; bits<5> Rn; bits<5> Rm; let Inst{30-21} = 0b0011010110; let Inst{20-16} = Rm; let Inst{15-14} = 0b00; let Inst{13-10} = opc; let Inst{9-5} = Rn; let Inst{4-0} = Rd; } class BaseDiv : BaseTwoOperand<{0,0,1,?}, regtype, asm, OpNode> { let Inst{10} = isSigned; } multiclass Div { def Wr : BaseDiv, Sched<[WriteID32, ReadID, ReadID]> { let Inst{31} = 0; } def Xr : BaseDiv, Sched<[WriteID64, ReadID, ReadID]> { let Inst{31} = 1; } } class BaseShift shift_type, RegisterClass regtype, string asm, SDPatternOperator OpNode = null_frag> : BaseTwoOperand<{1,0,?,?}, regtype, asm, OpNode>, Sched<[WriteIS, ReadI]> { let Inst{11-10} = shift_type; } multiclass Shift shift_type, string asm, SDNode OpNode> { def Wr : BaseShift { let Inst{31} = 0; } def Xr : BaseShift { let Inst{31} = 1; } def : Pat<(i32 (OpNode GPR32:$Rn, i64:$Rm)), (!cast(NAME # "Wr") GPR32:$Rn, (EXTRACT_SUBREG i64:$Rm, sub_32))>; def : Pat<(i32 (OpNode GPR32:$Rn, (i64 (zext GPR32:$Rm)))), (!cast(NAME # "Wr") GPR32:$Rn, GPR32:$Rm)>; def : Pat<(i32 (OpNode GPR32:$Rn, (i64 (anyext GPR32:$Rm)))), (!cast(NAME # "Wr") GPR32:$Rn, GPR32:$Rm)>; def : Pat<(i32 (OpNode GPR32:$Rn, (i64 (sext GPR32:$Rm)))), (!cast(NAME # "Wr") GPR32:$Rn, GPR32:$Rm)>; } class ShiftAlias : InstAlias; class BaseMulAccum opc, RegisterClass multype, RegisterClass addtype, string asm, list pattern> : I<(outs addtype:$Rd), (ins multype:$Rn, multype:$Rm, addtype:$Ra), asm, "\t$Rd, $Rn, $Rm, $Ra", "", pattern> { bits<5> Rd; bits<5> Rn; bits<5> Rm; bits<5> Ra; let Inst{30-24} = 0b0011011; let Inst{23-21} = opc; let Inst{20-16} = Rm; let Inst{15} = isSub; let Inst{14-10} = Ra; let Inst{9-5} = Rn; let Inst{4-0} = Rd; } multiclass MulAccum { def Wrrr : BaseMulAccum, Sched<[WriteIM32, ReadIM, ReadIM, ReadIMA]> { let Inst{31} = 0; } def Xrrr : BaseMulAccum, Sched<[WriteIM64, ReadIM, ReadIM, ReadIMA]> { let Inst{31} = 1; } } class WideMulAccum opc, string asm, SDNode AccNode, SDNode ExtNode> : BaseMulAccum, Sched<[WriteIM32, ReadIM, ReadIM, ReadIMA]> { let Inst{31} = 1; } class MulHi opc, string asm, SDNode OpNode> : I<(outs GPR64:$Rd), (ins GPR64:$Rn, GPR64:$Rm), asm, "\t$Rd, $Rn, $Rm", "", [(set GPR64:$Rd, (OpNode GPR64:$Rn, GPR64:$Rm))]>, Sched<[WriteIM64, ReadIM, ReadIM]> { bits<5> Rd; bits<5> Rn; bits<5> Rm; let Inst{31-24} = 0b10011011; let Inst{23-21} = opc; let Inst{20-16} = Rm; let Inst{15} = 0; let Inst{9-5} = Rn; let Inst{4-0} = Rd; // The Ra field of SMULH and UMULH is unused: it should be assembled as 31 // (i.e. all bits 1) but is ignored by the processor. let PostEncoderMethod = "fixMulHigh"; } class MulAccumWAlias : InstAlias; class MulAccumXAlias : InstAlias; class WideMulAccumAlias : InstAlias; class BaseCRC32 sz, bit C, RegisterClass StreamReg, SDPatternOperator OpNode, string asm> : I<(outs GPR32:$Rd), (ins GPR32:$Rn, StreamReg:$Rm), asm, "\t$Rd, $Rn, $Rm", "", [(set GPR32:$Rd, (OpNode GPR32:$Rn, StreamReg:$Rm))]>, Sched<[WriteISReg, ReadI, ReadISReg]> { bits<5> Rd; bits<5> Rn; bits<5> Rm; let Inst{31} = sf; let Inst{30-21} = 0b0011010110; let Inst{20-16} = Rm; let Inst{15-13} = 0b010; let Inst{12} = C; let Inst{11-10} = sz; let Inst{9-5} = Rn; let Inst{4-0} = Rd; let Predicates = [HasCRC]; } //--- // Address generation. //--- class ADRI pattern> : I<(outs GPR64:$Xd), (ins adr:$label), asm, "\t$Xd, $label", "", pattern>, Sched<[WriteI]> { bits<5> Xd; bits<21> label; let Inst{31} = page; let Inst{30-29} = label{1-0}; let Inst{28-24} = 0b10000; let Inst{23-5} = label{20-2}; let Inst{4-0} = Xd; let DecoderMethod = "DecodeAdrInstruction"; } //--- // Move immediate. //--- def movimm32_imm : Operand { let ParserMatchClass = Imm0_65535Operand; let EncoderMethod = "getMoveWideImmOpValue"; let PrintMethod = "printHexImm"; } def movimm32_shift : Operand { let PrintMethod = "printShifter"; let ParserMatchClass = MovImm32ShifterOperand; } def movimm64_shift : Operand { let PrintMethod = "printShifter"; let ParserMatchClass = MovImm64ShifterOperand; } let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in class BaseMoveImmediate opc, RegisterClass regtype, Operand shifter, string asm> : I<(outs regtype:$Rd), (ins movimm32_imm:$imm, shifter:$shift), asm, "\t$Rd, $imm$shift", "", []>, Sched<[WriteImm]> { bits<5> Rd; bits<16> imm; bits<6> shift; let Inst{30-29} = opc; let Inst{28-23} = 0b100101; let Inst{22-21} = shift{5-4}; let Inst{20-5} = imm; let Inst{4-0} = Rd; let DecoderMethod = "DecodeMoveImmInstruction"; } multiclass MoveImmediate opc, string asm> { def Wi : BaseMoveImmediate { let Inst{31} = 0; } def Xi : BaseMoveImmediate { let Inst{31} = 1; } } let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in class BaseInsertImmediate opc, RegisterClass regtype, Operand shifter, string asm> : I<(outs regtype:$Rd), (ins regtype:$src, movimm32_imm:$imm, shifter:$shift), asm, "\t$Rd, $imm$shift", "$src = $Rd", []>, Sched<[WriteI, ReadI]> { bits<5> Rd; bits<16> imm; bits<6> shift; let Inst{30-29} = opc; let Inst{28-23} = 0b100101; let Inst{22-21} = shift{5-4}; let Inst{20-5} = imm; let Inst{4-0} = Rd; let DecoderMethod = "DecodeMoveImmInstruction"; } multiclass InsertImmediate opc, string asm> { def Wi : BaseInsertImmediate { let Inst{31} = 0; } def Xi : BaseInsertImmediate { let Inst{31} = 1; } } //--- // Add/Subtract //--- class BaseAddSubImm : I<(outs dstRegtype:$Rd), (ins srcRegtype:$Rn, immtype:$imm), asm, "\t$Rd, $Rn, $imm", "", [(set dstRegtype:$Rd, (OpNode srcRegtype:$Rn, immtype:$imm))]>, Sched<[WriteI, ReadI]> { bits<5> Rd; bits<5> Rn; bits<14> imm; let Inst{30} = isSub; let Inst{29} = setFlags; let Inst{28-24} = 0b10001; let Inst{23-22} = imm{13-12}; // '00' => lsl #0, '01' => lsl #12 let Inst{21-10} = imm{11-0}; let Inst{9-5} = Rn; let Inst{4-0} = Rd; let DecoderMethod = "DecodeBaseAddSubImm"; } class BaseAddSubRegPseudo : Pseudo<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm), [(set regtype:$Rd, (OpNode regtype:$Rn, regtype:$Rm))]>, Sched<[WriteI, ReadI, ReadI]>; class BaseAddSubSReg : I<(outs regtype:$Rd), (ins regtype:$Rn, shifted_regtype:$Rm), asm, "\t$Rd, $Rn, $Rm", "", [(set regtype:$Rd, (OpNode regtype:$Rn, shifted_regtype:$Rm))]>, Sched<[WriteISReg, ReadI, ReadISReg]> { // The operands are in order to match the 'addr' MI operands, so we // don't need an encoder method and by-name matching. Just use the default // in-order handling. Since we're using by-order, make sure the names // do not match. bits<5> dst; bits<5> src1; bits<5> src2; bits<8> shift; let Inst{30} = isSub; let Inst{29} = setFlags; let Inst{28-24} = 0b01011; let Inst{23-22} = shift{7-6}; let Inst{21} = 0; let Inst{20-16} = src2; let Inst{15-10} = shift{5-0}; let Inst{9-5} = src1; let Inst{4-0} = dst; let DecoderMethod = "DecodeThreeAddrSRegInstruction"; } class BaseAddSubEReg : I<(outs dstRegtype:$R1), (ins src1Regtype:$R2, src2Regtype:$R3), asm, "\t$R1, $R2, $R3", "", [(set dstRegtype:$R1, (OpNode src1Regtype:$R2, src2Regtype:$R3))]>, Sched<[WriteIEReg, ReadI, ReadIEReg]> { bits<5> Rd; bits<5> Rn; bits<5> Rm; bits<6> ext; let Inst{30} = isSub; let Inst{29} = setFlags; let Inst{28-24} = 0b01011; let Inst{23-21} = 0b001; let Inst{20-16} = Rm; let Inst{15-13} = ext{5-3}; let Inst{12-10} = ext{2-0}; let Inst{9-5} = Rn; let Inst{4-0} = Rd; let DecoderMethod = "DecodeAddSubERegInstruction"; } let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in class BaseAddSubEReg64 : I<(outs dstRegtype:$Rd), (ins src1Regtype:$Rn, src2Regtype:$Rm, ext_op:$ext), asm, "\t$Rd, $Rn, $Rm$ext", "", []>, Sched<[WriteIEReg, ReadI, ReadIEReg]> { bits<5> Rd; bits<5> Rn; bits<5> Rm; bits<6> ext; let Inst{30} = isSub; let Inst{29} = setFlags; let Inst{28-24} = 0b01011; let Inst{23-21} = 0b001; let Inst{20-16} = Rm; let Inst{15} = ext{5}; let Inst{12-10} = ext{2-0}; let Inst{9-5} = Rn; let Inst{4-0} = Rd; let DecoderMethod = "DecodeAddSubERegInstruction"; } // Aliases for register+register add/subtract. class AddSubRegAlias : InstAlias; multiclass AddSub { let hasSideEffects = 0 in { // Add/Subtract immediate def Wri : BaseAddSubImm { let Inst{31} = 0; } def Xri : BaseAddSubImm { let Inst{31} = 1; } // Add/Subtract register - Only used for CodeGen def Wrr : BaseAddSubRegPseudo; def Xrr : BaseAddSubRegPseudo; // Add/Subtract shifted register def Wrs : BaseAddSubSReg { let Inst{31} = 0; } def Xrs : BaseAddSubSReg { let Inst{31} = 1; } } // Add/Subtract extended register let AddedComplexity = 1, hasSideEffects = 0 in { def Wrx : BaseAddSubEReg, mnemonic, OpNode> { let Inst{31} = 0; } def Xrx : BaseAddSubEReg, mnemonic, OpNode> { let Inst{31} = 1; } } def Xrx64 : BaseAddSubEReg64 { // UXTX and SXTX only. let Inst{14-13} = 0b11; let Inst{31} = 1; } // Register/register aliases with no shift when SP is not used. def : AddSubRegAlias(NAME#"Wrs"), GPR32, GPR32, GPR32, 0>; def : AddSubRegAlias(NAME#"Xrs"), GPR64, GPR64, GPR64, 0>; // Register/register aliases with no shift when either the destination or // first source register is SP. def : AddSubRegAlias(NAME#"Wrx"), GPR32sponly, GPR32sp, GPR32, 16>; // UXTW #0 def : AddSubRegAlias(NAME#"Wrx"), GPR32sp, GPR32sponly, GPR32, 16>; // UXTW #0 def : AddSubRegAlias(NAME#"Xrx64"), GPR64sponly, GPR64sp, GPR64, 24>; // UXTX #0 def : AddSubRegAlias(NAME#"Xrx64"), GPR64sp, GPR64sponly, GPR64, 24>; // UXTX #0 } multiclass AddSubS { let isCompare = 1, Defs = [NZCV] in { // Add/Subtract immediate def Wri : BaseAddSubImm { let Inst{31} = 0; } def Xri : BaseAddSubImm { let Inst{31} = 1; } // Add/Subtract register def Wrr : BaseAddSubRegPseudo; def Xrr : BaseAddSubRegPseudo; // Add/Subtract shifted register def Wrs : BaseAddSubSReg { let Inst{31} = 0; } def Xrs : BaseAddSubSReg { let Inst{31} = 1; } // Add/Subtract extended register let AddedComplexity = 1 in { def Wrx : BaseAddSubEReg, mnemonic, OpNode> { let Inst{31} = 0; } def Xrx : BaseAddSubEReg, mnemonic, OpNode> { let Inst{31} = 1; } } def Xrx64 : BaseAddSubEReg64 { // UXTX and SXTX only. let Inst{14-13} = 0b11; let Inst{31} = 1; } } // Defs = [NZCV] // Compare aliases def : InstAlias(NAME#"Wri") WZR, GPR32sp:$src, addsub_shifted_imm32:$imm), 5>; def : InstAlias(NAME#"Xri") XZR, GPR64sp:$src, addsub_shifted_imm64:$imm), 5>; def : InstAlias(NAME#"Wrx") WZR, GPR32sp:$src1, GPR32:$src2, arith_extend:$sh), 4>; def : InstAlias(NAME#"Xrx") XZR, GPR64sp:$src1, GPR32:$src2, arith_extend:$sh), 4>; def : InstAlias(NAME#"Xrx64") XZR, GPR64sp:$src1, GPR64:$src2, arith_extendlsl64:$sh), 4>; def : InstAlias(NAME#"Wrs") WZR, GPR32:$src1, GPR32:$src2, arith_shift32:$sh), 4>; def : InstAlias(NAME#"Xrs") XZR, GPR64:$src1, GPR64:$src2, arith_shift64:$sh), 4>; // Compare shorthands def : InstAlias(NAME#"Wrs") WZR, GPR32:$src1, GPR32:$src2, 0), 5>; def : InstAlias(NAME#"Xrs") XZR, GPR64:$src1, GPR64:$src2, 0), 5>; def : InstAlias(NAME#"Wrx") WZR, GPR32sponly:$src1, GPR32:$src2, 16), 5>; def : InstAlias(NAME#"Xrx64") XZR, GPR64sponly:$src1, GPR64:$src2, 24), 5>; // Register/register aliases with no shift when SP is not used. def : AddSubRegAlias(NAME#"Wrs"), GPR32, GPR32, GPR32, 0>; def : AddSubRegAlias(NAME#"Xrs"), GPR64, GPR64, GPR64, 0>; // Register/register aliases with no shift when the first source register // is SP. def : AddSubRegAlias(NAME#"Wrx"), GPR32, GPR32sponly, GPR32, 16>; // UXTW #0 def : AddSubRegAlias(NAME#"Xrx64"), GPR64, GPR64sponly, GPR64, 24>; // UXTX #0 } //--- // Extract //--- def SDTA64EXTR : SDTypeProfile<1, 3, [SDTCisSameAs<0, 1>, SDTCisSameAs<0, 2>, SDTCisPtrTy<3>]>; def AArch64Extr : SDNode<"AArch64ISD::EXTR", SDTA64EXTR>; class BaseExtractImm patterns> : I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm, imm_type:$imm), asm, "\t$Rd, $Rn, $Rm, $imm", "", patterns>, Sched<[WriteExtr, ReadExtrHi]> { bits<5> Rd; bits<5> Rn; bits<5> Rm; bits<6> imm; let Inst{30-23} = 0b00100111; let Inst{21} = 0; let Inst{20-16} = Rm; let Inst{15-10} = imm; let Inst{9-5} = Rn; let Inst{4-0} = Rd; } multiclass ExtractImm { def Wrri : BaseExtractImm { let Inst{31} = 0; let Inst{22} = 0; // imm<5> must be zero. let imm{5} = 0; } def Xrri : BaseExtractImm { let Inst{31} = 1; let Inst{22} = 1; } } //--- // Bitfield //--- let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in class BaseBitfieldImm opc, RegisterClass regtype, Operand imm_type, string asm> : I<(outs regtype:$Rd), (ins regtype:$Rn, imm_type:$immr, imm_type:$imms), asm, "\t$Rd, $Rn, $immr, $imms", "", []>, Sched<[WriteIS, ReadI]> { bits<5> Rd; bits<5> Rn; bits<6> immr; bits<6> imms; let Inst{30-29} = opc; let Inst{28-23} = 0b100110; let Inst{21-16} = immr; let Inst{15-10} = imms; let Inst{9-5} = Rn; let Inst{4-0} = Rd; } multiclass BitfieldImm opc, string asm> { def Wri : BaseBitfieldImm { let Inst{31} = 0; let Inst{22} = 0; // imms<5> and immr<5> must be zero, else ReservedValue(). let Inst{21} = 0; let Inst{15} = 0; } def Xri : BaseBitfieldImm { let Inst{31} = 1; let Inst{22} = 1; } } let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in class BaseBitfieldImmWith2RegArgs opc, RegisterClass regtype, Operand imm_type, string asm> : I<(outs regtype:$Rd), (ins regtype:$src, regtype:$Rn, imm_type:$immr, imm_type:$imms), asm, "\t$Rd, $Rn, $immr, $imms", "$src = $Rd", []>, Sched<[WriteIS, ReadI]> { bits<5> Rd; bits<5> Rn; bits<6> immr; bits<6> imms; let Inst{30-29} = opc; let Inst{28-23} = 0b100110; let Inst{21-16} = immr; let Inst{15-10} = imms; let Inst{9-5} = Rn; let Inst{4-0} = Rd; } multiclass BitfieldImmWith2RegArgs opc, string asm> { def Wri : BaseBitfieldImmWith2RegArgs { let Inst{31} = 0; let Inst{22} = 0; // imms<5> and immr<5> must be zero, else ReservedValue(). let Inst{21} = 0; let Inst{15} = 0; } def Xri : BaseBitfieldImmWith2RegArgs { let Inst{31} = 1; let Inst{22} = 1; } } //--- // Logical //--- // Logical (immediate) class BaseLogicalImm opc, RegisterClass dregtype, RegisterClass sregtype, Operand imm_type, string asm, list pattern> : I<(outs dregtype:$Rd), (ins sregtype:$Rn, imm_type:$imm), asm, "\t$Rd, $Rn, $imm", "", pattern>, Sched<[WriteI, ReadI]> { bits<5> Rd; bits<5> Rn; bits<13> imm; let Inst{30-29} = opc; let Inst{28-23} = 0b100100; let Inst{22} = imm{12}; let Inst{21-16} = imm{11-6}; let Inst{15-10} = imm{5-0}; let Inst{9-5} = Rn; let Inst{4-0} = Rd; let DecoderMethod = "DecodeLogicalImmInstruction"; } // Logical (shifted register) class BaseLogicalSReg opc, bit N, RegisterClass regtype, logical_shifted_reg shifted_regtype, string asm, list pattern> : I<(outs regtype:$Rd), (ins regtype:$Rn, shifted_regtype:$Rm), asm, "\t$Rd, $Rn, $Rm", "", pattern>, Sched<[WriteISReg, ReadI, ReadISReg]> { // The operands are in order to match the 'addr' MI operands, so we // don't need an encoder method and by-name matching. Just use the default // in-order handling. Since we're using by-order, make sure the names // do not match. bits<5> dst; bits<5> src1; bits<5> src2; bits<8> shift; let Inst{30-29} = opc; let Inst{28-24} = 0b01010; let Inst{23-22} = shift{7-6}; let Inst{21} = N; let Inst{20-16} = src2; let Inst{15-10} = shift{5-0}; let Inst{9-5} = src1; let Inst{4-0} = dst; let DecoderMethod = "DecodeThreeAddrSRegInstruction"; } // Aliases for register+register logical instructions. class LogicalRegAlias : InstAlias; let AddedComplexity = 6 in multiclass LogicalImm opc, string mnemonic, SDNode OpNode> { def Wri : BaseLogicalImm { let Inst{31} = 0; let Inst{22} = 0; // 64-bit version has an additional bit of immediate. } def Xri : BaseLogicalImm { let Inst{31} = 1; } } multiclass LogicalImmS opc, string mnemonic, SDNode OpNode> { let isCompare = 1, Defs = [NZCV] in { def Wri : BaseLogicalImm { let Inst{31} = 0; let Inst{22} = 0; // 64-bit version has an additional bit of immediate. } def Xri : BaseLogicalImm { let Inst{31} = 1; } } // end Defs = [NZCV] } class BaseLogicalRegPseudo : Pseudo<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm), [(set regtype:$Rd, (OpNode regtype:$Rn, regtype:$Rm))]>, Sched<[WriteI, ReadI, ReadI]>; // Split from LogicalImm as not all instructions have both. multiclass LogicalReg opc, bit N, string mnemonic, SDPatternOperator OpNode> { def Wrr : BaseLogicalRegPseudo; def Xrr : BaseLogicalRegPseudo; def Wrs : BaseLogicalSReg { let Inst{31} = 0; } def Xrs : BaseLogicalSReg { let Inst{31} = 1; } def : LogicalRegAlias(NAME#"Wrs"), GPR32>; def : LogicalRegAlias(NAME#"Xrs"), GPR64>; } // Split from LogicalReg to allow setting NZCV Defs multiclass LogicalRegS opc, bit N, string mnemonic, SDPatternOperator OpNode = null_frag> { let Defs = [NZCV], mayLoad = 0, mayStore = 0, hasSideEffects = 0 in { def Wrr : BaseLogicalRegPseudo; def Xrr : BaseLogicalRegPseudo; def Wrs : BaseLogicalSReg { let Inst{31} = 0; } def Xrs : BaseLogicalSReg { let Inst{31} = 1; } } // Defs = [NZCV] def : LogicalRegAlias(NAME#"Wrs"), GPR32>; def : LogicalRegAlias(NAME#"Xrs"), GPR64>; } //--- // Conditionally set flags //--- let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in class BaseCondSetFlagsImm : I<(outs), (ins regtype:$Rn, imm0_31:$imm, imm0_15:$nzcv, ccode:$cond), asm, "\t$Rn, $imm, $nzcv, $cond", "", []>, Sched<[WriteI, ReadI]> { let Uses = [NZCV]; let Defs = [NZCV]; bits<5> Rn; bits<5> imm; bits<4> nzcv; bits<4> cond; let Inst{30} = op; let Inst{29-21} = 0b111010010; let Inst{20-16} = imm; let Inst{15-12} = cond; let Inst{11-10} = 0b10; let Inst{9-5} = Rn; let Inst{4} = 0b0; let Inst{3-0} = nzcv; } multiclass CondSetFlagsImm { def Wi : BaseCondSetFlagsImm { let Inst{31} = 0; } def Xi : BaseCondSetFlagsImm { let Inst{31} = 1; } } let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in class BaseCondSetFlagsReg : I<(outs), (ins regtype:$Rn, regtype:$Rm, imm0_15:$nzcv, ccode:$cond), asm, "\t$Rn, $Rm, $nzcv, $cond", "", []>, Sched<[WriteI, ReadI, ReadI]> { let Uses = [NZCV]; let Defs = [NZCV]; bits<5> Rn; bits<5> Rm; bits<4> nzcv; bits<4> cond; let Inst{30} = op; let Inst{29-21} = 0b111010010; let Inst{20-16} = Rm; let Inst{15-12} = cond; let Inst{11-10} = 0b00; let Inst{9-5} = Rn; let Inst{4} = 0b0; let Inst{3-0} = nzcv; } multiclass CondSetFlagsReg { def Wr : BaseCondSetFlagsReg { let Inst{31} = 0; } def Xr : BaseCondSetFlagsReg { let Inst{31} = 1; } } //--- // Conditional select //--- class BaseCondSelect op2, RegisterClass regtype, string asm> : I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm, ccode:$cond), asm, "\t$Rd, $Rn, $Rm, $cond", "", [(set regtype:$Rd, (AArch64csel regtype:$Rn, regtype:$Rm, (i32 imm:$cond), NZCV))]>, Sched<[WriteI, ReadI, ReadI]> { let Uses = [NZCV]; bits<5> Rd; bits<5> Rn; bits<5> Rm; bits<4> cond; let Inst{30} = op; let Inst{29-21} = 0b011010100; let Inst{20-16} = Rm; let Inst{15-12} = cond; let Inst{11-10} = op2; let Inst{9-5} = Rn; let Inst{4-0} = Rd; } multiclass CondSelect op2, string asm> { def Wr : BaseCondSelect { let Inst{31} = 0; } def Xr : BaseCondSelect { let Inst{31} = 1; } } class BaseCondSelectOp op2, RegisterClass regtype, string asm, PatFrag frag> : I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm, ccode:$cond), asm, "\t$Rd, $Rn, $Rm, $cond", "", [(set regtype:$Rd, (AArch64csel regtype:$Rn, (frag regtype:$Rm), (i32 imm:$cond), NZCV))]>, Sched<[WriteI, ReadI, ReadI]> { let Uses = [NZCV]; bits<5> Rd; bits<5> Rn; bits<5> Rm; bits<4> cond; let Inst{30} = op; let Inst{29-21} = 0b011010100; let Inst{20-16} = Rm; let Inst{15-12} = cond; let Inst{11-10} = op2; let Inst{9-5} = Rn; let Inst{4-0} = Rd; } def inv_cond_XFORM : SDNodeXForm(N->getZExtValue()); return CurDAG->getTargetConstant(AArch64CC::getInvertedCondCode(CC), MVT::i32); }]>; multiclass CondSelectOp op2, string asm, PatFrag frag> { def Wr : BaseCondSelectOp { let Inst{31} = 0; } def Xr : BaseCondSelectOp { let Inst{31} = 1; } def : Pat<(AArch64csel (frag GPR32:$Rm), GPR32:$Rn, (i32 imm:$cond), NZCV), (!cast(NAME # Wr) GPR32:$Rn, GPR32:$Rm, (inv_cond_XFORM imm:$cond))>; def : Pat<(AArch64csel (frag GPR64:$Rm), GPR64:$Rn, (i32 imm:$cond), NZCV), (!cast(NAME # Xr) GPR64:$Rn, GPR64:$Rm, (inv_cond_XFORM imm:$cond))>; } //--- // Special Mask Value //--- def maski8_or_more : Operand, ImmLeaf { } def maski16_or_more : Operand, ImmLeaf { } //--- // Load/store //--- // (unsigned immediate) // Indexed for 8-bit registers. offset is in range [0,4095]. def am_indexed8 : ComplexPattern; def am_indexed16 : ComplexPattern; def am_indexed32 : ComplexPattern; def am_indexed64 : ComplexPattern; def am_indexed128 : ComplexPattern; class UImm12OffsetOperand : AsmOperandClass { let Name = "UImm12Offset" # Scale; let RenderMethod = "addUImm12OffsetOperands<" # Scale # ">"; let PredicateMethod = "isUImm12Offset<" # Scale # ">"; let DiagnosticType = "InvalidMemoryIndexed" # Scale; } def UImm12OffsetScale1Operand : UImm12OffsetOperand<1>; def UImm12OffsetScale2Operand : UImm12OffsetOperand<2>; def UImm12OffsetScale4Operand : UImm12OffsetOperand<4>; def UImm12OffsetScale8Operand : UImm12OffsetOperand<8>; def UImm12OffsetScale16Operand : UImm12OffsetOperand<16>; class uimm12_scaled : Operand { let ParserMatchClass = !cast("UImm12OffsetScale" # Scale # "Operand"); let EncoderMethod = "getLdStUImm12OpValue"; let PrintMethod = "printUImm12Offset<" # Scale # ">"; } def uimm12s1 : uimm12_scaled<1>; def uimm12s2 : uimm12_scaled<2>; def uimm12s4 : uimm12_scaled<4>; def uimm12s8 : uimm12_scaled<8>; def uimm12s16 : uimm12_scaled<16>; class BaseLoadStoreUI sz, bit V, bits<2> opc, dag oops, dag iops, string asm, list pattern> : I { bits<5> Rt; bits<5> Rn; bits<12> offset; let Inst{31-30} = sz; let Inst{29-27} = 0b111; let Inst{26} = V; let Inst{25-24} = 0b01; let Inst{23-22} = opc; let Inst{21-10} = offset; let Inst{9-5} = Rn; let Inst{4-0} = Rt; let DecoderMethod = "DecodeUnsignedLdStInstruction"; } multiclass LoadUI sz, bit V, bits<2> opc, RegisterClass regtype, Operand indextype, string asm, list pattern> { let AddedComplexity = 10, mayLoad = 1, mayStore = 0, hasSideEffects = 0 in def ui : BaseLoadStoreUI, Sched<[WriteLD]>; def : InstAlias(NAME # "ui") regtype:$Rt, GPR64sp:$Rn, 0)>; } multiclass StoreUI sz, bit V, bits<2> opc, RegisterClass regtype, Operand indextype, string asm, list pattern> { let AddedComplexity = 10, mayLoad = 0, mayStore = 1, hasSideEffects = 0 in def ui : BaseLoadStoreUI, Sched<[WriteST]>; def : InstAlias(NAME # "ui") regtype:$Rt, GPR64sp:$Rn, 0)>; } def PrefetchOperand : AsmOperandClass { let Name = "Prefetch"; let ParserMethod = "tryParsePrefetch"; } def prfop : Operand { let PrintMethod = "printPrefetchOp"; let ParserMatchClass = PrefetchOperand; } let mayLoad = 0, mayStore = 0, hasSideEffects = 1 in class PrefetchUI sz, bit V, bits<2> opc, string asm, list pat> : BaseLoadStoreUI, Sched<[WriteLD]>; //--- // Load literal //--- // Load literal address: 19-bit immediate. The low two bits of the target // offset are implied zero and so are not part of the immediate. def am_ldrlit : Operand { let EncoderMethod = "getLoadLiteralOpValue"; let DecoderMethod = "DecodePCRelLabel19"; let PrintMethod = "printAlignedLabel"; let ParserMatchClass = PCRelLabel19Operand; } let mayLoad = 1, mayStore = 0, hasSideEffects = 0 in class LoadLiteral opc, bit V, RegisterClass regtype, string asm> : I<(outs regtype:$Rt), (ins am_ldrlit:$label), asm, "\t$Rt, $label", "", []>, Sched<[WriteLD]> { bits<5> Rt; bits<19> label; let Inst{31-30} = opc; let Inst{29-27} = 0b011; let Inst{26} = V; let Inst{25-24} = 0b00; let Inst{23-5} = label; let Inst{4-0} = Rt; } let mayLoad = 0, mayStore = 0, hasSideEffects = 1 in class PrefetchLiteral opc, bit V, string asm, list pat> : I<(outs), (ins prfop:$Rt, am_ldrlit:$label), asm, "\t$Rt, $label", "", pat>, Sched<[WriteLD]> { bits<5> Rt; bits<19> label; let Inst{31-30} = opc; let Inst{29-27} = 0b011; let Inst{26} = V; let Inst{25-24} = 0b00; let Inst{23-5} = label; let Inst{4-0} = Rt; } //--- // Load/store register offset //--- def ro_Xindexed8 : ComplexPattern", []>; def ro_Xindexed16 : ComplexPattern", []>; def ro_Xindexed32 : ComplexPattern", []>; def ro_Xindexed64 : ComplexPattern", []>; def ro_Xindexed128 : ComplexPattern", []>; def ro_Windexed8 : ComplexPattern", []>; def ro_Windexed16 : ComplexPattern", []>; def ro_Windexed32 : ComplexPattern