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llvm-mirror/lib/Target/AArch64/AArch64InstrFormats.td
Sam Parker 3d30332768 [AArch64] v8.3-a complex number support
New instructions are added to AArch32 and AArch64 to aid
floating-point multiplication and addition of complex numbers,
where the complex numbers are packed in a vector register as a
pair of elements. The Imaginary part of the number is placed in the
more significant element, and the Real part of the number is placed
in the less significant element.

Differential Revision: https://reviews.llvm.org/D36792

llvm-svn: 312228
2017-08-31 09:27:04 +00:00

9998 lines
380 KiB
TableGen

//===- 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<bits<2> val> {
bits<2> Value = val;
}
def PseudoFrm : Format<0>;
def NormalFrm : Format<1>; // Do we need any others?
// AArch64 Instruction Format
class AArch64Inst<Format f, string cstr> : 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;
}
class InstSubst<string Asm, dag Result, bit EmitPriority = 0>
: InstAlias<Asm, Result, EmitPriority>, Requires<[UseNegativeImmediates]>;
// Pseudo instructions (don't have encoding information)
class Pseudo<dag oops, dag iops, list<dag> pattern, string cstr = "">
: AArch64Inst<PseudoFrm, cstr> {
dag OutOperandList = oops;
dag InOperandList = iops;
let Pattern = pattern;
let isCodeGenOnly = 1;
}
// Real instructions (have encoding information)
class EncodedI<string cstr, list<dag> pattern> : AArch64Inst<NormalFrm, cstr> {
let Pattern = pattern;
let Size = 4;
}
// Normal instructions
class I<dag oops, dag iops, string asm, string operands, string cstr,
list<dag> pattern>
: EncodedI<cstr, pattern> {
dag OutOperandList = oops;
dag InOperandList = iops;
let AsmString = !strconcat(asm, operands);
}
class TriOpFrag<dag res> : PatFrag<(ops node:$LHS, node:$MHS, node:$RHS), res>;
class BinOpFrag<dag res> : PatFrag<(ops node:$LHS, node:$RHS), res>;
class UnOpFrag<dag res> : PatFrag<(ops node:$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<int width> : 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<int width> : 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<GPR32> {
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"; }
// Authenticated loads for v8.3 can have scaled 10-bit immediate offsets.
def SImm10s8Operand : AsmOperandClass {
let Name = "SImm10s8";
let DiagnosticType = "InvalidMemoryIndexedSImm10";
}
//===----------------------------------------------------------------------===//
// Operand Definitions.
//
// ADR[P] instruction labels.
def AdrpOperand : AsmOperandClass {
let Name = "AdrpLabel";
let ParserMethod = "tryParseAdrpLabel";
let DiagnosticType = "InvalidLabel";
}
def adrplabel : Operand<i64> {
let EncoderMethod = "getAdrLabelOpValue";
let PrintMethod = "printAdrpLabel";
let ParserMatchClass = AdrpOperand;
}
def AdrOperand : AsmOperandClass {
let Name = "AdrLabel";
let ParserMethod = "tryParseAdrLabel";
let DiagnosticType = "InvalidLabel";
}
def adrlabel : Operand<i64> {
let EncoderMethod = "getAdrLabelOpValue";
let ParserMatchClass = AdrOperand;
}
def simm10Scaled : Operand<i64> {
let ParserMatchClass = SImm10s8Operand;
let DecoderMethod = "DecodeSImm<10>";
let PrintMethod = "printImmScale<8>";
}
// simm9 predicate - True if the immediate is in the range [-256, 255].
def SImm9Operand : AsmOperandClass {
let Name = "SImm9";
let DiagnosticType = "InvalidMemoryIndexedSImm9";
}
def simm9 : Operand<i64>, ImmLeaf<i64, [{ return Imm >= -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<int Scale> : 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<i32> {
let ParserMatchClass = SImm7s4Operand;
let PrintMethod = "printImmScale<4>";
}
def simm7s8 : Operand<i32> {
let ParserMatchClass = SImm7s8Operand;
let PrintMethod = "printImmScale<8>";
}
def simm7s16 : Operand<i32> {
let ParserMatchClass = SImm7s16Operand;
let PrintMethod = "printImmScale<16>";
}
def am_indexed7s8 : ComplexPattern<i64, 2, "SelectAddrModeIndexed7S8", []>;
def am_indexed7s16 : ComplexPattern<i64, 2, "SelectAddrModeIndexed7S16", []>;
def am_indexed7s32 : ComplexPattern<i64, 2, "SelectAddrModeIndexed7S32", []>;
def am_indexed7s64 : ComplexPattern<i64, 2, "SelectAddrModeIndexed7S64", []>;
def am_indexed7s128 : ComplexPattern<i64, 2, "SelectAddrModeIndexed7S128", []>;
class AsmImmRange<int Low, int High> : AsmOperandClass {
let Name = "Imm" # Low # "_" # High;
let DiagnosticType = "InvalidImm" # Low # "_" # High;
let PredicateMethod = "isImmInRange<" # 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>;
class BranchTarget<int N> : AsmOperandClass {
let Name = "BranchTarget" # N;
let DiagnosticType = "InvalidLabel";
let PredicateMethod = "isBranchTarget<" # N # ">";
}
class PCRelLabel<int N> : BranchTarget<N> {
let Name = "PCRelLabel" # N;
}
def BranchTarget14Operand : BranchTarget<14>;
def BranchTarget26Operand : BranchTarget<26>;
def PCRelLabel19Operand : PCRelLabel<19>;
def MovZSymbolG3AsmOperand : AsmOperandClass {
let Name = "MovZSymbolG3";
let RenderMethod = "addImmOperands";
}
def movz_symbol_g3 : Operand<i32> {
let ParserMatchClass = MovZSymbolG3AsmOperand;
}
def MovZSymbolG2AsmOperand : AsmOperandClass {
let Name = "MovZSymbolG2";
let RenderMethod = "addImmOperands";
}
def movz_symbol_g2 : Operand<i32> {
let ParserMatchClass = MovZSymbolG2AsmOperand;
}
def MovZSymbolG1AsmOperand : AsmOperandClass {
let Name = "MovZSymbolG1";
let RenderMethod = "addImmOperands";
}
def movz_symbol_g1 : Operand<i32> {
let ParserMatchClass = MovZSymbolG1AsmOperand;
}
def MovZSymbolG0AsmOperand : AsmOperandClass {
let Name = "MovZSymbolG0";
let RenderMethod = "addImmOperands";
}
def movz_symbol_g0 : Operand<i32> {
let ParserMatchClass = MovZSymbolG0AsmOperand;
}
def MovKSymbolG3AsmOperand : AsmOperandClass {
let Name = "MovKSymbolG3";
let RenderMethod = "addImmOperands";
}
def movk_symbol_g3 : Operand<i32> {
let ParserMatchClass = MovKSymbolG3AsmOperand;
}
def MovKSymbolG2AsmOperand : AsmOperandClass {
let Name = "MovKSymbolG2";
let RenderMethod = "addImmOperands";
}
def movk_symbol_g2 : Operand<i32> {
let ParserMatchClass = MovKSymbolG2AsmOperand;
}
def MovKSymbolG1AsmOperand : AsmOperandClass {
let Name = "MovKSymbolG1";
let RenderMethod = "addImmOperands";
}
def movk_symbol_g1 : Operand<i32> {
let ParserMatchClass = MovKSymbolG1AsmOperand;
}
def MovKSymbolG0AsmOperand : AsmOperandClass {
let Name = "MovKSymbolG0";
let RenderMethod = "addImmOperands";
}
def movk_symbol_g0 : Operand<i32> {
let ParserMatchClass = MovKSymbolG0AsmOperand;
}
class fixedpoint_i32<ValueType FloatVT>
: Operand<FloatVT>,
ComplexPattern<FloatVT, 1, "SelectCVTFixedPosOperand<32>", [fpimm, ld]> {
let EncoderMethod = "getFixedPointScaleOpValue";
let DecoderMethod = "DecodeFixedPointScaleImm32";
let ParserMatchClass = Imm1_32Operand;
}
class fixedpoint_i64<ValueType FloatVT>
: Operand<FloatVT>,
ComplexPattern<FloatVT, 1, "SelectCVTFixedPosOperand<64>", [fpimm, ld]> {
let EncoderMethod = "getFixedPointScaleOpValue";
let DecoderMethod = "DecodeFixedPointScaleImm64";
let ParserMatchClass = Imm1_64Operand;
}
def fixedpoint_f16_i32 : fixedpoint_i32<f16>;
def fixedpoint_f32_i32 : fixedpoint_i32<f32>;
def fixedpoint_f64_i32 : fixedpoint_i32<f64>;
def fixedpoint_f16_i64 : fixedpoint_i64<f16>;
def fixedpoint_f32_i64 : fixedpoint_i64<f32>;
def fixedpoint_f64_i64 : fixedpoint_i64<f64>;
def vecshiftR8 : Operand<i32>, ImmLeaf<i32, [{
return (((uint32_t)Imm) > 0) && (((uint32_t)Imm) < 9);
}]> {
let EncoderMethod = "getVecShiftR8OpValue";
let DecoderMethod = "DecodeVecShiftR8Imm";
let ParserMatchClass = Imm1_8Operand;
}
def vecshiftR16 : Operand<i32>, ImmLeaf<i32, [{
return (((uint32_t)Imm) > 0) && (((uint32_t)Imm) < 17);
}]> {
let EncoderMethod = "getVecShiftR16OpValue";
let DecoderMethod = "DecodeVecShiftR16Imm";
let ParserMatchClass = Imm1_16Operand;
}
def vecshiftR16Narrow : Operand<i32>, ImmLeaf<i32, [{
return (((uint32_t)Imm) > 0) && (((uint32_t)Imm) < 9);
}]> {
let EncoderMethod = "getVecShiftR16OpValue";
let DecoderMethod = "DecodeVecShiftR16ImmNarrow";
let ParserMatchClass = Imm1_8Operand;
}
def vecshiftR32 : Operand<i32>, ImmLeaf<i32, [{
return (((uint32_t)Imm) > 0) && (((uint32_t)Imm) < 33);
}]> {
let EncoderMethod = "getVecShiftR32OpValue";
let DecoderMethod = "DecodeVecShiftR32Imm";
let ParserMatchClass = Imm1_32Operand;
}
def vecshiftR32Narrow : Operand<i32>, ImmLeaf<i32, [{
return (((uint32_t)Imm) > 0) && (((uint32_t)Imm) < 17);
}]> {
let EncoderMethod = "getVecShiftR32OpValue";
let DecoderMethod = "DecodeVecShiftR32ImmNarrow";
let ParserMatchClass = Imm1_16Operand;
}
def vecshiftR64 : Operand<i32>, ImmLeaf<i32, [{
return (((uint32_t)Imm) > 0) && (((uint32_t)Imm) < 65);
}]> {
let EncoderMethod = "getVecShiftR64OpValue";
let DecoderMethod = "DecodeVecShiftR64Imm";
let ParserMatchClass = Imm1_64Operand;
}
def vecshiftR64Narrow : Operand<i32>, ImmLeaf<i32, [{
return (((uint32_t)Imm) > 0) && (((uint32_t)Imm) < 33);
}]> {
let EncoderMethod = "getVecShiftR64OpValue";
let DecoderMethod = "DecodeVecShiftR64ImmNarrow";
let ParserMatchClass = Imm1_32Operand;
}
def Imm0_1Operand : AsmImmRange<0, 1>;
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<i32>, ImmLeaf<i32, [{
return (((uint32_t)Imm) < 8);
}]> {
let EncoderMethod = "getVecShiftL8OpValue";
let DecoderMethod = "DecodeVecShiftL8Imm";
let ParserMatchClass = Imm0_7Operand;
}
def vecshiftL16 : Operand<i32>, ImmLeaf<i32, [{
return (((uint32_t)Imm) < 16);
}]> {
let EncoderMethod = "getVecShiftL16OpValue";
let DecoderMethod = "DecodeVecShiftL16Imm";
let ParserMatchClass = Imm0_15Operand;
}
def vecshiftL32 : Operand<i32>, ImmLeaf<i32, [{
return (((uint32_t)Imm) < 32);
}]> {
let EncoderMethod = "getVecShiftL32OpValue";
let DecoderMethod = "DecodeVecShiftL32Imm";
let ParserMatchClass = Imm0_31Operand;
}
def vecshiftL64 : Operand<i32>, ImmLeaf<i32, [{
return (((uint32_t)Imm) < 64);
}]> {
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 : SDNodeXForm<imm, [{
uint64_t enc = AArch64_AM::encodeLogicalImmediate(N->getZExtValue(), 32);
return CurDAG->getTargetConstant(enc, SDLoc(N), MVT::i32);
}]>;
def logical_imm64_XFORM : SDNodeXForm<imm, [{
uint64_t enc = AArch64_AM::encodeLogicalImmediate(N->getZExtValue(), 64);
return CurDAG->getTargetConstant(enc, SDLoc(N), MVT::i32);
}]>;
let DiagnosticType = "LogicalSecondSource" in {
def LogicalImm32Operand : AsmOperandClass {
let Name = "LogicalImm32";
}
def LogicalImm64Operand : AsmOperandClass {
let Name = "LogicalImm64";
}
def LogicalImm32NotOperand : AsmOperandClass {
let Name = "LogicalImm32Not";
}
def LogicalImm64NotOperand : AsmOperandClass {
let Name = "LogicalImm64Not";
}
}
def logical_imm32 : Operand<i32>, PatLeaf<(imm), [{
return AArch64_AM::isLogicalImmediate(N->getZExtValue(), 32);
}], logical_imm32_XFORM> {
let PrintMethod = "printLogicalImm32";
let ParserMatchClass = LogicalImm32Operand;
}
def logical_imm64 : Operand<i64>, PatLeaf<(imm), [{
return AArch64_AM::isLogicalImmediate(N->getZExtValue(), 64);
}], logical_imm64_XFORM> {
let PrintMethod = "printLogicalImm64";
let ParserMatchClass = LogicalImm64Operand;
}
def logical_imm32_not : Operand<i32> {
let ParserMatchClass = LogicalImm32NotOperand;
}
def logical_imm64_not : Operand<i64> {
let ParserMatchClass = LogicalImm64NotOperand;
}
// imm0_65535 predicate - True if the immediate is in the range [0,65535].
def Imm0_65535Operand : AsmImmRange<0, 65535>;
def imm0_65535 : Operand<i32>, ImmLeaf<i32, [{
return ((uint32_t)Imm) < 65536;
}]> {
let ParserMatchClass = Imm0_65535Operand;
let PrintMethod = "printImmHex";
}
// imm0_255 predicate - True if the immediate is in the range [0,255].
def Imm0_255Operand : AsmImmRange<0,255>;
def imm0_255 : Operand<i32>, ImmLeaf<i32, [{
return ((uint32_t)Imm) < 256;
}]> {
let ParserMatchClass = Imm0_255Operand;
let PrintMethod = "printImm";
}
// imm0_127 predicate - True if the immediate is in the range [0,127]
def Imm0_127Operand : AsmImmRange<0, 127>;
def imm0_127 : Operand<i32>, ImmLeaf<i32, [{
return ((uint32_t)Imm) < 128;
}]> {
let ParserMatchClass = Imm0_127Operand;
let PrintMethod = "printImm";
}
// 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<i64>, ImmLeaf<i64, [{
return ((uint64_t)Imm) < 64;
}]> {
let ParserMatchClass = Imm0_63Operand;
}
// imm0_31 predicate - True if the immediate is in the range [0,31]
def imm0_31 : Operand<i64>, ImmLeaf<i64, [{
return ((uint64_t)Imm) < 32;
}]> {
let ParserMatchClass = Imm0_31Operand;
}
// True if the 32-bit immediate is in the range [0,31]
def imm32_0_31 : Operand<i32>, ImmLeaf<i32, [{
return ((uint64_t)Imm) < 32;
}]> {
let ParserMatchClass = Imm0_31Operand;
}
// imm0_1 predicate - True if the immediate is in the range [0,1]
def imm0_1 : Operand<i64>, ImmLeaf<i64, [{
return ((uint64_t)Imm) < 2;
}]> {
let ParserMatchClass = Imm0_1Operand;
}
// imm0_15 predicate - True if the immediate is in the range [0,15]
def imm0_15 : Operand<i64>, ImmLeaf<i64, [{
return ((uint64_t)Imm) < 16;
}]> {
let ParserMatchClass = Imm0_15Operand;
}
// imm0_7 predicate - True if the immediate is in the range [0,7]
def imm0_7 : Operand<i64>, ImmLeaf<i64, [{
return ((uint64_t)Imm) < 8;
}]> {
let ParserMatchClass = Imm0_7Operand;
}
// imm32_0_15 predicate - True if the 32-bit immediate is in the range [0,15]
def imm32_0_15 : Operand<i32>, ImmLeaf<i32, [{
return ((uint32_t)Imm) < 16;
}]> {
let ParserMatchClass = Imm0_15Operand;
}
// An arithmetic shifter operand:
// {7-6} - shift type: 00 = lsl, 01 = lsr, 10 = asr
// {5-0} - imm6
class arith_shift<ValueType Ty, int width> : Operand<Ty> {
let PrintMethod = "printShifter";
let ParserMatchClass = !cast<AsmOperandClass>(
"ArithmeticShifterOperand" # width);
}
def arith_shift32 : arith_shift<i32, 32>;
def arith_shift64 : arith_shift<i64, 64>;
class arith_shifted_reg<ValueType Ty, RegisterClass regclass, int width>
: Operand<Ty>,
ComplexPattern<Ty, 2, "SelectArithShiftedRegister", []> {
let PrintMethod = "printShiftedRegister";
let MIOperandInfo = (ops regclass, !cast<Operand>("arith_shift" # width));
}
def arith_shifted_reg32 : arith_shifted_reg<i32, GPR32, 32>;
def arith_shifted_reg64 : arith_shifted_reg<i64, GPR64, 64>;
// An arithmetic shifter operand:
// {7-6} - shift type: 00 = lsl, 01 = lsr, 10 = asr, 11 = ror
// {5-0} - imm6
class logical_shift<int width> : Operand<i32> {
let PrintMethod = "printShifter";
let ParserMatchClass = !cast<AsmOperandClass>(
"LogicalShifterOperand" # width);
}
def logical_shift32 : logical_shift<32>;
def logical_shift64 : logical_shift<64>;
class logical_shifted_reg<ValueType Ty, RegisterClass regclass, Operand shiftop>
: Operand<Ty>,
ComplexPattern<Ty, 2, "SelectLogicalShiftedRegister", []> {
let PrintMethod = "printShiftedRegister";
let MIOperandInfo = (ops regclass, shiftop);
}
def logical_shifted_reg32 : logical_shifted_reg<i32, GPR32, logical_shift32>;
def logical_shifted_reg64 : logical_shifted_reg<i64, GPR64, logical_shift64>;
// A logical vector shifter operand:
// {7-6} - shift type: 00 = lsl
// {5-0} - imm6: #0, #8, #16, or #24
def logical_vec_shift : Operand<i32> {
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<i32> {
let PrintMethod = "printShifter";
let EncoderMethod = "getVecShifterOpValue";
let ParserMatchClass = LogicalVecHalfWordShifterOperand;
}
// A vector move shifter operand:
// {0} - imm1: #8 or #16
def move_vec_shift : Operand<i32> {
let PrintMethod = "printShifter";
let EncoderMethod = "getMoveVecShifterOpValue";
let ParserMatchClass = MoveVecShifterOperand;
}
let DiagnosticType = "AddSubSecondSource" in {
def AddSubImmOperand : AsmOperandClass {
let Name = "AddSubImm";
let ParserMethod = "tryParseAddSubImm";
}
def AddSubImmNegOperand : AsmOperandClass {
let Name = "AddSubImmNeg";
let ParserMethod = "tryParseAddSubImm";
}
}
// An ADD/SUB immediate shifter operand:
// second operand:
// {7-6} - shift type: 00 = lsl
// {5-0} - imm6: #0 or #12
class addsub_shifted_imm<ValueType Ty>
: Operand<Ty>, ComplexPattern<Ty, 2, "SelectArithImmed", [imm]> {
let PrintMethod = "printAddSubImm";
let EncoderMethod = "getAddSubImmOpValue";
let ParserMatchClass = AddSubImmOperand;
let MIOperandInfo = (ops i32imm, i32imm);
}
class addsub_shifted_imm_neg<ValueType Ty>
: Operand<Ty> {
let EncoderMethod = "getAddSubImmOpValue";
let ParserMatchClass = AddSubImmNegOperand;
let MIOperandInfo = (ops i32imm, i32imm);
}
def addsub_shifted_imm32 : addsub_shifted_imm<i32>;
def addsub_shifted_imm64 : addsub_shifted_imm<i64>;
def addsub_shifted_imm32_neg : addsub_shifted_imm_neg<i32>;
def addsub_shifted_imm64_neg : addsub_shifted_imm_neg<i64>;
def gi_addsub_shifted_imm32 :
GIComplexOperandMatcher<s32, "selectArithImmed">,
GIComplexPatternEquiv<addsub_shifted_imm32>;
def gi_addsub_shifted_imm64 :
GIComplexOperandMatcher<s64, "selectArithImmed">,
GIComplexPatternEquiv<addsub_shifted_imm64>;
class neg_addsub_shifted_imm<ValueType Ty>
: Operand<Ty>, ComplexPattern<Ty, 2, "SelectNegArithImmed", [imm]> {
let PrintMethod = "printAddSubImm";
let EncoderMethod = "getAddSubImmOpValue";
let ParserMatchClass = AddSubImmOperand;
let MIOperandInfo = (ops i32imm, i32imm);
}
def neg_addsub_shifted_imm32 : neg_addsub_shifted_imm<i32>;
def neg_addsub_shifted_imm64 : neg_addsub_shifted_imm<i64>;
// An extend operand:
// {5-3} - extend type
// {2-0} - imm3
def arith_extend : Operand<i32> {
let PrintMethod = "printArithExtend";
let ParserMatchClass = ExtendOperand;
}
def arith_extend64 : Operand<i32> {
let PrintMethod = "printArithExtend";
let ParserMatchClass = ExtendOperand64;
}
// 'extend' that's a lsl of a 64-bit register.
def arith_extendlsl64 : Operand<i32> {
let PrintMethod = "printArithExtend";
let ParserMatchClass = ExtendOperandLSL64;
}
class arith_extended_reg32<ValueType Ty> : Operand<Ty>,
ComplexPattern<Ty, 2, "SelectArithExtendedRegister", []> {
let PrintMethod = "printExtendedRegister";
let MIOperandInfo = (ops GPR32, arith_extend);
}
class arith_extended_reg32to64<ValueType Ty> : Operand<Ty>,
ComplexPattern<Ty, 2, "SelectArithExtendedRegister", []> {
let PrintMethod = "printExtendedRegister";
let MIOperandInfo = (ops GPR32, arith_extend64);
}
// Floating-point immediate.
def fpimm16 : Operand<f16>,
PatLeaf<(f16 fpimm), [{
return AArch64_AM::getFP16Imm(N->getValueAPF()) != -1;
}], SDNodeXForm<fpimm, [{
APFloat InVal = N->getValueAPF();
uint32_t enc = AArch64_AM::getFP16Imm(InVal);
return CurDAG->getTargetConstant(enc, SDLoc(N), MVT::i32);
}]>> {
let ParserMatchClass = FPImmOperand;
let PrintMethod = "printFPImmOperand";
}
def fpimm32 : Operand<f32>,
PatLeaf<(f32 fpimm), [{
return AArch64_AM::getFP32Imm(N->getValueAPF()) != -1;
}], SDNodeXForm<fpimm, [{
APFloat InVal = N->getValueAPF();
uint32_t enc = AArch64_AM::getFP32Imm(InVal);
return CurDAG->getTargetConstant(enc, SDLoc(N), MVT::i32);
}]>> {
let ParserMatchClass = FPImmOperand;
let PrintMethod = "printFPImmOperand";
}
def fpimm64 : Operand<f64>,
PatLeaf<(f64 fpimm), [{
return AArch64_AM::getFP64Imm(N->getValueAPF()) != -1;
}], SDNodeXForm<fpimm, [{
APFloat InVal = N->getValueAPF();
uint32_t enc = AArch64_AM::getFP64Imm(InVal);
return CurDAG->getTargetConstant(enc, SDLoc(N), MVT::i32);
}]>> {
let ParserMatchClass = FPImmOperand;
let PrintMethod = "printFPImmOperand";
}
def fpimm8 : Operand<i32> {
let ParserMatchClass = FPImmOperand;
let PrintMethod = "printFPImmOperand";
}
def fpimm0 : PatLeaf<(fpimm), [{
return N->isExactlyValue(+0.0);
}]>;
// Vector lane operands
class AsmVectorIndex<string Suffix> : 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<i64>, ImmLeaf<i64, [{
return ((uint64_t)Imm) == 1;
}]> {
let ParserMatchClass = VectorIndex1Operand;
let PrintMethod = "printVectorIndex";
let MIOperandInfo = (ops i64imm);
}
def VectorIndexB : Operand<i64>, ImmLeaf<i64, [{
return ((uint64_t)Imm) < 16;
}]> {
let ParserMatchClass = VectorIndexBOperand;
let PrintMethod = "printVectorIndex";
let MIOperandInfo = (ops i64imm);
}
def VectorIndexH : Operand<i64>, ImmLeaf<i64, [{
return ((uint64_t)Imm) < 8;
}]> {
let ParserMatchClass = VectorIndexHOperand;
let PrintMethod = "printVectorIndex";
let MIOperandInfo = (ops i64imm);
}
def VectorIndexS : Operand<i64>, ImmLeaf<i64, [{
return ((uint64_t)Imm) < 4;
}]> {
let ParserMatchClass = VectorIndexSOperand;
let PrintMethod = "printVectorIndex";
let MIOperandInfo = (ops i64imm);
}
def VectorIndexD : Operand<i64>, ImmLeaf<i64, [{
return ((uint64_t)Imm) < 2;
}]> {
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<i32>,
PatLeaf<(f64 fpimm), [{
return AArch64_AM::isAdvSIMDModImmType10(N->getValueAPF()
.bitcastToAPInt()
.getZExtValue());
}], SDNodeXForm<fpimm, [{
APFloat InVal = N->getValueAPF();
uint32_t enc = AArch64_AM::encodeAdvSIMDModImmType10(N->getValueAPF()
.bitcastToAPInt()
.getZExtValue());
return CurDAG->getTargetConstant(enc, SDLoc(N), 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<bit L, dag oops, dag iops, string asm, string operands,
list<dag> pattern = []>
: I<oops, iops, asm, operands, "", pattern> {
let Inst{31-22} = 0b1101010100;
let Inst{21} = L;
}
// System instructions which do not have an Rt register.
class SimpleSystemI<bit L, dag iops, string asm, string operands,
list<dag> pattern = []>
: BaseSystemI<L, (outs), iops, asm, operands, pattern> {
let Inst{4-0} = 0b11111;
}
// System instructions which have an Rt register.
class RtSystemI<bit L, dag oops, dag iops, string asm, string operands>
: BaseSystemI<L, oops, iops, asm, operands>,
Sched<[WriteSys]> {
bits<5> Rt;
let Inst{4-0} = Rt;
}
// Hint instructions that take both a CRm and a 3-bit immediate.
// NOTE: ideally, this would have mayStore = 0, mayLoad = 0, but we cannot
// model patterns with sufficiently fine granularity
let mayStore = 1, mayLoad = 1, hasSideEffects = 1 in
class HintI<string mnemonic>
: SimpleSystemI<0, (ins imm0_127:$imm), mnemonic#"\t$imm", "",
[(int_aarch64_hint imm0_127:$imm)]>,
Sched<[WriteHint]> {
bits <7> imm;
let Inst{20-12} = 0b000110010;
let Inst{11-5} = imm;
}
// System instructions taking a single literal operand which encodes into
// CRm. op2 differentiates the opcodes.
def BarrierAsmOperand : AsmOperandClass {
let Name = "Barrier";
let ParserMethod = "tryParseBarrierOperand";
}
def barrier_op : Operand<i32> {
let PrintMethod = "printBarrierOption";
let ParserMatchClass = BarrierAsmOperand;
}
class CRmSystemI<Operand crmtype, bits<3> opc, string asm,
list<dag> pattern = []>
: SimpleSystemI<0, (ins crmtype:$CRm), asm, "\t$CRm", pattern>,
Sched<[WriteBarrier]> {
bits<4> CRm;
let Inst{20-12} = 0b000110011;
let Inst{11-8} = CRm;
let Inst{7-5} = opc;
}
class SystemNoOperands<bits<3> op2, string asm, list<dag> pattern = []>
: SimpleSystemI<0, (ins), asm, "", pattern>,
Sched<[]> {
bits<4> CRm;
let CRm = 0b0011;
let Inst{31-12} = 0b11010101000000110010;
let Inst{11-8} = CRm;
let Inst{7-5} = op2;
let Inst{4-0} = 0b11111;
}
// MRS/MSR system instructions. These have different operand classes because
// a different subset of registers can be accessed through each instruction.
def MRSSystemRegisterOperand : AsmOperandClass {
let Name = "MRSSystemRegister";
let ParserMethod = "tryParseSysReg";
let DiagnosticType = "MRS";
}
// concatenation of op0, op1, CRn, CRm, op2. 16-bit immediate.
def mrs_sysreg_op : Operand<i32> {
let ParserMatchClass = MRSSystemRegisterOperand;
let DecoderMethod = "DecodeMRSSystemRegister";
let PrintMethod = "printMRSSystemRegister";
}
def MSRSystemRegisterOperand : AsmOperandClass {
let Name = "MSRSystemRegister";
let ParserMethod = "tryParseSysReg";
let DiagnosticType = "MSR";
}
def msr_sysreg_op : Operand<i32> {
let ParserMatchClass = MSRSystemRegisterOperand;
let DecoderMethod = "DecodeMSRSystemRegister";
let PrintMethod = "printMSRSystemRegister";
}
def PSBHintOperand : AsmOperandClass {
let Name = "PSBHint";
let ParserMethod = "tryParsePSBHint";
}
def psbhint_op : Operand<i32> {
let ParserMatchClass = PSBHintOperand;
let PrintMethod = "printPSBHintOp";
let MCOperandPredicate = [{
// Check, if operand is valid, to fix exhaustive aliasing in disassembly.
// "psb" is an alias to "hint" only for certain values of CRm:Op2 fields.
if (!MCOp.isImm())
return false;
return AArch64PSBHint::lookupPSBByEncoding(MCOp.getImm()) != nullptr;
}];
}
class MRSI : RtSystemI<1, (outs GPR64:$Rt), (ins mrs_sysreg_op:$systemreg),
"mrs", "\t$Rt, $systemreg"> {
bits<16> systemreg;
let Inst{20-5} = systemreg;
}
// FIXME: Some of these def NZCV, others don't. Best way to model that?
// Explicitly modeling each of the system register as a register class
// would do it, but feels like overkill at this point.
class MSRI : RtSystemI<0, (outs), (ins msr_sysreg_op:$systemreg, GPR64:$Rt),
"msr", "\t$systemreg, $Rt"> {
bits<16> systemreg;
let Inst{20-5} = systemreg;
}
def SystemPStateFieldWithImm0_15Operand : AsmOperandClass {
let Name = "SystemPStateFieldWithImm0_15";
let ParserMethod = "tryParseSysReg";
}
def pstatefield4_op : Operand<i32> {
let ParserMatchClass = SystemPStateFieldWithImm0_15Operand;
let PrintMethod = "printSystemPStateField";
}
let Defs = [NZCV] in
class MSRpstateImm0_15
: SimpleSystemI<0, (ins pstatefield4_op:$pstatefield, imm0_15:$imm),
"msr", "\t$pstatefield, $imm">,
Sched<[WriteSys]> {
bits<6> pstatefield;
bits<4> imm;
let Inst{20-19} = 0b00;
let Inst{18-16} = pstatefield{5-3};
let Inst{15-12} = 0b0100;
let Inst{11-8} = imm;
let Inst{7-5} = pstatefield{2-0};
let DecoderMethod = "DecodeSystemPStateInstruction";
// MSRpstateI aliases with MSRI. When the MSRpstateI decoder method returns
// Fail the decoder should attempt to decode the instruction as MSRI.
let hasCompleteDecoder = 0;
}
def SystemPStateFieldWithImm0_1Operand : AsmOperandClass {
let Name = "SystemPStateFieldWithImm0_1";
let ParserMethod = "tryParseSysReg";
}
def pstatefield1_op : Operand<i32> {
let ParserMatchClass = SystemPStateFieldWithImm0_1Operand;
let PrintMethod = "printSystemPStateField";
}
let Defs = [NZCV] in
class MSRpstateImm0_1
: SimpleSystemI<0, (ins pstatefield1_op:$pstatefield, imm0_1:$imm),
"msr", "\t$pstatefield, $imm">,
Sched<[WriteSys]> {
bits<6> pstatefield;
bit imm;
let Inst{20-19} = 0b00;
let Inst{18-16} = pstatefield{5-3};
let Inst{15-9} = 0b0100000;
let Inst{8} = imm;
let Inst{7-5} = pstatefield{2-0};
let DecoderMethod = "DecodeSystemPStateInstruction";
// MSRpstateI aliases with MSRI. When the MSRpstateI decoder method returns
// Fail the decoder should attempt to decode the instruction as MSRI.
let hasCompleteDecoder = 0;
}
// SYS and SYSL generic system instructions.
def SysCRAsmOperand : AsmOperandClass {
let Name = "SysCR";
let ParserMethod = "tryParseSysCROperand";
}
def sys_cr_op : Operand<i32> {
let PrintMethod = "printSysCROperand";
let ParserMatchClass = SysCRAsmOperand;
}
class SystemXtI<bit L, string asm>
: RtSystemI<L, (outs),
(ins imm0_7:$op1, sys_cr_op:$Cn, sys_cr_op:$Cm, imm0_7:$op2, GPR64:$Rt),
asm, "\t$op1, $Cn, $Cm, $op2, $Rt"> {
bits<3> op1;
bits<4> Cn;
bits<4> Cm;
bits<3> op2;
let Inst{20-19} = 0b01;
let Inst{18-16} = op1;
let Inst{15-12} = Cn;
let Inst{11-8} = Cm;
let Inst{7-5} = op2;
}
class SystemLXtI<bit L, string asm>
: RtSystemI<L, (outs),
(ins GPR64:$Rt, imm0_7:$op1, sys_cr_op:$Cn, sys_cr_op:$Cm, imm0_7:$op2),
asm, "\t$Rt, $op1, $Cn, $Cm, $op2"> {
bits<3> op1;
bits<4> Cn;
bits<4> Cm;
bits<3> op2;
let Inst{20-19} = 0b01;
let Inst{18-16} = op1;
let Inst{15-12} = Cn;
let Inst{11-8} = Cm;
let Inst{7-5} = op2;
}
// Branch (register) instructions:
//
// case opc of
// 0001 blr
// 0000 br
// 0101 dret
// 0100 eret
// 0010 ret
// otherwise UNDEFINED
class BaseBranchReg<bits<4> opc, dag oops, dag iops, string asm,
string operands, list<dag> pattern>
: I<oops, iops, asm, operands, "", pattern>, Sched<[WriteBrReg]> {
let Inst{31-25} = 0b1101011;
let Inst{24-21} = opc;
let Inst{20-16} = 0b11111;
let Inst{15-10} = 0b000000;
let Inst{4-0} = 0b00000;
}
class BranchReg<bits<4> opc, string asm, list<dag> pattern>
: BaseBranchReg<opc, (outs), (ins GPR64:$Rn), asm, "\t$Rn", pattern> {
bits<5> Rn;
let Inst{9-5} = Rn;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 1, isReturn = 1 in
class SpecialReturn<bits<4> opc, string asm>
: BaseBranchReg<opc, (outs), (ins), asm, "", []> {
let Inst{9-5} = 0b11111;
}
let mayLoad = 1 in
class RCPCLoad<bits<2> sz, string asm, RegisterClass RC>
: I<(outs RC:$Rt), (ins GPR64sp0:$Rn), asm, "\t$Rt, [$Rn]", "", []>,
Sched<[]> {
bits<5> Rn;
bits<5> Rt;
let Inst{31-30} = sz;
let Inst{29-10} = 0b11100010111111110000;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
}
class AuthBase<bits<1> M, dag oops, dag iops, string asm, string operands,
list<dag> pattern>
: I<oops, iops, asm, operands, "", pattern>, Sched<[]> {
let Inst{31-25} = 0b1101011;
let Inst{20-11} = 0b1111100001;
let Inst{10} = M;
let Inst{4-0} = 0b11111;
}
class AuthBranchTwoOperands<bits<1> op, bits<1> M, string asm>
: AuthBase<M, (outs), (ins GPR64:$Rn, GPR64sp:$Rm), asm, "\t$Rn, $Rm", []> {
bits<5> Rn;
bits<5> Rm;
let Inst{24-22} = 0b100;
let Inst{21} = op;
let Inst{9-5} = Rn;
let Inst{4-0} = Rm;
}
class AuthOneOperand<bits<3> opc, bits<1> M, string asm>
: AuthBase<M, (outs), (ins GPR64:$Rn), asm, "\t$Rn", []> {
bits<5> Rn;
let Inst{24} = 0;
let Inst{23-21} = opc;
let Inst{9-5} = Rn;
}
class AuthReturn<bits<3> op, bits<1> M, string asm>
: AuthBase<M, (outs), (ins), asm, "", []> {
let Inst{24} = 0;
let Inst{23-21} = op;
let Inst{9-0} = 0b1111111111;
}
let mayLoad = 1 in
class BaseAuthLoad<bit M, bit W, dag oops, dag iops, string asm,
string operands, string cstr, Operand opr>
: I<oops, iops, asm, operands, cstr, []>, Sched<[]> {
bits<10> offset;
bits<5> Rn;
bits<5> Rt;
let Inst{31-24} = 0b11111000;
let Inst{23} = M;
let Inst{22} = offset{9};
let Inst{21} = 1;
let Inst{20-12} = offset{8-0};
let Inst{11} = W;
let Inst{10} = 1;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
}
multiclass AuthLoad<bit M, string asm, Operand opr> {
def indexed : BaseAuthLoad<M, 0, (outs GPR64:$Rt),
(ins GPR64sp:$Rn, opr:$offset),
asm, "\t$Rt, [$Rn, $offset]", "", opr>;
def writeback : BaseAuthLoad<M, 1, (outs GPR64sp:$wback, GPR64:$Rt),
(ins GPR64sp:$Rn, opr:$offset),
asm, "\t$Rt, [$Rn, $offset]!",
"$Rn = $wback,@earlyclobber $wback", opr>;
def : InstAlias<asm # "\t$Rt, [$Rn]",
(!cast<Instruction>(NAME # "indexed") GPR64:$Rt, GPR64sp:$Rn, 0)>;
}
//---
// Conditional branch instruction.
//---
// Condition code.
// 4-bit immediate. Pretty-printed as <cc>
def ccode : Operand<i32> {
let PrintMethod = "printCondCode";
let ParserMatchClass = CondCode;
}
def inv_ccode : Operand<i32> {
// AL and NV are invalid in the aliases which use inv_ccode
let PrintMethod = "printInverseCondCode";
let ParserMatchClass = CondCode;
let MCOperandPredicate = [{
return MCOp.isImm() &&
MCOp.getImm() != AArch64CC::AL &&
MCOp.getImm() != AArch64CC::NV;
}];
}
// Conditional branch target. 19-bit immediate. The low two bits of the target
// offset are implied zero and so are not part of the immediate.
def am_brcond : Operand<OtherVT> {
let EncoderMethod = "getCondBranchTargetOpValue";
let DecoderMethod = "DecodePCRelLabel19";
let PrintMethod = "printAlignedLabel";
let ParserMatchClass = PCRelLabel19Operand;
}
class BranchCond : I<(outs), (ins ccode:$cond, am_brcond:$target),
"b", ".$cond\t$target", "",
[(AArch64brcond bb:$target, imm:$cond, NZCV)]>,
Sched<[WriteBr]> {
let isBranch = 1;
let isTerminator = 1;
let Uses = [NZCV];
bits<4> cond;
bits<19> target;
let Inst{31-24} = 0b01010100;
let Inst{23-5} = target;
let Inst{4} = 0;
let Inst{3-0} = cond;
}
//---
// Compare-and-branch instructions.
//---
class BaseCmpBranch<RegisterClass regtype, bit op, string asm, SDNode node>
: I<(outs), (ins regtype:$Rt, am_brcond:$target),
asm, "\t$Rt, $target", "",
[(node regtype:$Rt, bb:$target)]>,
Sched<[WriteBr]> {
let isBranch = 1;
let isTerminator = 1;
bits<5> Rt;
bits<19> target;
let Inst{30-25} = 0b011010;
let Inst{24} = op;
let Inst{23-5} = target;
let Inst{4-0} = Rt;
}
multiclass CmpBranch<bit op, string asm, SDNode node> {
def W : BaseCmpBranch<GPR32, op, asm, node> {
let Inst{31} = 0;
}
def X : BaseCmpBranch<GPR64, op, asm, node> {
let Inst{31} = 1;
}
}
//---
// Test-bit-and-branch instructions.
//---
// Test-and-branch target. 14-bit sign-extended immediate. The low two bits of
// the target offset are implied zero and so are not part of the immediate.
def am_tbrcond : Operand<OtherVT> {
let EncoderMethod = "getTestBranchTargetOpValue";
let PrintMethod = "printAlignedLabel";
let ParserMatchClass = BranchTarget14Operand;
}
// AsmOperand classes to emit (or not) special diagnostics
def TBZImm0_31Operand : AsmOperandClass {
let Name = "TBZImm0_31";
let PredicateMethod = "isImmInRange<0,31>";
let RenderMethod = "addImm0_31Operands";
}
def TBZImm32_63Operand : AsmOperandClass {
let Name = "Imm32_63";
let PredicateMethod = "isImmInRange<32,63>";
let DiagnosticType = "InvalidImm0_63";
}
class tbz_imm0_31<AsmOperandClass matcher> : Operand<i64>, ImmLeaf<i64, [{
return (((uint32_t)Imm) < 32);
}]> {
let ParserMatchClass = matcher;
}
def tbz_imm0_31_diag : tbz_imm0_31<Imm0_31Operand>;
def tbz_imm0_31_nodiag : tbz_imm0_31<TBZImm0_31Operand>;
def tbz_imm32_63 : Operand<i64>, ImmLeaf<i64, [{
return (((uint32_t)Imm) > 31) && (((uint32_t)Imm) < 64);
}]> {
let ParserMatchClass = TBZImm32_63Operand;
}
class BaseTestBranch<RegisterClass regtype, Operand immtype,
bit op, string asm, SDNode node>
: I<(outs), (ins regtype:$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<bit op, string asm, SDNode node> {
def W : BaseTestBranch<GPR32, tbz_imm0_31_diag, op, asm, node> {
let Inst{31} = 0;
}
def X : BaseTestBranch<GPR64, tbz_imm32_63, op, asm, node> {
let Inst{31} = 1;
}
// Alias X-reg with 0-31 imm to W-Reg.
def : InstAlias<asm # "\t$Rd, $imm, $target",
(!cast<Instruction>(NAME#"W") GPR32as64:$Rd,
tbz_imm0_31_nodiag:$imm, am_tbrcond:$target), 0>;
def : Pat<(node GPR64:$Rn, tbz_imm0_31_diag:$imm, bb:$target),
(!cast<Instruction>(NAME#"W") (EXTRACT_SUBREG GPR64:$Rn, sub_32),
tbz_imm0_31_diag:$imm, bb:$target)>;
}
//---
// Unconditional branch (immediate) instructions.
//---
def am_b_target : Operand<OtherVT> {
let EncoderMethod = "getBranchTargetOpValue";
let PrintMethod = "printAlignedLabel";
let ParserMatchClass = BranchTarget26Operand;
}
def am_bl_target : Operand<i64> {
let EncoderMethod = "getBranchTargetOpValue";
let PrintMethod = "printAlignedLabel";
let ParserMatchClass = BranchTarget26Operand;
}
class BImm<bit op, dag iops, string asm, list<dag> pattern>
: I<(outs), iops, asm, "\t$addr", "", pattern>, Sched<[WriteBr]> {
bits<26> addr;
let Inst{31} = op;
let Inst{30-26} = 0b00101;
let Inst{25-0} = addr;
let DecoderMethod = "DecodeUnconditionalBranch";
}
class BranchImm<bit op, string asm, list<dag> pattern>
: BImm<op, (ins am_b_target:$addr), asm, pattern>;
class CallImm<bit op, string asm, list<dag> pattern>
: BImm<op, (ins am_bl_target:$addr), asm, pattern>;
//---
// Basic one-operand data processing instructions.
//---
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseOneOperandData<bits<3> opc, RegisterClass regtype, string asm,
SDPatternOperator node>
: I<(outs regtype:$Rd), (ins regtype:$Rn), asm, "\t$Rd, $Rn", "",
[(set regtype:$Rd, (node regtype:$Rn))]>,
Sched<[WriteI, ReadI]> {
bits<5> Rd;
bits<5> Rn;
let Inst{30-13} = 0b101101011000000000;
let Inst{12-10} = opc;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
multiclass OneOperandData<bits<3> opc, string asm,
SDPatternOperator node = null_frag> {
def Wr : BaseOneOperandData<opc, GPR32, asm, node> {
let Inst{31} = 0;
}
def Xr : BaseOneOperandData<opc, GPR64, asm, node> {
let Inst{31} = 1;
}
}
class OneWRegData<bits<3> opc, string asm, SDPatternOperator node>
: BaseOneOperandData<opc, GPR32, asm, node> {
let Inst{31} = 0;
}
class OneXRegData<bits<3> opc, string asm, SDPatternOperator node>
: BaseOneOperandData<opc, GPR64, asm, node> {
let Inst{31} = 1;
}
class SignAuthOneData<bits<3> opcode_prefix, bits<2> opcode, string asm>
: I<(outs GPR64:$Rd), (ins GPR64sp:$Rn), asm, "\t$Rd, $Rn", "",
[]>,
Sched<[WriteI, ReadI]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31-15} = 0b11011010110000010;
let Inst{14-12} = opcode_prefix;
let Inst{11-10} = opcode;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
class SignAuthZero<bits<3> opcode_prefix, bits<2> opcode, string asm>
: I<(outs GPR64:$Rd), (ins), asm, "\t$Rd", "", []>, Sched<[]> {
bits<5> Rd;
let Inst{31-15} = 0b11011010110000010;
let Inst{14-12} = opcode_prefix;
let Inst{11-10} = opcode;
let Inst{9-5} = 0b11111;
let Inst{4-0} = Rd;
}
class SignAuthTwoOperand<bits<4> opc, string asm,
SDPatternOperator OpNode>
: I<(outs GPR64:$Rd), (ins GPR64:$Rn, GPR64sp:$Rm),
asm, "\t$Rd, $Rn, $Rm", "",
[(set GPR64:$Rd, (OpNode GPR64:$Rn, GPR64sp:$Rm))]>,
Sched<[WriteI, ReadI, ReadI]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
let Inst{31-21} = 0b10011010110;
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;
}
//---
// Basic two-operand data processing instructions.
//---
class BaseBaseAddSubCarry<bit isSub, RegisterClass regtype, string asm,
list<dag> pattern>
: I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm),
asm, "\t$Rd, $Rn, $Rm", "", pattern>,
Sched<[WriteI, ReadI, ReadI]> {
let Uses = [NZCV];
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
let Inst{30} = isSub;
let Inst{28-21} = 0b11010000;
let Inst{20-16} = Rm;
let Inst{15-10} = 0;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
class BaseAddSubCarry<bit isSub, RegisterClass regtype, string asm,
SDNode OpNode>
: BaseBaseAddSubCarry<isSub, regtype, asm,
[(set regtype:$Rd, (OpNode regtype:$Rn, regtype:$Rm, NZCV))]>;
class BaseAddSubCarrySetFlags<bit isSub, RegisterClass regtype, string asm,
SDNode OpNode>
: BaseBaseAddSubCarry<isSub, regtype, asm,
[(set regtype:$Rd, (OpNode regtype:$Rn, regtype:$Rm, NZCV)),
(implicit NZCV)]> {
let Defs = [NZCV];
}
multiclass AddSubCarry<bit isSub, string asm, string asm_setflags,
SDNode OpNode, SDNode OpNode_setflags> {
def Wr : BaseAddSubCarry<isSub, GPR32, asm, OpNode> {
let Inst{31} = 0;
let Inst{29} = 0;
}
def Xr : BaseAddSubCarry<isSub, GPR64, asm, OpNode> {
let Inst{31} = 1;
let Inst{29} = 0;
}
// Sets flags.
def SWr : BaseAddSubCarrySetFlags<isSub, GPR32, asm_setflags,
OpNode_setflags> {
let Inst{31} = 0;
let Inst{29} = 1;
}
def SXr : BaseAddSubCarrySetFlags<isSub, GPR64, asm_setflags,
OpNode_setflags> {
let Inst{31} = 1;
let Inst{29} = 1;
}
}
class BaseTwoOperand<bits<4> opc, RegisterClass regtype, string asm,
SDPatternOperator OpNode>
: I<(outs regtype:$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<bit isSigned, RegisterClass regtype, string asm,
SDPatternOperator OpNode>
: BaseTwoOperand<{0,0,1,?}, regtype, asm, OpNode> {
let Inst{10} = isSigned;
}
multiclass Div<bit isSigned, string asm, SDPatternOperator OpNode> {
def Wr : BaseDiv<isSigned, GPR32, asm, OpNode>,
Sched<[WriteID32, ReadID, ReadID]> {
let Inst{31} = 0;
}
def Xr : BaseDiv<isSigned, GPR64, asm, OpNode>,
Sched<[WriteID64, ReadID, ReadID]> {
let Inst{31} = 1;
}
}
class BaseShift<bits<2> 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<bits<2> shift_type, string asm, SDNode OpNode> {
def Wr : BaseShift<shift_type, GPR32, asm> {
let Inst{31} = 0;
}
def Xr : BaseShift<shift_type, GPR64, asm, OpNode> {
let Inst{31} = 1;
}
def : Pat<(i32 (OpNode GPR32:$Rn, i64:$Rm)),
(!cast<Instruction>(NAME # "Wr") GPR32:$Rn,
(EXTRACT_SUBREG i64:$Rm, sub_32))>;
def : Pat<(i32 (OpNode GPR32:$Rn, (i64 (zext GPR32:$Rm)))),
(!cast<Instruction>(NAME # "Wr") GPR32:$Rn, GPR32:$Rm)>;
def : Pat<(i32 (OpNode GPR32:$Rn, (i64 (anyext GPR32:$Rm)))),
(!cast<Instruction>(NAME # "Wr") GPR32:$Rn, GPR32:$Rm)>;
def : Pat<(i32 (OpNode GPR32:$Rn, (i64 (sext GPR32:$Rm)))),
(!cast<Instruction>(NAME # "Wr") GPR32:$Rn, GPR32:$Rm)>;
}
class ShiftAlias<string asm, Instruction inst, RegisterClass regtype>
: InstAlias<asm#"\t$dst, $src1, $src2",
(inst regtype:$dst, regtype:$src1, regtype:$src2), 0>;
class BaseMulAccum<bit isSub, bits<3> opc, RegisterClass multype,
RegisterClass addtype, string asm,
list<dag> pattern>
: I<(outs addtype:$Rd), (ins multype:$Rn, multype:$Rm, addtype:$Ra),
asm, "\t$Rd, $Rn, $Rm, $Ra", "", pattern> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
bits<5> Ra;
let Inst{30-24} = 0b0011011;
let Inst{23-21} = opc;
let Inst{20-16} = Rm;
let Inst{15} = isSub;
let Inst{14-10} = Ra;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass MulAccum<bit isSub, string asm, SDNode AccNode> {
// MADD/MSUB generation is decided by MachineCombiner.cpp
def Wrrr : BaseMulAccum<isSub, 0b000, GPR32, GPR32, asm,
[/*(set GPR32:$Rd, (AccNode GPR32:$Ra, (mul GPR32:$Rn, GPR32:$Rm)))*/]>,
Sched<[WriteIM32, ReadIM, ReadIM, ReadIMA]> {
let Inst{31} = 0;
}
def Xrrr : BaseMulAccum<isSub, 0b000, GPR64, GPR64, asm,
[/*(set GPR64:$Rd, (AccNode GPR64:$Ra, (mul GPR64:$Rn, GPR64:$Rm)))*/]>,
Sched<[WriteIM64, ReadIM, ReadIM, ReadIMA]> {
let Inst{31} = 1;
}
}
class WideMulAccum<bit isSub, bits<3> opc, string asm,
SDNode AccNode, SDNode ExtNode>
: BaseMulAccum<isSub, opc, GPR32, GPR64, asm,
[(set GPR64:$Rd, (AccNode GPR64:$Ra,
(mul (ExtNode GPR32:$Rn), (ExtNode GPR32:$Rm))))]>,
Sched<[WriteIM32, ReadIM, ReadIM, ReadIMA]> {
let Inst{31} = 1;
}
class MulHi<bits<3> opc, string asm, SDNode OpNode>
: I<(outs GPR64:$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<string asm, Instruction inst>
: InstAlias<asm#"\t$dst, $src1, $src2",
(inst GPR32:$dst, GPR32:$src1, GPR32:$src2, WZR)>;
class MulAccumXAlias<string asm, Instruction inst>
: InstAlias<asm#"\t$dst, $src1, $src2",
(inst GPR64:$dst, GPR64:$src1, GPR64:$src2, XZR)>;
class WideMulAccumAlias<string asm, Instruction inst>
: InstAlias<asm#"\t$dst, $src1, $src2",
(inst GPR64:$dst, GPR32:$src1, GPR32:$src2, XZR)>;
class BaseCRC32<bit sf, bits<2> 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<bit page, string asm, Operand adr, list<dag> pattern>
: I<(outs GPR64:$Xd), (ins adr:$label), asm, "\t$Xd, $label", "",
pattern>,
Sched<[WriteI]> {
bits<5> Xd;
bits<21> label;
let Inst{31} = page;
let Inst{30-29} = label{1-0};
let Inst{28-24} = 0b10000;
let Inst{23-5} = label{20-2};
let Inst{4-0} = Xd;
let DecoderMethod = "DecodeAdrInstruction";
}
//---
// Move immediate.
//---
def movimm32_imm : Operand<i32> {
let ParserMatchClass = Imm0_65535Operand;
let EncoderMethod = "getMoveWideImmOpValue";
let PrintMethod = "printImm";
}
def movimm32_shift : Operand<i32> {
let PrintMethod = "printShifter";
let ParserMatchClass = MovImm32ShifterOperand;
}
def movimm64_shift : Operand<i32> {
let PrintMethod = "printShifter";
let ParserMatchClass = MovImm64ShifterOperand;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseMoveImmediate<bits<2> opc, RegisterClass regtype, Operand shifter,
string asm>
: I<(outs regtype:$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<bits<2> opc, string asm> {
def Wi : BaseMoveImmediate<opc, GPR32, movimm32_shift, asm> {
let Inst{31} = 0;
}
def Xi : BaseMoveImmediate<opc, GPR64, movimm64_shift, asm> {
let Inst{31} = 1;
}
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseInsertImmediate<bits<2> 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 = $Rd", []>,
Sched<[WriteI, ReadI]> {
bits<5> Rd;
bits<16> imm;
bits<6> shift;
let Inst{30-29} = opc;
let Inst{28-23} = 0b100101;
let Inst{22-21} = shift{5-4};
let Inst{20-5} = imm;
let Inst{4-0} = Rd;
let DecoderMethod = "DecodeMoveImmInstruction";
}
multiclass InsertImmediate<bits<2> opc, string asm> {
def Wi : BaseInsertImmediate<opc, GPR32, movimm32_shift, asm> {
let Inst{31} = 0;
}
def Xi : BaseInsertImmediate<opc, GPR64, movimm64_shift, asm> {
let Inst{31} = 1;
}
}
//---
// Add/Subtract
//---
class BaseAddSubImm<bit isSub, bit setFlags, RegisterClass dstRegtype,
RegisterClass srcRegtype, addsub_shifted_imm immtype,
string asm, SDPatternOperator OpNode>
: I<(outs dstRegtype:$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<RegisterClass regtype,
SDPatternOperator OpNode>
: Pseudo<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm),
[(set regtype:$Rd, (OpNode regtype:$Rn, regtype:$Rm))]>,
Sched<[WriteI, ReadI, ReadI]>;
class BaseAddSubSReg<bit isSub, bit setFlags, RegisterClass regtype,
arith_shifted_reg shifted_regtype, string asm,
SDPatternOperator OpNode>
: 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<bit isSub, bit setFlags, RegisterClass dstRegtype,
RegisterClass src1Regtype, Operand src2Regtype,
string asm, SDPatternOperator OpNode>
: 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<bit isSub, bit setFlags, RegisterClass dstRegtype,
RegisterClass src1Regtype, RegisterClass src2Regtype,
Operand ext_op, string asm>
: 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<string asm, Instruction inst, RegisterClass dstRegtype,
RegisterClass src1Regtype, RegisterClass src2Regtype,
int shiftExt>
: InstAlias<asm#"\t$dst, $src1, $src2",
(inst dstRegtype:$dst, src1Regtype:$src1, src2Regtype:$src2,
shiftExt)>;
multiclass AddSub<bit isSub, string mnemonic, string alias,
SDPatternOperator OpNode = null_frag> {
let hasSideEffects = 0, isReMaterializable = 1, isAsCheapAsAMove = 1 in {
// Add/Subtract immediate
// Increase the weight of the immediate variant to try to match it before
// the extended register variant.
// We used to match the register variant before the immediate when the
// register argument could be implicitly zero-extended.
let AddedComplexity = 6 in
def Wri : BaseAddSubImm<isSub, 0, GPR32sp, GPR32sp, addsub_shifted_imm32,
mnemonic, OpNode> {
let Inst{31} = 0;
}
let AddedComplexity = 6 in
def Xri : BaseAddSubImm<isSub, 0, GPR64sp, GPR64sp, addsub_shifted_imm64,
mnemonic, OpNode> {
let Inst{31} = 1;
}
// Add/Subtract register - Only used for CodeGen
def Wrr : BaseAddSubRegPseudo<GPR32, OpNode>;
def Xrr : BaseAddSubRegPseudo<GPR64, OpNode>;
// Add/Subtract shifted register
def Wrs : BaseAddSubSReg<isSub, 0, GPR32, arith_shifted_reg32, mnemonic,
OpNode> {
let Inst{31} = 0;
}
def Xrs : BaseAddSubSReg<isSub, 0, GPR64, arith_shifted_reg64, mnemonic,
OpNode> {
let Inst{31} = 1;
}
}
// Add/Subtract extended register
let AddedComplexity = 1, hasSideEffects = 0 in {
def Wrx : BaseAddSubEReg<isSub, 0, GPR32sp, GPR32sp,
arith_extended_reg32<i32>, mnemonic, OpNode> {
let Inst{31} = 0;
}
def Xrx : BaseAddSubEReg<isSub, 0, GPR64sp, GPR64sp,
arith_extended_reg32to64<i64>, mnemonic, OpNode> {
let Inst{31} = 1;
}
}
def Xrx64 : BaseAddSubEReg64<isSub, 0, GPR64sp, GPR64sp, GPR64,
arith_extendlsl64, mnemonic> {
// UXTX and SXTX only.
let Inst{14-13} = 0b11;
let Inst{31} = 1;
}
// add Rd, Rb, -imm -> sub Rd, Rn, imm
def : InstSubst<alias#"\t$Rd, $Rn, $imm",
(!cast<Instruction>(NAME # "Wri") GPR32sp:$Rd, GPR32sp:$Rn,
addsub_shifted_imm32_neg:$imm), 0>;
def : InstSubst<alias#"\t$Rd, $Rn, $imm",
(!cast<Instruction>(NAME # "Xri") GPR64sp:$Rd, GPR64sp:$Rn,
addsub_shifted_imm64_neg:$imm), 0>;
// Register/register aliases with no shift when SP is not used.
def : AddSubRegAlias<mnemonic, !cast<Instruction>(NAME#"Wrs"),
GPR32, GPR32, GPR32, 0>;
def : AddSubRegAlias<mnemonic, !cast<Instruction>(NAME#"Xrs"),
GPR64, GPR64, GPR64, 0>;
// Register/register aliases with no shift when either the destination or
// first source register is SP.
def : AddSubRegAlias<mnemonic, !cast<Instruction>(NAME#"Wrx"),
GPR32sponly, GPR32sp, GPR32, 16>; // UXTW #0
def : AddSubRegAlias<mnemonic, !cast<Instruction>(NAME#"Wrx"),
GPR32sp, GPR32sponly, GPR32, 16>; // UXTW #0
def : AddSubRegAlias<mnemonic,
!cast<Instruction>(NAME#"Xrx64"),
GPR64sponly, GPR64sp, GPR64, 24>; // UXTX #0
def : AddSubRegAlias<mnemonic,
!cast<Instruction>(NAME#"Xrx64"),
GPR64sp, GPR64sponly, GPR64, 24>; // UXTX #0
}
multiclass AddSubS<bit isSub, string mnemonic, SDNode OpNode, string cmp,
string alias, string cmpAlias> {
let isCompare = 1, Defs = [NZCV] in {
// Add/Subtract immediate
def Wri : BaseAddSubImm<isSub, 1, GPR32, GPR32sp, addsub_shifted_imm32,
mnemonic, OpNode> {
let Inst{31} = 0;
}
def Xri : BaseAddSubImm<isSub, 1, GPR64, GPR64sp, addsub_shifted_imm64,
mnemonic, OpNode> {
let Inst{31} = 1;
}
// Add/Subtract register
def Wrr : BaseAddSubRegPseudo<GPR32, OpNode>;
def Xrr : BaseAddSubRegPseudo<GPR64, OpNode>;
// Add/Subtract shifted register
def Wrs : BaseAddSubSReg<isSub, 1, GPR32, arith_shifted_reg32, mnemonic,
OpNode> {
let Inst{31} = 0;
}
def Xrs : BaseAddSubSReg<isSub, 1, GPR64, arith_shifted_reg64, mnemonic,
OpNode> {
let Inst{31} = 1;
}
// Add/Subtract extended register
let AddedComplexity = 1 in {
def Wrx : BaseAddSubEReg<isSub, 1, GPR32, GPR32sp,
arith_extended_reg32<i32>, mnemonic, OpNode> {
let Inst{31} = 0;
}
def Xrx : BaseAddSubEReg<isSub, 1, GPR64, GPR64sp,
arith_extended_reg32<i64>, mnemonic, OpNode> {
let Inst{31} = 1;
}
}
def Xrx64 : BaseAddSubEReg64<isSub, 1, GPR64, GPR64sp, GPR64,
arith_extendlsl64, mnemonic> {
// UXTX and SXTX only.
let Inst{14-13} = 0b11;
let Inst{31} = 1;
}
} // Defs = [NZCV]
// Support negative immediates, e.g. adds Rd, Rn, -imm -> subs Rd, Rn, imm
def : InstSubst<alias#"\t$Rd, $Rn, $imm",
(!cast<Instruction>(NAME # "Wri") GPR32:$Rd, GPR32sp:$Rn,
addsub_shifted_imm32_neg:$imm), 0>;
def : InstSubst<alias#"\t$Rd, $Rn, $imm",
(!cast<Instruction>(NAME # "Xri") GPR64:$Rd, GPR64sp:$Rn,
addsub_shifted_imm64_neg:$imm), 0>;
// Compare aliases
def : InstAlias<cmp#"\t$src, $imm", (!cast<Instruction>(NAME#"Wri")
WZR, GPR32sp:$src, addsub_shifted_imm32:$imm), 5>;
def : InstAlias<cmp#"\t$src, $imm", (!cast<Instruction>(NAME#"Xri")
XZR, GPR64sp:$src, addsub_shifted_imm64:$imm), 5>;
def : InstAlias<cmp#"\t$src1, $src2$sh", (!cast<Instruction>(NAME#"Wrx")
WZR, GPR32sp:$src1, GPR32:$src2, arith_extend:$sh), 4>;
def : InstAlias<cmp#"\t$src1, $src2$sh", (!cast<Instruction>(NAME#"Xrx")
XZR, GPR64sp:$src1, GPR32:$src2, arith_extend:$sh), 4>;
def : InstAlias<cmp#"\t$src1, $src2$sh", (!cast<Instruction>(NAME#"Xrx64")
XZR, GPR64sp:$src1, GPR64:$src2, arith_extendlsl64:$sh), 4>;
def : InstAlias<cmp#"\t$src1, $src2$sh", (!cast<Instruction>(NAME#"Wrs")
WZR, GPR32:$src1, GPR32:$src2, arith_shift32:$sh), 4>;
def : InstAlias<cmp#"\t$src1, $src2$sh", (!cast<Instruction>(NAME#"Xrs")
XZR, GPR64:$src1, GPR64:$src2, arith_shift64:$sh), 4>;
// Support negative immediates, e.g. cmp Rn, -imm -> cmn Rn, imm
def : InstSubst<cmpAlias#"\t$src, $imm", (!cast<Instruction>(NAME#"Wri")
WZR, GPR32sp:$src, addsub_shifted_imm32_neg:$imm), 0>;
def : InstSubst<cmpAlias#"\t$src, $imm", (!cast<Instruction>(NAME#"Xri")
XZR, GPR64sp:$src, addsub_shifted_imm64_neg:$imm), 0>;
// Compare shorthands
def : InstAlias<cmp#"\t$src1, $src2", (!cast<Instruction>(NAME#"Wrs")
WZR, GPR32:$src1, GPR32:$src2, 0), 5>;
def : InstAlias<cmp#"\t$src1, $src2", (!cast<Instruction>(NAME#"Xrs")
XZR, GPR64:$src1, GPR64:$src2, 0), 5>;
def : InstAlias<cmp#"\t$src1, $src2", (!cast<Instruction>(NAME#"Wrx")
WZR, GPR32sponly:$src1, GPR32:$src2, 16), 5>;
def : InstAlias<cmp#"\t$src1, $src2", (!cast<Instruction>(NAME#"Xrx64")
XZR, GPR64sponly:$src1, GPR64:$src2, 24), 5>;
// Register/register aliases with no shift when SP is not used.
def : AddSubRegAlias<mnemonic, !cast<Instruction>(NAME#"Wrs"),
GPR32, GPR32, GPR32, 0>;
def : AddSubRegAlias<mnemonic, !cast<Instruction>(NAME#"Xrs"),
GPR64, GPR64, GPR64, 0>;
// Register/register aliases with no shift when the first source register
// is SP.
def : AddSubRegAlias<mnemonic, !cast<Instruction>(NAME#"Wrx"),
GPR32, GPR32sponly, GPR32, 16>; // UXTW #0
def : AddSubRegAlias<mnemonic,
!cast<Instruction>(NAME#"Xrx64"),
GPR64, GPR64sponly, GPR64, 24>; // UXTX #0
}
//---
// Extract
//---
def SDTA64EXTR : SDTypeProfile<1, 3, [SDTCisSameAs<0, 1>, SDTCisSameAs<0, 2>,
SDTCisPtrTy<3>]>;
def AArch64Extr : SDNode<"AArch64ISD::EXTR", SDTA64EXTR>;
class BaseExtractImm<RegisterClass regtype, Operand imm_type, string asm,
list<dag> patterns>
: I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm, imm_type:$imm),
asm, "\t$Rd, $Rn, $Rm, $imm", "", patterns>,
Sched<[WriteExtr, ReadExtrHi]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
bits<6> imm;
let Inst{30-23} = 0b00100111;
let Inst{21} = 0;
let Inst{20-16} = Rm;
let Inst{15-10} = imm;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass ExtractImm<string asm> {
def Wrri : BaseExtractImm<GPR32, imm0_31, asm,
[(set GPR32:$Rd,
(AArch64Extr GPR32:$Rn, GPR32:$Rm, imm0_31:$imm))]> {
let Inst{31} = 0;
let Inst{22} = 0;
// imm<5> must be zero.
let imm{5} = 0;
}
def Xrri : BaseExtractImm<GPR64, imm0_63, asm,
[(set GPR64:$Rd,
(AArch64Extr GPR64:$Rn, GPR64:$Rm, imm0_63:$imm))]> {
let Inst{31} = 1;
let Inst{22} = 1;
}
}
//---
// Bitfield
//---
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseBitfieldImm<bits<2> opc,
RegisterClass regtype, Operand imm_type, string asm>
: I<(outs regtype:$Rd), (ins regtype:$Rn, imm_type:$immr, imm_type:$imms),
asm, "\t$Rd, $Rn, $immr, $imms", "", []>,
Sched<[WriteIS, ReadI]> {
bits<5> Rd;
bits<5> Rn;
bits<6> immr;
bits<6> imms;
let Inst{30-29} = opc;
let Inst{28-23} = 0b100110;
let Inst{21-16} = immr;
let Inst{15-10} = imms;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass BitfieldImm<bits<2> opc, string asm> {
def Wri : BaseBitfieldImm<opc, GPR32, imm0_31, asm> {
let Inst{31} = 0;
let Inst{22} = 0;
// imms<5> and immr<5> must be zero, else ReservedValue().
let Inst{21} = 0;
let Inst{15} = 0;
}
def Xri : BaseBitfieldImm<opc, GPR64, imm0_63, asm> {
let Inst{31} = 1;
let Inst{22} = 1;
}
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseBitfieldImmWith2RegArgs<bits<2> opc,
RegisterClass regtype, Operand imm_type, string asm>
: I<(outs regtype:$Rd), (ins regtype:$src, regtype:$Rn, imm_type:$immr,
imm_type:$imms),
asm, "\t$Rd, $Rn, $immr, $imms", "$src = $Rd", []>,
Sched<[WriteIS, ReadI]> {
bits<5> Rd;
bits<5> Rn;
bits<6> immr;
bits<6> imms;
let Inst{30-29} = opc;
let Inst{28-23} = 0b100110;
let Inst{21-16} = immr;
let Inst{15-10} = imms;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass BitfieldImmWith2RegArgs<bits<2> opc, string asm> {
def Wri : BaseBitfieldImmWith2RegArgs<opc, GPR32, imm0_31, asm> {
let Inst{31} = 0;
let Inst{22} = 0;
// imms<5> and immr<5> must be zero, else ReservedValue().
let Inst{21} = 0;
let Inst{15} = 0;
}
def Xri : BaseBitfieldImmWith2RegArgs<opc, GPR64, imm0_63, asm> {
let Inst{31} = 1;
let Inst{22} = 1;
}
}
//---
// Logical
//---
// Logical (immediate)
class BaseLogicalImm<bits<2> opc, RegisterClass dregtype,
RegisterClass sregtype, Operand imm_type, string asm,
list<dag> pattern>
: I<(outs dregtype:$Rd), (ins sregtype:$Rn, imm_type:$imm),
asm, "\t$Rd, $Rn, $imm", "", pattern>,
Sched<[WriteI, ReadI]> {
bits<5> Rd;
bits<5> Rn;
bits<13> imm;
let Inst{30-29} = opc;
let Inst{28-23} = 0b100100;
let Inst{22} = imm{12};
let Inst{21-16} = imm{11-6};
let Inst{15-10} = imm{5-0};
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
let DecoderMethod = "DecodeLogicalImmInstruction";
}
// Logical (shifted register)
class BaseLogicalSReg<bits<2> opc, bit N, RegisterClass regtype,
logical_shifted_reg shifted_regtype, string asm,
list<dag> pattern>
: I<(outs regtype:$Rd), (ins regtype:$Rn, shifted_regtype:$Rm),
asm, "\t$Rd, $Rn, $Rm", "", pattern>,
Sched<[WriteISReg, ReadI, ReadISReg]> {
// The operands are in order to match the 'addr' MI operands, so we
// don't need an encoder method and by-name matching. Just use the default
// in-order handling. Since we're using by-order, make sure the names
// do not match.
bits<5> dst;
bits<5> src1;
bits<5> src2;
bits<8> shift;
let Inst{30-29} = opc;
let Inst{28-24} = 0b01010;
let Inst{23-22} = shift{7-6};
let Inst{21} = N;
let Inst{20-16} = src2;
let Inst{15-10} = shift{5-0};
let Inst{9-5} = src1;
let Inst{4-0} = dst;
let DecoderMethod = "DecodeThreeAddrSRegInstruction";
}
// Aliases for register+register logical instructions.
class LogicalRegAlias<string asm, Instruction inst, RegisterClass regtype>
: InstAlias<asm#"\t$dst, $src1, $src2",
(inst regtype:$dst, regtype:$src1, regtype:$src2, 0)>;
multiclass LogicalImm<bits<2> opc, string mnemonic, SDNode OpNode,
string Alias> {
let AddedComplexity = 6, isReMaterializable = 1, isAsCheapAsAMove = 1 in
def Wri : BaseLogicalImm<opc, GPR32sp, GPR32, logical_imm32, mnemonic,
[(set GPR32sp:$Rd, (OpNode GPR32:$Rn,
logical_imm32:$imm))]> {
let Inst{31} = 0;
let Inst{22} = 0; // 64-bit version has an additional bit of immediate.
}
let AddedComplexity = 6, isReMaterializable = 1, isAsCheapAsAMove = 1 in
def Xri : BaseLogicalImm<opc, GPR64sp, GPR64, logical_imm64, mnemonic,
[(set GPR64sp:$Rd, (OpNode GPR64:$Rn,
logical_imm64:$imm))]> {
let Inst{31} = 1;
}
def : InstSubst<Alias # "\t$Rd, $Rn, $imm",
(!cast<Instruction>(NAME # "Wri") GPR32sp:$Rd, GPR32:$Rn,
logical_imm32_not:$imm), 0>;
def : InstSubst<Alias # "\t$Rd, $Rn, $imm",
(!cast<Instruction>(NAME # "Xri") GPR64sp:$Rd, GPR64:$Rn,
logical_imm64_not:$imm), 0>;
}
multiclass LogicalImmS<bits<2> opc, string mnemonic, SDNode OpNode,
string Alias> {
let isCompare = 1, Defs = [NZCV] in {
def Wri : BaseLogicalImm<opc, GPR32, GPR32, logical_imm32, mnemonic,
[(set GPR32:$Rd, (OpNode GPR32:$Rn, logical_imm32:$imm))]> {
let Inst{31} = 0;
let Inst{22} = 0; // 64-bit version has an additional bit of immediate.
}
def Xri : BaseLogicalImm<opc, GPR64, GPR64, logical_imm64, mnemonic,
[(set GPR64:$Rd, (OpNode GPR64:$Rn, logical_imm64:$imm))]> {
let Inst{31} = 1;
}
} // end Defs = [NZCV]
def : InstSubst<Alias # "\t$Rd, $Rn, $imm",
(!cast<Instruction>(NAME # "Wri") GPR32:$Rd, GPR32:$Rn,
logical_imm32_not:$imm), 0>;
def : InstSubst<Alias # "\t$Rd, $Rn, $imm",
(!cast<Instruction>(NAME # "Xri") GPR64:$Rd, GPR64:$Rn,
logical_imm64_not:$imm), 0>;
}
class BaseLogicalRegPseudo<RegisterClass regtype, SDPatternOperator OpNode>
: 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<bits<2> opc, bit N, string mnemonic,
SDPatternOperator OpNode> {
let isReMaterializable = 1, isAsCheapAsAMove = 1 in {
def Wrr : BaseLogicalRegPseudo<GPR32, OpNode>;
def Xrr : BaseLogicalRegPseudo<GPR64, OpNode>;
}
def Wrs : BaseLogicalSReg<opc, N, GPR32, logical_shifted_reg32, mnemonic,
[(set GPR32:$Rd, (OpNode GPR32:$Rn,
logical_shifted_reg32:$Rm))]> {
let Inst{31} = 0;
}
def Xrs : BaseLogicalSReg<opc, N, GPR64, logical_shifted_reg64, mnemonic,
[(set GPR64:$Rd, (OpNode GPR64:$Rn,
logical_shifted_reg64:$Rm))]> {
let Inst{31} = 1;
}
def : LogicalRegAlias<mnemonic,
!cast<Instruction>(NAME#"Wrs"), GPR32>;
def : LogicalRegAlias<mnemonic,
!cast<Instruction>(NAME#"Xrs"), GPR64>;
}
// Split from LogicalReg to allow setting NZCV Defs
multiclass LogicalRegS<bits<2> opc, bit N, string mnemonic,
SDPatternOperator OpNode = null_frag> {
let Defs = [NZCV], mayLoad = 0, mayStore = 0, hasSideEffects = 0 in {
def Wrr : BaseLogicalRegPseudo<GPR32, OpNode>;
def Xrr : BaseLogicalRegPseudo<GPR64, OpNode>;
def Wrs : BaseLogicalSReg<opc, N, GPR32, logical_shifted_reg32, mnemonic,
[(set GPR32:$Rd, (OpNode GPR32:$Rn, logical_shifted_reg32:$Rm))]> {
let Inst{31} = 0;
}
def Xrs : BaseLogicalSReg<opc, N, GPR64, logical_shifted_reg64, mnemonic,
[(set GPR64:$Rd, (OpNode GPR64:$Rn, logical_shifted_reg64:$Rm))]> {
let Inst{31} = 1;
}
} // Defs = [NZCV]
def : LogicalRegAlias<mnemonic,
!cast<Instruction>(NAME#"Wrs"), GPR32>;
def : LogicalRegAlias<mnemonic,
!cast<Instruction>(NAME#"Xrs"), GPR64>;
}
//---
// Conditionally set flags
//---
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseCondComparisonImm<bit op, RegisterClass regtype, ImmLeaf immtype,
string mnemonic, SDNode OpNode>
: I<(outs), (ins regtype:$Rn, immtype:$imm, imm32_0_15:$nzcv, ccode:$cond),
mnemonic, "\t$Rn, $imm, $nzcv, $cond", "",
[(set NZCV, (OpNode regtype:$Rn, immtype:$imm, (i32 imm:$nzcv),
(i32 imm:$cond), NZCV))]>,
Sched<[WriteI, ReadI]> {
let Uses = [NZCV];
let Defs = [NZCV];
bits<5> Rn;
bits<5> imm;
bits<4> nzcv;
bits<4> cond;
let Inst{30} = op;
let Inst{29-21} = 0b111010010;
let Inst{20-16} = imm;
let Inst{15-12} = cond;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4} = 0b0;
let Inst{3-0} = nzcv;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseCondComparisonReg<bit op, RegisterClass regtype, string mnemonic,
SDNode OpNode>
: I<(outs), (ins regtype:$Rn, regtype:$Rm, imm32_0_15:$nzcv, ccode:$cond),
mnemonic, "\t$Rn, $Rm, $nzcv, $cond", "",
[(set NZCV, (OpNode regtype:$Rn, regtype:$Rm, (i32 imm:$nzcv),
(i32 imm:$cond), NZCV))]>,
Sched<[WriteI, ReadI, ReadI]> {
let Uses = [NZCV];
let Defs = [NZCV];
bits<5> Rn;
bits<5> Rm;
bits<4> nzcv;
bits<4> cond;
let Inst{30} = op;
let Inst{29-21} = 0b111010010;
let Inst{20-16} = Rm;
let Inst{15-12} = cond;
let Inst{11-10} = 0b00;
let Inst{9-5} = Rn;
let Inst{4} = 0b0;
let Inst{3-0} = nzcv;
}
multiclass CondComparison<bit op, string mnemonic, SDNode OpNode> {
// immediate operand variants
def Wi : BaseCondComparisonImm<op, GPR32, imm32_0_31, mnemonic, OpNode> {
let Inst{31} = 0;
}
def Xi : BaseCondComparisonImm<op, GPR64, imm0_31, mnemonic, OpNode> {
let Inst{31} = 1;
}
// register operand variants
def Wr : BaseCondComparisonReg<op, GPR32, mnemonic, OpNode> {
let Inst{31} = 0;
}
def Xr : BaseCondComparisonReg<op, GPR64, mnemonic, OpNode> {
let Inst{31} = 1;
}
}
//---
// Conditional select
//---
class BaseCondSelect<bit op, bits<2> op2, RegisterClass regtype, string asm>
: I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm, ccode:$cond),
asm, "\t$Rd, $Rn, $Rm, $cond", "",
[(set regtype:$Rd,
(AArch64csel regtype:$Rn, regtype:$Rm, (i32 imm:$cond), NZCV))]>,
Sched<[WriteI, ReadI, ReadI]> {
let Uses = [NZCV];
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
bits<4> cond;
let Inst{30} = op;
let Inst{29-21} = 0b011010100;
let Inst{20-16} = Rm;
let Inst{15-12} = cond;
let Inst{11-10} = op2;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass CondSelect<bit op, bits<2> op2, string asm> {
def Wr : BaseCondSelect<op, op2, GPR32, asm> {
let Inst{31} = 0;
}
def Xr : BaseCondSelect<op, op2, GPR64, asm> {
let Inst{31} = 1;
}
}
class BaseCondSelectOp<bit op, bits<2> op2, RegisterClass regtype, string asm,
PatFrag frag>
: I<(outs regtype:$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:$cond), NZCV))]>,
Sched<[WriteI, ReadI, ReadI]> {
let Uses = [NZCV];
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
bits<4> cond;
let Inst{30} = op;
let Inst{29-21} = 0b011010100;
let Inst{20-16} = Rm;
let Inst{15-12} = cond;
let Inst{11-10} = op2;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
def inv_cond_XFORM : SDNodeXForm<imm, [{
AArch64CC::CondCode CC = static_cast<AArch64CC::CondCode>(N->getZExtValue());
return CurDAG->getTargetConstant(AArch64CC::getInvertedCondCode(CC), SDLoc(N),
MVT::i32);
}]>;
multiclass CondSelectOp<bit op, bits<2> op2, string asm, PatFrag frag> {
def Wr : BaseCondSelectOp<op, op2, GPR32, asm, frag> {
let Inst{31} = 0;
}
def Xr : BaseCondSelectOp<op, op2, GPR64, asm, frag> {
let Inst{31} = 1;
}
def : Pat<(AArch64csel (frag GPR32:$Rm), GPR32:$Rn, (i32 imm:$cond), NZCV),
(!cast<Instruction>(NAME # Wr) GPR32:$Rn, GPR32:$Rm,
(inv_cond_XFORM imm:$cond))>;
def : Pat<(AArch64csel (frag GPR64:$Rm), GPR64:$Rn, (i32 imm:$cond), NZCV),
(!cast<Instruction>(NAME # Xr) GPR64:$Rn, GPR64:$Rm,
(inv_cond_XFORM imm:$cond))>;
}
//---
// Special Mask Value
//---
def maski8_or_more : Operand<i32>,
ImmLeaf<i32, [{ return (Imm & 0xff) == 0xff; }]> {
}
def maski16_or_more : Operand<i32>,
ImmLeaf<i32, [{ return (Imm & 0xffff) == 0xffff; }]> {
}
//---
// Load/store
//---
// (unsigned immediate)
// Indexed for 8-bit registers. offset is in range [0,4095].
def am_indexed8 : ComplexPattern<i64, 2, "SelectAddrModeIndexed8", []>;
def am_indexed16 : ComplexPattern<i64, 2, "SelectAddrModeIndexed16", []>;
def am_indexed32 : ComplexPattern<i64, 2, "SelectAddrModeIndexed32", []>;
def am_indexed64 : ComplexPattern<i64, 2, "SelectAddrModeIndexed64", []>;
def am_indexed128 : ComplexPattern<i64, 2, "SelectAddrModeIndexed128", []>;
class UImm12OffsetOperand<int Scale> : AsmOperandClass {
let Name = "UImm12Offset" # Scale;
let RenderMethod = "addUImm12OffsetOperands<" # Scale # ">";
let PredicateMethod = "isUImm12Offset<" # Scale # ">";
let DiagnosticType = "InvalidMemoryIndexed" # Scale;
}
def UImm12OffsetScale1Operand : UImm12OffsetOperand<1>;
def UImm12OffsetScale2Operand : UImm12OffsetOperand<2>;
def UImm12OffsetScale4Operand : UImm12OffsetOperand<4>;
def UImm12OffsetScale8Operand : UImm12OffsetOperand<8>;
def UImm12OffsetScale16Operand : UImm12OffsetOperand<16>;
class uimm12_scaled<int Scale> : Operand<i64> {
let ParserMatchClass
= !cast<AsmOperandClass>("UImm12OffsetScale" # Scale # "Operand");
let EncoderMethod
= "getLdStUImm12OpValue<AArch64::fixup_aarch64_ldst_imm12_scale" # Scale # ">";
let PrintMethod = "printUImm12Offset<" # Scale # ">";
}
def uimm12s1 : uimm12_scaled<1>;
def uimm12s2 : uimm12_scaled<2>;
def uimm12s4 : uimm12_scaled<4>;
def uimm12s8 : uimm12_scaled<8>;
def uimm12s16 : uimm12_scaled<16>;
class BaseLoadStoreUI<bits<2> sz, bit V, bits<2> opc, dag oops, dag iops,
string asm, list<dag> pattern>
: I<oops, iops, asm, "\t$Rt, [$Rn, $offset]", "", pattern> {
bits<5> Rt;
bits<5> Rn;
bits<12> offset;
let Inst{31-30} = sz;
let Inst{29-27} = 0b111;
let Inst{26} = V;
let Inst{25-24} = 0b01;
let Inst{23-22} = opc;
let Inst{21-10} = offset;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let DecoderMethod = "DecodeUnsignedLdStInstruction";
}
multiclass LoadUI<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
Operand indextype, string asm, list<dag> pattern> {
let AddedComplexity = 10, mayLoad = 1, mayStore = 0, hasSideEffects = 0 in
def ui : BaseLoadStoreUI<sz, V, opc, (outs regtype:$Rt),
(ins GPR64sp:$Rn, indextype:$offset),
asm, pattern>,
Sched<[WriteLD]>;
def : InstAlias<asm # "\t$Rt, [$Rn]",
(!cast<Instruction>(NAME # "ui") regtype:$Rt, GPR64sp:$Rn, 0)>;
}
multiclass StoreUI<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
Operand indextype, string asm, list<dag> pattern> {
let AddedComplexity = 10, mayLoad = 0, mayStore = 1, hasSideEffects = 0 in
def ui : BaseLoadStoreUI<sz, V, opc, (outs),
(ins regtype:$Rt, GPR64sp:$Rn, indextype:$offset),
asm, pattern>,
Sched<[WriteST]>;
def : InstAlias<asm # "\t$Rt, [$Rn]",
(!cast<Instruction>(NAME # "ui") regtype:$Rt, GPR64sp:$Rn, 0)>;
}
def PrefetchOperand : AsmOperandClass {
let Name = "Prefetch";
let ParserMethod = "tryParsePrefetch";
}
def prfop : Operand<i32> {
let PrintMethod = "printPrefetchOp";
let ParserMatchClass = PrefetchOperand;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 1 in
class PrefetchUI<bits<2> sz, bit V, bits<2> opc, string asm, list<dag> pat>
: BaseLoadStoreUI<sz, V, opc,
(outs), (ins prfop:$Rt, GPR64sp:$Rn, uimm12s8:$offset),
asm, pat>,
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<iPTR> {
let EncoderMethod = "getLoadLiteralOpValue";
let DecoderMethod = "DecodePCRelLabel19";
let PrintMethod = "printAlignedLabel";
let ParserMatchClass = PCRelLabel19Operand;
}
let mayLoad = 1, mayStore = 0, hasSideEffects = 0 in
class LoadLiteral<bits<2> opc, bit V, RegisterClass regtype, string asm>
: I<(outs regtype:$Rt), (ins am_ldrlit:$label),
asm, "\t$Rt, $label", "", []>,
Sched<[WriteLD]> {
bits<5> Rt;
bits<19> label;
let Inst{31-30} = opc;
let Inst{29-27} = 0b011;
let Inst{26} = V;
let Inst{25-24} = 0b00;
let Inst{23-5} = label;
let Inst{4-0} = Rt;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 1 in
class PrefetchLiteral<bits<2> opc, bit V, string asm, list<dag> pat>
: I<(outs), (ins prfop:$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<i64, 4, "SelectAddrModeXRO<8>", []>;
def ro_Xindexed16 : ComplexPattern<i64, 4, "SelectAddrModeXRO<16>", []>;
def ro_Xindexed32 : ComplexPattern<i64, 4, "SelectAddrModeXRO<32>", []>;
def ro_Xindexed64 : ComplexPattern<i64, 4, "SelectAddrModeXRO<64>", []>;
def ro_Xindexed128 : ComplexPattern<i64, 4, "SelectAddrModeXRO<128>", []>;
def ro_Windexed8 : ComplexPattern<i64, 4, "SelectAddrModeWRO<8>", []>;
def ro_Windexed16 : ComplexPattern<i64, 4, "SelectAddrModeWRO<16>", []>;
def ro_Windexed32 : ComplexPattern<i64, 4, "SelectAddrModeWRO<32>", []>;
def ro_Windexed64 : ComplexPattern<i64, 4, "SelectAddrModeWRO<64>", []>;
def ro_Windexed128 : ComplexPattern<i64, 4, "SelectAddrModeWRO<128>", []>;
class MemExtendOperand<string Reg, int Width> : AsmOperandClass {
let Name = "Mem" # Reg # "Extend" # Width;
let PredicateMethod = "isMem" # Reg # "Extend<" # Width # ">";
let RenderMethod = "addMemExtendOperands";
let DiagnosticType = "InvalidMemory" # Reg # "Extend" # Width;
}
def MemWExtend8Operand : MemExtendOperand<"W", 8> {
// The address "[x0, x1, lsl #0]" actually maps to the variant which performs
// the trivial shift.
let RenderMethod = "addMemExtend8Operands";
}
def MemWExtend16Operand : MemExtendOperand<"W", 16>;
def MemWExtend32Operand : MemExtendOperand<"W", 32>;
def MemWExtend64Operand : MemExtendOperand<"W", 64>;
def MemWExtend128Operand : MemExtendOperand<"W", 128>;
def MemXExtend8Operand : MemExtendOperand<"X", 8> {
// The address "[x0, x1, lsl #0]" actually maps to the variant which performs
// the trivial shift.
let RenderMethod = "addMemExtend8Operands";
}
def MemXExtend16Operand : MemExtendOperand<"X", 16>;
def MemXExtend32Operand : MemExtendOperand<"X", 32>;
def MemXExtend64Operand : MemExtendOperand<"X", 64>;
def MemXExtend128Operand : MemExtendOperand<"X", 128>;
class ro_extend<AsmOperandClass ParserClass, string Reg, int Width>
: Operand<i32> {
let ParserMatchClass = ParserClass;
let PrintMethod = "printMemExtend<'" # Reg # "', " # Width # ">";
let DecoderMethod = "DecodeMemExtend";
let EncoderMethod = "getMemExtendOpValue";
let MIOperandInfo = (ops i32imm:$signed, i32imm:$doshift);
}
def ro_Wextend8 : ro_extend<MemWExtend8Operand, "w", 8>;
def ro_Wextend16 : ro_extend<MemWExtend16Operand, "w", 16>;
def ro_Wextend32 : ro_extend<MemWExtend32Operand, "w", 32>;
def ro_Wextend64 : ro_extend<MemWExtend64Operand, "w", 64>;
def ro_Wextend128 : ro_extend<MemWExtend128Operand, "w", 128>;
def ro_Xextend8 : ro_extend<MemXExtend8Operand, "x", 8>;
def ro_Xextend16 : ro_extend<MemXExtend16Operand, "x", 16>;
def ro_Xextend32 : ro_extend<MemXExtend32Operand, "x", 32>;
def ro_Xextend64 : ro_extend<MemXExtend64Operand, "x", 64>;
def ro_Xextend128 : ro_extend<MemXExtend128Operand, "x", 128>;
class ROAddrMode<ComplexPattern windex, ComplexPattern xindex,
Operand wextend, Operand xextend> {
// CodeGen-level pattern covering the entire addressing mode.
ComplexPattern Wpat = windex;
ComplexPattern Xpat = xindex;
// Asm-level Operand covering the valid "uxtw #3" style syntax.
Operand Wext = wextend;
Operand Xext = xextend;
}
def ro8 : ROAddrMode<ro_Windexed8, ro_Xindexed8, ro_Wextend8, ro_Xextend8>;
def ro16 : ROAddrMode<ro_Windexed16, ro_Xindexed16, ro_Wextend16, ro_Xextend16>;
def ro32 : ROAddrMode<ro_Windexed32, ro_Xindexed32, ro_Wextend32, ro_Xextend32>;
def ro64 : ROAddrMode<ro_Windexed64, ro_Xindexed64, ro_Wextend64, ro_Xextend64>;
def ro128 : ROAddrMode<ro_Windexed128, ro_Xindexed128, ro_Wextend128,
ro_Xextend128>;
class LoadStore8RO<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, dag ins, dag outs, list<dag> pat>
: I<ins, outs, asm, "\t$Rt, [$Rn, $Rm, $extend]", "", pat> {
bits<5> Rt;
bits<5> Rn;
bits<5> Rm;
bits<2> extend;
let Inst{31-30} = sz;
let Inst{29-27} = 0b111;
let Inst{26} = V;
let Inst{25-24} = 0b00;
let Inst{23-22} = opc;
let Inst{21} = 1;
let Inst{20-16} = Rm;
let Inst{15} = extend{1}; // sign extend Rm?
let Inst{14} = 1;
let Inst{12} = extend{0}; // do shift?
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
}
class ROInstAlias<string asm, RegisterClass regtype, Instruction INST>
: InstAlias<asm # "\t$Rt, [$Rn, $Rm]",
(INST regtype:$Rt, GPR64sp:$Rn, GPR64:$Rm, 0, 0)>;
multiclass Load8RO<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, ValueType Ty, SDPatternOperator loadop> {
let AddedComplexity = 10 in
def roW : LoadStore8RO<sz, V, opc, regtype, asm,
(outs regtype:$Rt),
(ins GPR64sp:$Rn, GPR32:$Rm, ro_Wextend8:$extend),
[(set (Ty regtype:$Rt),
(loadop (ro_Windexed8 GPR64sp:$Rn, GPR32:$Rm,
ro_Wextend8:$extend)))]>,
Sched<[WriteLDIdx, ReadAdrBase]> {
let Inst{13} = 0b0;
}
let AddedComplexity = 10 in
def roX : LoadStore8RO<sz, V, opc, regtype, asm,
(outs regtype:$Rt),
(ins GPR64sp:$Rn, GPR64:$Rm, ro_Xextend8:$extend),
[(set (Ty regtype:$Rt),
(loadop (ro_Xindexed8 GPR64sp:$Rn, GPR64:$Rm,
ro_Xextend8:$extend)))]>,
Sched<[WriteLDIdx, ReadAdrBase]> {
let Inst{13} = 0b1;
}
def : ROInstAlias<asm, regtype, !cast<Instruction>(NAME # "roX")>;
}
multiclass Store8RO<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, ValueType Ty, SDPatternOperator storeop> {
let AddedComplexity = 10 in
def roW : LoadStore8RO<sz, V, opc, regtype, asm, (outs),
(ins regtype:$Rt, GPR64sp:$Rn, GPR32:$Rm, ro_Wextend8:$extend),
[(storeop (Ty regtype:$Rt),
(ro_Windexed8 GPR64sp:$Rn, GPR32:$Rm,
ro_Wextend8:$extend))]>,
Sched<[WriteSTIdx, ReadAdrBase]> {
let Inst{13} = 0b0;
}
let AddedComplexity = 10 in
def roX : LoadStore8RO<sz, V, opc, regtype, asm, (outs),
(ins regtype:$Rt, GPR64sp:$Rn, GPR64:$Rm, ro_Xextend8:$extend),
[(storeop (Ty regtype:$Rt),
(ro_Xindexed8 GPR64sp:$Rn, GPR64:$Rm,
ro_Xextend8:$extend))]>,
Sched<[WriteSTIdx, ReadAdrBase]> {
let Inst{13} = 0b1;
}
def : ROInstAlias<asm, regtype, !cast<Instruction>(NAME # "roX")>;
}
class LoadStore16RO<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, dag ins, dag outs, list<dag> pat>
: I<ins, outs, asm, "\t$Rt, [$Rn, $Rm, $extend]", "", pat> {
bits<5> Rt;
bits<5> Rn;
bits<5> Rm;
bits<2> extend;
let Inst{31-30} = sz;
let Inst{29-27} = 0b111;
let Inst{26} = V;
let Inst{25-24} = 0b00;
let Inst{23-22} = opc;
let Inst{21} = 1;
let Inst{20-16} = Rm;
let Inst{15} = extend{1}; // sign extend Rm?
let Inst{14} = 1;
let Inst{12} = extend{0}; // do shift?
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
}
multiclass Load16RO<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, ValueType Ty, SDPatternOperator loadop> {
let AddedComplexity = 10 in
def roW : LoadStore16RO<sz, V, opc, regtype, asm, (outs regtype:$Rt),
(ins GPR64sp:$Rn, GPR32:$Rm, ro_Wextend16:$extend),
[(set (Ty regtype:$Rt),
(loadop (ro_Windexed16 GPR64sp:$Rn, GPR32:$Rm,
ro_Wextend16:$extend)))]>,
Sched<[WriteLDIdx, ReadAdrBase]> {
let Inst{13} = 0b0;
}
let AddedComplexity = 10 in
def roX : LoadStore16RO<sz, V, opc, regtype, asm, (outs regtype:$Rt),
(ins GPR64sp:$Rn, GPR64:$Rm, ro_Xextend16:$extend),
[(set (Ty regtype:$Rt),
(loadop (ro_Xindexed16 GPR64sp:$Rn, GPR64:$Rm,
ro_Xextend16:$extend)))]>,
Sched<[WriteLDIdx, ReadAdrBase]> {
let Inst{13} = 0b1;
}
def : ROInstAlias<asm, regtype, !cast<Instruction>(NAME # "roX")>;
}
multiclass Store16RO<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, ValueType Ty, SDPatternOperator storeop> {
let AddedComplexity = 10 in
def roW : LoadStore16RO<sz, V, opc, regtype, asm, (outs),
(ins regtype:$Rt, GPR64sp:$Rn, GPR32:$Rm, ro_Wextend16:$extend),
[(storeop (Ty regtype:$Rt),
(ro_Windexed16 GPR64sp:$Rn, GPR32:$Rm,
ro_Wextend16:$extend))]>,
Sched<[WriteSTIdx, ReadAdrBase]> {
let Inst{13} = 0b0;
}
let AddedComplexity = 10 in
def roX : LoadStore16RO<sz, V, opc, regtype, asm, (outs),
(ins regtype:$Rt, GPR64sp:$Rn, GPR64:$Rm, ro_Xextend16:$extend),
[(storeop (Ty regtype:$Rt),
(ro_Xindexed16 GPR64sp:$Rn, GPR64:$Rm,
ro_Xextend16:$extend))]>,
Sched<[WriteSTIdx, ReadAdrBase]> {
let Inst{13} = 0b1;
}
def : ROInstAlias<asm, regtype, !cast<Instruction>(NAME # "roX")>;
}
class LoadStore32RO<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, dag ins, dag outs, list<dag> pat>
: I<ins, outs, asm, "\t$Rt, [$Rn, $Rm, $extend]", "", pat> {
bits<5> Rt;
bits<5> Rn;
bits<5> Rm;
bits<2> extend;
let Inst{31-30} = sz;
let Inst{29-27} = 0b111;
let Inst{26} = V;
let Inst{25-24} = 0b00;
let Inst{23-22} = opc;
let Inst{21} = 1;
let Inst{20-16} = Rm;
let Inst{15} = extend{1}; // sign extend Rm?
let Inst{14} = 1;
let Inst{12} = extend{0}; // do shift?
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
}
multiclass Load32RO<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, ValueType Ty, SDPatternOperator loadop> {
let AddedComplexity = 10 in
def roW : LoadStore32RO<sz, V, opc, regtype, asm, (outs regtype:$Rt),
(ins GPR64sp:$Rn, GPR32:$Rm, ro_Wextend32:$extend),
[(set (Ty regtype:$Rt),
(loadop (ro_Windexed32 GPR64sp:$Rn, GPR32:$Rm,
ro_Wextend32:$extend)))]>,
Sched<[WriteLDIdx, ReadAdrBase]> {
let Inst{13} = 0b0;
}
let AddedComplexity = 10 in
def roX : LoadStore32RO<sz, V, opc, regtype, asm, (outs regtype:$Rt),
(ins GPR64sp:$Rn, GPR64:$Rm, ro_Xextend32:$extend),
[(set (Ty regtype:$Rt),
(loadop (ro_Xindexed32 GPR64sp:$Rn, GPR64:$Rm,
ro_Xextend32:$extend)))]>,
Sched<[WriteLDIdx, ReadAdrBase]> {
let Inst{13} = 0b1;
}
def : ROInstAlias<asm, regtype, !cast<Instruction>(NAME # "roX")>;
}
multiclass Store32RO<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, ValueType Ty, SDPatternOperator storeop> {
let AddedComplexity = 10 in
def roW : LoadStore32RO<sz, V, opc, regtype, asm, (outs),
(ins regtype:$Rt, GPR64sp:$Rn, GPR32:$Rm, ro_Wextend32:$extend),
[(storeop (Ty regtype:$Rt),
(ro_Windexed32 GPR64sp:$Rn, GPR32:$Rm,
ro_Wextend32:$extend))]>,
Sched<[WriteSTIdx, ReadAdrBase]> {
let Inst{13} = 0b0;
}
let AddedComplexity = 10 in
def roX : LoadStore32RO<sz, V, opc, regtype, asm, (outs),
(ins regtype:$Rt, GPR64sp:$Rn, GPR64:$Rm, ro_Xextend32:$extend),
[(storeop (Ty regtype:$Rt),
(ro_Xindexed32 GPR64sp:$Rn, GPR64:$Rm,
ro_Xextend32:$extend))]>,
Sched<[WriteSTIdx, ReadAdrBase]> {
let Inst{13} = 0b1;
}
def : ROInstAlias<asm, regtype, !cast<Instruction>(NAME # "roX")>;
}
class LoadStore64RO<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, dag ins, dag outs, list<dag> pat>
: I<ins, outs, asm, "\t$Rt, [$Rn, $Rm, $extend]", "", pat> {
bits<5> Rt;
bits<5> Rn;
bits<5> Rm;
bits<2> extend;
let Inst{31-30} = sz;
let Inst{29-27} = 0b111;
let Inst{26} = V;
let Inst{25-24} = 0b00;
let Inst{23-22} = opc;
let Inst{21} = 1;
let Inst{20-16} = Rm;
let Inst{15} = extend{1}; // sign extend Rm?
let Inst{14} = 1;
let Inst{12} = extend{0}; // do shift?
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
}
multiclass Load64RO<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, ValueType Ty, SDPatternOperator loadop> {
let AddedComplexity = 10, mayLoad = 1, mayStore = 0, hasSideEffects = 0 in
def roW : LoadStore64RO<sz, V, opc, regtype, asm, (outs regtype:$Rt),
(ins GPR64sp:$Rn, GPR32:$Rm, ro_Wextend64:$extend),
[(set (Ty regtype:$Rt),
(loadop (ro_Windexed64 GPR64sp:$Rn, GPR32:$Rm,
ro_Wextend64:$extend)))]>,
Sched<[WriteLDIdx, ReadAdrBase]> {
let Inst{13} = 0b0;
}
let AddedComplexity = 10, mayLoad = 1, mayStore = 0, hasSideEffects = 0 in
def roX : LoadStore64RO<sz, V, opc, regtype, asm, (outs regtype:$Rt),
(ins GPR64sp:$Rn, GPR64:$Rm, ro_Xextend64:$extend),
[(set (Ty regtype:$Rt),
(loadop (ro_Xindexed64 GPR64sp:$Rn, GPR64:$Rm,
ro_Xextend64:$extend)))]>,
Sched<[WriteLDIdx, ReadAdrBase]> {
let Inst{13} = 0b1;
}
def : ROInstAlias<asm, regtype, !cast<Instruction>(NAME # "roX")>;
}
multiclass Store64RO<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, ValueType Ty, SDPatternOperator storeop> {
let AddedComplexity = 10, mayLoad = 0, mayStore = 1, hasSideEffects = 0 in
def roW : LoadStore64RO<sz, V, opc, regtype, asm, (outs),
(ins regtype:$Rt, GPR64sp:$Rn, GPR32:$Rm, ro_Wextend64:$extend),
[(storeop (Ty regtype:$Rt),
(ro_Windexed64 GPR64sp:$Rn, GPR32:$Rm,
ro_Wextend64:$extend))]>,
Sched<[WriteSTIdx, ReadAdrBase]> {
let Inst{13} = 0b0;
}
let AddedComplexity = 10, mayLoad = 0, mayStore = 1, hasSideEffects = 0 in
def roX : LoadStore64RO<sz, V, opc, regtype, asm, (outs),
(ins regtype:$Rt, GPR64sp:$Rn, GPR64:$Rm, ro_Xextend64:$extend),
[(storeop (Ty regtype:$Rt),
(ro_Xindexed64 GPR64sp:$Rn, GPR64:$Rm,
ro_Xextend64:$extend))]>,
Sched<[WriteSTIdx, ReadAdrBase]> {
let Inst{13} = 0b1;
}
def : ROInstAlias<asm, regtype, !cast<Instruction>(NAME # "roX")>;
}
class LoadStore128RO<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, dag ins, dag outs, list<dag> pat>
: I<ins, outs, asm, "\t$Rt, [$Rn, $Rm, $extend]", "", pat> {
bits<5> Rt;
bits<5> Rn;
bits<5> Rm;
bits<2> extend;
let Inst{31-30} = sz;
let Inst{29-27} = 0b111;
let Inst{26} = V;
let Inst{25-24} = 0b00;
let Inst{23-22} = opc;
let Inst{21} = 1;
let Inst{20-16} = Rm;
let Inst{15} = extend{1}; // sign extend Rm?
let Inst{14} = 1;
let Inst{12} = extend{0}; // do shift?
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
}
multiclass Load128RO<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, ValueType Ty, SDPatternOperator loadop> {
let AddedComplexity = 10, mayLoad = 1, mayStore = 0, hasSideEffects = 0 in
def roW : LoadStore128RO<sz, V, opc, regtype, asm, (outs regtype:$Rt),
(ins GPR64sp:$Rn, GPR32:$Rm, ro_Wextend128:$extend),
[(set (Ty regtype:$Rt),
(loadop (ro_Windexed128 GPR64sp:$Rn, GPR32:$Rm,
ro_Wextend128:$extend)))]>,
Sched<[WriteLDIdx, ReadAdrBase]> {
let Inst{13} = 0b0;
}
let AddedComplexity = 10, mayLoad = 1, mayStore = 0, hasSideEffects = 0 in
def roX : LoadStore128RO<sz, V, opc, regtype, asm, (outs regtype:$Rt),
(ins GPR64sp:$Rn, GPR64:$Rm, ro_Xextend128:$extend),
[(set (Ty regtype:$Rt),
(loadop (ro_Xindexed128 GPR64sp:$Rn, GPR64:$Rm,
ro_Xextend128:$extend)))]>,
Sched<[WriteLDIdx, ReadAdrBase]> {
let Inst{13} = 0b1;
}
def : ROInstAlias<asm, regtype, !cast<Instruction>(NAME # "roX")>;
}
multiclass Store128RO<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, ValueType Ty, SDPatternOperator storeop> {
let mayLoad = 0, mayStore = 1, hasSideEffects = 0 in
def roW : LoadStore128RO<sz, V, opc, regtype, asm, (outs),
(ins regtype:$Rt, GPR64sp:$Rn, GPR32:$Rm, ro_Wextend128:$extend),
[]>,
Sched<[WriteSTIdx, ReadAdrBase]> {
let Inst{13} = 0b0;
}
let mayLoad = 0, mayStore = 1, hasSideEffects = 0 in
def roX : LoadStore128RO<sz, V, opc, regtype, asm, (outs),
(ins regtype:$Rt, GPR64sp:$Rn, GPR64:$Rm, ro_Xextend128:$extend),
[]>,
Sched<[WriteSTIdx, ReadAdrBase]> {
let Inst{13} = 0b1;
}
def : ROInstAlias<asm, regtype, !cast<Instruction>(NAME # "roX")>;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 1 in
class BasePrefetchRO<bits<2> sz, bit V, bits<2> opc, dag outs, dag ins,
string asm, list<dag> pat>
: I<outs, ins, asm, "\t$Rt, [$Rn, $Rm, $extend]", "", pat>,
Sched<[WriteLD]> {
bits<5> Rt;
bits<5> Rn;
bits<5> Rm;
bits<2> extend;
let Inst{31-30} = sz;
let Inst{29-27} = 0b111;
let Inst{26} = V;
let Inst{25-24} = 0b00;
let Inst{23-22} = opc;
let Inst{21} = 1;
let Inst{20-16} = Rm;
let Inst{15} = extend{1}; // sign extend Rm?
let Inst{14} = 1;
let Inst{12} = extend{0}; // do shift?
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
}
multiclass PrefetchRO<bits<2> sz, bit V, bits<2> opc, string asm> {
def roW : BasePrefetchRO<sz, V, opc, (outs),
(ins prfop:$Rt, GPR64sp:$Rn, GPR32:$Rm, ro_Wextend64:$extend),
asm, [(AArch64Prefetch imm:$Rt,
(ro_Windexed64 GPR64sp:$Rn, GPR32:$Rm,
ro_Wextend64:$extend))]> {
let Inst{13} = 0b0;
}
def roX : BasePrefetchRO<sz, V, opc, (outs),
(ins prfop:$Rt, GPR64sp:$Rn, GPR64:$Rm, ro_Xextend64:$extend),
asm, [(AArch64Prefetch imm:$Rt,
(ro_Xindexed64 GPR64sp:$Rn, GPR64:$Rm,
ro_Xextend64:$extend))]> {
let Inst{13} = 0b1;
}
def : InstAlias<"prfm $Rt, [$Rn, $Rm]",
(!cast<Instruction>(NAME # "roX") prfop:$Rt,
GPR64sp:$Rn, GPR64:$Rm, 0, 0)>;
}
//---
// Load/store unscaled immediate
//---
def am_unscaled8 : ComplexPattern<i64, 2, "SelectAddrModeUnscaled8", []>;
def am_unscaled16 : ComplexPattern<i64, 2, "SelectAddrModeUnscaled16", []>;
def am_unscaled32 : ComplexPattern<i64, 2, "SelectAddrModeUnscaled32", []>;
def am_unscaled64 : ComplexPattern<i64, 2, "SelectAddrModeUnscaled64", []>;
def am_unscaled128 :ComplexPattern<i64, 2, "SelectAddrModeUnscaled128", []>;
class BaseLoadStoreUnscale<bits<2> sz, bit V, bits<2> opc, dag oops, dag iops,
string asm, list<dag> pattern>
: I<oops, iops, asm, "\t$Rt, [$Rn, $offset]", "", pattern> {
bits<5> Rt;
bits<5> Rn;
bits<9> offset;
let Inst{31-30} = sz;
let Inst{29-27} = 0b111;
let Inst{26} = V;
let Inst{25-24} = 0b00;
let Inst{23-22} = opc;
let Inst{21} = 0;
let Inst{20-12} = offset;
let Inst{11-10} = 0b00;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let DecoderMethod = "DecodeSignedLdStInstruction";
}
multiclass LoadUnscaled<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, list<dag> pattern> {
let AddedComplexity = 1 in // try this before LoadUI
def i : BaseLoadStoreUnscale<sz, V, opc, (outs regtype:$Rt),
(ins GPR64sp:$Rn, simm9:$offset), asm, pattern>,
Sched<[WriteLD]>;
def : InstAlias<asm # "\t$Rt, [$Rn]",
(!cast<Instruction>(NAME # "i") regtype:$Rt, GPR64sp:$Rn, 0)>;
}
multiclass StoreUnscaled<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, list<dag> pattern> {
let AddedComplexity = 1 in // try this before StoreUI
def i : BaseLoadStoreUnscale<sz, V, opc, (outs),
(ins regtype:$Rt, GPR64sp:$Rn, simm9:$offset),
asm, pattern>,
Sched<[WriteST]>;
def : InstAlias<asm # "\t$Rt, [$Rn]",
(!cast<Instruction>(NAME # "i") regtype:$Rt, GPR64sp:$Rn, 0)>;
}
multiclass PrefetchUnscaled<bits<2> sz, bit V, bits<2> opc, string asm,
list<dag> pat> {
let mayLoad = 0, mayStore = 0, hasSideEffects = 1 in
def i : BaseLoadStoreUnscale<sz, V, opc, (outs),
(ins prfop:$Rt, GPR64sp:$Rn, simm9:$offset),
asm, pat>,
Sched<[WriteLD]>;
def : InstAlias<asm # "\t$Rt, [$Rn]",
(!cast<Instruction>(NAME # "i") prfop:$Rt, GPR64sp:$Rn, 0)>;
}
//---
// Load/store unscaled immediate, unprivileged
//---
class BaseLoadStoreUnprivileged<bits<2> sz, bit V, bits<2> opc,
dag oops, dag iops, string asm>
: I<oops, iops, asm, "\t$Rt, [$Rn, $offset]", "", []> {
bits<5> Rt;
bits<5> Rn;
bits<9> offset;
let Inst{31-30} = sz;
let Inst{29-27} = 0b111;
let Inst{26} = V;
let Inst{25-24} = 0b00;
let Inst{23-22} = opc;
let Inst{21} = 0;
let Inst{20-12} = offset;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let DecoderMethod = "DecodeSignedLdStInstruction";
}
multiclass LoadUnprivileged<bits<2> sz, bit V, bits<2> opc,
RegisterClass regtype, string asm> {
let mayStore = 0, mayLoad = 1, hasSideEffects = 0 in
def i : BaseLoadStoreUnprivileged<sz, V, opc, (outs regtype:$Rt),
(ins GPR64sp:$Rn, simm9:$offset), asm>,
Sched<[WriteLD]>;
def : InstAlias<asm # "\t$Rt, [$Rn]",
(!cast<Instruction>(NAME # "i") regtype:$Rt, GPR64sp:$Rn, 0)>;
}
multiclass StoreUnprivileged<bits<2> sz, bit V, bits<2> opc,
RegisterClass regtype, string asm> {
let mayStore = 1, mayLoad = 0, hasSideEffects = 0 in
def i : BaseLoadStoreUnprivileged<sz, V, opc, (outs),
(ins regtype:$Rt, GPR64sp:$Rn, simm9:$offset),
asm>,
Sched<[WriteST]>;
def : InstAlias<asm # "\t$Rt, [$Rn]",
(!cast<Instruction>(NAME # "i") regtype:$Rt, GPR64sp:$Rn, 0)>;
}
//---
// Load/store pre-indexed
//---
class BaseLoadStorePreIdx<bits<2> sz, bit V, bits<2> opc, dag oops, dag iops,
string asm, string cstr, list<dag> pat>
: I<oops, iops, asm, "\t$Rt, [$Rn, $offset]!", cstr, pat> {
bits<5> Rt;
bits<5> Rn;
bits<9> offset;
let Inst{31-30} = sz;
let Inst{29-27} = 0b111;
let Inst{26} = V;
let Inst{25-24} = 0;
let Inst{23-22} = opc;
let Inst{21} = 0;
let Inst{20-12} = offset;
let Inst{11-10} = 0b11;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let DecoderMethod = "DecodeSignedLdStInstruction";
}
let hasSideEffects = 0 in {
let mayStore = 0, mayLoad = 1 in
class LoadPreIdx<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm>
: BaseLoadStorePreIdx<sz, V, opc,
(outs GPR64sp:$wback, regtype:$Rt),
(ins GPR64sp:$Rn, simm9:$offset), asm,
"$Rn = $wback,@earlyclobber $wback", []>,
Sched<[WriteLD, WriteAdr]>;
let mayStore = 1, mayLoad = 0 in
class StorePreIdx<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, SDPatternOperator storeop, ValueType Ty>
: BaseLoadStorePreIdx<sz, V, opc,
(outs GPR64sp:$wback),
(ins regtype:$Rt, GPR64sp:$Rn, simm9:$offset),
asm, "$Rn = $wback,@earlyclobber $wback",
[(set GPR64sp:$wback,
(storeop (Ty regtype:$Rt), GPR64sp:$Rn, simm9:$offset))]>,
Sched<[WriteAdr, WriteST]>;
} // hasSideEffects = 0
//---
// Load/store post-indexed
//---
class BaseLoadStorePostIdx<bits<2> sz, bit V, bits<2> opc, dag oops, dag iops,
string asm, string cstr, list<dag> pat>
: I<oops, iops, asm, "\t$Rt, [$Rn], $offset", cstr, pat> {
bits<5> Rt;
bits<5> Rn;
bits<9> offset;
let Inst{31-30} = sz;
let Inst{29-27} = 0b111;
let Inst{26} = V;
let Inst{25-24} = 0b00;
let Inst{23-22} = opc;
let Inst{21} = 0b0;
let Inst{20-12} = offset;
let Inst{11-10} = 0b01;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let DecoderMethod = "DecodeSignedLdStInstruction";
}
let hasSideEffects = 0 in {
let mayStore = 0, mayLoad = 1 in
class LoadPostIdx<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm>
: BaseLoadStorePostIdx<sz, V, opc,
(outs GPR64sp:$wback, regtype:$Rt),
(ins GPR64sp:$Rn, simm9:$offset),
asm, "$Rn = $wback,@earlyclobber $wback", []>,
Sched<[WriteLD, WriteI]>;
let mayStore = 1, mayLoad = 0 in
class StorePostIdx<bits<2> sz, bit V, bits<2> opc, RegisterClass regtype,
string asm, SDPatternOperator storeop, ValueType Ty>
: BaseLoadStorePostIdx<sz, V, opc,
(outs GPR64sp:$wback),
(ins regtype:$Rt, GPR64sp:$Rn, simm9:$offset),
asm, "$Rn = $wback,@earlyclobber $wback",
[(set GPR64sp:$wback,
(storeop (Ty regtype:$Rt), GPR64sp:$Rn, simm9:$offset))]>,
Sched<[WriteAdr, WriteST, ReadAdrBase]>;
} // hasSideEffects = 0
//---
// Load/store pair
//---
// (indexed, offset)
class BaseLoadStorePairOffset<bits<2> opc, bit V, bit L, dag oops, dag iops,
string asm>
: I<oops, iops, asm, "\t$Rt, $Rt2, [$Rn, $offset]", "", []> {
bits<5> Rt;
bits<5> Rt2;
bits<5> Rn;
bits<7> offset;
let Inst{31-30} = opc;
let Inst{29-27} = 0b101;
let Inst{26} = V;
let Inst{25-23} = 0b010;
let Inst{22} = L;
let Inst{21-15} = offset;
let Inst{14-10} = Rt2;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let DecoderMethod = "DecodePairLdStInstruction";
}
multiclass LoadPairOffset<bits<2> opc, bit V, RegisterClass regtype,
Operand indextype, string asm> {
let hasSideEffects = 0, mayStore = 0, mayLoad = 1 in
def i : BaseLoadStorePairOffset<opc, V, 1,
(outs regtype:$Rt, regtype:$Rt2),
(ins GPR64sp:$Rn, indextype:$offset), asm>,
Sched<[WriteLD, WriteLDHi]>;
def : InstAlias<asm # "\t$Rt, $Rt2, [$Rn]",
(!cast<Instruction>(NAME # "i") regtype:$Rt, regtype:$Rt2,
GPR64sp:$Rn, 0)>;
}
multiclass StorePairOffset<bits<2> opc, bit V, RegisterClass regtype,
Operand indextype, string asm> {
let hasSideEffects = 0, mayLoad = 0, mayStore = 1 in
def i : BaseLoadStorePairOffset<opc, V, 0, (outs),
(ins regtype:$Rt, regtype:$Rt2,
GPR64sp:$Rn, indextype:$offset),
asm>,
Sched<[WriteSTP]>;
def : InstAlias<asm # "\t$Rt, $Rt2, [$Rn]",
(!cast<Instruction>(NAME # "i") regtype:$Rt, regtype:$Rt2,
GPR64sp:$Rn, 0)>;
}
// (pre-indexed)
class BaseLoadStorePairPreIdx<bits<2> opc, bit V, bit L, dag oops, dag iops,
string asm>
: I<oops, iops, asm, "\t$Rt, $Rt2, [$Rn, $offset]!", "$Rn = $wback,@earlyclobber $wback", []> {
bits<5> Rt;
bits<5> Rt2;
bits<5> Rn;
bits<7> offset;
let Inst{31-30} = opc;
let Inst{29-27} = 0b101;
let Inst{26} = V;
let Inst{25-23} = 0b011;
let Inst{22} = L;
let Inst{21-15} = offset;
let Inst{14-10} = Rt2;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let DecoderMethod = "DecodePairLdStInstruction";
}
let hasSideEffects = 0 in {
let mayStore = 0, mayLoad = 1 in
class LoadPairPreIdx<bits<2> opc, bit V, RegisterClass regtype,
Operand indextype, string asm>
: BaseLoadStorePairPreIdx<opc, V, 1,
(outs GPR64sp:$wback, regtype:$Rt, regtype:$Rt2),
(ins GPR64sp:$Rn, indextype:$offset), asm>,
Sched<[WriteLD, WriteLDHi, WriteAdr]>;
let mayStore = 1, mayLoad = 0 in
class StorePairPreIdx<bits<2> opc, bit V, RegisterClass regtype,
Operand indextype, string asm>
: BaseLoadStorePairPreIdx<opc, V, 0, (outs GPR64sp:$wback),
(ins regtype:$Rt, regtype:$Rt2,
GPR64sp:$Rn, indextype:$offset),
asm>,
Sched<[WriteAdr, WriteSTP]>;
} // hasSideEffects = 0
// (post-indexed)
class BaseLoadStorePairPostIdx<bits<2> opc, bit V, bit L, dag oops, dag iops,
string asm>
: I<oops, iops, asm, "\t$Rt, $Rt2, [$Rn], $offset", "$Rn = $wback,@earlyclobber $wback", []> {
bits<5> Rt;
bits<5> Rt2;
bits<5> Rn;
bits<7> offset;
let Inst{31-30} = opc;
let Inst{29-27} = 0b101;
let Inst{26} = V;
let Inst{25-23} = 0b001;
let Inst{22} = L;
let Inst{21-15} = offset;
let Inst{14-10} = Rt2;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let DecoderMethod = "DecodePairLdStInstruction";
}
let hasSideEffects = 0 in {
let mayStore = 0, mayLoad = 1 in
class LoadPairPostIdx<bits<2> opc, bit V, RegisterClass regtype,
Operand idxtype, string asm>
: BaseLoadStorePairPostIdx<opc, V, 1,
(outs GPR64sp:$wback, regtype:$Rt, regtype:$Rt2),
(ins GPR64sp:$Rn, idxtype:$offset), asm>,
Sched<[WriteLD, WriteLDHi, WriteAdr]>;
let mayStore = 1, mayLoad = 0 in
class StorePairPostIdx<bits<2> opc, bit V, RegisterClass regtype,
Operand idxtype, string asm>
: BaseLoadStorePairPostIdx<opc, V, 0, (outs GPR64sp:$wback),
(ins regtype:$Rt, regtype:$Rt2,
GPR64sp:$Rn, idxtype:$offset),
asm>,
Sched<[WriteAdr, WriteSTP]>;
} // hasSideEffects = 0
// (no-allocate)
class BaseLoadStorePairNoAlloc<bits<2> opc, bit V, bit L, dag oops, dag iops,
string asm>
: I<oops, iops, asm, "\t$Rt, $Rt2, [$Rn, $offset]", "", []> {
bits<5> Rt;
bits<5> Rt2;
bits<5> Rn;
bits<7> offset;
let Inst{31-30} = opc;
let Inst{29-27} = 0b101;
let Inst{26} = V;
let Inst{25-23} = 0b000;
let Inst{22} = L;
let Inst{21-15} = offset;
let Inst{14-10} = Rt2;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let DecoderMethod = "DecodePairLdStInstruction";
}
multiclass LoadPairNoAlloc<bits<2> opc, bit V, RegisterClass regtype,
Operand indextype, string asm> {
let hasSideEffects = 0, mayStore = 0, mayLoad = 1 in
def i : BaseLoadStorePairNoAlloc<opc, V, 1,
(outs regtype:$Rt, regtype:$Rt2),
(ins GPR64sp:$Rn, indextype:$offset), asm>,
Sched<[WriteLD, WriteLDHi]>;
def : InstAlias<asm # "\t$Rt, $Rt2, [$Rn]",
(!cast<Instruction>(NAME # "i") regtype:$Rt, regtype:$Rt2,
GPR64sp:$Rn, 0)>;
}
multiclass StorePairNoAlloc<bits<2> opc, bit V, RegisterClass regtype,
Operand indextype, string asm> {
let hasSideEffects = 0, mayStore = 1, mayLoad = 0 in
def i : BaseLoadStorePairNoAlloc<opc, V, 0, (outs),
(ins regtype:$Rt, regtype:$Rt2,
GPR64sp:$Rn, indextype:$offset),
asm>,
Sched<[WriteSTP]>;
def : InstAlias<asm # "\t$Rt, $Rt2, [$Rn]",
(!cast<Instruction>(NAME # "i") regtype:$Rt, regtype:$Rt2,
GPR64sp:$Rn, 0)>;
}
//---
// Load/store exclusive
//---
// True exclusive operations write to and/or read from the system's exclusive
// monitors, which as far as a compiler is concerned can be modelled as a
// random shared memory address. Hence LoadExclusive mayStore.
//
// Since these instructions have the undefined register bits set to 1 in
// their canonical form, we need a post encoder method to set those bits
// to 1 when encoding these instructions. We do this using the
// fixLoadStoreExclusive function. This function has template parameters:
//
// fixLoadStoreExclusive<int hasRs, int hasRt2>
//
// hasRs indicates that the instruction uses the Rs field, so we won't set
// it to 1 (and the same for Rt2). We don't need template parameters for
// the other register fields since Rt and Rn are always used.
//
let hasSideEffects = 1, mayLoad = 1, mayStore = 1 in
class BaseLoadStoreExclusive<bits<2> sz, bit o2, bit L, bit o1, bit o0,
dag oops, dag iops, string asm, string operands>
: I<oops, iops, asm, operands, "", []> {
let Inst{31-30} = sz;
let Inst{29-24} = 0b001000;
let Inst{23} = o2;
let Inst{22} = L;
let Inst{21} = o1;
let Inst{15} = o0;
let DecoderMethod = "DecodeExclusiveLdStInstruction";
}
// Neither Rs nor Rt2 operands.
class LoadStoreExclusiveSimple<bits<2> sz, bit o2, bit L, bit o1, bit o0,
dag oops, dag iops, string asm, string operands>
: BaseLoadStoreExclusive<sz, o2, L, o1, o0, oops, iops, asm, operands> {
bits<5> Rt;
bits<5> Rn;
let Inst{20-16} = 0b11111;
let Unpredictable{20-16} = 0b11111;
let Inst{14-10} = 0b11111;
let Unpredictable{14-10} = 0b11111;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let PostEncoderMethod = "fixLoadStoreExclusive<0,0>";
}
// Simple load acquires don't set the exclusive monitor
let mayLoad = 1, mayStore = 0 in
class LoadAcquire<bits<2> sz, bit o2, bit L, bit o1, bit o0,
RegisterClass regtype, string asm>
: LoadStoreExclusiveSimple<sz, o2, L, o1, o0, (outs regtype:$Rt),
(ins GPR64sp0:$Rn), asm, "\t$Rt, [$Rn]">,
Sched<[WriteLD]>;
class LoadExclusive<bits<2> sz, bit o2, bit L, bit o1, bit o0,
RegisterClass regtype, string asm>
: LoadStoreExclusiveSimple<sz, o2, L, o1, o0, (outs regtype:$Rt),
(ins GPR64sp0:$Rn), asm, "\t$Rt, [$Rn]">,
Sched<[WriteLD]>;
class LoadExclusivePair<bits<2> sz, bit o2, bit L, bit o1, bit o0,
RegisterClass regtype, string asm>
: BaseLoadStoreExclusive<sz, o2, L, o1, o0,
(outs regtype:$Rt, regtype:$Rt2),
(ins GPR64sp0:$Rn), asm,
"\t$Rt, $Rt2, [$Rn]">,
Sched<[WriteLD, WriteLDHi]> {
bits<5> Rt;
bits<5> Rt2;
bits<5> Rn;
let Inst{14-10} = Rt2;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let PostEncoderMethod = "fixLoadStoreExclusive<0,1>";
}
// Simple store release operations do not check the exclusive monitor.
let mayLoad = 0, mayStore = 1 in
class StoreRelease<bits<2> sz, bit o2, bit L, bit o1, bit o0,
RegisterClass regtype, string asm>
: LoadStoreExclusiveSimple<sz, o2, L, o1, o0, (outs),
(ins regtype:$Rt, GPR64sp0:$Rn),
asm, "\t$Rt, [$Rn]">,
Sched<[WriteST]>;
let mayLoad = 1, mayStore = 1 in
class StoreExclusive<bits<2> sz, bit o2, bit L, bit o1, bit o0,
RegisterClass regtype, string asm>
: BaseLoadStoreExclusive<sz, o2, L, o1, o0, (outs GPR32:$Ws),
(ins regtype:$Rt, GPR64sp0:$Rn),
asm, "\t$Ws, $Rt, [$Rn]">,
Sched<[WriteSTX]> {
bits<5> Ws;
bits<5> Rt;
bits<5> Rn;
let Inst{20-16} = Ws;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let Constraints = "@earlyclobber $Ws";
let PostEncoderMethod = "fixLoadStoreExclusive<1,0>";
}
class StoreExclusivePair<bits<2> sz, bit o2, bit L, bit o1, bit o0,
RegisterClass regtype, string asm>
: BaseLoadStoreExclusive<sz, o2, L, o1, o0,
(outs GPR32:$Ws),
(ins regtype:$Rt, regtype:$Rt2, GPR64sp0:$Rn),
asm, "\t$Ws, $Rt, $Rt2, [$Rn]">,
Sched<[WriteSTX]> {
bits<5> Ws;
bits<5> Rt;
bits<5> Rt2;
bits<5> Rn;
let Inst{20-16} = Ws;
let Inst{14-10} = Rt2;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let Constraints = "@earlyclobber $Ws";
}
//---
// Exception generation
//---
let mayLoad = 0, mayStore = 0, hasSideEffects = 1 in
class ExceptionGeneration<bits<3> op1, bits<2> ll, string asm>
: I<(outs), (ins imm0_65535:$imm), asm, "\t$imm", "", []>,
Sched<[WriteSys]> {
bits<16> imm;
let Inst{31-24} = 0b11010100;
let Inst{23-21} = op1;
let Inst{20-5} = imm;
let Inst{4-2} = 0b000;
let Inst{1-0} = ll;
}
let Predicates = [HasFPARMv8] in {
//---
// Floating point to integer conversion
//---
class BaseFPToIntegerUnscaled<bits<2> type, bits<2> rmode, bits<3> opcode,
RegisterClass srcType, RegisterClass dstType,
string asm, list<dag> pattern>
: I<(outs dstType:$Rd), (ins srcType:$Rn),
asm, "\t$Rd, $Rn", "", pattern>,
Sched<[WriteFCvt]> {
bits<5> Rd;
bits<5> Rn;
let Inst{30-29} = 0b00;
let Inst{28-24} = 0b11110;
let Inst{23-22} = type;
let Inst{21} = 1;
let Inst{20-19} = rmode;
let Inst{18-16} = opcode;
let Inst{15-10} = 0;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseFPToInteger<bits<2> type, bits<2> rmode, bits<3> opcode,
RegisterClass srcType, RegisterClass dstType,
Operand immType, string asm, list<dag> pattern>
: I<(outs dstType:$Rd), (ins srcType:$Rn, immType:$scale),
asm, "\t$Rd, $Rn, $scale", "", pattern>,
Sched<[WriteFCvt]> {
bits<5> Rd;
bits<5> Rn;
bits<6> scale;
let Inst{30-29} = 0b00;
let Inst{28-24} = 0b11110;
let Inst{23-22} = type;
let Inst{21} = 0;
let Inst{20-19} = rmode;
let Inst{18-16} = opcode;
let Inst{15-10} = scale;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass FPToIntegerUnscaled<bits<2> rmode, bits<3> opcode, string asm,
SDPatternOperator OpN> {
// Unscaled half-precision to 32-bit
def UWHr : BaseFPToIntegerUnscaled<0b11, rmode, opcode, FPR16, GPR32, asm,
[(set GPR32:$Rd, (OpN FPR16:$Rn))]> {
let Inst{31} = 0; // 32-bit GPR flag
let Predicates = [HasFullFP16];
}
// Unscaled half-precision to 64-bit
def UXHr : BaseFPToIntegerUnscaled<0b11, rmode, opcode, FPR16, GPR64, asm,
[(set GPR64:$Rd, (OpN FPR16:$Rn))]> {
let Inst{31} = 1; // 64-bit GPR flag
let Predicates = [HasFullFP16];
}
// Unscaled single-precision to 32-bit
def UWSr : BaseFPToIntegerUnscaled<0b00, rmode, opcode, FPR32, GPR32, asm,
[(set GPR32:$Rd, (OpN FPR32:$Rn))]> {
let Inst{31} = 0; // 32-bit GPR flag
}
// Unscaled single-precision to 64-bit
def UXSr : BaseFPToIntegerUnscaled<0b00, rmode, opcode, FPR32, GPR64, asm,
[(set GPR64:$Rd, (OpN FPR32:$Rn))]> {
let Inst{31} = 1; // 64-bit GPR flag
}
// Unscaled double-precision to 32-bit
def UWDr : BaseFPToIntegerUnscaled<0b01, rmode, opcode, FPR64, GPR32, asm,
[(set GPR32:$Rd, (OpN (f64 FPR64:$Rn)))]> {
let Inst{31} = 0; // 32-bit GPR flag
}
// Unscaled double-precision to 64-bit
def UXDr : BaseFPToIntegerUnscaled<0b01, rmode, opcode, FPR64, GPR64, asm,
[(set GPR64:$Rd, (OpN (f64 FPR64:$Rn)))]> {
let Inst{31} = 1; // 64-bit GPR flag
}
}
multiclass FPToIntegerScaled<bits<2> rmode, bits<3> opcode, string asm,
SDPatternOperator OpN> {
// Scaled half-precision to 32-bit
def SWHri : BaseFPToInteger<0b11, rmode, opcode, FPR16, GPR32,
fixedpoint_f16_i32, asm,
[(set GPR32:$Rd, (OpN (fmul FPR16:$Rn,
fixedpoint_f16_i32:$scale)))]> {
let Inst{31} = 0; // 32-bit GPR flag
let scale{5} = 1;
let Predicates = [HasFullFP16];
}
// Scaled half-precision to 64-bit
def SXHri : BaseFPToInteger<0b11, rmode, opcode, FPR16, GPR64,
fixedpoint_f16_i64, asm,
[(set GPR64:$Rd, (OpN (fmul FPR16:$Rn,
fixedpoint_f16_i64:$scale)))]> {
let Inst{31} = 1; // 64-bit GPR flag
let Predicates = [HasFullFP16];
}
// Scaled single-precision to 32-bit
def SWSri : BaseFPToInteger<0b00, rmode, opcode, FPR32, GPR32,
fixedpoint_f32_i32, asm,
[(set GPR32:$Rd, (OpN (fmul FPR32:$Rn,
fixedpoint_f32_i32:$scale)))]> {
let Inst{31} = 0; // 32-bit GPR flag
let scale{5} = 1;
}
// Scaled single-precision to 64-bit
def SXSri : BaseFPToInteger<0b00, rmode, opcode, FPR32, GPR64,
fixedpoint_f32_i64, asm,
[(set GPR64:$Rd, (OpN (fmul FPR32:$Rn,
fixedpoint_f32_i64:$scale)))]> {
let Inst{31} = 1; // 64-bit GPR flag
}
// Scaled double-precision to 32-bit
def SWDri : BaseFPToInteger<0b01, rmode, opcode, FPR64, GPR32,
fixedpoint_f64_i32, asm,
[(set GPR32:$Rd, (OpN (fmul FPR64:$Rn,
fixedpoint_f64_i32:$scale)))]> {
let Inst{31} = 0; // 32-bit GPR flag
let scale{5} = 1;
}
// Scaled double-precision to 64-bit
def SXDri : BaseFPToInteger<0b01, rmode, opcode, FPR64, GPR64,
fixedpoint_f64_i64, asm,
[(set GPR64:$Rd, (OpN (fmul FPR64:$Rn,
fixedpoint_f64_i64:$scale)))]> {
let Inst{31} = 1; // 64-bit GPR flag
}
}
//---
// Integer to floating point conversion
//---
let mayStore = 0, mayLoad = 0, hasSideEffects = 0 in
class BaseIntegerToFP<bit isUnsigned,
RegisterClass srcType, RegisterClass dstType,
Operand immType, string asm, list<dag> pattern>
: I<(outs dstType:$Rd), (ins srcType:$Rn, immType:$scale),
asm, "\t$Rd, $Rn, $scale", "", pattern>,
Sched<[WriteFCvt]> {
bits<5> Rd;
bits<5> Rn;
bits<6> scale;
let Inst{30-24} = 0b0011110;
let Inst{21-17} = 0b00001;
let Inst{16} = isUnsigned;
let Inst{15-10} = scale;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
class BaseIntegerToFPUnscaled<bit isUnsigned,
RegisterClass srcType, RegisterClass dstType,
ValueType dvt, string asm, SDNode node>
: I<(outs dstType:$Rd), (ins srcType:$Rn),
asm, "\t$Rd, $Rn", "", [(set (dvt dstType:$Rd), (node srcType:$Rn))]>,
Sched<[WriteFCvt]> {
bits<5> Rd;
bits<5> Rn;
bits<6> scale;
let Inst{30-24} = 0b0011110;
let Inst{21-17} = 0b10001;
let Inst{16} = isUnsigned;
let Inst{15-10} = 0b000000;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass IntegerToFP<bit isUnsigned, string asm, SDNode node> {
// Unscaled
def UWHri: BaseIntegerToFPUnscaled<isUnsigned, GPR32, FPR16, f16, asm, node> {
let Inst{31} = 0; // 32-bit GPR flag
let Inst{23-22} = 0b11; // 16-bit FPR flag
let Predicates = [HasFullFP16];
}
def UWSri: BaseIntegerToFPUnscaled<isUnsigned, GPR32, FPR32, f32, asm, node> {
let Inst{31} = 0; // 32-bit GPR flag
let Inst{23-22} = 0b00; // 32-bit FPR flag
}
def UWDri: BaseIntegerToFPUnscaled<isUnsigned, GPR32, FPR64, f64, asm, node> {
let Inst{31} = 0; // 32-bit GPR flag
let Inst{23-22} = 0b01; // 64-bit FPR flag
}
def UXHri: BaseIntegerToFPUnscaled<isUnsigned, GPR64, FPR16, f16, asm, node> {
let Inst{31} = 1; // 64-bit GPR flag
let Inst{23-22} = 0b11; // 16-bit FPR flag
let Predicates = [HasFullFP16];
}
def UXSri: BaseIntegerToFPUnscaled<isUnsigned, GPR64, FPR32, f32, asm, node> {
let Inst{31} = 1; // 64-bit GPR flag
let Inst{23-22} = 0b00; // 32-bit FPR flag
}
def UXDri: BaseIntegerToFPUnscaled<isUnsigned, GPR64, FPR64, f64, asm, node> {
let Inst{31} = 1; // 64-bit GPR flag
let Inst{23-22} = 0b01; // 64-bit FPR flag
}
// Scaled
def SWHri: BaseIntegerToFP<isUnsigned, GPR32, FPR16, fixedpoint_f16_i32, asm,
[(set FPR16:$Rd,
(fdiv (node GPR32:$Rn),
fixedpoint_f16_i32:$scale))]> {
let Inst{31} = 0; // 32-bit GPR flag
let Inst{23-22} = 0b11; // 16-bit FPR flag
let scale{5} = 1;
let Predicates = [HasFullFP16];
}
def SWSri: BaseIntegerToFP<isUnsigned, GPR32, FPR32, fixedpoint_f32_i32, asm,
[(set FPR32:$Rd,
(fdiv (node GPR32:$Rn),
fixedpoint_f32_i32:$scale))]> {
let Inst{31} = 0; // 32-bit GPR flag
let Inst{23-22} = 0b00; // 32-bit FPR flag
let scale{5} = 1;
}
def SWDri: BaseIntegerToFP<isUnsigned, GPR32, FPR64, fixedpoint_f64_i32, asm,
[(set FPR64:$Rd,
(fdiv (node GPR32:$Rn),
fixedpoint_f64_i32:$scale))]> {
let Inst{31} = 0; // 32-bit GPR flag
let Inst{23-22} = 0b01; // 64-bit FPR flag
let scale{5} = 1;
}
def SXHri: BaseIntegerToFP<isUnsigned, GPR64, FPR16, fixedpoint_f16_i64, asm,
[(set FPR16:$Rd,
(fdiv (node GPR64:$Rn),
fixedpoint_f16_i64:$scale))]> {
let Inst{31} = 1; // 64-bit GPR flag
let Inst{23-22} = 0b11; // 16-bit FPR flag
let Predicates = [HasFullFP16];
}
def SXSri: BaseIntegerToFP<isUnsigned, GPR64, FPR32, fixedpoint_f32_i64, asm,
[(set FPR32:$Rd,
(fdiv (node GPR64:$Rn),
fixedpoint_f32_i64:$scale))]> {
let Inst{31} = 1; // 64-bit GPR flag
let Inst{23-22} = 0b00; // 32-bit FPR flag
}
def SXDri: BaseIntegerToFP<isUnsigned, GPR64, FPR64, fixedpoint_f64_i64, asm,
[(set FPR64:$Rd,
(fdiv (node GPR64:$Rn),
fixedpoint_f64_i64:$scale))]> {
let Inst{31} = 1; // 64-bit GPR flag
let Inst{23-22} = 0b01; // 64-bit FPR flag
}
}
//---
// Unscaled integer <-> floating point conversion (i.e. FMOV)
//---
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseUnscaledConversion<bits<2> rmode, bits<3> opcode,
RegisterClass srcType, RegisterClass dstType,
string asm>
: I<(outs dstType:$Rd), (ins srcType:$Rn), asm, "\t$Rd, $Rn", "",
// We use COPY_TO_REGCLASS for these bitconvert operations.
// copyPhysReg() expands the resultant COPY instructions after
// regalloc is done. This gives greater freedom for the allocator
// and related passes (coalescing, copy propagation, et. al.) to
// be more effective.
[/*(set (dvt dstType:$Rd), (bitconvert (svt srcType:$Rn)))*/]>,
Sched<[WriteFCopy]> {
bits<5> Rd;
bits<5> Rn;
let Inst{30-24} = 0b0011110;
let Inst{21} = 1;
let Inst{20-19} = rmode;
let Inst{18-16} = opcode;
let Inst{15-10} = 0b000000;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseUnscaledConversionToHigh<bits<2> rmode, bits<3> opcode,
RegisterClass srcType, RegisterOperand dstType, string asm,
string kind>
: I<(outs dstType:$Rd), (ins srcType:$Rn, VectorIndex1:$idx), asm,
"{\t$Rd"#kind#"$idx, $Rn|"#kind#"\t$Rd$idx, $Rn}", "", []>,
Sched<[WriteFCopy]> {
bits<5> Rd;
bits<5> Rn;
let Inst{30-23} = 0b00111101;
let Inst{21} = 1;
let Inst{20-19} = rmode;
let Inst{18-16} = opcode;
let Inst{15-10} = 0b000000;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
let DecoderMethod = "DecodeFMOVLaneInstruction";
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseUnscaledConversionFromHigh<bits<2> rmode, bits<3> opcode,
RegisterOperand srcType, RegisterClass dstType, string asm,
string kind>
: I<(outs dstType:$Rd), (ins srcType:$Rn, VectorIndex1:$idx), asm,
"{\t$Rd, $Rn"#kind#"$idx|"#kind#"\t$Rd, $Rn$idx}", "", []>,
Sched<[WriteFCopy]> {
bits<5> Rd;
bits<5> Rn;
let Inst{30-23} = 0b00111101;
let Inst{21} = 1;
let Inst{20-19} = rmode;
let Inst{18-16} = opcode;
let Inst{15-10} = 0b000000;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
let DecoderMethod = "DecodeFMOVLaneInstruction";
}
multiclass UnscaledConversion<string asm> {
def WHr : BaseUnscaledConversion<0b00, 0b111, GPR32, FPR16, asm> {
let Inst{31} = 0; // 32-bit GPR flag
let Inst{23-22} = 0b11; // 16-bit FPR flag
let Predicates = [HasFullFP16];
}
def XHr : BaseUnscaledConversion<0b00, 0b111, GPR64, FPR16, asm> {
let Inst{31} = 1; // 64-bit GPR flag
let Inst{23-22} = 0b11; // 16-bit FPR flag
let Predicates = [HasFullFP16];
}
def WSr : BaseUnscaledConversion<0b00, 0b111, GPR32, FPR32, asm> {
let Inst{31} = 0; // 32-bit GPR flag
let Inst{23-22} = 0b00; // 32-bit FPR flag
}
def XDr : BaseUnscaledConversion<0b00, 0b111, GPR64, FPR64, asm> {
let Inst{31} = 1; // 64-bit GPR flag
let Inst{23-22} = 0b01; // 64-bit FPR flag
}
def HWr : BaseUnscaledConversion<0b00, 0b110, FPR16, GPR32, asm> {
let Inst{31} = 0; // 32-bit GPR flag
let Inst{23-22} = 0b11; // 16-bit FPR flag
let Predicates = [HasFullFP16];
}
def HXr : BaseUnscaledConversion<0b00, 0b110, FPR16, GPR64, asm> {
let Inst{31} = 1; // 64-bit GPR flag
let Inst{23-22} = 0b11; // 16-bit FPR flag
let Predicates = [HasFullFP16];
}
def SWr : BaseUnscaledConversion<0b00, 0b110, FPR32, GPR32, asm> {
let Inst{31} = 0; // 32-bit GPR flag
let Inst{23-22} = 0b00; // 32-bit FPR flag
}
def DXr : BaseUnscaledConversion<0b00, 0b110, FPR64, GPR64, asm> {
let Inst{31} = 1; // 64-bit GPR flag
let Inst{23-22} = 0b01; // 64-bit FPR flag
}
def XDHighr : BaseUnscaledConversionToHigh<0b01, 0b111, GPR64, V128,
asm, ".d"> {
let Inst{31} = 1;
let Inst{22} = 0;
}
def DXHighr : BaseUnscaledConversionFromHigh<0b01, 0b110, V128, GPR64,
asm, ".d"> {
let Inst{31} = 1;
let Inst{22} = 0;
}
}
//---
// Floating point conversion
//---
class BaseFPConversion<bits<2> type, bits<2> opcode, RegisterClass dstType,
RegisterClass srcType, string asm, list<dag> pattern>
: I<(outs dstType:$Rd), (ins srcType:$Rn), asm, "\t$Rd, $Rn", "", pattern>,
Sched<[WriteFCvt]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31-24} = 0b00011110;
let Inst{23-22} = type;
let Inst{21-17} = 0b10001;
let Inst{16-15} = opcode;
let Inst{14-10} = 0b10000;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass FPConversion<string asm> {
// Double-precision to Half-precision
def HDr : BaseFPConversion<0b01, 0b11, FPR16, FPR64, asm,
[(set FPR16:$Rd, (fpround FPR64:$Rn))]>;
// Double-precision to Single-precision
def SDr : BaseFPConversion<0b01, 0b00, FPR32, FPR64, asm,
[(set FPR32:$Rd, (fpround FPR64:$Rn))]>;
// Half-precision to Double-precision
def DHr : BaseFPConversion<0b11, 0b01, FPR64, FPR16, asm,
[(set FPR64:$Rd, (fpextend FPR16:$Rn))]>;
// Half-precision to Single-precision
def SHr : BaseFPConversion<0b11, 0b00, FPR32, FPR16, asm,
[(set FPR32:$Rd, (fpextend FPR16:$Rn))]>;
// Single-precision to Double-precision
def DSr : BaseFPConversion<0b00, 0b01, FPR64, FPR32, asm,
[(set FPR64:$Rd, (fpextend FPR32:$Rn))]>;
// Single-precision to Half-precision
def HSr : BaseFPConversion<0b00, 0b11, FPR16, FPR32, asm,
[(set FPR16:$Rd, (fpround FPR32:$Rn))]>;
}
//---
// Single operand floating point data processing
//---
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSingleOperandFPData<bits<4> opcode, RegisterClass regtype,
ValueType vt, string asm, SDPatternOperator node>
: I<(outs regtype:$Rd), (ins regtype:$Rn), asm, "\t$Rd, $Rn", "",
[(set (vt regtype:$Rd), (node (vt regtype:$Rn)))]>,
Sched<[WriteF]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31-24} = 0b00011110;
let Inst{21-19} = 0b100;
let Inst{18-15} = opcode;
let Inst{14-10} = 0b10000;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass SingleOperandFPData<bits<4> opcode, string asm,
SDPatternOperator node = null_frag> {
def Hr : BaseSingleOperandFPData<opcode, FPR16, f16, asm, node> {
let Inst{23-22} = 0b11; // 16-bit size flag
let Predicates = [HasFullFP16];
}
def Sr : BaseSingleOperandFPData<opcode, FPR32, f32, asm, node> {
let Inst{23-22} = 0b00; // 32-bit size flag
}
def Dr : BaseSingleOperandFPData<opcode, FPR64, f64, asm, node> {
let Inst{23-22} = 0b01; // 64-bit size flag
}
}
//---
// Two operand floating point data processing
//---
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseTwoOperandFPData<bits<4> opcode, RegisterClass regtype,
string asm, list<dag> pat>
: I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm),
asm, "\t$Rd, $Rn, $Rm", "", pat>,
Sched<[WriteF]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
let Inst{31-24} = 0b00011110;
let Inst{21} = 1;
let Inst{20-16} = Rm;
let Inst{15-12} = opcode;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass TwoOperandFPData<bits<4> opcode, string asm,
SDPatternOperator node = null_frag> {
def Hrr : BaseTwoOperandFPData<opcode, FPR16, asm,
[(set (f16 FPR16:$Rd),
(node (f16 FPR16:$Rn), (f16 FPR16:$Rm)))]> {
let Inst{23-22} = 0b11; // 16-bit size flag
let Predicates = [HasFullFP16];
}
def Srr : BaseTwoOperandFPData<opcode, FPR32, asm,
[(set (f32 FPR32:$Rd),
(node (f32 FPR32:$Rn), (f32 FPR32:$Rm)))]> {
let Inst{23-22} = 0b00; // 32-bit size flag
}
def Drr : BaseTwoOperandFPData<opcode, FPR64, asm,
[(set (f64 FPR64:$Rd),
(node (f64 FPR64:$Rn), (f64 FPR64:$Rm)))]> {
let Inst{23-22} = 0b01; // 64-bit size flag
}
}
multiclass TwoOperandFPDataNeg<bits<4> opcode, string asm, SDNode node> {
def Hrr : BaseTwoOperandFPData<opcode, FPR16, asm,
[(set FPR16:$Rd, (fneg (node FPR16:$Rn, (f16 FPR16:$Rm))))]> {
let Inst{23-22} = 0b11; // 16-bit size flag
let Predicates = [HasFullFP16];
}
def Srr : BaseTwoOperandFPData<opcode, FPR32, asm,
[(set FPR32:$Rd, (fneg (node FPR32:$Rn, (f32 FPR32:$Rm))))]> {
let Inst{23-22} = 0b00; // 32-bit size flag
}
def Drr : BaseTwoOperandFPData<opcode, FPR64, asm,
[(set FPR64:$Rd, (fneg (node FPR64:$Rn, (f64 FPR64:$Rm))))]> {
let Inst{23-22} = 0b01; // 64-bit size flag
}
}
//---
// Three operand floating point data processing
//---
class BaseThreeOperandFPData<bit isNegated, bit isSub,
RegisterClass regtype, string asm, list<dag> pat>
: I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm, regtype: $Ra),
asm, "\t$Rd, $Rn, $Rm, $Ra", "", pat>,
Sched<[WriteFMul]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
bits<5> Ra;
let Inst{31-24} = 0b00011111;
let Inst{21} = isNegated;
let Inst{20-16} = Rm;
let Inst{15} = isSub;
let Inst{14-10} = Ra;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass ThreeOperandFPData<bit isNegated, bit isSub,string asm,
SDPatternOperator node> {
def Hrrr : BaseThreeOperandFPData<isNegated, isSub, FPR16, asm,
[(set FPR16:$Rd,
(node (f16 FPR16:$Rn), (f16 FPR16:$Rm), (f16 FPR16:$Ra)))]> {
let Inst{23-22} = 0b11; // 16-bit size flag
let Predicates = [HasFullFP16];
}
def Srrr : BaseThreeOperandFPData<isNegated, isSub, FPR32, asm,
[(set FPR32:$Rd,
(node (f32 FPR32:$Rn), (f32 FPR32:$Rm), (f32 FPR32:$Ra)))]> {
let Inst{23-22} = 0b00; // 32-bit size flag
}
def Drrr : BaseThreeOperandFPData<isNegated, isSub, FPR64, asm,
[(set FPR64:$Rd,
(node (f64 FPR64:$Rn), (f64 FPR64:$Rm), (f64 FPR64:$Ra)))]> {
let Inst{23-22} = 0b01; // 64-bit size flag
}
}
//---
// Floating point data comparisons
//---
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseOneOperandFPComparison<bit signalAllNans,
RegisterClass regtype, string asm,
list<dag> pat>
: I<(outs), (ins regtype:$Rn), asm, "\t$Rn, #0.0", "", pat>,
Sched<[WriteFCmp]> {
bits<5> Rn;
let Inst{31-24} = 0b00011110;
let Inst{21} = 1;
let Inst{15-10} = 0b001000;
let Inst{9-5} = Rn;
let Inst{4} = signalAllNans;
let Inst{3-0} = 0b1000;
// Rm should be 0b00000 canonically, but we need to accept any value.
let PostEncoderMethod = "fixOneOperandFPComparison";
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseTwoOperandFPComparison<bit signalAllNans, RegisterClass regtype,
string asm, list<dag> pat>
: I<(outs), (ins regtype:$Rn, regtype:$Rm), asm, "\t$Rn, $Rm", "", pat>,
Sched<[WriteFCmp]> {
bits<5> Rm;
bits<5> Rn;
let Inst{31-24} = 0b00011110;
let Inst{21} = 1;
let Inst{20-16} = Rm;
let Inst{15-10} = 0b001000;
let Inst{9-5} = Rn;
let Inst{4} = signalAllNans;
let Inst{3-0} = 0b0000;
}
multiclass FPComparison<bit signalAllNans, string asm,
SDPatternOperator OpNode = null_frag> {
let Defs = [NZCV] in {
def Hrr : BaseTwoOperandFPComparison<signalAllNans, FPR16, asm,
[(OpNode FPR16:$Rn, (f16 FPR16:$Rm)), (implicit NZCV)]> {
let Inst{23-22} = 0b11;
let Predicates = [HasFullFP16];
}
def Hri : BaseOneOperandFPComparison<signalAllNans, FPR16, asm,
[(OpNode (f16 FPR16:$Rn), fpimm0), (implicit NZCV)]> {
let Inst{23-22} = 0b11;
let Predicates = [HasFullFP16];
}
def Srr : BaseTwoOperandFPComparison<signalAllNans, FPR32, asm,
[(OpNode FPR32:$Rn, (f32 FPR32:$Rm)), (implicit NZCV)]> {
let Inst{23-22} = 0b00;
}
def Sri : BaseOneOperandFPComparison<signalAllNans, FPR32, asm,
[(OpNode (f32 FPR32:$Rn), fpimm0), (implicit NZCV)]> {
let Inst{23-22} = 0b00;
}
def Drr : BaseTwoOperandFPComparison<signalAllNans, FPR64, asm,
[(OpNode FPR64:$Rn, (f64 FPR64:$Rm)), (implicit NZCV)]> {
let Inst{23-22} = 0b01;
}
def Dri : BaseOneOperandFPComparison<signalAllNans, FPR64, asm,
[(OpNode (f64 FPR64:$Rn), fpimm0), (implicit NZCV)]> {
let Inst{23-22} = 0b01;
}
} // Defs = [NZCV]
}
//---
// Floating point conditional comparisons
//---
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseFPCondComparison<bit signalAllNans, RegisterClass regtype,
string mnemonic, list<dag> pat>
: I<(outs), (ins regtype:$Rn, regtype:$Rm, imm32_0_15:$nzcv, ccode:$cond),
mnemonic, "\t$Rn, $Rm, $nzcv, $cond", "", pat>,
Sched<[WriteFCmp]> {
let Uses = [NZCV];
let Defs = [NZCV];
bits<5> Rn;
bits<5> Rm;
bits<4> nzcv;
bits<4> cond;
let Inst{31-24} = 0b00011110;
let Inst{21} = 1;
let Inst{20-16} = Rm;
let Inst{15-12} = cond;
let Inst{11-10} = 0b01;
let Inst{9-5} = Rn;
let Inst{4} = signalAllNans;
let Inst{3-0} = nzcv;
}
multiclass FPCondComparison<bit signalAllNans, string mnemonic,
SDPatternOperator OpNode = null_frag> {
def Hrr : BaseFPCondComparison<signalAllNans, FPR16, mnemonic, []> {
let Inst{23-22} = 0b11;
let Predicates = [HasFullFP16];
}
def Srr : BaseFPCondComparison<signalAllNans, FPR32, mnemonic,
[(set NZCV, (OpNode (f32 FPR32:$Rn), (f32 FPR32:$Rm), (i32 imm:$nzcv),
(i32 imm:$cond), NZCV))]> {
let Inst{23-22} = 0b00;
}
def Drr : BaseFPCondComparison<signalAllNans, FPR64, mnemonic,
[(set NZCV, (OpNode (f64 FPR64:$Rn), (f64 FPR64:$Rm), (i32 imm:$nzcv),
(i32 imm:$cond), NZCV))]> {
let Inst{23-22} = 0b01;
}
}
//---
// Floating point conditional select
//---
class BaseFPCondSelect<RegisterClass regtype, ValueType vt, string asm>
: I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm, ccode:$cond),
asm, "\t$Rd, $Rn, $Rm, $cond", "",
[(set regtype:$Rd,
(AArch64csel (vt regtype:$Rn), regtype:$Rm,
(i32 imm:$cond), NZCV))]>,
Sched<[WriteF]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
bits<4> cond;
let Inst{31-24} = 0b00011110;
let Inst{21} = 1;
let Inst{20-16} = Rm;
let Inst{15-12} = cond;
let Inst{11-10} = 0b11;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass FPCondSelect<string asm> {
let Uses = [NZCV] in {
def Hrrr : BaseFPCondSelect<FPR16, f16, asm> {
let Inst{23-22} = 0b11;
let Predicates = [HasFullFP16];
}
def Srrr : BaseFPCondSelect<FPR32, f32, asm> {
let Inst{23-22} = 0b00;
}
def Drrr : BaseFPCondSelect<FPR64, f64, asm> {
let Inst{23-22} = 0b01;
}
} // Uses = [NZCV]
}
//---
// Floating move immediate
//---
class BaseFPMoveImmediate<RegisterClass regtype, Operand fpimmtype, string asm>
: I<(outs regtype:$Rd), (ins fpimmtype:$imm), asm, "\t$Rd, $imm", "",
[(set regtype:$Rd, fpimmtype:$imm)]>,
Sched<[WriteFImm]> {
bits<5> Rd;
bits<8> imm;
let Inst{31-24} = 0b00011110;
let Inst{21} = 1;
let Inst{20-13} = imm;
let Inst{12-5} = 0b10000000;
let Inst{4-0} = Rd;
}
multiclass FPMoveImmediate<string asm> {
def Hi : BaseFPMoveImmediate<FPR16, fpimm16, asm> {
let Inst{23-22} = 0b11;
let Predicates = [HasFullFP16];
}
def Si : BaseFPMoveImmediate<FPR32, fpimm32, asm> {
let Inst{23-22} = 0b00;
}
def Di : BaseFPMoveImmediate<FPR64, fpimm64, asm> {
let Inst{23-22} = 0b01;
}
}
} // end of 'let Predicates = [HasFPARMv8]'
//----------------------------------------------------------------------------
// AdvSIMD
//----------------------------------------------------------------------------
let Predicates = [HasNEON] in {
//----------------------------------------------------------------------------
// AdvSIMD three register vector instructions
//----------------------------------------------------------------------------
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDThreeSameVector<bit Q, bit U, bits<3> size, bits<5> opcode,
RegisterOperand regtype, string asm, string kind,
list<dag> pattern>
: I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm), asm,
"{\t$Rd" # kind # ", $Rn" # kind # ", $Rm" # kind #
"|" # kind # "\t$Rd, $Rn, $Rm|}", "", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28-24} = 0b01110;
let Inst{23-21} = size;
let Inst{20-16} = Rm;
let Inst{15-11} = opcode;
let Inst{10} = 1;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDThreeSameVectorTied<bit Q, bit U, bits<3> size, bits<5> opcode,
RegisterOperand regtype, string asm, string kind,
list<dag> pattern>
: I<(outs regtype:$dst), (ins regtype:$Rd, regtype:$Rn, regtype:$Rm), asm,
"{\t$Rd" # kind # ", $Rn" # kind # ", $Rm" # kind #
"|" # kind # "\t$Rd, $Rn, $Rm}", "$Rd = $dst", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28-24} = 0b01110;
let Inst{23-21} = size;
let Inst{20-16} = Rm;
let Inst{15-11} = opcode;
let Inst{10} = 1;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
class BaseSIMDThreeSameVectorDot<bit Q, bit U, string asm, string kind1,
string kind2> :
BaseSIMDThreeSameVector<Q, U, 0b100, 0b10010, V128, asm, kind1, [] > {
let AsmString = !strconcat(asm, "{\t$Rd" # kind1 # ", $Rn" # kind2 # ", $Rm" # kind2 # "}");
}
// All operand sizes distinguished in the encoding.
multiclass SIMDThreeSameVector<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v8i8 : BaseSIMDThreeSameVector<0, U, 0b001, opc, V64,
asm, ".8b",
[(set (v8i8 V64:$Rd), (OpNode (v8i8 V64:$Rn), (v8i8 V64:$Rm)))]>;
def v16i8 : BaseSIMDThreeSameVector<1, U, 0b001, opc, V128,
asm, ".16b",
[(set (v16i8 V128:$Rd), (OpNode (v16i8 V128:$Rn), (v16i8 V128:$Rm)))]>;
def v4i16 : BaseSIMDThreeSameVector<0, U, 0b011, opc, V64,
asm, ".4h",
[(set (v4i16 V64:$Rd), (OpNode (v4i16 V64:$Rn), (v4i16 V64:$Rm)))]>;
def v8i16 : BaseSIMDThreeSameVector<1, U, 0b011, opc, V128,
asm, ".8h",
[(set (v8i16 V128:$Rd), (OpNode (v8i16 V128:$Rn), (v8i16 V128:$Rm)))]>;
def v2i32 : BaseSIMDThreeSameVector<0, U, 0b101, opc, V64,
asm, ".2s",
[(set (v2i32 V64:$Rd), (OpNode (v2i32 V64:$Rn), (v2i32 V64:$Rm)))]>;
def v4i32 : BaseSIMDThreeSameVector<1, U, 0b101, opc, V128,
asm, ".4s",
[(set (v4i32 V128:$Rd), (OpNode (v4i32 V128:$Rn), (v4i32 V128:$Rm)))]>;
def v2i64 : BaseSIMDThreeSameVector<1, U, 0b111, opc, V128,
asm, ".2d",
[(set (v2i64 V128:$Rd), (OpNode (v2i64 V128:$Rn), (v2i64 V128:$Rm)))]>;
}
// As above, but D sized elements unsupported.
multiclass SIMDThreeSameVectorBHS<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v8i8 : BaseSIMDThreeSameVector<0, U, 0b001, opc, V64,
asm, ".8b",
[(set V64:$Rd, (v8i8 (OpNode (v8i8 V64:$Rn), (v8i8 V64:$Rm))))]>;
def v16i8 : BaseSIMDThreeSameVector<1, U, 0b001, opc, V128,
asm, ".16b",
[(set V128:$Rd, (v16i8 (OpNode (v16i8 V128:$Rn), (v16i8 V128:$Rm))))]>;
def v4i16 : BaseSIMDThreeSameVector<0, U, 0b011, opc, V64,
asm, ".4h",
[(set V64:$Rd, (v4i16 (OpNode (v4i16 V64:$Rn), (v4i16 V64:$Rm))))]>;
def v8i16 : BaseSIMDThreeSameVector<1, U, 0b011, opc, V128,
asm, ".8h",
[(set V128:$Rd, (v8i16 (OpNode (v8i16 V128:$Rn), (v8i16 V128:$Rm))))]>;
def v2i32 : BaseSIMDThreeSameVector<0, U, 0b101, opc, V64,
asm, ".2s",
[(set V64:$Rd, (v2i32 (OpNode (v2i32 V64:$Rn), (v2i32 V64:$Rm))))]>;
def v4i32 : BaseSIMDThreeSameVector<1, U, 0b101, opc, V128,
asm, ".4s",
[(set V128:$Rd, (v4i32 (OpNode (v4i32 V128:$Rn), (v4i32 V128:$Rm))))]>;
}
multiclass SIMDThreeSameVectorBHSTied<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v8i8 : BaseSIMDThreeSameVectorTied<0, U, 0b001, opc, V64,
asm, ".8b",
[(set (v8i8 V64:$dst),
(OpNode (v8i8 V64:$Rd), (v8i8 V64:$Rn), (v8i8 V64:$Rm)))]>;
def v16i8 : BaseSIMDThreeSameVectorTied<1, U, 0b001, opc, V128,
asm, ".16b",
[(set (v16i8 V128:$dst),
(OpNode (v16i8 V128:$Rd), (v16i8 V128:$Rn), (v16i8 V128:$Rm)))]>;
def v4i16 : BaseSIMDThreeSameVectorTied<0, U, 0b011, opc, V64,
asm, ".4h",
[(set (v4i16 V64:$dst),
(OpNode (v4i16 V64:$Rd), (v4i16 V64:$Rn), (v4i16 V64:$Rm)))]>;
def v8i16 : BaseSIMDThreeSameVectorTied<1, U, 0b011, opc, V128,
asm, ".8h",
[(set (v8i16 V128:$dst),
(OpNode (v8i16 V128:$Rd), (v8i16 V128:$Rn), (v8i16 V128:$Rm)))]>;
def v2i32 : BaseSIMDThreeSameVectorTied<0, U, 0b101, opc, V64,
asm, ".2s",
[(set (v2i32 V64:$dst),
(OpNode (v2i32 V64:$Rd), (v2i32 V64:$Rn), (v2i32 V64:$Rm)))]>;
def v4i32 : BaseSIMDThreeSameVectorTied<1, U, 0b101, opc, V128,
asm, ".4s",
[(set (v4i32 V128:$dst),
(OpNode (v4i32 V128:$Rd), (v4i32 V128:$Rn), (v4i32 V128:$Rm)))]>;
}
// As above, but only B sized elements supported.
multiclass SIMDThreeSameVectorB<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v8i8 : BaseSIMDThreeSameVector<0, U, 0b001, opc, V64,
asm, ".8b",
[(set (v8i8 V64:$Rd), (OpNode (v8i8 V64:$Rn), (v8i8 V64:$Rm)))]>;
def v16i8 : BaseSIMDThreeSameVector<1, U, 0b001, opc, V128,
asm, ".16b",
[(set (v16i8 V128:$Rd),
(OpNode (v16i8 V128:$Rn), (v16i8 V128:$Rm)))]>;
}
// As above, but only floating point elements supported.
multiclass SIMDThreeSameVectorFP<bit U, bit S, bits<3> opc,
string asm, SDPatternOperator OpNode> {
let Predicates = [HasNEON, HasFullFP16] in {
def v4f16 : BaseSIMDThreeSameVector<0, U, {S,0b10}, {0b00,opc}, V64,
asm, ".4h",
[(set (v4f16 V64:$Rd), (OpNode (v4f16 V64:$Rn), (v4f16 V64:$Rm)))]>;
def v8f16 : BaseSIMDThreeSameVector<1, U, {S,0b10}, {0b00,opc}, V128,
asm, ".8h",
[(set (v8f16 V128:$Rd), (OpNode (v8f16 V128:$Rn), (v8f16 V128:$Rm)))]>;
} // Predicates = [HasNEON, HasFullFP16]
def v2f32 : BaseSIMDThreeSameVector<0, U, {S,0b01}, {0b11,opc}, V64,
asm, ".2s",
[(set (v2f32 V64:$Rd), (OpNode (v2f32 V64:$Rn), (v2f32 V64:$Rm)))]>;
def v4f32 : BaseSIMDThreeSameVector<1, U, {S,0b01}, {0b11,opc}, V128,
asm, ".4s",
[(set (v4f32 V128:$Rd), (OpNode (v4f32 V128:$Rn), (v4f32 V128:$Rm)))]>;
def v2f64 : BaseSIMDThreeSameVector<1, U, {S,0b11}, {0b11,opc}, V128,
asm, ".2d",
[(set (v2f64 V128:$Rd), (OpNode (v2f64 V128:$Rn), (v2f64 V128:$Rm)))]>;
}
multiclass SIMDThreeSameVectorFPCmp<bit U, bit S, bits<3> opc,
string asm,
SDPatternOperator OpNode> {
let Predicates = [HasNEON, HasFullFP16] in {
def v4f16 : BaseSIMDThreeSameVector<0, U, {S,0b10}, {0b00,opc}, V64,
asm, ".4h",
[(set (v4i16 V64:$Rd), (OpNode (v4f16 V64:$Rn), (v4f16 V64:$Rm)))]>;
def v8f16 : BaseSIMDThreeSameVector<1, U, {S,0b10}, {0b00,opc}, V128,
asm, ".8h",
[(set (v8i16 V128:$Rd), (OpNode (v8f16 V128:$Rn), (v8f16 V128:$Rm)))]>;
} // Predicates = [HasNEON, HasFullFP16]
def v2f32 : BaseSIMDThreeSameVector<0, U, {S,0b01}, {0b11,opc}, V64,
asm, ".2s",
[(set (v2i32 V64:$Rd), (OpNode (v2f32 V64:$Rn), (v2f32 V64:$Rm)))]>;
def v4f32 : BaseSIMDThreeSameVector<1, U, {S,0b01}, {0b11,opc}, V128,
asm, ".4s",
[(set (v4i32 V128:$Rd), (OpNode (v4f32 V128:$Rn), (v4f32 V128:$Rm)))]>;
def v2f64 : BaseSIMDThreeSameVector<1, U, {S,0b11}, {0b11,opc}, V128,
asm, ".2d",
[(set (v2i64 V128:$Rd), (OpNode (v2f64 V128:$Rn), (v2f64 V128:$Rm)))]>;
}
multiclass SIMDThreeSameVectorFPTied<bit U, bit S, bits<3> opc,
string asm, SDPatternOperator OpNode> {
let Predicates = [HasNEON, HasFullFP16] in {
def v4f16 : BaseSIMDThreeSameVectorTied<0, U, {S,0b10}, {0b00,opc}, V64,
asm, ".4h",
[(set (v4f16 V64:$dst),
(OpNode (v4f16 V64:$Rd), (v4f16 V64:$Rn), (v4f16 V64:$Rm)))]>;
def v8f16 : BaseSIMDThreeSameVectorTied<1, U, {S,0b10}, {0b00,opc}, V128,
asm, ".8h",
[(set (v8f16 V128:$dst),
(OpNode (v8f16 V128:$Rd), (v8f16 V128:$Rn), (v8f16 V128:$Rm)))]>;
} // Predicates = [HasNEON, HasFullFP16]
def v2f32 : BaseSIMDThreeSameVectorTied<0, U, {S,0b01}, {0b11,opc}, V64,
asm, ".2s",
[(set (v2f32 V64:$dst),
(OpNode (v2f32 V64:$Rd), (v2f32 V64:$Rn), (v2f32 V64:$Rm)))]>;
def v4f32 : BaseSIMDThreeSameVectorTied<1, U, {S,0b01}, {0b11,opc}, V128,
asm, ".4s",
[(set (v4f32 V128:$dst),
(OpNode (v4f32 V128:$Rd), (v4f32 V128:$Rn), (v4f32 V128:$Rm)))]>;
def v2f64 : BaseSIMDThreeSameVectorTied<1, U, {S,0b11}, {0b11,opc}, V128,
asm, ".2d",
[(set (v2f64 V128:$dst),
(OpNode (v2f64 V128:$Rd), (v2f64 V128:$Rn), (v2f64 V128:$Rm)))]>;
}
// As above, but D and B sized elements unsupported.
multiclass SIMDThreeSameVectorHS<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v4i16 : BaseSIMDThreeSameVector<0, U, 0b011, opc, V64,
asm, ".4h",
[(set (v4i16 V64:$Rd), (OpNode (v4i16 V64:$Rn), (v4i16 V64:$Rm)))]>;
def v8i16 : BaseSIMDThreeSameVector<1, U, 0b011, opc, V128,
asm, ".8h",
[(set (v8i16 V128:$Rd), (OpNode (v8i16 V128:$Rn), (v8i16 V128:$Rm)))]>;
def v2i32 : BaseSIMDThreeSameVector<0, U, 0b101, opc, V64,
asm, ".2s",
[(set (v2i32 V64:$Rd), (OpNode (v2i32 V64:$Rn), (v2i32 V64:$Rm)))]>;
def v4i32 : BaseSIMDThreeSameVector<1, U, 0b101, opc, V128,
asm, ".4s",
[(set (v4i32 V128:$Rd), (OpNode (v4i32 V128:$Rn), (v4i32 V128:$Rm)))]>;
}
// Logical three vector ops share opcode bits, and only use B sized elements.
multiclass SIMDLogicalThreeVector<bit U, bits<2> size, string asm,
SDPatternOperator OpNode = null_frag> {
def v8i8 : BaseSIMDThreeSameVector<0, U, {size,1}, 0b00011, V64,
asm, ".8b",
[(set (v8i8 V64:$Rd), (OpNode V64:$Rn, V64:$Rm))]>;
def v16i8 : BaseSIMDThreeSameVector<1, U, {size,1}, 0b00011, V128,
asm, ".16b",
[(set (v16i8 V128:$Rd), (OpNode V128:$Rn, V128:$Rm))]>;
def : Pat<(v4i16 (OpNode V64:$LHS, V64:$RHS)),
(!cast<Instruction>(NAME#"v8i8") V64:$LHS, V64:$RHS)>;
def : Pat<(v2i32 (OpNode V64:$LHS, V64:$RHS)),
(!cast<Instruction>(NAME#"v8i8") V64:$LHS, V64:$RHS)>;
def : Pat<(v1i64 (OpNode V64:$LHS, V64:$RHS)),
(!cast<Instruction>(NAME#"v8i8") V64:$LHS, V64:$RHS)>;
def : Pat<(v8i16 (OpNode V128:$LHS, V128:$RHS)),
(!cast<Instruction>(NAME#"v16i8") V128:$LHS, V128:$RHS)>;
def : Pat<(v4i32 (OpNode V128:$LHS, V128:$RHS)),
(!cast<Instruction>(NAME#"v16i8") V128:$LHS, V128:$RHS)>;
def : Pat<(v2i64 (OpNode V128:$LHS, V128:$RHS)),
(!cast<Instruction>(NAME#"v16i8") V128:$LHS, V128:$RHS)>;
}
multiclass SIMDLogicalThreeVectorTied<bit U, bits<2> size,
string asm, SDPatternOperator OpNode> {
def v8i8 : BaseSIMDThreeSameVectorTied<0, U, {size,1}, 0b00011, V64,
asm, ".8b",
[(set (v8i8 V64:$dst),
(OpNode (v8i8 V64:$Rd), (v8i8 V64:$Rn), (v8i8 V64:$Rm)))]>;
def v16i8 : BaseSIMDThreeSameVectorTied<1, U, {size,1}, 0b00011, V128,
asm, ".16b",
[(set (v16i8 V128:$dst),
(OpNode (v16i8 V128:$Rd), (v16i8 V128:$Rn),
(v16i8 V128:$Rm)))]>;
def : Pat<(v4i16 (OpNode (v4i16 V64:$LHS), (v4i16 V64:$MHS),
(v4i16 V64:$RHS))),
(!cast<Instruction>(NAME#"v8i8")
V64:$LHS, V64:$MHS, V64:$RHS)>;
def : Pat<(v2i32 (OpNode (v2i32 V64:$LHS), (v2i32 V64:$MHS),
(v2i32 V64:$RHS))),
(!cast<Instruction>(NAME#"v8i8")
V64:$LHS, V64:$MHS, V64:$RHS)>;
def : Pat<(v1i64 (OpNode (v1i64 V64:$LHS), (v1i64 V64:$MHS),
(v1i64 V64:$RHS))),
(!cast<Instruction>(NAME#"v8i8")
V64:$LHS, V64:$MHS, V64:$RHS)>;
def : Pat<(v8i16 (OpNode (v8i16 V128:$LHS), (v8i16 V128:$MHS),
(v8i16 V128:$RHS))),
(!cast<Instruction>(NAME#"v16i8")
V128:$LHS, V128:$MHS, V128:$RHS)>;
def : Pat<(v4i32 (OpNode (v4i32 V128:$LHS), (v4i32 V128:$MHS),
(v4i32 V128:$RHS))),
(!cast<Instruction>(NAME#"v16i8")
V128:$LHS, V128:$MHS, V128:$RHS)>;
def : Pat<(v2i64 (OpNode (v2i64 V128:$LHS), (v2i64 V128:$MHS),
(v2i64 V128:$RHS))),
(!cast<Instruction>(NAME#"v16i8")
V128:$LHS, V128:$MHS, V128:$RHS)>;
}
//----------------------------------------------------------------------------
// AdvSIMD two register vector instructions.
//----------------------------------------------------------------------------
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDTwoSameVector<bit Q, bit U, bits<2> size, bits<5> opcode,
bits<2> size2, RegisterOperand regtype, string asm,
string dstkind, string srckind, list<dag> pattern>
: I<(outs regtype:$Rd), (ins regtype:$Rn), asm,
"{\t$Rd" # dstkind # ", $Rn" # srckind #
"|" # dstkind # "\t$Rd, $Rn}", "", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28-24} = 0b01110;
let Inst{23-22} = size;
let Inst{21} = 0b1;
let Inst{20-19} = size2;
let Inst{18-17} = 0b00;
let Inst{16-12} = opcode;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDTwoSameVectorTied<bit Q, bit U, bits<2> size, bits<5> opcode,
bits<2> size2, RegisterOperand regtype,
string asm, string dstkind, string srckind,
list<dag> pattern>
: I<(outs regtype:$dst), (ins regtype:$Rd, regtype:$Rn), asm,
"{\t$Rd" # dstkind # ", $Rn" # srckind #
"|" # dstkind # "\t$Rd, $Rn}", "$Rd = $dst", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28-24} = 0b01110;
let Inst{23-22} = size;
let Inst{21} = 0b1;
let Inst{20-19} = size2;
let Inst{18-17} = 0b00;
let Inst{16-12} = opcode;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
// Supports B, H, and S element sizes.
multiclass SIMDTwoVectorBHS<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v8i8 : BaseSIMDTwoSameVector<0, U, 0b00, opc, 0b00, V64,
asm, ".8b", ".8b",
[(set (v8i8 V64:$Rd), (OpNode (v8i8 V64:$Rn)))]>;
def v16i8 : BaseSIMDTwoSameVector<1, U, 0b00, opc, 0b00, V128,
asm, ".16b", ".16b",
[(set (v16i8 V128:$Rd), (OpNode (v16i8 V128:$Rn)))]>;
def v4i16 : BaseSIMDTwoSameVector<0, U, 0b01, opc, 0b00, V64,
asm, ".4h", ".4h",
[(set (v4i16 V64:$Rd), (OpNode (v4i16 V64:$Rn)))]>;
def v8i16 : BaseSIMDTwoSameVector<1, U, 0b01, opc, 0b00, V128,
asm, ".8h", ".8h",
[(set (v8i16 V128:$Rd), (OpNode (v8i16 V128:$Rn)))]>;
def v2i32 : BaseSIMDTwoSameVector<0, U, 0b10, opc, 0b00, V64,
asm, ".2s", ".2s",
[(set (v2i32 V64:$Rd), (OpNode (v2i32 V64:$Rn)))]>;
def v4i32 : BaseSIMDTwoSameVector<1, U, 0b10, opc, 0b00, V128,
asm, ".4s", ".4s",
[(set (v4i32 V128:$Rd), (OpNode (v4i32 V128:$Rn)))]>;
}
class BaseSIMDVectorLShiftLongBySize<bit Q, bits<2> size,
RegisterOperand regtype, string asm, string dstkind,
string srckind, string amount>
: I<(outs V128:$Rd), (ins regtype:$Rn), asm,
"{\t$Rd" # dstkind # ", $Rn" # srckind # ", #" # amount #
"|" # dstkind # "\t$Rd, $Rn, #" # amount # "}", "", []>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29-24} = 0b101110;
let Inst{23-22} = size;
let Inst{21-10} = 0b100001001110;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass SIMDVectorLShiftLongBySizeBHS {
let hasSideEffects = 0 in {
def v8i8 : BaseSIMDVectorLShiftLongBySize<0, 0b00, V64,
"shll", ".8h", ".8b", "8">;
def v16i8 : BaseSIMDVectorLShiftLongBySize<1, 0b00, V128,
"shll2", ".8h", ".16b", "8">;
def v4i16 : BaseSIMDVectorLShiftLongBySize<0, 0b01, V64,
"shll", ".4s", ".4h", "16">;
def v8i16 : BaseSIMDVectorLShiftLongBySize<1, 0b01, V128,
"shll2", ".4s", ".8h", "16">;
def v2i32 : BaseSIMDVectorLShiftLongBySize<0, 0b10, V64,
"shll", ".2d", ".2s", "32">;
def v4i32 : BaseSIMDVectorLShiftLongBySize<1, 0b10, V128,
"shll2", ".2d", ".4s", "32">;
}
}
// Supports all element sizes.
multiclass SIMDLongTwoVector<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v8i8_v4i16 : BaseSIMDTwoSameVector<0, U, 0b00, opc, 0b00, V64,
asm, ".4h", ".8b",
[(set (v4i16 V64:$Rd), (OpNode (v8i8 V64:$Rn)))]>;
def v16i8_v8i16 : BaseSIMDTwoSameVector<1, U, 0b00, opc, 0b00, V128,
asm, ".8h", ".16b",
[(set (v8i16 V128:$Rd), (OpNode (v16i8 V128:$Rn)))]>;
def v4i16_v2i32 : BaseSIMDTwoSameVector<0, U, 0b01, opc, 0b00, V64,
asm, ".2s", ".4h",
[(set (v2i32 V64:$Rd), (OpNode (v4i16 V64:$Rn)))]>;
def v8i16_v4i32 : BaseSIMDTwoSameVector<1, U, 0b01, opc, 0b00, V128,
asm, ".4s", ".8h",
[(set (v4i32 V128:$Rd), (OpNode (v8i16 V128:$Rn)))]>;
def v2i32_v1i64 : BaseSIMDTwoSameVector<0, U, 0b10, opc, 0b00, V64,
asm, ".1d", ".2s",
[(set (v1i64 V64:$Rd), (OpNode (v2i32 V64:$Rn)))]>;
def v4i32_v2i64 : BaseSIMDTwoSameVector<1, U, 0b10, opc, 0b00, V128,
asm, ".2d", ".4s",
[(set (v2i64 V128:$Rd), (OpNode (v4i32 V128:$Rn)))]>;
}
multiclass SIMDLongTwoVectorTied<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v8i8_v4i16 : BaseSIMDTwoSameVectorTied<0, U, 0b00, opc, 0b00, V64,
asm, ".4h", ".8b",
[(set (v4i16 V64:$dst), (OpNode (v4i16 V64:$Rd),
(v8i8 V64:$Rn)))]>;
def v16i8_v8i16 : BaseSIMDTwoSameVectorTied<1, U, 0b00, opc, 0b00, V128,
asm, ".8h", ".16b",
[(set (v8i16 V128:$dst), (OpNode (v8i16 V128:$Rd),
(v16i8 V128:$Rn)))]>;
def v4i16_v2i32 : BaseSIMDTwoSameVectorTied<0, U, 0b01, opc, 0b00, V64,
asm, ".2s", ".4h",
[(set (v2i32 V64:$dst), (OpNode (v2i32 V64:$Rd),
(v4i16 V64:$Rn)))]>;
def v8i16_v4i32 : BaseSIMDTwoSameVectorTied<1, U, 0b01, opc, 0b00, V128,
asm, ".4s", ".8h",
[(set (v4i32 V128:$dst), (OpNode (v4i32 V128:$Rd),
(v8i16 V128:$Rn)))]>;
def v2i32_v1i64 : BaseSIMDTwoSameVectorTied<0, U, 0b10, opc, 0b00, V64,
asm, ".1d", ".2s",
[(set (v1i64 V64:$dst), (OpNode (v1i64 V64:$Rd),
(v2i32 V64:$Rn)))]>;
def v4i32_v2i64 : BaseSIMDTwoSameVectorTied<1, U, 0b10, opc, 0b00, V128,
asm, ".2d", ".4s",
[(set (v2i64 V128:$dst), (OpNode (v2i64 V128:$Rd),
(v4i32 V128:$Rn)))]>;
}
// Supports all element sizes, except 1xD.
multiclass SIMDTwoVectorBHSDTied<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v8i8 : BaseSIMDTwoSameVectorTied<0, U, 0b00, opc, 0b00, V64,
asm, ".8b", ".8b",
[(set (v8i8 V64:$dst), (OpNode (v8i8 V64:$Rd), (v8i8 V64:$Rn)))]>;
def v16i8 : BaseSIMDTwoSameVectorTied<1, U, 0b00, opc, 0b00, V128,
asm, ".16b", ".16b",
[(set (v16i8 V128:$dst), (OpNode (v16i8 V128:$Rd), (v16i8 V128:$Rn)))]>;
def v4i16 : BaseSIMDTwoSameVectorTied<0, U, 0b01, opc, 0b00, V64,
asm, ".4h", ".4h",
[(set (v4i16 V64:$dst), (OpNode (v4i16 V64:$Rd), (v4i16 V64:$Rn)))]>;
def v8i16 : BaseSIMDTwoSameVectorTied<1, U, 0b01, opc, 0b00, V128,
asm, ".8h", ".8h",
[(set (v8i16 V128:$dst), (OpNode (v8i16 V128:$Rd), (v8i16 V128:$Rn)))]>;
def v2i32 : BaseSIMDTwoSameVectorTied<0, U, 0b10, opc, 0b00, V64,
asm, ".2s", ".2s",
[(set (v2i32 V64:$dst), (OpNode (v2i32 V64:$Rd), (v2i32 V64:$Rn)))]>;
def v4i32 : BaseSIMDTwoSameVectorTied<1, U, 0b10, opc, 0b00, V128,
asm, ".4s", ".4s",
[(set (v4i32 V128:$dst), (OpNode (v4i32 V128:$Rd), (v4i32 V128:$Rn)))]>;
def v2i64 : BaseSIMDTwoSameVectorTied<1, U, 0b11, opc, 0b00, V128,
asm, ".2d", ".2d",
[(set (v2i64 V128:$dst), (OpNode (v2i64 V128:$Rd), (v2i64 V128:$Rn)))]>;
}
multiclass SIMDTwoVectorBHSD<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode = null_frag> {
def v8i8 : BaseSIMDTwoSameVector<0, U, 0b00, opc, 0b00, V64,
asm, ".8b", ".8b",
[(set (v8i8 V64:$Rd), (OpNode (v8i8 V64:$Rn)))]>;
def v16i8 : BaseSIMDTwoSameVector<1, U, 0b00, opc, 0b00, V128,
asm, ".16b", ".16b",
[(set (v16i8 V128:$Rd), (OpNode (v16i8 V128:$Rn)))]>;
def v4i16 : BaseSIMDTwoSameVector<0, U, 0b01, opc, 0b00, V64,
asm, ".4h", ".4h",
[(set (v4i16 V64:$Rd), (OpNode (v4i16 V64:$Rn)))]>;
def v8i16 : BaseSIMDTwoSameVector<1, U, 0b01, opc, 0b00, V128,
asm, ".8h", ".8h",
[(set (v8i16 V128:$Rd), (OpNode (v8i16 V128:$Rn)))]>;
def v2i32 : BaseSIMDTwoSameVector<0, U, 0b10, opc, 0b00, V64,
asm, ".2s", ".2s",
[(set (v2i32 V64:$Rd), (OpNode (v2i32 V64:$Rn)))]>;
def v4i32 : BaseSIMDTwoSameVector<1, U, 0b10, opc, 0b00, V128,
asm, ".4s", ".4s",
[(set (v4i32 V128:$Rd), (OpNode (v4i32 V128:$Rn)))]>;
def v2i64 : BaseSIMDTwoSameVector<1, U, 0b11, opc, 0b00, V128,
asm, ".2d", ".2d",
[(set (v2i64 V128:$Rd), (OpNode (v2i64 V128:$Rn)))]>;
}
// Supports only B element sizes.
multiclass SIMDTwoVectorB<bit U, bits<2> size, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v8i8 : BaseSIMDTwoSameVector<0, U, size, opc, 0b00, V64,
asm, ".8b", ".8b",
[(set (v8i8 V64:$Rd), (OpNode (v8i8 V64:$Rn)))]>;
def v16i8 : BaseSIMDTwoSameVector<1, U, size, opc, 0b00, V128,
asm, ".16b", ".16b",
[(set (v16i8 V128:$Rd), (OpNode (v16i8 V128:$Rn)))]>;
}
// Supports only B and H element sizes.
multiclass SIMDTwoVectorBH<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v8i8 : BaseSIMDTwoSameVector<0, U, 0b00, opc, 0b00, V64,
asm, ".8b", ".8b",
[(set (v8i8 V64:$Rd), (OpNode V64:$Rn))]>;
def v16i8 : BaseSIMDTwoSameVector<1, U, 0b00, opc, 0b00, V128,
asm, ".16b", ".16b",
[(set (v16i8 V128:$Rd), (OpNode V128:$Rn))]>;
def v4i16 : BaseSIMDTwoSameVector<0, U, 0b01, opc, 0b00, V64,
asm, ".4h", ".4h",
[(set (v4i16 V64:$Rd), (OpNode V64:$Rn))]>;
def v8i16 : BaseSIMDTwoSameVector<1, U, 0b01, opc, 0b00, V128,
asm, ".8h", ".8h",
[(set (v8i16 V128:$Rd), (OpNode V128:$Rn))]>;
}
// Supports only S and D element sizes, uses high bit of the size field
// as an extra opcode bit.
multiclass SIMDTwoVectorFP<bit U, bit S, bits<5> opc, string asm,
SDPatternOperator OpNode> {
let Predicates = [HasNEON, HasFullFP16] in {
def v4f16 : BaseSIMDTwoSameVector<0, U, {S,1}, opc, 0b11, V64,
asm, ".4h", ".4h",
[(set (v4f16 V64:$Rd), (OpNode (v4f16 V64:$Rn)))]>;
def v8f16 : BaseSIMDTwoSameVector<1, U, {S,1}, opc, 0b11, V128,
asm, ".8h", ".8h",
[(set (v8f16 V128:$Rd), (OpNode (v8f16 V128:$Rn)))]>;
} // Predicates = [HasNEON, HasFullFP16]
def v2f32 : BaseSIMDTwoSameVector<0, U, {S,0}, opc, 0b00, V64,
asm, ".2s", ".2s",
[(set (v2f32 V64:$Rd), (OpNode (v2f32 V64:$Rn)))]>;
def v4f32 : BaseSIMDTwoSameVector<1, U, {S,0}, opc, 0b00, V128,
asm, ".4s", ".4s",
[(set (v4f32 V128:$Rd), (OpNode (v4f32 V128:$Rn)))]>;
def v2f64 : BaseSIMDTwoSameVector<1, U, {S,1}, opc, 0b00, V128,
asm, ".2d", ".2d",
[(set (v2f64 V128:$Rd), (OpNode (v2f64 V128:$Rn)))]>;
}
// Supports only S element size.
multiclass SIMDTwoVectorS<bit U, bit S, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v2i32 : BaseSIMDTwoSameVector<0, U, {S,0}, opc, 0b00, V64,
asm, ".2s", ".2s",
[(set (v2i32 V64:$Rd), (OpNode (v2i32 V64:$Rn)))]>;
def v4i32 : BaseSIMDTwoSameVector<1, U, {S,0}, opc, 0b00, V128,
asm, ".4s", ".4s",
[(set (v4i32 V128:$Rd), (OpNode (v4i32 V128:$Rn)))]>;
}
multiclass SIMDTwoVectorFPToInt<bit U, bit S, bits<5> opc, string asm,
SDPatternOperator OpNode> {
let Predicates = [HasNEON, HasFullFP16] in {
def v4f16 : BaseSIMDTwoSameVector<0, U, {S,1}, opc, 0b11, V64,
asm, ".4h", ".4h",
[(set (v4i16 V64:$Rd), (OpNode (v4f16 V64:$Rn)))]>;
def v8f16 : BaseSIMDTwoSameVector<1, U, {S,1}, opc, 0b11, V128,
asm, ".8h", ".8h",
[(set (v8i16 V128:$Rd), (OpNode (v8f16 V128:$Rn)))]>;
} // Predicates = [HasNEON, HasFullFP16]
def v2f32 : BaseSIMDTwoSameVector<0, U, {S,0}, opc, 0b00, V64,
asm, ".2s", ".2s",
[(set (v2i32 V64:$Rd), (OpNode (v2f32 V64:$Rn)))]>;
def v4f32 : BaseSIMDTwoSameVector<1, U, {S,0}, opc, 0b00, V128,
asm, ".4s", ".4s",
[(set (v4i32 V128:$Rd), (OpNode (v4f32 V128:$Rn)))]>;
def v2f64 : BaseSIMDTwoSameVector<1, U, {S,1}, opc, 0b00, V128,
asm, ".2d", ".2d",
[(set (v2i64 V128:$Rd), (OpNode (v2f64 V128:$Rn)))]>;
}
multiclass SIMDTwoVectorIntToFP<bit U, bit S, bits<5> opc, string asm,
SDPatternOperator OpNode> {
let Predicates = [HasNEON, HasFullFP16] in {
def v4f16 : BaseSIMDTwoSameVector<0, U, {S,1}, opc, 0b11, V64,
asm, ".4h", ".4h",
[(set (v4f16 V64:$Rd), (OpNode (v4i16 V64:$Rn)))]>;
def v8f16 : BaseSIMDTwoSameVector<1, U, {S,1}, opc, 0b11, V128,
asm, ".8h", ".8h",
[(set (v8f16 V128:$Rd), (OpNode (v8i16 V128:$Rn)))]>;
} // Predicates = [HasNEON, HasFullFP16]
def v2f32 : BaseSIMDTwoSameVector<0, U, {S,0}, opc, 0b00, V64,
asm, ".2s", ".2s",
[(set (v2f32 V64:$Rd), (OpNode (v2i32 V64:$Rn)))]>;
def v4f32 : BaseSIMDTwoSameVector<1, U, {S,0}, opc, 0b00, V128,
asm, ".4s", ".4s",
[(set (v4f32 V128:$Rd), (OpNode (v4i32 V128:$Rn)))]>;
def v2f64 : BaseSIMDTwoSameVector<1, U, {S,1}, opc, 0b00, V128,
asm, ".2d", ".2d",
[(set (v2f64 V128:$Rd), (OpNode (v2i64 V128:$Rn)))]>;
}
class BaseSIMDMixedTwoVector<bit Q, bit U, bits<2> size, bits<5> opcode,
RegisterOperand inreg, RegisterOperand outreg,
string asm, string outkind, string inkind,
list<dag> pattern>
: I<(outs outreg:$Rd), (ins inreg:$Rn), asm,
"{\t$Rd" # outkind # ", $Rn" # inkind #
"|" # outkind # "\t$Rd, $Rn}", "", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28-24} = 0b01110;
let Inst{23-22} = size;
let Inst{21-17} = 0b10000;
let Inst{16-12} = opcode;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
class BaseSIMDMixedTwoVectorTied<bit Q, bit U, bits<2> size, bits<5> opcode,
RegisterOperand inreg, RegisterOperand outreg,
string asm, string outkind, string inkind,
list<dag> pattern>
: I<(outs outreg:$dst), (ins outreg:$Rd, inreg:$Rn), asm,
"{\t$Rd" # outkind # ", $Rn" # inkind #
"|" # outkind # "\t$Rd, $Rn}", "$Rd = $dst", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28-24} = 0b01110;
let Inst{23-22} = size;
let Inst{21-17} = 0b10000;
let Inst{16-12} = opcode;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass SIMDMixedTwoVector<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v8i8 : BaseSIMDMixedTwoVector<0, U, 0b00, opc, V128, V64,
asm, ".8b", ".8h",
[(set (v8i8 V64:$Rd), (OpNode (v8i16 V128:$Rn)))]>;
def v16i8 : BaseSIMDMixedTwoVectorTied<1, U, 0b00, opc, V128, V128,
asm#"2", ".16b", ".8h", []>;
def v4i16 : BaseSIMDMixedTwoVector<0, U, 0b01, opc, V128, V64,
asm, ".4h", ".4s",
[(set (v4i16 V64:$Rd), (OpNode (v4i32 V128:$Rn)))]>;
def v8i16 : BaseSIMDMixedTwoVectorTied<1, U, 0b01, opc, V128, V128,
asm#"2", ".8h", ".4s", []>;
def v2i32 : BaseSIMDMixedTwoVector<0, U, 0b10, opc, V128, V64,
asm, ".2s", ".2d",
[(set (v2i32 V64:$Rd), (OpNode (v2i64 V128:$Rn)))]>;
def v4i32 : BaseSIMDMixedTwoVectorTied<1, U, 0b10, opc, V128, V128,
asm#"2", ".4s", ".2d", []>;
def : Pat<(concat_vectors (v8i8 V64:$Rd), (OpNode (v8i16 V128:$Rn))),
(!cast<Instruction>(NAME # "v16i8")
(INSERT_SUBREG (IMPLICIT_DEF), V64:$Rd, dsub), V128:$Rn)>;
def : Pat<(concat_vectors (v4i16 V64:$Rd), (OpNode (v4i32 V128:$Rn))),
(!cast<Instruction>(NAME # "v8i16")
(INSERT_SUBREG (IMPLICIT_DEF), V64:$Rd, dsub), V128:$Rn)>;
def : Pat<(concat_vectors (v2i32 V64:$Rd), (OpNode (v2i64 V128:$Rn))),
(!cast<Instruction>(NAME # "v4i32")
(INSERT_SUBREG (IMPLICIT_DEF), V64:$Rd, dsub), V128:$Rn)>;
}
class BaseSIMDCmpTwoVector<bit Q, bit U, bits<2> size, bits<2> size2,
bits<5> opcode, RegisterOperand regtype, string asm,
string kind, string zero, ValueType dty,
ValueType sty, SDNode OpNode>
: I<(outs regtype:$Rd), (ins regtype:$Rn), asm,
"{\t$Rd" # kind # ", $Rn" # kind # ", #" # zero #
"|" # kind # "\t$Rd, $Rn, #" # zero # "}", "",
[(set (dty regtype:$Rd), (OpNode (sty regtype:$Rn)))]>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28-24} = 0b01110;
let Inst{23-22} = size;
let Inst{21} = 0b1;
let Inst{20-19} = size2;
let Inst{18-17} = 0b00;
let Inst{16-12} = opcode;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
// Comparisons support all element sizes, except 1xD.
multiclass SIMDCmpTwoVector<bit U, bits<5> opc, string asm,
SDNode OpNode> {
def v8i8rz : BaseSIMDCmpTwoVector<0, U, 0b00, 0b00, opc, V64,
asm, ".8b", "0",
v8i8, v8i8, OpNode>;
def v16i8rz : BaseSIMDCmpTwoVector<1, U, 0b00, 0b00, opc, V128,
asm, ".16b", "0",
v16i8, v16i8, OpNode>;
def v4i16rz : BaseSIMDCmpTwoVector<0, U, 0b01, 0b00, opc, V64,
asm, ".4h", "0",
v4i16, v4i16, OpNode>;
def v8i16rz : BaseSIMDCmpTwoVector<1, U, 0b01, 0b00, opc, V128,
asm, ".8h", "0",
v8i16, v8i16, OpNode>;
def v2i32rz : BaseSIMDCmpTwoVector<0, U, 0b10, 0b00, opc, V64,
asm, ".2s", "0",
v2i32, v2i32, OpNode>;
def v4i32rz : BaseSIMDCmpTwoVector<1, U, 0b10, 0b00, opc, V128,
asm, ".4s", "0",
v4i32, v4i32, OpNode>;
def v2i64rz : BaseSIMDCmpTwoVector<1, U, 0b11, 0b00, opc, V128,
asm, ".2d", "0",
v2i64, v2i64, OpNode>;
}
// FP Comparisons support only S and D element sizes (and H for v8.2a).
multiclass SIMDFPCmpTwoVector<bit U, bit S, bits<5> opc,
string asm, SDNode OpNode> {
let Predicates = [HasNEON, HasFullFP16] in {
def v4i16rz : BaseSIMDCmpTwoVector<0, U, {S,1}, 0b11, opc, V64,
asm, ".4h", "0.0",
v4i16, v4f16, OpNode>;
def v8i16rz : BaseSIMDCmpTwoVector<1, U, {S,1}, 0b11, opc, V128,
asm, ".8h", "0.0",
v8i16, v8f16, OpNode>;
} // Predicates = [HasNEON, HasFullFP16]
def v2i32rz : BaseSIMDCmpTwoVector<0, U, {S,0}, 0b00, opc, V64,
asm, ".2s", "0.0",
v2i32, v2f32, OpNode>;
def v4i32rz : BaseSIMDCmpTwoVector<1, U, {S,0}, 0b00, opc, V128,
asm, ".4s", "0.0",
v4i32, v4f32, OpNode>;
def v2i64rz : BaseSIMDCmpTwoVector<1, U, {S,1}, 0b00, opc, V128,
asm, ".2d", "0.0",
v2i64, v2f64, OpNode>;
let Predicates = [HasNEON, HasFullFP16] in {
def : InstAlias<asm # "\t$Vd.4h, $Vn.4h, #0",
(!cast<Instruction>(NAME # v4i16rz) V64:$Vd, V64:$Vn), 0>;
def : InstAlias<asm # "\t$Vd.8h, $Vn.8h, #0",
(!cast<Instruction>(NAME # v8i16rz) V128:$Vd, V128:$Vn), 0>;
}
def : InstAlias<asm # "\t$Vd.2s, $Vn.2s, #0",
(!cast<Instruction>(NAME # v2i32rz) V64:$Vd, V64:$Vn), 0>;
def : InstAlias<asm # "\t$Vd.4s, $Vn.4s, #0",
(!cast<Instruction>(NAME # v4i32rz) V128:$Vd, V128:$Vn), 0>;
def : InstAlias<asm # "\t$Vd.2d, $Vn.2d, #0",
(!cast<Instruction>(NAME # v2i64rz) V128:$Vd, V128:$Vn), 0>;
let Predicates = [HasNEON, HasFullFP16] in {
def : InstAlias<asm # ".4h\t$Vd, $Vn, #0",
(!cast<Instruction>(NAME # v4i16rz) V64:$Vd, V64:$Vn), 0>;
def : InstAlias<asm # ".8h\t$Vd, $Vn, #0",
(!cast<Instruction>(NAME # v8i16rz) V128:$Vd, V128:$Vn), 0>;
}
def : InstAlias<asm # ".2s\t$Vd, $Vn, #0",
(!cast<Instruction>(NAME # v2i32rz) V64:$Vd, V64:$Vn), 0>;
def : InstAlias<asm # ".4s\t$Vd, $Vn, #0",
(!cast<Instruction>(NAME # v4i32rz) V128:$Vd, V128:$Vn), 0>;
def : InstAlias<asm # ".2d\t$Vd, $Vn, #0",
(!cast<Instruction>(NAME # v2i64rz) V128:$Vd, V128:$Vn), 0>;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDFPCvtTwoVector<bit Q, bit U, bits<2> size, bits<5> opcode,
RegisterOperand outtype, RegisterOperand intype,
string asm, string VdTy, string VnTy,
list<dag> pattern>
: I<(outs outtype:$Rd), (ins intype:$Rn), asm,
!strconcat("\t$Rd", VdTy, ", $Rn", VnTy), "", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28-24} = 0b01110;
let Inst{23-22} = size;
let Inst{21-17} = 0b10000;
let Inst{16-12} = opcode;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
class BaseSIMDFPCvtTwoVectorTied<bit Q, bit U, bits<2> size, bits<5> opcode,
RegisterOperand outtype, RegisterOperand intype,
string asm, string VdTy, string VnTy,
list<dag> pattern>
: I<(outs outtype:$dst), (ins outtype:$Rd, intype:$Rn), asm,
!strconcat("\t$Rd", VdTy, ", $Rn", VnTy), "$Rd = $dst", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28-24} = 0b01110;
let Inst{23-22} = size;
let Inst{21-17} = 0b10000;
let Inst{16-12} = opcode;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass SIMDFPWidenTwoVector<bit U, bit S, bits<5> opc, string asm> {
def v4i16 : BaseSIMDFPCvtTwoVector<0, U, {S,0}, opc, V128, V64,
asm, ".4s", ".4h", []>;
def v8i16 : BaseSIMDFPCvtTwoVector<1, U, {S,0}, opc, V128, V128,
asm#"2", ".4s", ".8h", []>;
def v2i32 : BaseSIMDFPCvtTwoVector<0, U, {S,1}, opc, V128, V64,
asm, ".2d", ".2s", []>;
def v4i32 : BaseSIMDFPCvtTwoVector<1, U, {S,1}, opc, V128, V128,
asm#"2", ".2d", ".4s", []>;
}
multiclass SIMDFPNarrowTwoVector<bit U, bit S, bits<5> opc, string asm> {
def v4i16 : BaseSIMDFPCvtTwoVector<0, U, {S,0}, opc, V64, V128,
asm, ".4h", ".4s", []>;
def v8i16 : BaseSIMDFPCvtTwoVectorTied<1, U, {S,0}, opc, V128, V128,
asm#"2", ".8h", ".4s", []>;
def v2i32 : BaseSIMDFPCvtTwoVector<0, U, {S,1}, opc, V64, V128,
asm, ".2s", ".2d", []>;
def v4i32 : BaseSIMDFPCvtTwoVectorTied<1, U, {S,1}, opc, V128, V128,
asm#"2", ".4s", ".2d", []>;
}
multiclass SIMDFPInexactCvtTwoVector<bit U, bit S, bits<5> opc, string asm,
Intrinsic OpNode> {
def v2f32 : BaseSIMDFPCvtTwoVector<0, U, {S,1}, opc, V64, V128,
asm, ".2s", ".2d",
[(set (v2f32 V64:$Rd), (OpNode (v2f64 V128:$Rn)))]>;
def v4f32 : BaseSIMDFPCvtTwoVectorTied<1, U, {S,1}, opc, V128, V128,
asm#"2", ".4s", ".2d", []>;
def : Pat<(concat_vectors (v2f32 V64:$Rd), (OpNode (v2f64 V128:$Rn))),
(!cast<Instruction>(NAME # "v4f32")
(INSERT_SUBREG (IMPLICIT_DEF), V64:$Rd, dsub), V128:$Rn)>;
}
//----------------------------------------------------------------------------
// AdvSIMD three register different-size vector instructions.
//----------------------------------------------------------------------------
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDDifferentThreeVector<bit U, bits<3> size, bits<4> opcode,
RegisterOperand outtype, RegisterOperand intype1,
RegisterOperand intype2, string asm,
string outkind, string inkind1, string inkind2,
list<dag> pattern>
: I<(outs outtype:$Rd), (ins intype1:$Rn, intype2:$Rm), asm,
"{\t$Rd" # outkind # ", $Rn" # inkind1 # ", $Rm" # inkind2 #
"|" # outkind # "\t$Rd, $Rn, $Rm}", "", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
let Inst{31} = 0;
let Inst{30} = size{0};
let Inst{29} = U;
let Inst{28-24} = 0b01110;
let Inst{23-22} = size{2-1};
let Inst{21} = 1;
let Inst{20-16} = Rm;
let Inst{15-12} = opcode;
let Inst{11-10} = 0b00;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDDifferentThreeVectorTied<bit U, bits<3> size, bits<4> opcode,
RegisterOperand outtype, RegisterOperand intype1,
RegisterOperand intype2, string asm,
string outkind, string inkind1, string inkind2,
list<dag> pattern>
: I<(outs outtype:$dst), (ins outtype:$Rd, intype1:$Rn, intype2:$Rm), asm,
"{\t$Rd" # outkind # ", $Rn" # inkind1 # ", $Rm" # inkind2 #
"|" # outkind # "\t$Rd, $Rn, $Rm}", "$Rd = $dst", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
let Inst{31} = 0;
let Inst{30} = size{0};
let Inst{29} = U;
let Inst{28-24} = 0b01110;
let Inst{23-22} = size{2-1};
let Inst{21} = 1;
let Inst{20-16} = Rm;
let Inst{15-12} = opcode;
let Inst{11-10} = 0b00;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
// FIXME: TableGen doesn't know how to deal with expanded types that also
// change the element count (in this case, placing the results in
// the high elements of the result register rather than the low
// elements). Until that's fixed, we can't code-gen those.
multiclass SIMDNarrowThreeVectorBHS<bit U, bits<4> opc, string asm,
Intrinsic IntOp> {
def v8i16_v8i8 : BaseSIMDDifferentThreeVector<U, 0b000, opc,
V64, V128, V128,
asm, ".8b", ".8h", ".8h",
[(set (v8i8 V64:$Rd), (IntOp (v8i16 V128:$Rn), (v8i16 V128:$Rm)))]>;
def v8i16_v16i8 : BaseSIMDDifferentThreeVectorTied<U, 0b001, opc,
V128, V128, V128,
asm#"2", ".16b", ".8h", ".8h",
[]>;
def v4i32_v4i16 : BaseSIMDDifferentThreeVector<U, 0b010, opc,
V64, V128, V128,
asm, ".4h", ".4s", ".4s",
[(set (v4i16 V64:$Rd), (IntOp (v4i32 V128:$Rn), (v4i32 V128:$Rm)))]>;
def v4i32_v8i16 : BaseSIMDDifferentThreeVectorTied<U, 0b011, opc,
V128, V128, V128,
asm#"2", ".8h", ".4s", ".4s",
[]>;
def v2i64_v2i32 : BaseSIMDDifferentThreeVector<U, 0b100, opc,
V64, V128, V128,
asm, ".2s", ".2d", ".2d",
[(set (v2i32 V64:$Rd), (IntOp (v2i64 V128:$Rn), (v2i64 V128:$Rm)))]>;
def v2i64_v4i32 : BaseSIMDDifferentThreeVectorTied<U, 0b101, opc,
V128, V128, V128,
asm#"2", ".4s", ".2d", ".2d",
[]>;
// Patterns for the '2' variants involve INSERT_SUBREG, which you can't put in
// a version attached to an instruction.
def : Pat<(concat_vectors (v8i8 V64:$Rd), (IntOp (v8i16 V128:$Rn),
(v8i16 V128:$Rm))),
(!cast<Instruction>(NAME # "v8i16_v16i8")
(INSERT_SUBREG (IMPLICIT_DEF), V64:$Rd, dsub),
V128:$Rn, V128:$Rm)>;
def : Pat<(concat_vectors (v4i16 V64:$Rd), (IntOp (v4i32 V128:$Rn),
(v4i32 V128:$Rm))),
(!cast<Instruction>(NAME # "v4i32_v8i16")
(INSERT_SUBREG (IMPLICIT_DEF), V64:$Rd, dsub),
V128:$Rn, V128:$Rm)>;
def : Pat<(concat_vectors (v2i32 V64:$Rd), (IntOp (v2i64 V128:$Rn),
(v2i64 V128:$Rm))),
(!cast<Instruction>(NAME # "v2i64_v4i32")
(INSERT_SUBREG (IMPLICIT_DEF), V64:$Rd, dsub),
V128:$Rn, V128:$Rm)>;
}
multiclass SIMDDifferentThreeVectorBD<bit U, bits<4> opc, string asm,
Intrinsic IntOp> {
def v8i8 : BaseSIMDDifferentThreeVector<U, 0b000, opc,
V128, V64, V64,
asm, ".8h", ".8b", ".8b",
[(set (v8i16 V128:$Rd), (IntOp (v8i8 V64:$Rn), (v8i8 V64:$Rm)))]>;
def v16i8 : BaseSIMDDifferentThreeVector<U, 0b001, opc,
V128, V128, V128,
asm#"2", ".8h", ".16b", ".16b", []>;
let Predicates = [HasCrypto] in {
def v1i64 : BaseSIMDDifferentThreeVector<U, 0b110, opc,
V128, V64, V64,
asm, ".1q", ".1d", ".1d", []>;
def v2i64 : BaseSIMDDifferentThreeVector<U, 0b111, opc,
V128, V128, V128,
asm#"2", ".1q", ".2d", ".2d", []>;
}
def : Pat<(v8i16 (IntOp (v8i8 (extract_high_v16i8 V128:$Rn)),
(v8i8 (extract_high_v16i8 V128:$Rm)))),
(!cast<Instruction>(NAME#"v16i8") V128:$Rn, V128:$Rm)>;
}
multiclass SIMDLongThreeVectorHS<bit U, bits<4> opc, string asm,
SDPatternOperator OpNode> {
def v4i16_v4i32 : BaseSIMDDifferentThreeVector<U, 0b010, opc,
V128, V64, V64,
asm, ".4s", ".4h", ".4h",
[(set (v4i32 V128:$Rd), (OpNode (v4i16 V64:$Rn), (v4i16 V64:$Rm)))]>;
def v8i16_v4i32 : BaseSIMDDifferentThreeVector<U, 0b011, opc,
V128, V128, V128,
asm#"2", ".4s", ".8h", ".8h",
[(set (v4i32 V128:$Rd), (OpNode (extract_high_v8i16 V128:$Rn),
(extract_high_v8i16 V128:$Rm)))]>;
def v2i32_v2i64 : BaseSIMDDifferentThreeVector<U, 0b100, opc,
V128, V64, V64,
asm, ".2d", ".2s", ".2s",
[(set (v2i64 V128:$Rd), (OpNode (v2i32 V64:$Rn), (v2i32 V64:$Rm)))]>;
def v4i32_v2i64 : BaseSIMDDifferentThreeVector<U, 0b101, opc,
V128, V128, V128,
asm#"2", ".2d", ".4s", ".4s",
[(set (v2i64 V128:$Rd), (OpNode (extract_high_v4i32 V128:$Rn),
(extract_high_v4i32 V128:$Rm)))]>;
}
multiclass SIMDLongThreeVectorBHSabdl<bit U, bits<4> opc, string asm,
SDPatternOperator OpNode = null_frag> {
def v8i8_v8i16 : BaseSIMDDifferentThreeVector<U, 0b000, opc,
V128, V64, V64,
asm, ".8h", ".8b", ".8b",
[(set (v8i16 V128:$Rd),
(zext (v8i8 (OpNode (v8i8 V64:$Rn), (v8i8 V64:$Rm)))))]>;
def v16i8_v8i16 : BaseSIMDDifferentThreeVector<U, 0b001, opc,
V128, V128, V128,
asm#"2", ".8h", ".16b", ".16b",
[(set (v8i16 V128:$Rd),
(zext (v8i8 (OpNode (extract_high_v16i8 V128:$Rn),
(extract_high_v16i8 V128:$Rm)))))]>;
def v4i16_v4i32 : BaseSIMDDifferentThreeVector<U, 0b010, opc,
V128, V64, V64,
asm, ".4s", ".4h", ".4h",
[(set (v4i32 V128:$Rd),
(zext (v4i16 (OpNode (v4i16 V64:$Rn), (v4i16 V64:$Rm)))))]>;
def v8i16_v4i32 : BaseSIMDDifferentThreeVector<U, 0b011, opc,
V128, V128, V128,
asm#"2", ".4s", ".8h", ".8h",
[(set (v4i32 V128:$Rd),
(zext (v4i16 (OpNode (extract_high_v8i16 V128:$Rn),
(extract_high_v8i16 V128:$Rm)))))]>;
def v2i32_v2i64 : BaseSIMDDifferentThreeVector<U, 0b100, opc,
V128, V64, V64,
asm, ".2d", ".2s", ".2s",
[(set (v2i64 V128:$Rd),
(zext (v2i32 (OpNode (v2i32 V64:$Rn), (v2i32 V64:$Rm)))))]>;
def v4i32_v2i64 : BaseSIMDDifferentThreeVector<U, 0b101, opc,
V128, V128, V128,
asm#"2", ".2d", ".4s", ".4s",
[(set (v2i64 V128:$Rd),
(zext (v2i32 (OpNode (extract_high_v4i32 V128:$Rn),
(extract_high_v4i32 V128:$Rm)))))]>;
}
multiclass SIMDLongThreeVectorTiedBHSabal<bit U, bits<4> opc,
string asm,
SDPatternOperator OpNode> {
def v8i8_v8i16 : BaseSIMDDifferentThreeVectorTied<U, 0b000, opc,
V128, V64, V64,
asm, ".8h", ".8b", ".8b",
[(set (v8i16 V128:$dst),
(add (v8i16 V128:$Rd),
(zext (v8i8 (OpNode (v8i8 V64:$Rn), (v8i8 V64:$Rm))))))]>;
def v16i8_v8i16 : BaseSIMDDifferentThreeVectorTied<U, 0b001, opc,
V128, V128, V128,
asm#"2", ".8h", ".16b", ".16b",
[(set (v8i16 V128:$dst),
(add (v8i16 V128:$Rd),
(zext (v8i8 (OpNode (extract_high_v16i8 V128:$Rn),
(extract_high_v16i8 V128:$Rm))))))]>;
def v4i16_v4i32 : BaseSIMDDifferentThreeVectorTied<U, 0b010, opc,
V128, V64, V64,
asm, ".4s", ".4h", ".4h",
[(set (v4i32 V128:$dst),
(add (v4i32 V128:$Rd),
(zext (v4i16 (OpNode (v4i16 V64:$Rn), (v4i16 V64:$Rm))))))]>;
def v8i16_v4i32 : BaseSIMDDifferentThreeVectorTied<U, 0b011, opc,
V128, V128, V128,
asm#"2", ".4s", ".8h", ".8h",
[(set (v4i32 V128:$dst),
(add (v4i32 V128:$Rd),
(zext (v4i16 (OpNode (extract_high_v8i16 V128:$Rn),
(extract_high_v8i16 V128:$Rm))))))]>;
def v2i32_v2i64 : BaseSIMDDifferentThreeVectorTied<U, 0b100, opc,
V128, V64, V64,
asm, ".2d", ".2s", ".2s",
[(set (v2i64 V128:$dst),
(add (v2i64 V128:$Rd),
(zext (v2i32 (OpNode (v2i32 V64:$Rn), (v2i32 V64:$Rm))))))]>;
def v4i32_v2i64 : BaseSIMDDifferentThreeVectorTied<U, 0b101, opc,
V128, V128, V128,
asm#"2", ".2d", ".4s", ".4s",
[(set (v2i64 V128:$dst),
(add (v2i64 V128:$Rd),
(zext (v2i32 (OpNode (extract_high_v4i32 V128:$Rn),
(extract_high_v4i32 V128:$Rm))))))]>;
}
multiclass SIMDLongThreeVectorBHS<bit U, bits<4> opc, string asm,
SDPatternOperator OpNode = null_frag> {
def v8i8_v8i16 : BaseSIMDDifferentThreeVector<U, 0b000, opc,
V128, V64, V64,
asm, ".8h", ".8b", ".8b",
[(set (v8i16 V128:$Rd), (OpNode (v8i8 V64:$Rn), (v8i8 V64:$Rm)))]>;
def v16i8_v8i16 : BaseSIMDDifferentThreeVector<U, 0b001, opc,
V128, V128, V128,
asm#"2", ".8h", ".16b", ".16b",
[(set (v8i16 V128:$Rd), (OpNode (extract_high_v16i8 V128:$Rn),
(extract_high_v16i8 V128:$Rm)))]>;
def v4i16_v4i32 : BaseSIMDDifferentThreeVector<U, 0b010, opc,
V128, V64, V64,
asm, ".4s", ".4h", ".4h",
[(set (v4i32 V128:$Rd), (OpNode (v4i16 V64:$Rn), (v4i16 V64:$Rm)))]>;
def v8i16_v4i32 : BaseSIMDDifferentThreeVector<U, 0b011, opc,
V128, V128, V128,
asm#"2", ".4s", ".8h", ".8h",
[(set (v4i32 V128:$Rd), (OpNode (extract_high_v8i16 V128:$Rn),
(extract_high_v8i16 V128:$Rm)))]>;
def v2i32_v2i64 : BaseSIMDDifferentThreeVector<U, 0b100, opc,
V128, V64, V64,
asm, ".2d", ".2s", ".2s",
[(set (v2i64 V128:$Rd), (OpNode (v2i32 V64:$Rn), (v2i32 V64:$Rm)))]>;
def v4i32_v2i64 : BaseSIMDDifferentThreeVector<U, 0b101, opc,
V128, V128, V128,
asm#"2", ".2d", ".4s", ".4s",
[(set (v2i64 V128:$Rd), (OpNode (extract_high_v4i32 V128:$Rn),
(extract_high_v4i32 V128:$Rm)))]>;
}
multiclass SIMDLongThreeVectorTiedBHS<bit U, bits<4> opc,
string asm,
SDPatternOperator OpNode> {
def v8i8_v8i16 : BaseSIMDDifferentThreeVectorTied<U, 0b000, opc,
V128, V64, V64,
asm, ".8h", ".8b", ".8b",
[(set (v8i16 V128:$dst),
(OpNode (v8i16 V128:$Rd), (v8i8 V64:$Rn), (v8i8 V64:$Rm)))]>;
def v16i8_v8i16 : BaseSIMDDifferentThreeVectorTied<U, 0b001, opc,
V128, V128, V128,
asm#"2", ".8h", ".16b", ".16b",
[(set (v8i16 V128:$dst),
(OpNode (v8i16 V128:$Rd),
(extract_high_v16i8 V128:$Rn),
(extract_high_v16i8 V128:$Rm)))]>;
def v4i16_v4i32 : BaseSIMDDifferentThreeVectorTied<U, 0b010, opc,
V128, V64, V64,
asm, ".4s", ".4h", ".4h",
[(set (v4i32 V128:$dst),
(OpNode (v4i32 V128:$Rd), (v4i16 V64:$Rn), (v4i16 V64:$Rm)))]>;
def v8i16_v4i32 : BaseSIMDDifferentThreeVectorTied<U, 0b011, opc,
V128, V128, V128,
asm#"2", ".4s", ".8h", ".8h",
[(set (v4i32 V128:$dst),
(OpNode (v4i32 V128:$Rd),
(extract_high_v8i16 V128:$Rn),
(extract_high_v8i16 V128:$Rm)))]>;
def v2i32_v2i64 : BaseSIMDDifferentThreeVectorTied<U, 0b100, opc,
V128, V64, V64,
asm, ".2d", ".2s", ".2s",
[(set (v2i64 V128:$dst),
(OpNode (v2i64 V128:$Rd), (v2i32 V64:$Rn), (v2i32 V64:$Rm)))]>;
def v4i32_v2i64 : BaseSIMDDifferentThreeVectorTied<U, 0b101, opc,
V128, V128, V128,
asm#"2", ".2d", ".4s", ".4s",
[(set (v2i64 V128:$dst),
(OpNode (v2i64 V128:$Rd),
(extract_high_v4i32 V128:$Rn),
(extract_high_v4i32 V128:$Rm)))]>;
}
multiclass SIMDLongThreeVectorSQDMLXTiedHS<bit U, bits<4> opc, string asm,
SDPatternOperator Accum> {
def v4i16_v4i32 : BaseSIMDDifferentThreeVectorTied<U, 0b010, opc,
V128, V64, V64,
asm, ".4s", ".4h", ".4h",
[(set (v4i32 V128:$dst),
(Accum (v4i32 V128:$Rd),
(v4i32 (int_aarch64_neon_sqdmull (v4i16 V64:$Rn),
(v4i16 V64:$Rm)))))]>;
def v8i16_v4i32 : BaseSIMDDifferentThreeVectorTied<U, 0b011, opc,
V128, V128, V128,
asm#"2", ".4s", ".8h", ".8h",
[(set (v4i32 V128:$dst),
(Accum (v4i32 V128:$Rd),
(v4i32 (int_aarch64_neon_sqdmull (extract_high_v8i16 V128:$Rn),
(extract_high_v8i16 V128:$Rm)))))]>;
def v2i32_v2i64 : BaseSIMDDifferentThreeVectorTied<U, 0b100, opc,
V128, V64, V64,
asm, ".2d", ".2s", ".2s",
[(set (v2i64 V128:$dst),
(Accum (v2i64 V128:$Rd),
(v2i64 (int_aarch64_neon_sqdmull (v2i32 V64:$Rn),
(v2i32 V64:$Rm)))))]>;
def v4i32_v2i64 : BaseSIMDDifferentThreeVectorTied<U, 0b101, opc,
V128, V128, V128,
asm#"2", ".2d", ".4s", ".4s",
[(set (v2i64 V128:$dst),
(Accum (v2i64 V128:$Rd),
(v2i64 (int_aarch64_neon_sqdmull (extract_high_v4i32 V128:$Rn),
(extract_high_v4i32 V128:$Rm)))))]>;
}
multiclass SIMDWideThreeVectorBHS<bit U, bits<4> opc, string asm,
SDPatternOperator OpNode> {
def v8i8_v8i16 : BaseSIMDDifferentThreeVector<U, 0b000, opc,
V128, V128, V64,
asm, ".8h", ".8h", ".8b",
[(set (v8i16 V128:$Rd), (OpNode (v8i16 V128:$Rn), (v8i8 V64:$Rm)))]>;
def v16i8_v8i16 : BaseSIMDDifferentThreeVector<U, 0b001, opc,
V128, V128, V128,
asm#"2", ".8h", ".8h", ".16b",
[(set (v8i16 V128:$Rd), (OpNode (v8i16 V128:$Rn),
(extract_high_v16i8 V128:$Rm)))]>;
def v4i16_v4i32 : BaseSIMDDifferentThreeVector<U, 0b010, opc,
V128, V128, V64,
asm, ".4s", ".4s", ".4h",
[(set (v4i32 V128:$Rd), (OpNode (v4i32 V128:$Rn), (v4i16 V64:$Rm)))]>;
def v8i16_v4i32 : BaseSIMDDifferentThreeVector<U, 0b011, opc,
V128, V128, V128,
asm#"2", ".4s", ".4s", ".8h",
[(set (v4i32 V128:$Rd), (OpNode (v4i32 V128:$Rn),
(extract_high_v8i16 V128:$Rm)))]>;
def v2i32_v2i64 : BaseSIMDDifferentThreeVector<U, 0b100, opc,
V128, V128, V64,
asm, ".2d", ".2d", ".2s",
[(set (v2i64 V128:$Rd), (OpNode (v2i64 V128:$Rn), (v2i32 V64:$Rm)))]>;
def v4i32_v2i64 : BaseSIMDDifferentThreeVector<U, 0b101, opc,
V128, V128, V128,
asm#"2", ".2d", ".2d", ".4s",
[(set (v2i64 V128:$Rd), (OpNode (v2i64 V128:$Rn),
(extract_high_v4i32 V128:$Rm)))]>;
}
//----------------------------------------------------------------------------
// AdvSIMD bitwise extract from vector
//----------------------------------------------------------------------------
class BaseSIMDBitwiseExtract<bit size, RegisterOperand regtype, ValueType vty,
string asm, string kind>
: I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm, i32imm:$imm), asm,
"{\t$Rd" # kind # ", $Rn" # kind # ", $Rm" # kind # ", $imm" #
"|" # kind # "\t$Rd, $Rn, $Rm, $imm}", "",
[(set (vty regtype:$Rd),
(AArch64ext regtype:$Rn, regtype:$Rm, (i32 imm:$imm)))]>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
bits<4> imm;
let Inst{31} = 0;
let Inst{30} = size;
let Inst{29-21} = 0b101110000;
let Inst{20-16} = Rm;
let Inst{15} = 0;
let Inst{14-11} = imm;
let Inst{10} = 0;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass SIMDBitwiseExtract<string asm> {
def v8i8 : BaseSIMDBitwiseExtract<0, V64, v8i8, asm, ".8b"> {
let imm{3} = 0;
}
def v16i8 : BaseSIMDBitwiseExtract<1, V128, v16i8, asm, ".16b">;
}
//----------------------------------------------------------------------------
// AdvSIMD zip vector
//----------------------------------------------------------------------------
class BaseSIMDZipVector<bits<3> size, bits<3> opc, RegisterOperand regtype,
string asm, string kind, SDNode OpNode, ValueType valty>
: I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm), asm,
"{\t$Rd" # kind # ", $Rn" # kind # ", $Rm" # kind #
"|" # kind # "\t$Rd, $Rn, $Rm}", "",
[(set (valty regtype:$Rd), (OpNode regtype:$Rn, regtype:$Rm))]>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
let Inst{31} = 0;
let Inst{30} = size{0};
let Inst{29-24} = 0b001110;
let Inst{23-22} = size{2-1};
let Inst{21} = 0;
let Inst{20-16} = Rm;
let Inst{15} = 0;
let Inst{14-12} = opc;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass SIMDZipVector<bits<3>opc, string asm,
SDNode OpNode> {
def v8i8 : BaseSIMDZipVector<0b000, opc, V64,
asm, ".8b", OpNode, v8i8>;
def v16i8 : BaseSIMDZipVector<0b001, opc, V128,
asm, ".16b", OpNode, v16i8>;
def v4i16 : BaseSIMDZipVector<0b010, opc, V64,
asm, ".4h", OpNode, v4i16>;
def v8i16 : BaseSIMDZipVector<0b011, opc, V128,
asm, ".8h", OpNode, v8i16>;
def v2i32 : BaseSIMDZipVector<0b100, opc, V64,
asm, ".2s", OpNode, v2i32>;
def v4i32 : BaseSIMDZipVector<0b101, opc, V128,
asm, ".4s", OpNode, v4i32>;
def v2i64 : BaseSIMDZipVector<0b111, opc, V128,
asm, ".2d", OpNode, v2i64>;
def : Pat<(v4f16 (OpNode V64:$Rn, V64:$Rm)),
(!cast<Instruction>(NAME#"v4i16") V64:$Rn, V64:$Rm)>;
def : Pat<(v8f16 (OpNode V128:$Rn, V128:$Rm)),
(!cast<Instruction>(NAME#"v8i16") V128:$Rn, V128:$Rm)>;
def : Pat<(v2f32 (OpNode V64:$Rn, V64:$Rm)),
(!cast<Instruction>(NAME#"v2i32") V64:$Rn, V64:$Rm)>;
def : Pat<(v4f32 (OpNode V128:$Rn, V128:$Rm)),
(!cast<Instruction>(NAME#"v4i32") V128:$Rn, V128:$Rm)>;
def : Pat<(v2f64 (OpNode V128:$Rn, V128:$Rm)),
(!cast<Instruction>(NAME#"v2i64") V128:$Rn, V128:$Rm)>;
}
//----------------------------------------------------------------------------
// AdvSIMD three register scalar instructions
//----------------------------------------------------------------------------
let mayStore = 0, mayLoad = 0, hasSideEffects = 0 in
class BaseSIMDThreeScalar<bit U, bits<3> size, bits<5> opcode,
RegisterClass regtype, string asm,
list<dag> pattern>
: I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm), asm,
"\t$Rd, $Rn, $Rm", "", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
let Inst{31-30} = 0b01;
let Inst{29} = U;
let Inst{28-24} = 0b11110;
let Inst{23-21} = size;
let Inst{20-16} = Rm;
let Inst{15-11} = opcode;
let Inst{10} = 1;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
let mayStore = 0, mayLoad = 0, hasSideEffects = 0 in
class BaseSIMDThreeScalarTied<bit U, bits<2> size, bit R, bits<5> opcode,
dag oops, dag iops, string asm,
list<dag> pattern>
: I<oops, iops, asm, "\t$Rd, $Rn, $Rm", "$Rd = $dst", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
let Inst{31-30} = 0b01;
let Inst{29} = U;
let Inst{28-24} = 0b11110;
let Inst{23-22} = size;
let Inst{21} = R;
let Inst{20-16} = Rm;
let Inst{15-11} = opcode;
let Inst{10} = 1;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass SIMDThreeScalarD<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v1i64 : BaseSIMDThreeScalar<U, 0b111, opc, FPR64, asm,
[(set (v1i64 FPR64:$Rd), (OpNode (v1i64 FPR64:$Rn), (v1i64 FPR64:$Rm)))]>;
}
multiclass SIMDThreeScalarBHSD<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v1i64 : BaseSIMDThreeScalar<U, 0b111, opc, FPR64, asm,
[(set (v1i64 FPR64:$Rd), (OpNode (v1i64 FPR64:$Rn), (v1i64 FPR64:$Rm)))]>;
def v1i32 : BaseSIMDThreeScalar<U, 0b101, opc, FPR32, asm, []>;
def v1i16 : BaseSIMDThreeScalar<U, 0b011, opc, FPR16, asm, []>;
def v1i8 : BaseSIMDThreeScalar<U, 0b001, opc, FPR8 , asm, []>;
def : Pat<(i64 (OpNode (i64 FPR64:$Rn), (i64 FPR64:$Rm))),
(!cast<Instruction>(NAME#"v1i64") FPR64:$Rn, FPR64:$Rm)>;
def : Pat<(i32 (OpNode (i32 FPR32:$Rn), (i32 FPR32:$Rm))),
(!cast<Instruction>(NAME#"v1i32") FPR32:$Rn, FPR32:$Rm)>;
}
multiclass SIMDThreeScalarHS<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v1i32 : BaseSIMDThreeScalar<U, 0b101, opc, FPR32, asm,
[(set FPR32:$Rd, (OpNode FPR32:$Rn, FPR32:$Rm))]>;
def v1i16 : BaseSIMDThreeScalar<U, 0b011, opc, FPR16, asm, []>;
}
multiclass SIMDThreeScalarHSTied<bit U, bit R, bits<5> opc, string asm,
SDPatternOperator OpNode = null_frag> {
def v1i32: BaseSIMDThreeScalarTied<U, 0b10, R, opc, (outs FPR32:$dst),
(ins FPR32:$Rd, FPR32:$Rn, FPR32:$Rm),
asm, []>;
def v1i16: BaseSIMDThreeScalarTied<U, 0b01, R, opc, (outs FPR16:$dst),
(ins FPR16:$Rd, FPR16:$Rn, FPR16:$Rm),
asm, []>;
}
multiclass SIMDFPThreeScalar<bit U, bit S, bits<3> opc, string asm,
SDPatternOperator OpNode = null_frag> {
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in {
def #NAME#64 : BaseSIMDThreeScalar<U, {S,0b11}, {0b11,opc}, FPR64, asm,
[(set (f64 FPR64:$Rd), (OpNode (f64 FPR64:$Rn), (f64 FPR64:$Rm)))]>;
def #NAME#32 : BaseSIMDThreeScalar<U, {S,0b01}, {0b11,opc}, FPR32, asm,
[(set FPR32:$Rd, (OpNode FPR32:$Rn, FPR32:$Rm))]>;
let Predicates = [HasNEON, HasFullFP16] in {
def #NAME#16 : BaseSIMDThreeScalar<U, {S,0b10}, {0b00,opc}, FPR16, asm,
[(set FPR16:$Rd, (OpNode FPR16:$Rn, FPR16:$Rm))]>;
} // Predicates = [HasNEON, HasFullFP16]
}
def : Pat<(v1f64 (OpNode (v1f64 FPR64:$Rn), (v1f64 FPR64:$Rm))),
(!cast<Instruction>(NAME # "64") FPR64:$Rn, FPR64:$Rm)>;
}
multiclass SIMDThreeScalarFPCmp<bit U, bit S, bits<3> opc, string asm,
SDPatternOperator OpNode = null_frag> {
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in {
def #NAME#64 : BaseSIMDThreeScalar<U, {S,0b11}, {0b11,opc}, FPR64, asm,
[(set (i64 FPR64:$Rd), (OpNode (f64 FPR64:$Rn), (f64 FPR64:$Rm)))]>;
def #NAME#32 : BaseSIMDThreeScalar<U, {S,0b01}, {0b11,opc}, FPR32, asm,
[(set (i32 FPR32:$Rd), (OpNode (f32 FPR32:$Rn), (f32 FPR32:$Rm)))]>;
let Predicates = [HasNEON, HasFullFP16] in {
def #NAME#16 : BaseSIMDThreeScalar<U, {S,0b10}, {0b00,opc}, FPR16, asm,
[]>;
} // Predicates = [HasNEON, HasFullFP16]
}
def : Pat<(v1i64 (OpNode (v1f64 FPR64:$Rn), (v1f64 FPR64:$Rm))),
(!cast<Instruction>(NAME # "64") FPR64:$Rn, FPR64:$Rm)>;
}
class BaseSIMDThreeScalarMixed<bit U, bits<2> size, bits<5> opcode,
dag oops, dag iops, string asm, string cstr, list<dag> pat>
: I<oops, iops, asm,
"\t$Rd, $Rn, $Rm", cstr, pat>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
let Inst{31-30} = 0b01;
let Inst{29} = U;
let Inst{28-24} = 0b11110;
let Inst{23-22} = size;
let Inst{21} = 1;
let Inst{20-16} = Rm;
let Inst{15-11} = opcode;
let Inst{10} = 0;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
multiclass SIMDThreeScalarMixedHS<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode = null_frag> {
def i16 : BaseSIMDThreeScalarMixed<U, 0b01, opc,
(outs FPR32:$Rd),
(ins FPR16:$Rn, FPR16:$Rm), asm, "", []>;
def i32 : BaseSIMDThreeScalarMixed<U, 0b10, opc,
(outs FPR64:$Rd),
(ins FPR32:$Rn, FPR32:$Rm), asm, "",
[(set (i64 FPR64:$Rd), (OpNode (i32 FPR32:$Rn), (i32 FPR32:$Rm)))]>;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
multiclass SIMDThreeScalarMixedTiedHS<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode = null_frag> {
def i16 : BaseSIMDThreeScalarMixed<U, 0b01, opc,
(outs FPR32:$dst),
(ins FPR32:$Rd, FPR16:$Rn, FPR16:$Rm),
asm, "$Rd = $dst", []>;
def i32 : BaseSIMDThreeScalarMixed<U, 0b10, opc,
(outs FPR64:$dst),
(ins FPR64:$Rd, FPR32:$Rn, FPR32:$Rm),
asm, "$Rd = $dst",
[(set (i64 FPR64:$dst),
(OpNode (i64 FPR64:$Rd), (i32 FPR32:$Rn), (i32 FPR32:$Rm)))]>;
}
//----------------------------------------------------------------------------
// AdvSIMD two register scalar instructions
//----------------------------------------------------------------------------
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDTwoScalar<bit U, bits<2> size, bits<2> size2, bits<5> opcode,
RegisterClass regtype, RegisterClass regtype2,
string asm, list<dag> pat>
: I<(outs regtype:$Rd), (ins regtype2:$Rn), asm,
"\t$Rd, $Rn", "", pat>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31-30} = 0b01;
let Inst{29} = U;
let Inst{28-24} = 0b11110;
let Inst{23-22} = size;
let Inst{21} = 0b1;
let Inst{20-19} = size2;
let Inst{18-17} = 0b00;
let Inst{16-12} = opcode;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDTwoScalarTied<bit U, bits<2> size, bits<5> opcode,
RegisterClass regtype, RegisterClass regtype2,
string asm, list<dag> pat>
: I<(outs regtype:$dst), (ins regtype:$Rd, regtype2:$Rn), asm,
"\t$Rd, $Rn", "$Rd = $dst", pat>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31-30} = 0b01;
let Inst{29} = U;
let Inst{28-24} = 0b11110;
let Inst{23-22} = size;
let Inst{21-17} = 0b10000;
let Inst{16-12} = opcode;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDCmpTwoScalar<bit U, bits<2> size, bits<2> size2, bits<5> opcode,
RegisterClass regtype, string asm, string zero>
: I<(outs regtype:$Rd), (ins regtype:$Rn), asm,
"\t$Rd, $Rn, #" # zero, "", []>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31-30} = 0b01;
let Inst{29} = U;
let Inst{28-24} = 0b11110;
let Inst{23-22} = size;
let Inst{21} = 0b1;
let Inst{20-19} = size2;
let Inst{18-17} = 0b00;
let Inst{16-12} = opcode;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
class SIMDInexactCvtTwoScalar<bits<5> opcode, string asm>
: I<(outs FPR32:$Rd), (ins FPR64:$Rn), asm, "\t$Rd, $Rn", "",
[(set (f32 FPR32:$Rd), (int_aarch64_sisd_fcvtxn (f64 FPR64:$Rn)))]>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31-17} = 0b011111100110000;
let Inst{16-12} = opcode;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass SIMDCmpTwoScalarD<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v1i64rz : BaseSIMDCmpTwoScalar<U, 0b11, 0b00, opc, FPR64, asm, "0">;
def : Pat<(v1i64 (OpNode FPR64:$Rn)),
(!cast<Instruction>(NAME # v1i64rz) FPR64:$Rn)>;
}
multiclass SIMDFPCmpTwoScalar<bit U, bit S, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v1i64rz : BaseSIMDCmpTwoScalar<U, {S,1}, 0b00, opc, FPR64, asm, "0.0">;
def v1i32rz : BaseSIMDCmpTwoScalar<U, {S,0}, 0b00, opc, FPR32, asm, "0.0">;
let Predicates = [HasNEON, HasFullFP16] in {
def v1i16rz : BaseSIMDCmpTwoScalar<U, {S,1}, 0b11, opc, FPR16, asm, "0.0">;
}
def : InstAlias<asm # "\t$Rd, $Rn, #0",
(!cast<Instruction>(NAME # v1i64rz) FPR64:$Rd, FPR64:$Rn), 0>;
def : InstAlias<asm # "\t$Rd, $Rn, #0",
(!cast<Instruction>(NAME # v1i32rz) FPR32:$Rd, FPR32:$Rn), 0>;
let Predicates = [HasNEON, HasFullFP16] in {
def : InstAlias<asm # "\t$Rd, $Rn, #0",
(!cast<Instruction>(NAME # v1i16rz) FPR16:$Rd, FPR16:$Rn), 0>;
}
def : Pat<(v1i64 (OpNode (v1f64 FPR64:$Rn))),
(!cast<Instruction>(NAME # v1i64rz) FPR64:$Rn)>;
}
multiclass SIMDTwoScalarD<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode = null_frag> {
def v1i64 : BaseSIMDTwoScalar<U, 0b11, 0b00, opc, FPR64, FPR64, asm,
[(set (v1i64 FPR64:$Rd), (OpNode (v1i64 FPR64:$Rn)))]>;
def : Pat<(i64 (OpNode (i64 FPR64:$Rn))),
(!cast<Instruction>(NAME # "v1i64") FPR64:$Rn)>;
}
multiclass SIMDFPTwoScalar<bit U, bit S, bits<5> opc, string asm> {
def v1i64 : BaseSIMDTwoScalar<U, {S,1}, 0b00, opc, FPR64, FPR64, asm,[]>;
def v1i32 : BaseSIMDTwoScalar<U, {S,0}, 0b00, opc, FPR32, FPR32, asm,[]>;
let Predicates = [HasNEON, HasFullFP16] in {
def v1f16 : BaseSIMDTwoScalar<U, {S,1}, 0b11, opc, FPR16, FPR16, asm,[]>;
}
}
multiclass SIMDFPTwoScalarCVT<bit U, bit S, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v1i64 : BaseSIMDTwoScalar<U, {S,1}, 0b00, opc, FPR64, FPR64, asm,
[(set FPR64:$Rd, (OpNode (f64 FPR64:$Rn)))]>;
def v1i32 : BaseSIMDTwoScalar<U, {S,0}, 0b00, opc, FPR32, FPR32, asm,
[(set FPR32:$Rd, (OpNode (f32 FPR32:$Rn)))]>;
let Predicates = [HasNEON, HasFullFP16] in {
def v1i16 : BaseSIMDTwoScalar<U, {S,1}, 0b11, opc, FPR16, FPR16, asm,
[(set FPR16:$Rd, (OpNode (f16 FPR16:$Rn)))]>;
}
}
multiclass SIMDTwoScalarBHSD<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode = null_frag> {
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in {
def v1i64 : BaseSIMDTwoScalar<U, 0b11, 0b00, opc, FPR64, FPR64, asm,
[(set (i64 FPR64:$Rd), (OpNode (i64 FPR64:$Rn)))]>;
def v1i32 : BaseSIMDTwoScalar<U, 0b10, 0b00, opc, FPR32, FPR32, asm,
[(set (i32 FPR32:$Rd), (OpNode (i32 FPR32:$Rn)))]>;
def v1i16 : BaseSIMDTwoScalar<U, 0b01, 0b00, opc, FPR16, FPR16, asm, []>;
def v1i8 : BaseSIMDTwoScalar<U, 0b00, 0b00, opc, FPR8 , FPR8 , asm, []>;
}
def : Pat<(v1i64 (OpNode (v1i64 FPR64:$Rn))),
(!cast<Instruction>(NAME # v1i64) FPR64:$Rn)>;
}
multiclass SIMDTwoScalarBHSDTied<bit U, bits<5> opc, string asm,
Intrinsic OpNode> {
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in {
def v1i64 : BaseSIMDTwoScalarTied<U, 0b11, opc, FPR64, FPR64, asm,
[(set (i64 FPR64:$dst), (OpNode (i64 FPR64:$Rd), (i64 FPR64:$Rn)))]>;
def v1i32 : BaseSIMDTwoScalarTied<U, 0b10, opc, FPR32, FPR32, asm,
[(set (i32 FPR32:$dst), (OpNode (i32 FPR32:$Rd), (i32 FPR32:$Rn)))]>;
def v1i16 : BaseSIMDTwoScalarTied<U, 0b01, opc, FPR16, FPR16, asm, []>;
def v1i8 : BaseSIMDTwoScalarTied<U, 0b00, opc, FPR8 , FPR8 , asm, []>;
}
def : Pat<(v1i64 (OpNode (v1i64 FPR64:$Rd), (v1i64 FPR64:$Rn))),
(!cast<Instruction>(NAME # v1i64) FPR64:$Rd, FPR64:$Rn)>;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
multiclass SIMDTwoScalarMixedBHS<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode = null_frag> {
def v1i32 : BaseSIMDTwoScalar<U, 0b10, 0b00, opc, FPR32, FPR64, asm,
[(set (i32 FPR32:$Rd), (OpNode (i64 FPR64:$Rn)))]>;
def v1i16 : BaseSIMDTwoScalar<U, 0b01, 0b00, opc, FPR16, FPR32, asm, []>;
def v1i8 : BaseSIMDTwoScalar<U, 0b00, 0b00, opc, FPR8 , FPR16, asm, []>;
}
//----------------------------------------------------------------------------
// AdvSIMD scalar pairwise instructions
//----------------------------------------------------------------------------
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDPairwiseScalar<bit U, bits<2> size, bits<5> opcode,
RegisterOperand regtype, RegisterOperand vectype,
string asm, string kind>
: I<(outs regtype:$Rd), (ins vectype:$Rn), asm,
"{\t$Rd, $Rn" # kind # "|" # kind # "\t$Rd, $Rn}", "", []>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31-30} = 0b01;
let Inst{29} = U;
let Inst{28-24} = 0b11110;
let Inst{23-22} = size;
let Inst{21-17} = 0b11000;
let Inst{16-12} = opcode;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass SIMDPairwiseScalarD<bit U, bits<5> opc, string asm> {
def v2i64p : BaseSIMDPairwiseScalar<U, 0b11, opc, FPR64Op, V128,
asm, ".2d">;
}
multiclass SIMDFPPairwiseScalar<bit S, bits<5> opc, string asm> {
let Predicates = [HasNEON, HasFullFP16] in {
def v2i16p : BaseSIMDPairwiseScalar<0, {S,0}, opc, FPR16Op, V64,
asm, ".2h">;
}
def v2i32p : BaseSIMDPairwiseScalar<1, {S,0}, opc, FPR32Op, V64,
asm, ".2s">;
def v2i64p : BaseSIMDPairwiseScalar<1, {S,1}, opc, FPR64Op, V128,
asm, ".2d">;
}
//----------------------------------------------------------------------------
// AdvSIMD across lanes instructions
//----------------------------------------------------------------------------
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDAcrossLanes<bit Q, bit U, bits<2> size, bits<5> opcode,
RegisterClass regtype, RegisterOperand vectype,
string asm, string kind, list<dag> pattern>
: I<(outs regtype:$Rd), (ins vectype:$Rn), asm,
"{\t$Rd, $Rn" # kind # "|" # kind # "\t$Rd, $Rn}", "", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28-24} = 0b01110;
let Inst{23-22} = size;
let Inst{21-17} = 0b11000;
let Inst{16-12} = opcode;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass SIMDAcrossLanesBHS<bit U, bits<5> opcode,
string asm> {
def v8i8v : BaseSIMDAcrossLanes<0, U, 0b00, opcode, FPR8, V64,
asm, ".8b", []>;
def v16i8v : BaseSIMDAcrossLanes<1, U, 0b00, opcode, FPR8, V128,
asm, ".16b", []>;
def v4i16v : BaseSIMDAcrossLanes<0, U, 0b01, opcode, FPR16, V64,
asm, ".4h", []>;
def v8i16v : BaseSIMDAcrossLanes<1, U, 0b01, opcode, FPR16, V128,
asm, ".8h", []>;
def v4i32v : BaseSIMDAcrossLanes<1, U, 0b10, opcode, FPR32, V128,
asm, ".4s", []>;
}
multiclass SIMDAcrossLanesHSD<bit U, bits<5> opcode, string asm> {
def v8i8v : BaseSIMDAcrossLanes<0, U, 0b00, opcode, FPR16, V64,
asm, ".8b", []>;
def v16i8v : BaseSIMDAcrossLanes<1, U, 0b00, opcode, FPR16, V128,
asm, ".16b", []>;
def v4i16v : BaseSIMDAcrossLanes<0, U, 0b01, opcode, FPR32, V64,
asm, ".4h", []>;
def v8i16v : BaseSIMDAcrossLanes<1, U, 0b01, opcode, FPR32, V128,
asm, ".8h", []>;
def v4i32v : BaseSIMDAcrossLanes<1, U, 0b10, opcode, FPR64, V128,
asm, ".4s", []>;
}
multiclass SIMDFPAcrossLanes<bits<5> opcode, bit sz1, string asm,
Intrinsic intOp> {
let Predicates = [HasNEON, HasFullFP16] in {
def v4i16v : BaseSIMDAcrossLanes<0, 0, {sz1, 0}, opcode, FPR16, V64,
asm, ".4h",
[(set FPR16:$Rd, (intOp (v4f16 V64:$Rn)))]>;
def v8i16v : BaseSIMDAcrossLanes<1, 0, {sz1, 0}, opcode, FPR16, V128,
asm, ".8h",
[(set FPR16:$Rd, (intOp (v8f16 V128:$Rn)))]>;
} // Predicates = [HasNEON, HasFullFP16]
def v4i32v : BaseSIMDAcrossLanes<1, 1, {sz1, 0}, opcode, FPR32, V128,
asm, ".4s",
[(set FPR32:$Rd, (intOp (v4f32 V128:$Rn)))]>;
}
//----------------------------------------------------------------------------
// AdvSIMD INS/DUP instructions
//----------------------------------------------------------------------------
// FIXME: There has got to be a better way to factor these. ugh.
class BaseSIMDInsDup<bit Q, bit op, dag outs, dag ins, string asm,
string operands, string constraints, list<dag> pattern>
: I<outs, ins, asm, operands, constraints, pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = op;
let Inst{28-21} = 0b01110000;
let Inst{15} = 0;
let Inst{10} = 1;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
class SIMDDupFromMain<bit Q, bits<5> imm5, string size, ValueType vectype,
RegisterOperand vecreg, RegisterClass regtype>
: BaseSIMDInsDup<Q, 0, (outs vecreg:$Rd), (ins regtype:$Rn), "dup",
"{\t$Rd" # size # ", $Rn" #
"|" # size # "\t$Rd, $Rn}", "",
[(set (vectype vecreg:$Rd), (AArch64dup regtype:$Rn))]> {
let Inst{20-16} = imm5;
let Inst{14-11} = 0b0001;
}
class SIMDDupFromElement<bit Q, string dstkind, string srckind,
ValueType vectype, ValueType insreg,
RegisterOperand vecreg, Operand idxtype,
ValueType elttype, SDNode OpNode>
: BaseSIMDInsDup<Q, 0, (outs vecreg:$Rd), (ins V128:$Rn, idxtype:$idx), "dup",
"{\t$Rd" # dstkind # ", $Rn" # srckind # "$idx" #
"|" # dstkind # "\t$Rd, $Rn$idx}", "",
[(set (vectype vecreg:$Rd),
(OpNode (insreg V128:$Rn), idxtype:$idx))]> {
let Inst{14-11} = 0b0000;
}
class SIMDDup64FromElement
: SIMDDupFromElement<1, ".2d", ".d", v2i64, v2i64, V128,
VectorIndexD, i64, AArch64duplane64> {
bits<1> idx;
let Inst{20} = idx;
let Inst{19-16} = 0b1000;
}
class SIMDDup32FromElement<bit Q, string size, ValueType vectype,
RegisterOperand vecreg>
: SIMDDupFromElement<Q, size, ".s", vectype, v4i32, vecreg,
VectorIndexS, i64, AArch64duplane32> {
bits<2> idx;
let Inst{20-19} = idx;
let Inst{18-16} = 0b100;
}
class SIMDDup16FromElement<bit Q, string size, ValueType vectype,
RegisterOperand vecreg>
: SIMDDupFromElement<Q, size, ".h", vectype, v8i16, vecreg,
VectorIndexH, i64, AArch64duplane16> {
bits<3> idx;
let Inst{20-18} = idx;
let Inst{17-16} = 0b10;
}
class SIMDDup8FromElement<bit Q, string size, ValueType vectype,
RegisterOperand vecreg>
: SIMDDupFromElement<Q, size, ".b", vectype, v16i8, vecreg,
VectorIndexB, i64, AArch64duplane8> {
bits<4> idx;
let Inst{20-17} = idx;
let Inst{16} = 1;
}
class BaseSIMDMov<bit Q, string size, bits<4> imm4, RegisterClass regtype,
Operand idxtype, string asm, list<dag> pattern>
: BaseSIMDInsDup<Q, 0, (outs regtype:$Rd), (ins V128:$Rn, idxtype:$idx), asm,
"{\t$Rd, $Rn" # size # "$idx" #
"|" # size # "\t$Rd, $Rn$idx}", "", pattern> {
let Inst{14-11} = imm4;
}
class SIMDSMov<bit Q, string size, RegisterClass regtype,
Operand idxtype>
: BaseSIMDMov<Q, size, 0b0101, regtype, idxtype, "smov", []>;
class SIMDUMov<bit Q, string size, ValueType vectype, RegisterClass regtype,
Operand idxtype>
: BaseSIMDMov<Q, size, 0b0111, regtype, idxtype, "umov",
[(set regtype:$Rd, (vector_extract (vectype V128:$Rn), idxtype:$idx))]>;
class SIMDMovAlias<string asm, string size, Instruction inst,
RegisterClass regtype, Operand idxtype>
: InstAlias<asm#"{\t$dst, $src"#size#"$idx" #
"|" # size # "\t$dst, $src$idx}",
(inst regtype:$dst, V128:$src, idxtype:$idx)>;
multiclass SMov {
def vi8to32 : SIMDSMov<0, ".b", GPR32, VectorIndexB> {
bits<4> idx;
let Inst{20-17} = idx;
let Inst{16} = 1;
}
def vi8to64 : SIMDSMov<1, ".b", GPR64, VectorIndexB> {
bits<4> idx;
let Inst{20-17} = idx;
let Inst{16} = 1;
}
def vi16to32 : SIMDSMov<0, ".h", GPR32, VectorIndexH> {
bits<3> idx;
let Inst{20-18} = idx;
let Inst{17-16} = 0b10;
}
def vi16to64 : SIMDSMov<1, ".h", GPR64, VectorIndexH> {
bits<3> idx;
let Inst{20-18} = idx;
let Inst{17-16} = 0b10;
}
def vi32to64 : SIMDSMov<1, ".s", GPR64, VectorIndexS> {
bits<2> idx;
let Inst{20-19} = idx;
let Inst{18-16} = 0b100;
}
}
multiclass UMov {
def vi8 : SIMDUMov<0, ".b", v16i8, GPR32, VectorIndexB> {
bits<4> idx;
let Inst{20-17} = idx;
let Inst{16} = 1;
}
def vi16 : SIMDUMov<0, ".h", v8i16, GPR32, VectorIndexH> {
bits<3> idx;
let Inst{20-18} = idx;
let Inst{17-16} = 0b10;
}
def vi32 : SIMDUMov<0, ".s", v4i32, GPR32, VectorIndexS> {
bits<2> idx;
let Inst{20-19} = idx;
let Inst{18-16} = 0b100;
}
def vi64 : SIMDUMov<1, ".d", v2i64, GPR64, VectorIndexD> {
bits<1> idx;
let Inst{20} = idx;
let Inst{19-16} = 0b1000;
}
def : SIMDMovAlias<"mov", ".s",
!cast<Instruction>(NAME#"vi32"),
GPR32, VectorIndexS>;
def : SIMDMovAlias<"mov", ".d",
!cast<Instruction>(NAME#"vi64"),
GPR64, VectorIndexD>;
}
class SIMDInsFromMain<string size, ValueType vectype,
RegisterClass regtype, Operand idxtype>
: BaseSIMDInsDup<1, 0, (outs V128:$dst),
(ins V128:$Rd, idxtype:$idx, regtype:$Rn), "ins",
"{\t$Rd" # size # "$idx, $Rn" #
"|" # size # "\t$Rd$idx, $Rn}",
"$Rd = $dst",
[(set V128:$dst,
(vector_insert (vectype V128:$Rd), regtype:$Rn, idxtype:$idx))]> {
let Inst{14-11} = 0b0011;
}
class SIMDInsFromElement<string size, ValueType vectype,
ValueType elttype, Operand idxtype>
: BaseSIMDInsDup<1, 1, (outs V128:$dst),
(ins V128:$Rd, idxtype:$idx, V128:$Rn, idxtype:$idx2), "ins",
"{\t$Rd" # size # "$idx, $Rn" # size # "$idx2" #
"|" # size # "\t$Rd$idx, $Rn$idx2}",
"$Rd = $dst",
[(set V128:$dst,
(vector_insert
(vectype V128:$Rd),
(elttype (vector_extract (vectype V128:$Rn), idxtype:$idx2)),
idxtype:$idx))]>;
class SIMDInsMainMovAlias<string size, Instruction inst,
RegisterClass regtype, Operand idxtype>
: InstAlias<"mov" # "{\t$dst" # size # "$idx, $src" #
"|" # size #"\t$dst$idx, $src}",
(inst V128:$dst, idxtype:$idx, regtype:$src)>;
class SIMDInsElementMovAlias<string size, Instruction inst,
Operand idxtype>
: InstAlias<"mov" # "{\t$dst" # size # "$idx, $src" # size # "$idx2" #
# "|" # size #"\t$dst$idx, $src$idx2}",
(inst V128:$dst, idxtype:$idx, V128:$src, idxtype:$idx2)>;
multiclass SIMDIns {
def vi8gpr : SIMDInsFromMain<".b", v16i8, GPR32, VectorIndexB> {
bits<4> idx;
let Inst{20-17} = idx;
let Inst{16} = 1;
}
def vi16gpr : SIMDInsFromMain<".h", v8i16, GPR32, VectorIndexH> {
bits<3> idx;
let Inst{20-18} = idx;
let Inst{17-16} = 0b10;
}
def vi32gpr : SIMDInsFromMain<".s", v4i32, GPR32, VectorIndexS> {
bits<2> idx;
let Inst{20-19} = idx;
let Inst{18-16} = 0b100;
}
def vi64gpr : SIMDInsFromMain<".d", v2i64, GPR64, VectorIndexD> {
bits<1> idx;
let Inst{20} = idx;
let Inst{19-16} = 0b1000;
}
def vi8lane : SIMDInsFromElement<".b", v16i8, i32, VectorIndexB> {
bits<4> idx;
bits<4> idx2;
let Inst{20-17} = idx;
let Inst{16} = 1;
let Inst{14-11} = idx2;
}
def vi16lane : SIMDInsFromElement<".h", v8i16, i32, VectorIndexH> {
bits<3> idx;
bits<3> idx2;
let Inst{20-18} = idx;
let Inst{17-16} = 0b10;
let Inst{14-12} = idx2;
let Inst{11} = {?};
}
def vi32lane : SIMDInsFromElement<".s", v4i32, i32, VectorIndexS> {
bits<2> idx;
bits<2> idx2;
let Inst{20-19} = idx;
let Inst{18-16} = 0b100;
let Inst{14-13} = idx2;
let Inst{12-11} = {?,?};
}
def vi64lane : SIMDInsFromElement<".d", v2i64, i64, VectorIndexD> {
bits<1> idx;
bits<1> idx2;
let Inst{20} = idx;
let Inst{19-16} = 0b1000;
let Inst{14} = idx2;
let Inst{13-11} = {?,?,?};
}
// For all forms of the INS instruction, the "mov" mnemonic is the
// preferred alias. Why they didn't just call the instruction "mov" in
// the first place is a very good question indeed...
def : SIMDInsMainMovAlias<".b", !cast<Instruction>(NAME#"vi8gpr"),
GPR32, VectorIndexB>;
def : SIMDInsMainMovAlias<".h", !cast<Instruction>(NAME#"vi16gpr"),
GPR32, VectorIndexH>;
def : SIMDInsMainMovAlias<".s", !cast<Instruction>(NAME#"vi32gpr"),
GPR32, VectorIndexS>;
def : SIMDInsMainMovAlias<".d", !cast<Instruction>(NAME#"vi64gpr"),
GPR64, VectorIndexD>;
def : SIMDInsElementMovAlias<".b", !cast<Instruction>(NAME#"vi8lane"),
VectorIndexB>;
def : SIMDInsElementMovAlias<".h", !cast<Instruction>(NAME#"vi16lane"),
VectorIndexH>;
def : SIMDInsElementMovAlias<".s", !cast<Instruction>(NAME#"vi32lane"),
VectorIndexS>;
def : SIMDInsElementMovAlias<".d", !cast<Instruction>(NAME#"vi64lane"),
VectorIndexD>;
}
//----------------------------------------------------------------------------
// AdvSIMD TBL/TBX
//----------------------------------------------------------------------------
let mayStore = 0, mayLoad = 0, hasSideEffects = 0 in
class BaseSIMDTableLookup<bit Q, bits<2> len, bit op, RegisterOperand vectype,
RegisterOperand listtype, string asm, string kind>
: I<(outs vectype:$Vd), (ins listtype:$Vn, vectype:$Vm), asm,
"\t$Vd" # kind # ", $Vn, $Vm" # kind, "", []>,
Sched<[WriteV]> {
bits<5> Vd;
bits<5> Vn;
bits<5> Vm;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29-21} = 0b001110000;
let Inst{20-16} = Vm;
let Inst{15} = 0;
let Inst{14-13} = len;
let Inst{12} = op;
let Inst{11-10} = 0b00;
let Inst{9-5} = Vn;
let Inst{4-0} = Vd;
}
let mayStore = 0, mayLoad = 0, hasSideEffects = 0 in
class BaseSIMDTableLookupTied<bit Q, bits<2> len, bit op, RegisterOperand vectype,
RegisterOperand listtype, string asm, string kind>
: I<(outs vectype:$dst), (ins vectype:$Vd, listtype:$Vn, vectype:$Vm), asm,
"\t$Vd" # kind # ", $Vn, $Vm" # kind, "$Vd = $dst", []>,
Sched<[WriteV]> {
bits<5> Vd;
bits<5> Vn;
bits<5> Vm;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29-21} = 0b001110000;
let Inst{20-16} = Vm;
let Inst{15} = 0;
let Inst{14-13} = len;
let Inst{12} = op;
let Inst{11-10} = 0b00;
let Inst{9-5} = Vn;
let Inst{4-0} = Vd;
}
class SIMDTableLookupAlias<string asm, Instruction inst,
RegisterOperand vectype, RegisterOperand listtype>
: InstAlias<!strconcat(asm, "\t$dst, $lst, $index"),
(inst vectype:$dst, listtype:$lst, vectype:$index), 0>;
multiclass SIMDTableLookup<bit op, string asm> {
def v8i8One : BaseSIMDTableLookup<0, 0b00, op, V64, VecListOne16b,
asm, ".8b">;
def v8i8Two : BaseSIMDTableLookup<0, 0b01, op, V64, VecListTwo16b,
asm, ".8b">;
def v8i8Three : BaseSIMDTableLookup<0, 0b10, op, V64, VecListThree16b,
asm, ".8b">;
def v8i8Four : BaseSIMDTableLookup<0, 0b11, op, V64, VecListFour16b,
asm, ".8b">;
def v16i8One : BaseSIMDTableLookup<1, 0b00, op, V128, VecListOne16b,
asm, ".16b">;
def v16i8Two : BaseSIMDTableLookup<1, 0b01, op, V128, VecListTwo16b,
asm, ".16b">;
def v16i8Three: BaseSIMDTableLookup<1, 0b10, op, V128, VecListThree16b,
asm, ".16b">;
def v16i8Four : BaseSIMDTableLookup<1, 0b11, op, V128, VecListFour16b,
asm, ".16b">;
def : SIMDTableLookupAlias<asm # ".8b",
!cast<Instruction>(NAME#"v8i8One"),
V64, VecListOne128>;
def : SIMDTableLookupAlias<asm # ".8b",
!cast<Instruction>(NAME#"v8i8Two"),
V64, VecListTwo128>;
def : SIMDTableLookupAlias<asm # ".8b",
!cast<Instruction>(NAME#"v8i8Three"),
V64, VecListThree128>;
def : SIMDTableLookupAlias<asm # ".8b",
!cast<Instruction>(NAME#"v8i8Four"),
V64, VecListFour128>;
def : SIMDTableLookupAlias<asm # ".16b",
!cast<Instruction>(NAME#"v16i8One"),
V128, VecListOne128>;
def : SIMDTableLookupAlias<asm # ".16b",
!cast<Instruction>(NAME#"v16i8Two"),
V128, VecListTwo128>;
def : SIMDTableLookupAlias<asm # ".16b",
!cast<Instruction>(NAME#"v16i8Three"),
V128, VecListThree128>;
def : SIMDTableLookupAlias<asm # ".16b",
!cast<Instruction>(NAME#"v16i8Four"),
V128, VecListFour128>;
}
multiclass SIMDTableLookupTied<bit op, string asm> {
def v8i8One : BaseSIMDTableLookupTied<0, 0b00, op, V64, VecListOne16b,
asm, ".8b">;
def v8i8Two : BaseSIMDTableLookupTied<0, 0b01, op, V64, VecListTwo16b,
asm, ".8b">;
def v8i8Three : BaseSIMDTableLookupTied<0, 0b10, op, V64, VecListThree16b,
asm, ".8b">;
def v8i8Four : BaseSIMDTableLookupTied<0, 0b11, op, V64, VecListFour16b,
asm, ".8b">;
def v16i8One : BaseSIMDTableLookupTied<1, 0b00, op, V128, VecListOne16b,
asm, ".16b">;
def v16i8Two : BaseSIMDTableLookupTied<1, 0b01, op, V128, VecListTwo16b,
asm, ".16b">;
def v16i8Three: BaseSIMDTableLookupTied<1, 0b10, op, V128, VecListThree16b,
asm, ".16b">;
def v16i8Four : BaseSIMDTableLookupTied<1, 0b11, op, V128, VecListFour16b,
asm, ".16b">;
def : SIMDTableLookupAlias<asm # ".8b",
!cast<Instruction>(NAME#"v8i8One"),
V64, VecListOne128>;
def : SIMDTableLookupAlias<asm # ".8b",
!cast<Instruction>(NAME#"v8i8Two"),
V64, VecListTwo128>;
def : SIMDTableLookupAlias<asm # ".8b",
!cast<Instruction>(NAME#"v8i8Three"),
V64, VecListThree128>;
def : SIMDTableLookupAlias<asm # ".8b",
!cast<Instruction>(NAME#"v8i8Four"),
V64, VecListFour128>;
def : SIMDTableLookupAlias<asm # ".16b",
!cast<Instruction>(NAME#"v16i8One"),
V128, VecListOne128>;
def : SIMDTableLookupAlias<asm # ".16b",
!cast<Instruction>(NAME#"v16i8Two"),
V128, VecListTwo128>;
def : SIMDTableLookupAlias<asm # ".16b",
!cast<Instruction>(NAME#"v16i8Three"),
V128, VecListThree128>;
def : SIMDTableLookupAlias<asm # ".16b",
!cast<Instruction>(NAME#"v16i8Four"),
V128, VecListFour128>;
}
//----------------------------------------------------------------------------
// AdvSIMD scalar CPY
//----------------------------------------------------------------------------
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDScalarCPY<RegisterClass regtype, RegisterOperand vectype,
string kind, Operand idxtype>
: I<(outs regtype:$dst), (ins vectype:$src, idxtype:$idx), "mov",
"{\t$dst, $src" # kind # "$idx" #
"|\t$dst, $src$idx}", "", []>,
Sched<[WriteV]> {
bits<5> dst;
bits<5> src;
let Inst{31-21} = 0b01011110000;
let Inst{15-10} = 0b000001;
let Inst{9-5} = src;
let Inst{4-0} = dst;
}
class SIMDScalarCPYAlias<string asm, string size, Instruction inst,
RegisterClass regtype, RegisterOperand vectype, Operand idxtype>
: InstAlias<asm # "{\t$dst, $src" # size # "$index" #
# "|\t$dst, $src$index}",
(inst regtype:$dst, vectype:$src, idxtype:$index), 0>;
multiclass SIMDScalarCPY<string asm> {
def i8 : BaseSIMDScalarCPY<FPR8, V128, ".b", VectorIndexB> {
bits<4> idx;
let Inst{20-17} = idx;
let Inst{16} = 1;
}
def i16 : BaseSIMDScalarCPY<FPR16, V128, ".h", VectorIndexH> {
bits<3> idx;
let Inst{20-18} = idx;
let Inst{17-16} = 0b10;
}
def i32 : BaseSIMDScalarCPY<FPR32, V128, ".s", VectorIndexS> {
bits<2> idx;
let Inst{20-19} = idx;
let Inst{18-16} = 0b100;
}
def i64 : BaseSIMDScalarCPY<FPR64, V128, ".d", VectorIndexD> {
bits<1> idx;
let Inst{20} = idx;
let Inst{19-16} = 0b1000;
}
def : Pat<(v1i64 (scalar_to_vector (i64 (vector_extract (v2i64 V128:$src),
VectorIndexD:$idx)))),
(!cast<Instruction>(NAME # i64) V128:$src, VectorIndexD:$idx)>;
// 'DUP' mnemonic aliases.
def : SIMDScalarCPYAlias<"dup", ".b",
!cast<Instruction>(NAME#"i8"),
FPR8, V128, VectorIndexB>;
def : SIMDScalarCPYAlias<"dup", ".h",
!cast<Instruction>(NAME#"i16"),
FPR16, V128, VectorIndexH>;
def : SIMDScalarCPYAlias<"dup", ".s",
!cast<Instruction>(NAME#"i32"),
FPR32, V128, VectorIndexS>;
def : SIMDScalarCPYAlias<"dup", ".d",
!cast<Instruction>(NAME#"i64"),
FPR64, V128, VectorIndexD>;
}
//----------------------------------------------------------------------------
// AdvSIMD modified immediate instructions
//----------------------------------------------------------------------------
class BaseSIMDModifiedImm<bit Q, bit op, bit op2, dag oops, dag iops,
string asm, string op_string,
string cstr, list<dag> pattern>
: I<oops, iops, asm, op_string, cstr, pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<8> imm8;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = op;
let Inst{28-19} = 0b0111100000;
let Inst{18-16} = imm8{7-5};
let Inst{11} = op2;
let Inst{10} = 1;
let Inst{9-5} = imm8{4-0};
let Inst{4-0} = Rd;
}
class BaseSIMDModifiedImmVector<bit Q, bit op, bit op2, RegisterOperand vectype,
Operand immtype, dag opt_shift_iop,
string opt_shift, string asm, string kind,
list<dag> pattern>
: BaseSIMDModifiedImm<Q, op, op2, (outs vectype:$Rd),
!con((ins immtype:$imm8), opt_shift_iop), asm,
"{\t$Rd" # kind # ", $imm8" # opt_shift #
"|" # kind # "\t$Rd, $imm8" # opt_shift # "}",
"", pattern> {
let DecoderMethod = "DecodeModImmInstruction";
}
class BaseSIMDModifiedImmVectorTied<bit Q, bit op, RegisterOperand vectype,
Operand immtype, dag opt_shift_iop,
string opt_shift, string asm, string kind,
list<dag> pattern>
: BaseSIMDModifiedImm<Q, op, 0, (outs vectype:$dst),
!con((ins vectype:$Rd, immtype:$imm8), opt_shift_iop),
asm, "{\t$Rd" # kind # ", $imm8" # opt_shift #
"|" # kind # "\t$Rd, $imm8" # opt_shift # "}",
"$Rd = $dst", pattern> {
let DecoderMethod = "DecodeModImmTiedInstruction";
}
class BaseSIMDModifiedImmVectorShift<bit Q, bit op, bits<2> b15_b12,
RegisterOperand vectype, string asm,
string kind, list<dag> pattern>
: BaseSIMDModifiedImmVector<Q, op, 0, vectype, imm0_255,
(ins logical_vec_shift:$shift),
"$shift", asm, kind, pattern> {
bits<2> shift;
let Inst{15} = b15_b12{1};
let Inst{14-13} = shift;
let Inst{12} = b15_b12{0};
}
class BaseSIMDModifiedImmVectorShiftTied<bit Q, bit op, bits<2> b15_b12,
RegisterOperand vectype, string asm,
string kind, list<dag> pattern>
: BaseSIMDModifiedImmVectorTied<Q, op, vectype, imm0_255,
(ins logical_vec_shift:$shift),
"$shift", asm, kind, pattern> {
bits<2> shift;
let Inst{15} = b15_b12{1};
let Inst{14-13} = shift;
let Inst{12} = b15_b12{0};
}
class BaseSIMDModifiedImmVectorShiftHalf<bit Q, bit op, bits<2> b15_b12,
RegisterOperand vectype, string asm,
string kind, list<dag> pattern>
: BaseSIMDModifiedImmVector<Q, op, 0, vectype, imm0_255,
(ins logical_vec_hw_shift:$shift),
"$shift", asm, kind, pattern> {
bits<2> shift;
let Inst{15} = b15_b12{1};
let Inst{14} = 0;
let Inst{13} = shift{0};
let Inst{12} = b15_b12{0};
}
class BaseSIMDModifiedImmVectorShiftHalfTied<bit Q, bit op, bits<2> b15_b12,
RegisterOperand vectype, string asm,
string kind, list<dag> pattern>
: BaseSIMDModifiedImmVectorTied<Q, op, vectype, imm0_255,
(ins logical_vec_hw_shift:$shift),
"$shift", asm, kind, pattern> {
bits<2> shift;
let Inst{15} = b15_b12{1};
let Inst{14} = 0;
let Inst{13} = shift{0};
let Inst{12} = b15_b12{0};
}
multiclass SIMDModifiedImmVectorShift<bit op, bits<2> hw_cmode, bits<2> w_cmode,
string asm> {
def v4i16 : BaseSIMDModifiedImmVectorShiftHalf<0, op, hw_cmode, V64,
asm, ".4h", []>;
def v8i16 : BaseSIMDModifiedImmVectorShiftHalf<1, op, hw_cmode, V128,
asm, ".8h", []>;
def v2i32 : BaseSIMDModifiedImmVectorShift<0, op, w_cmode, V64,
asm, ".2s", []>;
def v4i32 : BaseSIMDModifiedImmVectorShift<1, op, w_cmode, V128,
asm, ".4s", []>;
}
multiclass SIMDModifiedImmVectorShiftTied<bit op, bits<2> hw_cmode,
bits<2> w_cmode, string asm,
SDNode OpNode> {
def v4i16 : BaseSIMDModifiedImmVectorShiftHalfTied<0, op, hw_cmode, V64,
asm, ".4h",
[(set (v4i16 V64:$dst), (OpNode V64:$Rd,
imm0_255:$imm8,
(i32 imm:$shift)))]>;
def v8i16 : BaseSIMDModifiedImmVectorShiftHalfTied<1, op, hw_cmode, V128,
asm, ".8h",
[(set (v8i16 V128:$dst), (OpNode V128:$Rd,
imm0_255:$imm8,
(i32 imm:$shift)))]>;
def v2i32 : BaseSIMDModifiedImmVectorShiftTied<0, op, w_cmode, V64,
asm, ".2s",
[(set (v2i32 V64:$dst), (OpNode V64:$Rd,
imm0_255:$imm8,
(i32 imm:$shift)))]>;
def v4i32 : BaseSIMDModifiedImmVectorShiftTied<1, op, w_cmode, V128,
asm, ".4s",
[(set (v4i32 V128:$dst), (OpNode V128:$Rd,
imm0_255:$imm8,
(i32 imm:$shift)))]>;
}
class SIMDModifiedImmMoveMSL<bit Q, bit op, bits<4> cmode,
RegisterOperand vectype, string asm,
string kind, list<dag> pattern>
: BaseSIMDModifiedImmVector<Q, op, 0, vectype, imm0_255,
(ins move_vec_shift:$shift),
"$shift", asm, kind, pattern> {
bits<1> shift;
let Inst{15-13} = cmode{3-1};
let Inst{12} = shift;
}
class SIMDModifiedImmVectorNoShift<bit Q, bit op, bit op2, bits<4> cmode,
RegisterOperand vectype,
Operand imm_type, string asm,
string kind, list<dag> pattern>
: BaseSIMDModifiedImmVector<Q, op, op2, vectype, imm_type, (ins), "",
asm, kind, pattern> {
let Inst{15-12} = cmode;
}
class SIMDModifiedImmScalarNoShift<bit Q, bit op, bits<4> cmode, string asm,
list<dag> pattern>
: BaseSIMDModifiedImm<Q, op, 0, (outs FPR64:$Rd), (ins simdimmtype10:$imm8), asm,
"\t$Rd, $imm8", "", pattern> {
let Inst{15-12} = cmode;
let DecoderMethod = "DecodeModImmInstruction";
}
//----------------------------------------------------------------------------
// AdvSIMD indexed element
//----------------------------------------------------------------------------
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDIndexed<bit Q, bit U, bit Scalar, bits<2> size, bits<4> opc,
RegisterOperand dst_reg, RegisterOperand lhs_reg,
RegisterOperand rhs_reg, Operand vec_idx, string asm,
string apple_kind, string dst_kind, string lhs_kind,
string rhs_kind, list<dag> pattern>
: I<(outs dst_reg:$Rd), (ins lhs_reg:$Rn, rhs_reg:$Rm, vec_idx:$idx),
asm,
"{\t$Rd" # dst_kind # ", $Rn" # lhs_kind # ", $Rm" # rhs_kind # "$idx" #
"|" # apple_kind # "\t$Rd, $Rn, $Rm$idx}", "", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28} = Scalar;
let Inst{27-24} = 0b1111;
let Inst{23-22} = size;
// Bit 21 must be set by the derived class.
let Inst{20-16} = Rm;
let Inst{15-12} = opc;
// Bit 11 must be set by the derived class.
let Inst{10} = 0;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDIndexedTied<bit Q, bit U, bit Scalar, bits<2> size, bits<4> opc,
RegisterOperand dst_reg, RegisterOperand lhs_reg,
RegisterOperand rhs_reg, Operand vec_idx, string asm,
string apple_kind, string dst_kind, string lhs_kind,
string rhs_kind, list<dag> pattern>
: I<(outs dst_reg:$dst),
(ins dst_reg:$Rd, lhs_reg:$Rn, rhs_reg:$Rm, vec_idx:$idx), asm,
"{\t$Rd" # dst_kind # ", $Rn" # lhs_kind # ", $Rm" # rhs_kind # "$idx" #
"|" # apple_kind # "\t$Rd, $Rn, $Rm$idx}", "$Rd = $dst", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28} = Scalar;
let Inst{27-24} = 0b1111;
let Inst{23-22} = size;
// Bit 21 must be set by the derived class.
let Inst{20-16} = Rm;
let Inst{15-12} = opc;
// Bit 11 must be set by the derived class.
let Inst{10} = 0;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
// ARMv8.2 Index Dot product instructions
class BaseSIMDThreeSameVectorDotIndex<bit Q, bit U, string asm, string dst_kind,
string lhs_kind, string rhs_kind> :
BaseSIMDIndexedTied<Q, U, 0b0, 0b10, 0b1110, V128, V128, V128, VectorIndexS,
asm, "", dst_kind, lhs_kind, rhs_kind, []> {
bits<2> idx;
let Inst{21} = idx{0}; // L
let Inst{11} = idx{1}; // H
}
multiclass SIMDFPIndexed<bit U, bits<4> opc, string asm,
SDPatternOperator OpNode> {
let Predicates = [HasNEON, HasFullFP16] in {
def v4i16_indexed : BaseSIMDIndexed<0, U, 0, 0b00, opc,
V64, V64,
V128_lo, VectorIndexH,
asm, ".4h", ".4h", ".4h", ".h",
[(set (v4f16 V64:$Rd),
(OpNode (v4f16 V64:$Rn),
(v4f16 (AArch64duplane16 (v8f16 V128_lo:$Rm), VectorIndexH:$idx))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v8i16_indexed : BaseSIMDIndexed<1, U, 0, 0b00, opc,
V128, V128,
V128_lo, VectorIndexH,
asm, ".8h", ".8h", ".8h", ".h",
[(set (v8f16 V128:$Rd),
(OpNode (v8f16 V128:$Rn),
(v8f16 (AArch64duplane16 (v8f16 V128_lo:$Rm), VectorIndexH:$idx))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
} // Predicates = [HasNEON, HasFullFP16]
def v2i32_indexed : BaseSIMDIndexed<0, U, 0, 0b10, opc,
V64, V64,
V128, VectorIndexS,
asm, ".2s", ".2s", ".2s", ".s",
[(set (v2f32 V64:$Rd),
(OpNode (v2f32 V64:$Rn),
(v2f32 (AArch64duplane32 (v4f32 V128:$Rm), VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v4i32_indexed : BaseSIMDIndexed<1, U, 0, 0b10, opc,
V128, V128,
V128, VectorIndexS,
asm, ".4s", ".4s", ".4s", ".s",
[(set (v4f32 V128:$Rd),
(OpNode (v4f32 V128:$Rn),
(v4f32 (AArch64duplane32 (v4f32 V128:$Rm), VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v2i64_indexed : BaseSIMDIndexed<1, U, 0, 0b11, opc,
V128, V128,
V128, VectorIndexD,
asm, ".2d", ".2d", ".2d", ".d",
[(set (v2f64 V128:$Rd),
(OpNode (v2f64 V128:$Rn),
(v2f64 (AArch64duplane64 (v2f64 V128:$Rm), VectorIndexD:$idx))))]> {
bits<1> idx;
let Inst{11} = idx{0};
let Inst{21} = 0;
}
let Predicates = [HasNEON, HasFullFP16] in {
def v1i16_indexed : BaseSIMDIndexed<1, U, 1, 0b00, opc,
FPR16Op, FPR16Op, V128_lo, VectorIndexH,
asm, ".h", "", "", ".h",
[(set (f16 FPR16Op:$Rd),
(OpNode (f16 FPR16Op:$Rn),
(f16 (vector_extract (v8f16 V128_lo:$Rm),
VectorIndexH:$idx))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
} // Predicates = [HasNEON, HasFullFP16]
def v1i32_indexed : BaseSIMDIndexed<1, U, 1, 0b10, opc,
FPR32Op, FPR32Op, V128, VectorIndexS,
asm, ".s", "", "", ".s",
[(set (f32 FPR32Op:$Rd),
(OpNode (f32 FPR32Op:$Rn),
(f32 (vector_extract (v4f32 V128:$Rm),
VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v1i64_indexed : BaseSIMDIndexed<1, U, 1, 0b11, opc,
FPR64Op, FPR64Op, V128, VectorIndexD,
asm, ".d", "", "", ".d",
[(set (f64 FPR64Op:$Rd),
(OpNode (f64 FPR64Op:$Rn),
(f64 (vector_extract (v2f64 V128:$Rm),
VectorIndexD:$idx))))]> {
bits<1> idx;
let Inst{11} = idx{0};
let Inst{21} = 0;
}
}
multiclass SIMDFPIndexedTiedPatterns<string INST, SDPatternOperator OpNode> {
// 2 variants for the .2s version: DUPLANE from 128-bit and DUP scalar.
def : Pat<(v2f32 (OpNode (v2f32 V64:$Rd), (v2f32 V64:$Rn),
(AArch64duplane32 (v4f32 V128:$Rm),
VectorIndexS:$idx))),
(!cast<Instruction>(INST # v2i32_indexed)
V64:$Rd, V64:$Rn, V128:$Rm, VectorIndexS:$idx)>;
def : Pat<(v2f32 (OpNode (v2f32 V64:$Rd), (v2f32 V64:$Rn),
(AArch64dup (f32 FPR32Op:$Rm)))),
(!cast<Instruction>(INST # "v2i32_indexed") V64:$Rd, V64:$Rn,
(SUBREG_TO_REG (i32 0), FPR32Op:$Rm, ssub), (i64 0))>;
// 2 variants for the .4s version: DUPLANE from 128-bit and DUP scalar.
def : Pat<(v4f32 (OpNode (v4f32 V128:$Rd), (v4f32 V128:$Rn),
(AArch64duplane32 (v4f32 V128:$Rm),
VectorIndexS:$idx))),
(!cast<Instruction>(INST # "v4i32_indexed")
V128:$Rd, V128:$Rn, V128:$Rm, VectorIndexS:$idx)>;
def : Pat<(v4f32 (OpNode (v4f32 V128:$Rd), (v4f32 V128:$Rn),
(AArch64dup (f32 FPR32Op:$Rm)))),
(!cast<Instruction>(INST # "v4i32_indexed") V128:$Rd, V128:$Rn,
(SUBREG_TO_REG (i32 0), FPR32Op:$Rm, ssub), (i64 0))>;
// 2 variants for the .2d version: DUPLANE from 128-bit and DUP scalar.
def : Pat<(v2f64 (OpNode (v2f64 V128:$Rd), (v2f64 V128:$Rn),
(AArch64duplane64 (v2f64 V128:$Rm),
VectorIndexD:$idx))),
(!cast<Instruction>(INST # "v2i64_indexed")
V128:$Rd, V128:$Rn, V128:$Rm, VectorIndexS:$idx)>;
def : Pat<(v2f64 (OpNode (v2f64 V128:$Rd), (v2f64 V128:$Rn),
(AArch64dup (f64 FPR64Op:$Rm)))),
(!cast<Instruction>(INST # "v2i64_indexed") V128:$Rd, V128:$Rn,
(SUBREG_TO_REG (i32 0), FPR64Op:$Rm, dsub), (i64 0))>;
// 2 variants for 32-bit scalar version: extract from .2s or from .4s
def : Pat<(f32 (OpNode (f32 FPR32:$Rd), (f32 FPR32:$Rn),
(vector_extract (v4f32 V128:$Rm), VectorIndexS:$idx))),
(!cast<Instruction>(INST # "v1i32_indexed") FPR32:$Rd, FPR32:$Rn,
V128:$Rm, VectorIndexS:$idx)>;
def : Pat<(f32 (OpNode (f32 FPR32:$Rd), (f32 FPR32:$Rn),
(vector_extract (v2f32 V64:$Rm), VectorIndexS:$idx))),
(!cast<Instruction>(INST # "v1i32_indexed") FPR32:$Rd, FPR32:$Rn,
(SUBREG_TO_REG (i32 0), V64:$Rm, dsub), VectorIndexS:$idx)>;
// 1 variant for 64-bit scalar version: extract from .1d or from .2d
def : Pat<(f64 (OpNode (f64 FPR64:$Rd), (f64 FPR64:$Rn),
(vector_extract (v2f64 V128:$Rm), VectorIndexD:$idx))),
(!cast<Instruction>(INST # "v1i64_indexed") FPR64:$Rd, FPR64:$Rn,
V128:$Rm, VectorIndexD:$idx)>;
}
multiclass SIMDFPIndexedTied<bit U, bits<4> opc, string asm> {
let Predicates = [HasNEON, HasFullFP16] in {
def v4i16_indexed : BaseSIMDIndexedTied<0, U, 0, 0b00, opc, V64, V64,
V128_lo, VectorIndexH,
asm, ".4h", ".4h", ".4h", ".h", []> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v8i16_indexed : BaseSIMDIndexedTied<1, U, 0, 0b00, opc,
V128, V128,
V128_lo, VectorIndexH,
asm, ".8h", ".8h", ".8h", ".h", []> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
} // Predicates = [HasNEON, HasFullFP16]
def v2i32_indexed : BaseSIMDIndexedTied<0, U, 0, 0b10, opc, V64, V64,
V128, VectorIndexS,
asm, ".2s", ".2s", ".2s", ".s", []> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v4i32_indexed : BaseSIMDIndexedTied<1, U, 0, 0b10, opc,
V128, V128,
V128, VectorIndexS,
asm, ".4s", ".4s", ".4s", ".s", []> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v2i64_indexed : BaseSIMDIndexedTied<1, U, 0, 0b11, opc,
V128, V128,
V128, VectorIndexD,
asm, ".2d", ".2d", ".2d", ".d", []> {
bits<1> idx;
let Inst{11} = idx{0};
let Inst{21} = 0;
}
let Predicates = [HasNEON, HasFullFP16] in {
def v1i16_indexed : BaseSIMDIndexedTied<1, U, 1, 0b00, opc,
FPR16Op, FPR16Op, V128_lo, VectorIndexH,
asm, ".h", "", "", ".h", []> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
} // Predicates = [HasNEON, HasFullFP16]
def v1i32_indexed : BaseSIMDIndexedTied<1, U, 1, 0b10, opc,
FPR32Op, FPR32Op, V128, VectorIndexS,
asm, ".s", "", "", ".s", []> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v1i64_indexed : BaseSIMDIndexedTied<1, U, 1, 0b11, opc,
FPR64Op, FPR64Op, V128, VectorIndexD,
asm, ".d", "", "", ".d", []> {
bits<1> idx;
let Inst{11} = idx{0};
let Inst{21} = 0;
}
}
multiclass SIMDIndexedHS<bit U, bits<4> opc, string asm,
SDPatternOperator OpNode> {
def v4i16_indexed : BaseSIMDIndexed<0, U, 0, 0b01, opc, V64, V64,
V128_lo, VectorIndexH,
asm, ".4h", ".4h", ".4h", ".h",
[(set (v4i16 V64:$Rd),
(OpNode (v4i16 V64:$Rn),
(v4i16 (AArch64duplane16 (v8i16 V128_lo:$Rm), VectorIndexH:$idx))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v8i16_indexed : BaseSIMDIndexed<1, U, 0, 0b01, opc,
V128, V128,
V128_lo, VectorIndexH,
asm, ".8h", ".8h", ".8h", ".h",
[(set (v8i16 V128:$Rd),
(OpNode (v8i16 V128:$Rn),
(v8i16 (AArch64duplane16 (v8i16 V128_lo:$Rm), VectorIndexH:$idx))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v2i32_indexed : BaseSIMDIndexed<0, U, 0, 0b10, opc,
V64, V64,
V128, VectorIndexS,
asm, ".2s", ".2s", ".2s", ".s",
[(set (v2i32 V64:$Rd),
(OpNode (v2i32 V64:$Rn),
(v2i32 (AArch64duplane32 (v4i32 V128:$Rm), VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v4i32_indexed : BaseSIMDIndexed<1, U, 0, 0b10, opc,
V128, V128,
V128, VectorIndexS,
asm, ".4s", ".4s", ".4s", ".s",
[(set (v4i32 V128:$Rd),
(OpNode (v4i32 V128:$Rn),
(v4i32 (AArch64duplane32 (v4i32 V128:$Rm), VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v1i16_indexed : BaseSIMDIndexed<1, U, 1, 0b01, opc,
FPR16Op, FPR16Op, V128_lo, VectorIndexH,
asm, ".h", "", "", ".h", []> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v1i32_indexed : BaseSIMDIndexed<1, U, 1, 0b10, opc,
FPR32Op, FPR32Op, V128, VectorIndexS,
asm, ".s", "", "", ".s",
[(set (i32 FPR32Op:$Rd),
(OpNode FPR32Op:$Rn,
(i32 (vector_extract (v4i32 V128:$Rm),
VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
}
multiclass SIMDVectorIndexedHS<bit U, bits<4> opc, string asm,
SDPatternOperator OpNode> {
def v4i16_indexed : BaseSIMDIndexed<0, U, 0, 0b01, opc,
V64, V64,
V128_lo, VectorIndexH,
asm, ".4h", ".4h", ".4h", ".h",
[(set (v4i16 V64:$Rd),
(OpNode (v4i16 V64:$Rn),
(v4i16 (AArch64duplane16 (v8i16 V128_lo:$Rm), VectorIndexH:$idx))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v8i16_indexed : BaseSIMDIndexed<1, U, 0, 0b01, opc,
V128, V128,
V128_lo, VectorIndexH,
asm, ".8h", ".8h", ".8h", ".h",
[(set (v8i16 V128:$Rd),
(OpNode (v8i16 V128:$Rn),
(v8i16 (AArch64duplane16 (v8i16 V128_lo:$Rm), VectorIndexH:$idx))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v2i32_indexed : BaseSIMDIndexed<0, U, 0, 0b10, opc,
V64, V64,
V128, VectorIndexS,
asm, ".2s", ".2s", ".2s", ".s",
[(set (v2i32 V64:$Rd),
(OpNode (v2i32 V64:$Rn),
(v2i32 (AArch64duplane32 (v4i32 V128:$Rm), VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v4i32_indexed : BaseSIMDIndexed<1, U, 0, 0b10, opc,
V128, V128,
V128, VectorIndexS,
asm, ".4s", ".4s", ".4s", ".s",
[(set (v4i32 V128:$Rd),
(OpNode (v4i32 V128:$Rn),
(v4i32 (AArch64duplane32 (v4i32 V128:$Rm), VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
}
multiclass SIMDVectorIndexedHSTied<bit U, bits<4> opc, string asm,
SDPatternOperator OpNode> {
def v4i16_indexed : BaseSIMDIndexedTied<0, U, 0, 0b01, opc, V64, V64,
V128_lo, VectorIndexH,
asm, ".4h", ".4h", ".4h", ".h",
[(set (v4i16 V64:$dst),
(OpNode (v4i16 V64:$Rd),(v4i16 V64:$Rn),
(v4i16 (AArch64duplane16 (v8i16 V128_lo:$Rm), VectorIndexH:$idx))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v8i16_indexed : BaseSIMDIndexedTied<1, U, 0, 0b01, opc,
V128, V128,
V128_lo, VectorIndexH,
asm, ".8h", ".8h", ".8h", ".h",
[(set (v8i16 V128:$dst),
(OpNode (v8i16 V128:$Rd), (v8i16 V128:$Rn),
(v8i16 (AArch64duplane16 (v8i16 V128_lo:$Rm), VectorIndexH:$idx))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v2i32_indexed : BaseSIMDIndexedTied<0, U, 0, 0b10, opc,
V64, V64,
V128, VectorIndexS,
asm, ".2s", ".2s", ".2s", ".s",
[(set (v2i32 V64:$dst),
(OpNode (v2i32 V64:$Rd), (v2i32 V64:$Rn),
(v2i32 (AArch64duplane32 (v4i32 V128:$Rm), VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v4i32_indexed : BaseSIMDIndexedTied<1, U, 0, 0b10, opc,
V128, V128,
V128, VectorIndexS,
asm, ".4s", ".4s", ".4s", ".s",
[(set (v4i32 V128:$dst),
(OpNode (v4i32 V128:$Rd), (v4i32 V128:$Rn),
(v4i32 (AArch64duplane32 (v4i32 V128:$Rm), VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
}
multiclass SIMDIndexedLongSD<bit U, bits<4> opc, string asm,
SDPatternOperator OpNode> {
def v4i16_indexed : BaseSIMDIndexed<0, U, 0, 0b01, opc,
V128, V64,
V128_lo, VectorIndexH,
asm, ".4s", ".4s", ".4h", ".h",
[(set (v4i32 V128:$Rd),
(OpNode (v4i16 V64:$Rn),
(v4i16 (AArch64duplane16 (v8i16 V128_lo:$Rm), VectorIndexH:$idx))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v8i16_indexed : BaseSIMDIndexed<1, U, 0, 0b01, opc,
V128, V128,
V128_lo, VectorIndexH,
asm#"2", ".4s", ".4s", ".8h", ".h",
[(set (v4i32 V128:$Rd),
(OpNode (extract_high_v8i16 V128:$Rn),
(extract_high_v8i16 (AArch64duplane16 (v8i16 V128_lo:$Rm),
VectorIndexH:$idx))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v2i32_indexed : BaseSIMDIndexed<0, U, 0, 0b10, opc,
V128, V64,
V128, VectorIndexS,
asm, ".2d", ".2d", ".2s", ".s",
[(set (v2i64 V128:$Rd),
(OpNode (v2i32 V64:$Rn),
(v2i32 (AArch64duplane32 (v4i32 V128:$Rm), VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v4i32_indexed : BaseSIMDIndexed<1, U, 0, 0b10, opc,
V128, V128,
V128, VectorIndexS,
asm#"2", ".2d", ".2d", ".4s", ".s",
[(set (v2i64 V128:$Rd),
(OpNode (extract_high_v4i32 V128:$Rn),
(extract_high_v4i32 (AArch64duplane32 (v4i32 V128:$Rm),
VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v1i32_indexed : BaseSIMDIndexed<1, U, 1, 0b01, opc,
FPR32Op, FPR16Op, V128_lo, VectorIndexH,
asm, ".h", "", "", ".h", []> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v1i64_indexed : BaseSIMDIndexed<1, U, 1, 0b10, opc,
FPR64Op, FPR32Op, V128, VectorIndexS,
asm, ".s", "", "", ".s", []> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
}
multiclass SIMDIndexedLongSQDMLXSDTied<bit U, bits<4> opc, string asm,
SDPatternOperator Accum> {
def v4i16_indexed : BaseSIMDIndexedTied<0, U, 0, 0b01, opc,
V128, V64,
V128_lo, VectorIndexH,
asm, ".4s", ".4s", ".4h", ".h",
[(set (v4i32 V128:$dst),
(Accum (v4i32 V128:$Rd),
(v4i32 (int_aarch64_neon_sqdmull
(v4i16 V64:$Rn),
(v4i16 (AArch64duplane16 (v8i16 V128_lo:$Rm),
VectorIndexH:$idx))))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
// FIXME: it would be nice to use the scalar (v1i32) instruction here, but an
// intermediate EXTRACT_SUBREG would be untyped.
def : Pat<(i32 (Accum (i32 FPR32Op:$Rd),
(i32 (vector_extract (v4i32
(int_aarch64_neon_sqdmull (v4i16 V64:$Rn),
(v4i16 (AArch64duplane16 (v8i16 V128_lo:$Rm),
VectorIndexH:$idx)))),
(i64 0))))),
(EXTRACT_SUBREG
(!cast<Instruction>(NAME # v4i16_indexed)
(SUBREG_TO_REG (i32 0), FPR32Op:$Rd, ssub), V64:$Rn,
V128_lo:$Rm, VectorIndexH:$idx),
ssub)>;
def v8i16_indexed : BaseSIMDIndexedTied<1, U, 0, 0b01, opc,
V128, V128,
V128_lo, VectorIndexH,
asm#"2", ".4s", ".4s", ".8h", ".h",
[(set (v4i32 V128:$dst),
(Accum (v4i32 V128:$Rd),
(v4i32 (int_aarch64_neon_sqdmull
(extract_high_v8i16 V128:$Rn),
(extract_high_v8i16
(AArch64duplane16 (v8i16 V128_lo:$Rm),
VectorIndexH:$idx))))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v2i32_indexed : BaseSIMDIndexedTied<0, U, 0, 0b10, opc,
V128, V64,
V128, VectorIndexS,
asm, ".2d", ".2d", ".2s", ".s",
[(set (v2i64 V128:$dst),
(Accum (v2i64 V128:$Rd),
(v2i64 (int_aarch64_neon_sqdmull
(v2i32 V64:$Rn),
(v2i32 (AArch64duplane32 (v4i32 V128:$Rm),
VectorIndexS:$idx))))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v4i32_indexed : BaseSIMDIndexedTied<1, U, 0, 0b10, opc,
V128, V128,
V128, VectorIndexS,
asm#"2", ".2d", ".2d", ".4s", ".s",
[(set (v2i64 V128:$dst),
(Accum (v2i64 V128:$Rd),
(v2i64 (int_aarch64_neon_sqdmull
(extract_high_v4i32 V128:$Rn),
(extract_high_v4i32
(AArch64duplane32 (v4i32 V128:$Rm),
VectorIndexS:$idx))))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v1i32_indexed : BaseSIMDIndexedTied<1, U, 1, 0b01, opc,
FPR32Op, FPR16Op, V128_lo, VectorIndexH,
asm, ".h", "", "", ".h", []> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v1i64_indexed : BaseSIMDIndexedTied<1, U, 1, 0b10, opc,
FPR64Op, FPR32Op, V128, VectorIndexS,
asm, ".s", "", "", ".s",
[(set (i64 FPR64Op:$dst),
(Accum (i64 FPR64Op:$Rd),
(i64 (int_aarch64_neon_sqdmulls_scalar
(i32 FPR32Op:$Rn),
(i32 (vector_extract (v4i32 V128:$Rm),
VectorIndexS:$idx))))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
}
multiclass SIMDVectorIndexedLongSD<bit U, bits<4> opc, string asm,
SDPatternOperator OpNode> {
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in {
def v4i16_indexed : BaseSIMDIndexed<0, U, 0, 0b01, opc,
V128, V64,
V128_lo, VectorIndexH,
asm, ".4s", ".4s", ".4h", ".h",
[(set (v4i32 V128:$Rd),
(OpNode (v4i16 V64:$Rn),
(v4i16 (AArch64duplane16 (v8i16 V128_lo:$Rm), VectorIndexH:$idx))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v8i16_indexed : BaseSIMDIndexed<1, U, 0, 0b01, opc,
V128, V128,
V128_lo, VectorIndexH,
asm#"2", ".4s", ".4s", ".8h", ".h",
[(set (v4i32 V128:$Rd),
(OpNode (extract_high_v8i16 V128:$Rn),
(extract_high_v8i16 (AArch64duplane16 (v8i16 V128_lo:$Rm),
VectorIndexH:$idx))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v2i32_indexed : BaseSIMDIndexed<0, U, 0, 0b10, opc,
V128, V64,
V128, VectorIndexS,
asm, ".2d", ".2d", ".2s", ".s",
[(set (v2i64 V128:$Rd),
(OpNode (v2i32 V64:$Rn),
(v2i32 (AArch64duplane32 (v4i32 V128:$Rm), VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v4i32_indexed : BaseSIMDIndexed<1, U, 0, 0b10, opc,
V128, V128,
V128, VectorIndexS,
asm#"2", ".2d", ".2d", ".4s", ".s",
[(set (v2i64 V128:$Rd),
(OpNode (extract_high_v4i32 V128:$Rn),
(extract_high_v4i32 (AArch64duplane32 (v4i32 V128:$Rm),
VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
}
}
multiclass SIMDVectorIndexedLongSDTied<bit U, bits<4> opc, string asm,
SDPatternOperator OpNode> {
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in {
def v4i16_indexed : BaseSIMDIndexedTied<0, U, 0, 0b01, opc,
V128, V64,
V128_lo, VectorIndexH,
asm, ".4s", ".4s", ".4h", ".h",
[(set (v4i32 V128:$dst),
(OpNode (v4i32 V128:$Rd), (v4i16 V64:$Rn),
(v4i16 (AArch64duplane16 (v8i16 V128_lo:$Rm), VectorIndexH:$idx))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v8i16_indexed : BaseSIMDIndexedTied<1, U, 0, 0b01, opc,
V128, V128,
V128_lo, VectorIndexH,
asm#"2", ".4s", ".4s", ".8h", ".h",
[(set (v4i32 V128:$dst),
(OpNode (v4i32 V128:$Rd),
(extract_high_v8i16 V128:$Rn),
(extract_high_v8i16 (AArch64duplane16 (v8i16 V128_lo:$Rm),
VectorIndexH:$idx))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v2i32_indexed : BaseSIMDIndexedTied<0, U, 0, 0b10, opc,
V128, V64,
V128, VectorIndexS,
asm, ".2d", ".2d", ".2s", ".s",
[(set (v2i64 V128:$dst),
(OpNode (v2i64 V128:$Rd), (v2i32 V64:$Rn),
(v2i32 (AArch64duplane32 (v4i32 V128:$Rm), VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
def v4i32_indexed : BaseSIMDIndexedTied<1, U, 0, 0b10, opc,
V128, V128,
V128, VectorIndexS,
asm#"2", ".2d", ".2d", ".4s", ".s",
[(set (v2i64 V128:$dst),
(OpNode (v2i64 V128:$Rd),
(extract_high_v4i32 V128:$Rn),
(extract_high_v4i32 (AArch64duplane32 (v4i32 V128:$Rm),
VectorIndexS:$idx))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
}
}
//----------------------------------------------------------------------------
// AdvSIMD scalar shift by immediate
//----------------------------------------------------------------------------
let mayStore = 0, mayLoad = 0, hasSideEffects = 0 in
class BaseSIMDScalarShift<bit U, bits<5> opc, bits<7> fixed_imm,
RegisterClass regtype1, RegisterClass regtype2,
Operand immtype, string asm, list<dag> pattern>
: I<(outs regtype1:$Rd), (ins regtype2:$Rn, immtype:$imm),
asm, "\t$Rd, $Rn, $imm", "", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<7> imm;
let Inst{31-30} = 0b01;
let Inst{29} = U;
let Inst{28-23} = 0b111110;
let Inst{22-16} = fixed_imm;
let Inst{15-11} = opc;
let Inst{10} = 1;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
let mayStore = 0, mayLoad = 0, hasSideEffects = 0 in
class BaseSIMDScalarShiftTied<bit U, bits<5> opc, bits<7> fixed_imm,
RegisterClass regtype1, RegisterClass regtype2,
Operand immtype, string asm, list<dag> pattern>
: I<(outs regtype1:$dst), (ins regtype1:$Rd, regtype2:$Rn, immtype:$imm),
asm, "\t$Rd, $Rn, $imm", "$Rd = $dst", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<7> imm;
let Inst{31-30} = 0b01;
let Inst{29} = U;
let Inst{28-23} = 0b111110;
let Inst{22-16} = fixed_imm;
let Inst{15-11} = opc;
let Inst{10} = 1;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass SIMDFPScalarRShift<bit U, bits<5> opc, string asm> {
let Predicates = [HasNEON, HasFullFP16] in {
def h : BaseSIMDScalarShift<U, opc, {0,0,1,?,?,?,?},
FPR16, FPR16, vecshiftR16, asm, []> {
let Inst{19-16} = imm{3-0};
}
} // Predicates = [HasNEON, HasFullFP16]
def s : BaseSIMDScalarShift<U, opc, {0,1,?,?,?,?,?},
FPR32, FPR32, vecshiftR32, asm, []> {
let Inst{20-16} = imm{4-0};
}
def d : BaseSIMDScalarShift<U, opc, {1,?,?,?,?,?,?},
FPR64, FPR64, vecshiftR64, asm, []> {
let Inst{21-16} = imm{5-0};
}
}
multiclass SIMDScalarRShiftD<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def d : BaseSIMDScalarShift<U, opc, {1,?,?,?,?,?,?},
FPR64, FPR64, vecshiftR64, asm,
[(set (i64 FPR64:$Rd),
(OpNode (i64 FPR64:$Rn), (i32 vecshiftR64:$imm)))]> {
let Inst{21-16} = imm{5-0};
}
def : Pat<(v1i64 (OpNode (v1i64 FPR64:$Rn), (i32 vecshiftR64:$imm))),
(!cast<Instruction>(NAME # "d") FPR64:$Rn, vecshiftR64:$imm)>;
}
multiclass SIMDScalarRShiftDTied<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode = null_frag> {
def d : BaseSIMDScalarShiftTied<U, opc, {1,?,?,?,?,?,?},
FPR64, FPR64, vecshiftR64, asm,
[(set (i64 FPR64:$dst), (OpNode (i64 FPR64:$Rd), (i64 FPR64:$Rn),
(i32 vecshiftR64:$imm)))]> {
let Inst{21-16} = imm{5-0};
}
def : Pat<(v1i64 (OpNode (v1i64 FPR64:$Rd), (v1i64 FPR64:$Rn),
(i32 vecshiftR64:$imm))),
(!cast<Instruction>(NAME # "d") FPR64:$Rd, FPR64:$Rn,
vecshiftR64:$imm)>;
}
multiclass SIMDScalarLShiftD<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def d : BaseSIMDScalarShift<U, opc, {1,?,?,?,?,?,?},
FPR64, FPR64, vecshiftL64, asm,
[(set (v1i64 FPR64:$Rd),
(OpNode (v1i64 FPR64:$Rn), (i32 vecshiftL64:$imm)))]> {
let Inst{21-16} = imm{5-0};
}
}
let mayStore = 0, mayLoad = 0, hasSideEffects = 0 in
multiclass SIMDScalarLShiftDTied<bit U, bits<5> opc, string asm> {
def d : BaseSIMDScalarShiftTied<U, opc, {1,?,?,?,?,?,?},
FPR64, FPR64, vecshiftL64, asm, []> {
let Inst{21-16} = imm{5-0};
}
}
let mayStore = 0, mayLoad = 0, hasSideEffects = 0 in
multiclass SIMDScalarRShiftBHS<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode = null_frag> {
def b : BaseSIMDScalarShift<U, opc, {0,0,0,1,?,?,?},
FPR8, FPR16, vecshiftR8, asm, []> {
let Inst{18-16} = imm{2-0};
}
def h : BaseSIMDScalarShift<U, opc, {0,0,1,?,?,?,?},
FPR16, FPR32, vecshiftR16, asm, []> {
let Inst{19-16} = imm{3-0};
}
def s : BaseSIMDScalarShift<U, opc, {0,1,?,?,?,?,?},
FPR32, FPR64, vecshiftR32, asm,
[(set (i32 FPR32:$Rd), (OpNode (i64 FPR64:$Rn), vecshiftR32:$imm))]> {
let Inst{20-16} = imm{4-0};
}
}
multiclass SIMDScalarLShiftBHSD<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def b : BaseSIMDScalarShift<U, opc, {0,0,0,1,?,?,?},
FPR8, FPR8, vecshiftL8, asm, []> {
let Inst{18-16} = imm{2-0};
}
def h : BaseSIMDScalarShift<U, opc, {0,0,1,?,?,?,?},
FPR16, FPR16, vecshiftL16, asm, []> {
let Inst{19-16} = imm{3-0};
}
def s : BaseSIMDScalarShift<U, opc, {0,1,?,?,?,?,?},
FPR32, FPR32, vecshiftL32, asm,
[(set (i32 FPR32:$Rd), (OpNode (i32 FPR32:$Rn), (i32 vecshiftL32:$imm)))]> {
let Inst{20-16} = imm{4-0};
}
def d : BaseSIMDScalarShift<U, opc, {1,?,?,?,?,?,?},
FPR64, FPR64, vecshiftL64, asm,
[(set (i64 FPR64:$Rd), (OpNode (i64 FPR64:$Rn), (i32 vecshiftL64:$imm)))]> {
let Inst{21-16} = imm{5-0};
}
def : Pat<(v1i64 (OpNode (v1i64 FPR64:$Rn), (i32 vecshiftL64:$imm))),
(!cast<Instruction>(NAME # "d") FPR64:$Rn, vecshiftL64:$imm)>;
}
multiclass SIMDScalarRShiftBHSD<bit U, bits<5> opc, string asm> {
def b : BaseSIMDScalarShift<U, opc, {0,0,0,1,?,?,?},
FPR8, FPR8, vecshiftR8, asm, []> {
let Inst{18-16} = imm{2-0};
}
def h : BaseSIMDScalarShift<U, opc, {0,0,1,?,?,?,?},
FPR16, FPR16, vecshiftR16, asm, []> {
let Inst{19-16} = imm{3-0};
}
def s : BaseSIMDScalarShift<U, opc, {0,1,?,?,?,?,?},
FPR32, FPR32, vecshiftR32, asm, []> {
let Inst{20-16} = imm{4-0};
}
def d : BaseSIMDScalarShift<U, opc, {1,?,?,?,?,?,?},
FPR64, FPR64, vecshiftR64, asm, []> {
let Inst{21-16} = imm{5-0};
}
}
//----------------------------------------------------------------------------
// AdvSIMD vector x indexed element
//----------------------------------------------------------------------------
let mayStore = 0, mayLoad = 0, hasSideEffects = 0 in
class BaseSIMDVectorShift<bit Q, bit U, bits<5> opc, bits<7> fixed_imm,
RegisterOperand dst_reg, RegisterOperand src_reg,
Operand immtype,
string asm, string dst_kind, string src_kind,
list<dag> pattern>
: I<(outs dst_reg:$Rd), (ins src_reg:$Rn, immtype:$imm),
asm, "{\t$Rd" # dst_kind # ", $Rn" # src_kind # ", $imm" #
"|" # dst_kind # "\t$Rd, $Rn, $imm}", "", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28-23} = 0b011110;
let Inst{22-16} = fixed_imm;
let Inst{15-11} = opc;
let Inst{10} = 1;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
let mayStore = 0, mayLoad = 0, hasSideEffects = 0 in
class BaseSIMDVectorShiftTied<bit Q, bit U, bits<5> opc, bits<7> fixed_imm,
RegisterOperand vectype1, RegisterOperand vectype2,
Operand immtype,
string asm, string dst_kind, string src_kind,
list<dag> pattern>
: I<(outs vectype1:$dst), (ins vectype1:$Rd, vectype2:$Rn, immtype:$imm),
asm, "{\t$Rd" # dst_kind # ", $Rn" # src_kind # ", $imm" #
"|" # dst_kind # "\t$Rd, $Rn, $imm}", "$Rd = $dst", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28-23} = 0b011110;
let Inst{22-16} = fixed_imm;
let Inst{15-11} = opc;
let Inst{10} = 1;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass SIMDVectorRShiftSD<bit U, bits<5> opc, string asm,
Intrinsic OpNode> {
let Predicates = [HasNEON, HasFullFP16] in {
def v4i16_shift : BaseSIMDVectorShift<0, U, opc, {0,0,1,?,?,?,?},
V64, V64, vecshiftR16,
asm, ".4h", ".4h",
[(set (v4i16 V64:$Rd), (OpNode (v4f16 V64:$Rn), (i32 imm:$imm)))]> {
bits<4> imm;
let Inst{19-16} = imm;
}
def v8i16_shift : BaseSIMDVectorShift<1, U, opc, {0,0,1,?,?,?,?},
V128, V128, vecshiftR16,
asm, ".8h", ".8h",
[(set (v8i16 V128:$Rd), (OpNode (v8f16 V128:$Rn), (i32 imm:$imm)))]> {
bits<4> imm;
let Inst{19-16} = imm;
}
} // Predicates = [HasNEON, HasFullFP16]
def v2i32_shift : BaseSIMDVectorShift<0, U, opc, {0,1,?,?,?,?,?},
V64, V64, vecshiftR32,
asm, ".2s", ".2s",
[(set (v2i32 V64:$Rd), (OpNode (v2f32 V64:$Rn), (i32 imm:$imm)))]> {
bits<5> imm;
let Inst{20-16} = imm;
}
def v4i32_shift : BaseSIMDVectorShift<1, U, opc, {0,1,?,?,?,?,?},
V128, V128, vecshiftR32,
asm, ".4s", ".4s",
[(set (v4i32 V128:$Rd), (OpNode (v4f32 V128:$Rn), (i32 imm:$imm)))]> {
bits<5> imm;
let Inst{20-16} = imm;
}
def v2i64_shift : BaseSIMDVectorShift<1, U, opc, {1,?,?,?,?,?,?},
V128, V128, vecshiftR64,
asm, ".2d", ".2d",
[(set (v2i64 V128:$Rd), (OpNode (v2f64 V128:$Rn), (i32 imm:$imm)))]> {
bits<6> imm;
let Inst{21-16} = imm;
}
}
multiclass SIMDVectorRShiftToFP<bit U, bits<5> opc, string asm,
Intrinsic OpNode> {
let Predicates = [HasNEON, HasFullFP16] in {
def v4i16_shift : BaseSIMDVectorShift<0, U, opc, {0,0,1,?,?,?,?},
V64, V64, vecshiftR16,
asm, ".4h", ".4h",
[(set (v4f16 V64:$Rd), (OpNode (v4i16 V64:$Rn), (i32 imm:$imm)))]> {
bits<4> imm;
let Inst{19-16} = imm;
}
def v8i16_shift : BaseSIMDVectorShift<1, U, opc, {0,0,1,?,?,?,?},
V128, V128, vecshiftR16,
asm, ".8h", ".8h",
[(set (v8f16 V128:$Rd), (OpNode (v8i16 V128:$Rn), (i32 imm:$imm)))]> {
bits<4> imm;
let Inst{19-16} = imm;
}
} // Predicates = [HasNEON, HasFullFP16]
def v2i32_shift : BaseSIMDVectorShift<0, U, opc, {0,1,?,?,?,?,?},
V64, V64, vecshiftR32,
asm, ".2s", ".2s",
[(set (v2f32 V64:$Rd), (OpNode (v2i32 V64:$Rn), (i32 imm:$imm)))]> {
bits<5> imm;
let Inst{20-16} = imm;
}
def v4i32_shift : BaseSIMDVectorShift<1, U, opc, {0,1,?,?,?,?,?},
V128, V128, vecshiftR32,
asm, ".4s", ".4s",
[(set (v4f32 V128:$Rd), (OpNode (v4i32 V128:$Rn), (i32 imm:$imm)))]> {
bits<5> imm;
let Inst{20-16} = imm;
}
def v2i64_shift : BaseSIMDVectorShift<1, U, opc, {1,?,?,?,?,?,?},
V128, V128, vecshiftR64,
asm, ".2d", ".2d",
[(set (v2f64 V128:$Rd), (OpNode (v2i64 V128:$Rn), (i32 imm:$imm)))]> {
bits<6> imm;
let Inst{21-16} = imm;
}
}
multiclass SIMDVectorRShiftNarrowBHS<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v8i8_shift : BaseSIMDVectorShift<0, U, opc, {0,0,0,1,?,?,?},
V64, V128, vecshiftR16Narrow,
asm, ".8b", ".8h",
[(set (v8i8 V64:$Rd), (OpNode (v8i16 V128:$Rn), vecshiftR16Narrow:$imm))]> {
bits<3> imm;
let Inst{18-16} = imm;
}
def v16i8_shift : BaseSIMDVectorShiftTied<1, U, opc, {0,0,0,1,?,?,?},
V128, V128, vecshiftR16Narrow,
asm#"2", ".16b", ".8h", []> {
bits<3> imm;
let Inst{18-16} = imm;
let hasSideEffects = 0;
}
def v4i16_shift : BaseSIMDVectorShift<0, U, opc, {0,0,1,?,?,?,?},
V64, V128, vecshiftR32Narrow,
asm, ".4h", ".4s",
[(set (v4i16 V64:$Rd), (OpNode (v4i32 V128:$Rn), vecshiftR32Narrow:$imm))]> {
bits<4> imm;
let Inst{19-16} = imm;
}
def v8i16_shift : BaseSIMDVectorShiftTied<1, U, opc, {0,0,1,?,?,?,?},
V128, V128, vecshiftR32Narrow,
asm#"2", ".8h", ".4s", []> {
bits<4> imm;
let Inst{19-16} = imm;
let hasSideEffects = 0;
}
def v2i32_shift : BaseSIMDVectorShift<0, U, opc, {0,1,?,?,?,?,?},
V64, V128, vecshiftR64Narrow,
asm, ".2s", ".2d",
[(set (v2i32 V64:$Rd), (OpNode (v2i64 V128:$Rn), vecshiftR64Narrow:$imm))]> {
bits<5> imm;
let Inst{20-16} = imm;
}
def v4i32_shift : BaseSIMDVectorShiftTied<1, U, opc, {0,1,?,?,?,?,?},
V128, V128, vecshiftR64Narrow,
asm#"2", ".4s", ".2d", []> {
bits<5> imm;
let Inst{20-16} = imm;
let hasSideEffects = 0;
}
// TableGen doesn't like patters w/ INSERT_SUBREG on the instructions
// themselves, so put them here instead.
// Patterns involving what's effectively an insert high and a normal
// intrinsic, represented by CONCAT_VECTORS.
def : Pat<(concat_vectors (v8i8 V64:$Rd),(OpNode (v8i16 V128:$Rn),
vecshiftR16Narrow:$imm)),
(!cast<Instruction>(NAME # "v16i8_shift")
(INSERT_SUBREG (IMPLICIT_DEF), V64:$Rd, dsub),
V128:$Rn, vecshiftR16Narrow:$imm)>;
def : Pat<(concat_vectors (v4i16 V64:$Rd), (OpNode (v4i32 V128:$Rn),
vecshiftR32Narrow:$imm)),
(!cast<Instruction>(NAME # "v8i16_shift")
(INSERT_SUBREG (IMPLICIT_DEF), V64:$Rd, dsub),
V128:$Rn, vecshiftR32Narrow:$imm)>;
def : Pat<(concat_vectors (v2i32 V64:$Rd), (OpNode (v2i64 V128:$Rn),
vecshiftR64Narrow:$imm)),
(!cast<Instruction>(NAME # "v4i32_shift")
(INSERT_SUBREG (IMPLICIT_DEF), V64:$Rd, dsub),
V128:$Rn, vecshiftR64Narrow:$imm)>;
}
multiclass SIMDVectorLShiftBHSD<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v8i8_shift : BaseSIMDVectorShift<0, U, opc, {0,0,0,1,?,?,?},
V64, V64, vecshiftL8,
asm, ".8b", ".8b",
[(set (v8i8 V64:$Rd), (OpNode (v8i8 V64:$Rn),
(i32 vecshiftL8:$imm)))]> {
bits<3> imm;
let Inst{18-16} = imm;
}
def v16i8_shift : BaseSIMDVectorShift<1, U, opc, {0,0,0,1,?,?,?},
V128, V128, vecshiftL8,
asm, ".16b", ".16b",
[(set (v16i8 V128:$Rd), (OpNode (v16i8 V128:$Rn),
(i32 vecshiftL8:$imm)))]> {
bits<3> imm;
let Inst{18-16} = imm;
}
def v4i16_shift : BaseSIMDVectorShift<0, U, opc, {0,0,1,?,?,?,?},
V64, V64, vecshiftL16,
asm, ".4h", ".4h",
[(set (v4i16 V64:$Rd), (OpNode (v4i16 V64:$Rn),
(i32 vecshiftL16:$imm)))]> {
bits<4> imm;
let Inst{19-16} = imm;
}
def v8i16_shift : BaseSIMDVectorShift<1, U, opc, {0,0,1,?,?,?,?},
V128, V128, vecshiftL16,
asm, ".8h", ".8h",
[(set (v8i16 V128:$Rd), (OpNode (v8i16 V128:$Rn),
(i32 vecshiftL16:$imm)))]> {
bits<4> imm;
let Inst{19-16} = imm;
}
def v2i32_shift : BaseSIMDVectorShift<0, U, opc, {0,1,?,?,?,?,?},
V64, V64, vecshiftL32,
asm, ".2s", ".2s",
[(set (v2i32 V64:$Rd), (OpNode (v2i32 V64:$Rn),
(i32 vecshiftL32:$imm)))]> {
bits<5> imm;
let Inst{20-16} = imm;
}
def v4i32_shift : BaseSIMDVectorShift<1, U, opc, {0,1,?,?,?,?,?},
V128, V128, vecshiftL32,
asm, ".4s", ".4s",
[(set (v4i32 V128:$Rd), (OpNode (v4i32 V128:$Rn),
(i32 vecshiftL32:$imm)))]> {
bits<5> imm;
let Inst{20-16} = imm;
}
def v2i64_shift : BaseSIMDVectorShift<1, U, opc, {1,?,?,?,?,?,?},
V128, V128, vecshiftL64,
asm, ".2d", ".2d",
[(set (v2i64 V128:$Rd), (OpNode (v2i64 V128:$Rn),
(i32 vecshiftL64:$imm)))]> {
bits<6> imm;
let Inst{21-16} = imm;
}
}
multiclass SIMDVectorRShiftBHSD<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v8i8_shift : BaseSIMDVectorShift<0, U, opc, {0,0,0,1,?,?,?},
V64, V64, vecshiftR8,
asm, ".8b", ".8b",
[(set (v8i8 V64:$Rd), (OpNode (v8i8 V64:$Rn),
(i32 vecshiftR8:$imm)))]> {
bits<3> imm;
let Inst{18-16} = imm;
}
def v16i8_shift : BaseSIMDVectorShift<1, U, opc, {0,0,0,1,?,?,?},
V128, V128, vecshiftR8,
asm, ".16b", ".16b",
[(set (v16i8 V128:$Rd), (OpNode (v16i8 V128:$Rn),
(i32 vecshiftR8:$imm)))]> {
bits<3> imm;
let Inst{18-16} = imm;
}
def v4i16_shift : BaseSIMDVectorShift<0, U, opc, {0,0,1,?,?,?,?},
V64, V64, vecshiftR16,
asm, ".4h", ".4h",
[(set (v4i16 V64:$Rd), (OpNode (v4i16 V64:$Rn),
(i32 vecshiftR16:$imm)))]> {
bits<4> imm;
let Inst{19-16} = imm;
}
def v8i16_shift : BaseSIMDVectorShift<1, U, opc, {0,0,1,?,?,?,?},
V128, V128, vecshiftR16,
asm, ".8h", ".8h",
[(set (v8i16 V128:$Rd), (OpNode (v8i16 V128:$Rn),
(i32 vecshiftR16:$imm)))]> {
bits<4> imm;
let Inst{19-16} = imm;
}
def v2i32_shift : BaseSIMDVectorShift<0, U, opc, {0,1,?,?,?,?,?},
V64, V64, vecshiftR32,
asm, ".2s", ".2s",
[(set (v2i32 V64:$Rd), (OpNode (v2i32 V64:$Rn),
(i32 vecshiftR32:$imm)))]> {
bits<5> imm;
let Inst{20-16} = imm;
}
def v4i32_shift : BaseSIMDVectorShift<1, U, opc, {0,1,?,?,?,?,?},
V128, V128, vecshiftR32,
asm, ".4s", ".4s",
[(set (v4i32 V128:$Rd), (OpNode (v4i32 V128:$Rn),
(i32 vecshiftR32:$imm)))]> {
bits<5> imm;
let Inst{20-16} = imm;
}
def v2i64_shift : BaseSIMDVectorShift<1, U, opc, {1,?,?,?,?,?,?},
V128, V128, vecshiftR64,
asm, ".2d", ".2d",
[(set (v2i64 V128:$Rd), (OpNode (v2i64 V128:$Rn),
(i32 vecshiftR64:$imm)))]> {
bits<6> imm;
let Inst{21-16} = imm;
}
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
multiclass SIMDVectorRShiftBHSDTied<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode = null_frag> {
def v8i8_shift : BaseSIMDVectorShiftTied<0, U, opc, {0,0,0,1,?,?,?},
V64, V64, vecshiftR8, asm, ".8b", ".8b",
[(set (v8i8 V64:$dst),
(OpNode (v8i8 V64:$Rd), (v8i8 V64:$Rn),
(i32 vecshiftR8:$imm)))]> {
bits<3> imm;
let Inst{18-16} = imm;
}
def v16i8_shift : BaseSIMDVectorShiftTied<1, U, opc, {0,0,0,1,?,?,?},
V128, V128, vecshiftR8, asm, ".16b", ".16b",
[(set (v16i8 V128:$dst),
(OpNode (v16i8 V128:$Rd), (v16i8 V128:$Rn),
(i32 vecshiftR8:$imm)))]> {
bits<3> imm;
let Inst{18-16} = imm;
}
def v4i16_shift : BaseSIMDVectorShiftTied<0, U, opc, {0,0,1,?,?,?,?},
V64, V64, vecshiftR16, asm, ".4h", ".4h",
[(set (v4i16 V64:$dst),
(OpNode (v4i16 V64:$Rd), (v4i16 V64:$Rn),
(i32 vecshiftR16:$imm)))]> {
bits<4> imm;
let Inst{19-16} = imm;
}
def v8i16_shift : BaseSIMDVectorShiftTied<1, U, opc, {0,0,1,?,?,?,?},
V128, V128, vecshiftR16, asm, ".8h", ".8h",
[(set (v8i16 V128:$dst),
(OpNode (v8i16 V128:$Rd), (v8i16 V128:$Rn),
(i32 vecshiftR16:$imm)))]> {
bits<4> imm;
let Inst{19-16} = imm;
}
def v2i32_shift : BaseSIMDVectorShiftTied<0, U, opc, {0,1,?,?,?,?,?},
V64, V64, vecshiftR32, asm, ".2s", ".2s",
[(set (v2i32 V64:$dst),
(OpNode (v2i32 V64:$Rd), (v2i32 V64:$Rn),
(i32 vecshiftR32:$imm)))]> {
bits<5> imm;
let Inst{20-16} = imm;
}
def v4i32_shift : BaseSIMDVectorShiftTied<1, U, opc, {0,1,?,?,?,?,?},
V128, V128, vecshiftR32, asm, ".4s", ".4s",
[(set (v4i32 V128:$dst),
(OpNode (v4i32 V128:$Rd), (v4i32 V128:$Rn),
(i32 vecshiftR32:$imm)))]> {
bits<5> imm;
let Inst{20-16} = imm;
}
def v2i64_shift : BaseSIMDVectorShiftTied<1, U, opc, {1,?,?,?,?,?,?},
V128, V128, vecshiftR64,
asm, ".2d", ".2d", [(set (v2i64 V128:$dst),
(OpNode (v2i64 V128:$Rd), (v2i64 V128:$Rn),
(i32 vecshiftR64:$imm)))]> {
bits<6> imm;
let Inst{21-16} = imm;
}
}
multiclass SIMDVectorLShiftBHSDTied<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode = null_frag> {
def v8i8_shift : BaseSIMDVectorShiftTied<0, U, opc, {0,0,0,1,?,?,?},
V64, V64, vecshiftL8,
asm, ".8b", ".8b",
[(set (v8i8 V64:$dst),
(OpNode (v8i8 V64:$Rd), (v8i8 V64:$Rn),
(i32 vecshiftL8:$imm)))]> {
bits<3> imm;
let Inst{18-16} = imm;
}
def v16i8_shift : BaseSIMDVectorShiftTied<1, U, opc, {0,0,0,1,?,?,?},
V128, V128, vecshiftL8,
asm, ".16b", ".16b",
[(set (v16i8 V128:$dst),
(OpNode (v16i8 V128:$Rd), (v16i8 V128:$Rn),
(i32 vecshiftL8:$imm)))]> {
bits<3> imm;
let Inst{18-16} = imm;
}
def v4i16_shift : BaseSIMDVectorShiftTied<0, U, opc, {0,0,1,?,?,?,?},
V64, V64, vecshiftL16,
asm, ".4h", ".4h",
[(set (v4i16 V64:$dst),
(OpNode (v4i16 V64:$Rd), (v4i16 V64:$Rn),
(i32 vecshiftL16:$imm)))]> {
bits<4> imm;
let Inst{19-16} = imm;
}
def v8i16_shift : BaseSIMDVectorShiftTied<1, U, opc, {0,0,1,?,?,?,?},
V128, V128, vecshiftL16,
asm, ".8h", ".8h",
[(set (v8i16 V128:$dst),
(OpNode (v8i16 V128:$Rd), (v8i16 V128:$Rn),
(i32 vecshiftL16:$imm)))]> {
bits<4> imm;
let Inst{19-16} = imm;
}
def v2i32_shift : BaseSIMDVectorShiftTied<0, U, opc, {0,1,?,?,?,?,?},
V64, V64, vecshiftL32,
asm, ".2s", ".2s",
[(set (v2i32 V64:$dst),
(OpNode (v2i32 V64:$Rd), (v2i32 V64:$Rn),
(i32 vecshiftL32:$imm)))]> {
bits<5> imm;
let Inst{20-16} = imm;
}
def v4i32_shift : BaseSIMDVectorShiftTied<1, U, opc, {0,1,?,?,?,?,?},
V128, V128, vecshiftL32,
asm, ".4s", ".4s",
[(set (v4i32 V128:$dst),
(OpNode (v4i32 V128:$Rd), (v4i32 V128:$Rn),
(i32 vecshiftL32:$imm)))]> {
bits<5> imm;
let Inst{20-16} = imm;
}
def v2i64_shift : BaseSIMDVectorShiftTied<1, U, opc, {1,?,?,?,?,?,?},
V128, V128, vecshiftL64,
asm, ".2d", ".2d",
[(set (v2i64 V128:$dst),
(OpNode (v2i64 V128:$Rd), (v2i64 V128:$Rn),
(i32 vecshiftL64:$imm)))]> {
bits<6> imm;
let Inst{21-16} = imm;
}
}
multiclass SIMDVectorLShiftLongBHSD<bit U, bits<5> opc, string asm,
SDPatternOperator OpNode> {
def v8i8_shift : BaseSIMDVectorShift<0, U, opc, {0,0,0,1,?,?,?},
V128, V64, vecshiftL8, asm, ".8h", ".8b",
[(set (v8i16 V128:$Rd), (OpNode (v8i8 V64:$Rn), vecshiftL8:$imm))]> {
bits<3> imm;
let Inst{18-16} = imm;
}
def v16i8_shift : BaseSIMDVectorShift<1, U, opc, {0,0,0,1,?,?,?},
V128, V128, vecshiftL8,
asm#"2", ".8h", ".16b",
[(set (v8i16 V128:$Rd),
(OpNode (extract_high_v16i8 V128:$Rn), vecshiftL8:$imm))]> {
bits<3> imm;
let Inst{18-16} = imm;
}
def v4i16_shift : BaseSIMDVectorShift<0, U, opc, {0,0,1,?,?,?,?},
V128, V64, vecshiftL16, asm, ".4s", ".4h",
[(set (v4i32 V128:$Rd), (OpNode (v4i16 V64:$Rn), vecshiftL16:$imm))]> {
bits<4> imm;
let Inst{19-16} = imm;
}
def v8i16_shift : BaseSIMDVectorShift<1, U, opc, {0,0,1,?,?,?,?},
V128, V128, vecshiftL16,
asm#"2", ".4s", ".8h",
[(set (v4i32 V128:$Rd),
(OpNode (extract_high_v8i16 V128:$Rn), vecshiftL16:$imm))]> {
bits<4> imm;
let Inst{19-16} = imm;
}
def v2i32_shift : BaseSIMDVectorShift<0, U, opc, {0,1,?,?,?,?,?},
V128, V64, vecshiftL32, asm, ".2d", ".2s",
[(set (v2i64 V128:$Rd), (OpNode (v2i32 V64:$Rn), vecshiftL32:$imm))]> {
bits<5> imm;
let Inst{20-16} = imm;
}
def v4i32_shift : BaseSIMDVectorShift<1, U, opc, {0,1,?,?,?,?,?},
V128, V128, vecshiftL32,
asm#"2", ".2d", ".4s",
[(set (v2i64 V128:$Rd),
(OpNode (extract_high_v4i32 V128:$Rn), vecshiftL32:$imm))]> {
bits<5> imm;
let Inst{20-16} = imm;
}
}
//---
// Vector load/store
//---
// SIMD ldX/stX no-index memory references don't allow the optional
// ", #0" constant and handle post-indexing explicitly, so we use
// a more specialized parse method for them. Otherwise, it's the same as
// the general GPR64sp handling.
class BaseSIMDLdSt<bit Q, bit L, bits<4> opcode, bits<2> size,
string asm, dag oops, dag iops, list<dag> pattern>
: I<oops, iops, asm, "\t$Vt, [$Rn]", "", pattern> {
bits<5> Vt;
bits<5> Rn;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29-23} = 0b0011000;
let Inst{22} = L;
let Inst{21-16} = 0b000000;
let Inst{15-12} = opcode;
let Inst{11-10} = size;
let Inst{9-5} = Rn;
let Inst{4-0} = Vt;
}
class BaseSIMDLdStPost<bit Q, bit L, bits<4> opcode, bits<2> size,
string asm, dag oops, dag iops>
: I<oops, iops, asm, "\t$Vt, [$Rn], $Xm", "$Rn = $wback", []> {
bits<5> Vt;
bits<5> Rn;
bits<5> Xm;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29-23} = 0b0011001;
let Inst{22} = L;
let Inst{21} = 0;
let Inst{20-16} = Xm;
let Inst{15-12} = opcode;
let Inst{11-10} = size;
let Inst{9-5} = Rn;
let Inst{4-0} = Vt;
}
// The immediate form of AdvSIMD post-indexed addressing is encoded with
// register post-index addressing from the zero register.
multiclass SIMDLdStAliases<string asm, string layout, string Count,
int Offset, int Size> {
// E.g. "ld1 { v0.8b, v1.8b }, [x1], #16"
// "ld1\t$Vt, [$Rn], #16"
// may get mapped to
// (LD1Twov8b_POST VecListTwo8b:$Vt, GPR64sp:$Rn, XZR)
def : InstAlias<asm # "\t$Vt, [$Rn], #" # Offset,
(!cast<Instruction>(NAME # Count # "v" # layout # "_POST")
GPR64sp:$Rn,
!cast<RegisterOperand>("VecList" # Count # layout):$Vt,
XZR), 1>;
// E.g. "ld1.8b { v0, v1 }, [x1], #16"
// "ld1.8b\t$Vt, [$Rn], #16"
// may get mapped to
// (LD1Twov8b_POST VecListTwo64:$Vt, GPR64sp:$Rn, XZR)
def : InstAlias<asm # "." # layout # "\t$Vt, [$Rn], #" # Offset,
(!cast<Instruction>(NAME # Count # "v" # layout # "_POST")
GPR64sp:$Rn,
!cast<RegisterOperand>("VecList" # Count # Size):$Vt,
XZR), 0>;
// E.g. "ld1.8b { v0, v1 }, [x1]"
// "ld1\t$Vt, [$Rn]"
// may get mapped to
// (LD1Twov8b VecListTwo64:$Vt, GPR64sp:$Rn)
def : InstAlias<asm # "." # layout # "\t$Vt, [$Rn]",
(!cast<Instruction>(NAME # Count # "v" # layout)
!cast<RegisterOperand>("VecList" # Count # Size):$Vt,
GPR64sp:$Rn), 0>;
// E.g. "ld1.8b { v0, v1 }, [x1], x2"
// "ld1\t$Vt, [$Rn], $Xm"
// may get mapped to
// (LD1Twov8b_POST VecListTwo64:$Vt, GPR64sp:$Rn, GPR64pi8:$Xm)
def : InstAlias<asm # "." # layout # "\t$Vt, [$Rn], $Xm",
(!cast<Instruction>(NAME # Count # "v" # layout # "_POST")
GPR64sp:$Rn,
!cast<RegisterOperand>("VecList" # Count # Size):$Vt,
!cast<RegisterOperand>("GPR64pi" # Offset):$Xm), 0>;
}
multiclass BaseSIMDLdN<string Count, string asm, string veclist, int Offset128,
int Offset64, bits<4> opcode> {
let hasSideEffects = 0, mayLoad = 1, mayStore = 0 in {
def v16b: BaseSIMDLdSt<1, 1, opcode, 0b00, asm,
(outs !cast<RegisterOperand>(veclist # "16b"):$Vt),
(ins GPR64sp:$Rn), []>;
def v8h : BaseSIMDLdSt<1, 1, opcode, 0b01, asm,
(outs !cast<RegisterOperand>(veclist # "8h"):$Vt),
(ins GPR64sp:$Rn), []>;
def v4s : BaseSIMDLdSt<1, 1, opcode, 0b10, asm,
(outs !cast<RegisterOperand>(veclist # "4s"):$Vt),
(ins GPR64sp:$Rn), []>;
def v2d : BaseSIMDLdSt<1, 1, opcode, 0b11, asm,
(outs !cast<RegisterOperand>(veclist # "2d"):$Vt),
(ins GPR64sp:$Rn), []>;
def v8b : BaseSIMDLdSt<0, 1, opcode, 0b00, asm,
(outs !cast<RegisterOperand>(veclist # "8b"):$Vt),
(ins GPR64sp:$Rn), []>;
def v4h : BaseSIMDLdSt<0, 1, opcode, 0b01, asm,
(outs !cast<RegisterOperand>(veclist # "4h"):$Vt),
(ins GPR64sp:$Rn), []>;
def v2s : BaseSIMDLdSt<0, 1, opcode, 0b10, asm,
(outs !cast<RegisterOperand>(veclist # "2s"):$Vt),
(ins GPR64sp:$Rn), []>;
def v16b_POST: BaseSIMDLdStPost<1, 1, opcode, 0b00, asm,
(outs GPR64sp:$wback,
!cast<RegisterOperand>(veclist # "16b"):$Vt),
(ins GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset128):$Xm)>;
def v8h_POST : BaseSIMDLdStPost<1, 1, opcode, 0b01, asm,
(outs GPR64sp:$wback,
!cast<RegisterOperand>(veclist # "8h"):$Vt),
(ins GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset128):$Xm)>;
def v4s_POST : BaseSIMDLdStPost<1, 1, opcode, 0b10, asm,
(outs GPR64sp:$wback,
!cast<RegisterOperand>(veclist # "4s"):$Vt),
(ins GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset128):$Xm)>;
def v2d_POST : BaseSIMDLdStPost<1, 1, opcode, 0b11, asm,
(outs GPR64sp:$wback,
!cast<RegisterOperand>(veclist # "2d"):$Vt),
(ins GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset128):$Xm)>;
def v8b_POST : BaseSIMDLdStPost<0, 1, opcode, 0b00, asm,
(outs GPR64sp:$wback,
!cast<RegisterOperand>(veclist # "8b"):$Vt),
(ins GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset64):$Xm)>;
def v4h_POST : BaseSIMDLdStPost<0, 1, opcode, 0b01, asm,
(outs GPR64sp:$wback,
!cast<RegisterOperand>(veclist # "4h"):$Vt),
(ins GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset64):$Xm)>;
def v2s_POST : BaseSIMDLdStPost<0, 1, opcode, 0b10, asm,
(outs GPR64sp:$wback,
!cast<RegisterOperand>(veclist # "2s"):$Vt),
(ins GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset64):$Xm)>;
}
defm : SIMDLdStAliases<asm, "16b", Count, Offset128, 128>;
defm : SIMDLdStAliases<asm, "8h", Count, Offset128, 128>;
defm : SIMDLdStAliases<asm, "4s", Count, Offset128, 128>;
defm : SIMDLdStAliases<asm, "2d", Count, Offset128, 128>;
defm : SIMDLdStAliases<asm, "8b", Count, Offset64, 64>;
defm : SIMDLdStAliases<asm, "4h", Count, Offset64, 64>;
defm : SIMDLdStAliases<asm, "2s", Count, Offset64, 64>;
}
// Only ld1/st1 has a v1d version.
multiclass BaseSIMDStN<string Count, string asm, string veclist, int Offset128,
int Offset64, bits<4> opcode> {
let hasSideEffects = 0, mayStore = 1, mayLoad = 0 in {
def v16b : BaseSIMDLdSt<1, 0, opcode, 0b00, asm, (outs),
(ins !cast<RegisterOperand>(veclist # "16b"):$Vt,
GPR64sp:$Rn), []>;
def v8h : BaseSIMDLdSt<1, 0, opcode, 0b01, asm, (outs),
(ins !cast<RegisterOperand>(veclist # "8h"):$Vt,
GPR64sp:$Rn), []>;
def v4s : BaseSIMDLdSt<1, 0, opcode, 0b10, asm, (outs),
(ins !cast<RegisterOperand>(veclist # "4s"):$Vt,
GPR64sp:$Rn), []>;
def v2d : BaseSIMDLdSt<1, 0, opcode, 0b11, asm, (outs),
(ins !cast<RegisterOperand>(veclist # "2d"):$Vt,
GPR64sp:$Rn), []>;
def v8b : BaseSIMDLdSt<0, 0, opcode, 0b00, asm, (outs),
(ins !cast<RegisterOperand>(veclist # "8b"):$Vt,
GPR64sp:$Rn), []>;
def v4h : BaseSIMDLdSt<0, 0, opcode, 0b01, asm, (outs),
(ins !cast<RegisterOperand>(veclist # "4h"):$Vt,
GPR64sp:$Rn), []>;
def v2s : BaseSIMDLdSt<0, 0, opcode, 0b10, asm, (outs),
(ins !cast<RegisterOperand>(veclist # "2s"):$Vt,
GPR64sp:$Rn), []>;
def v16b_POST : BaseSIMDLdStPost<1, 0, opcode, 0b00, asm,
(outs GPR64sp:$wback),
(ins !cast<RegisterOperand>(veclist # "16b"):$Vt,
GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset128):$Xm)>;
def v8h_POST : BaseSIMDLdStPost<1, 0, opcode, 0b01, asm,
(outs GPR64sp:$wback),
(ins !cast<RegisterOperand>(veclist # "8h"):$Vt,
GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset128):$Xm)>;
def v4s_POST : BaseSIMDLdStPost<1, 0, opcode, 0b10, asm,
(outs GPR64sp:$wback),
(ins !cast<RegisterOperand>(veclist # "4s"):$Vt,
GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset128):$Xm)>;
def v2d_POST : BaseSIMDLdStPost<1, 0, opcode, 0b11, asm,
(outs GPR64sp:$wback),
(ins !cast<RegisterOperand>(veclist # "2d"):$Vt,
GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset128):$Xm)>;
def v8b_POST : BaseSIMDLdStPost<0, 0, opcode, 0b00, asm,
(outs GPR64sp:$wback),
(ins !cast<RegisterOperand>(veclist # "8b"):$Vt,
GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset64):$Xm)>;
def v4h_POST : BaseSIMDLdStPost<0, 0, opcode, 0b01, asm,
(outs GPR64sp:$wback),
(ins !cast<RegisterOperand>(veclist # "4h"):$Vt,
GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset64):$Xm)>;
def v2s_POST : BaseSIMDLdStPost<0, 0, opcode, 0b10, asm,
(outs GPR64sp:$wback),
(ins !cast<RegisterOperand>(veclist # "2s"):$Vt,
GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset64):$Xm)>;
}
defm : SIMDLdStAliases<asm, "16b", Count, Offset128, 128>;
defm : SIMDLdStAliases<asm, "8h", Count, Offset128, 128>;
defm : SIMDLdStAliases<asm, "4s", Count, Offset128, 128>;
defm : SIMDLdStAliases<asm, "2d", Count, Offset128, 128>;
defm : SIMDLdStAliases<asm, "8b", Count, Offset64, 64>;
defm : SIMDLdStAliases<asm, "4h", Count, Offset64, 64>;
defm : SIMDLdStAliases<asm, "2s", Count, Offset64, 64>;
}
multiclass BaseSIMDLd1<string Count, string asm, string veclist,
int Offset128, int Offset64, bits<4> opcode>
: BaseSIMDLdN<Count, asm, veclist, Offset128, Offset64, opcode> {
// LD1 instructions have extra "1d" variants.
let hasSideEffects = 0, mayLoad = 1, mayStore = 0 in {
def v1d : BaseSIMDLdSt<0, 1, opcode, 0b11, asm,
(outs !cast<RegisterOperand>(veclist # "1d"):$Vt),
(ins GPR64sp:$Rn), []>;
def v1d_POST : BaseSIMDLdStPost<0, 1, opcode, 0b11, asm,
(outs GPR64sp:$wback,
!cast<RegisterOperand>(veclist # "1d"):$Vt),
(ins GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset64):$Xm)>;
}
defm : SIMDLdStAliases<asm, "1d", Count, Offset64, 64>;
}
multiclass BaseSIMDSt1<string Count, string asm, string veclist,
int Offset128, int Offset64, bits<4> opcode>
: BaseSIMDStN<Count, asm, veclist, Offset128, Offset64, opcode> {
// ST1 instructions have extra "1d" variants.
let hasSideEffects = 0, mayLoad = 0, mayStore = 1 in {
def v1d : BaseSIMDLdSt<0, 0, opcode, 0b11, asm, (outs),
(ins !cast<RegisterOperand>(veclist # "1d"):$Vt,
GPR64sp:$Rn), []>;
def v1d_POST : BaseSIMDLdStPost<0, 0, opcode, 0b11, asm,
(outs GPR64sp:$wback),
(ins !cast<RegisterOperand>(veclist # "1d"):$Vt,
GPR64sp:$Rn,
!cast<RegisterOperand>("GPR64pi" # Offset64):$Xm)>;
}
defm : SIMDLdStAliases<asm, "1d", Count, Offset64, 64>;
}
multiclass SIMDLd1Multiple<string asm> {
defm One : BaseSIMDLd1<"One", asm, "VecListOne", 16, 8, 0b0111>;
defm Two : BaseSIMDLd1<"Two", asm, "VecListTwo", 32, 16, 0b1010>;
defm Three : BaseSIMDLd1<"Three", asm, "VecListThree", 48, 24, 0b0110>;
defm Four : BaseSIMDLd1<"Four", asm, "VecListFour", 64, 32, 0b0010>;
}
multiclass SIMDSt1Multiple<string asm> {
defm One : BaseSIMDSt1<"One", asm, "VecListOne", 16, 8, 0b0111>;
defm Two : BaseSIMDSt1<"Two", asm, "VecListTwo", 32, 16, 0b1010>;
defm Three : BaseSIMDSt1<"Three", asm, "VecListThree", 48, 24, 0b0110>;
defm Four : BaseSIMDSt1<"Four", asm, "VecListFour", 64, 32, 0b0010>;
}
multiclass SIMDLd2Multiple<string asm> {
defm Two : BaseSIMDLdN<"Two", asm, "VecListTwo", 32, 16, 0b1000>;
}
multiclass SIMDSt2Multiple<string asm> {
defm Two : BaseSIMDStN<"Two", asm, "VecListTwo", 32, 16, 0b1000>;
}
multiclass SIMDLd3Multiple<string asm> {
defm Three : BaseSIMDLdN<"Three", asm, "VecListThree", 48, 24, 0b0100>;
}
multiclass SIMDSt3Multiple<string asm> {
defm Three : BaseSIMDStN<"Three", asm, "VecListThree", 48, 24, 0b0100>;
}
multiclass SIMDLd4Multiple<string asm> {
defm Four : BaseSIMDLdN<"Four", asm, "VecListFour", 64, 32, 0b0000>;
}
multiclass SIMDSt4Multiple<string asm> {
defm Four : BaseSIMDStN<"Four", asm, "VecListFour", 64, 32, 0b0000>;
}
//---
// AdvSIMD Load/store single-element
//---
class BaseSIMDLdStSingle<bit L, bit R, bits<3> opcode,
string asm, string operands, string cst,
dag oops, dag iops, list<dag> pattern>
: I<oops, iops, asm, operands, cst, pattern> {
bits<5> Vt;
bits<5> Rn;
let Inst{31} = 0;
let Inst{29-24} = 0b001101;
let Inst{22} = L;
let Inst{21} = R;
let Inst{15-13} = opcode;
let Inst{9-5} = Rn;
let Inst{4-0} = Vt;
}
class BaseSIMDLdStSingleTied<bit L, bit R, bits<3> opcode,
string asm, string operands, string cst,
dag oops, dag iops, list<dag> pattern>
: I<oops, iops, asm, operands, "$Vt = $dst," # cst, pattern> {
bits<5> Vt;
bits<5> Rn;
let Inst{31} = 0;
let Inst{29-24} = 0b001101;
let Inst{22} = L;
let Inst{21} = R;
let Inst{15-13} = opcode;
let Inst{9-5} = Rn;
let Inst{4-0} = Vt;
}
let mayLoad = 1, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDLdR<bit Q, bit R, bits<3> opcode, bit S, bits<2> size, string asm,
Operand listtype>
: BaseSIMDLdStSingle<1, R, opcode, asm, "\t$Vt, [$Rn]", "",
(outs listtype:$Vt), (ins GPR64sp:$Rn),
[]> {
let Inst{30} = Q;
let Inst{23} = 0;
let Inst{20-16} = 0b00000;
let Inst{12} = S;
let Inst{11-10} = size;
}
let mayLoad = 1, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDLdRPost<bit Q, bit R, bits<3> opcode, bit S, bits<2> size,
string asm, Operand listtype, Operand GPR64pi>
: BaseSIMDLdStSingle<1, R, opcode, asm, "\t$Vt, [$Rn], $Xm",
"$Rn = $wback",
(outs GPR64sp:$wback, listtype:$Vt),
(ins GPR64sp:$Rn, GPR64pi:$Xm), []> {
bits<5> Xm;
let Inst{30} = Q;
let Inst{23} = 1;
let Inst{20-16} = Xm;
let Inst{12} = S;
let Inst{11-10} = size;
}
multiclass SIMDLdrAliases<string asm, string layout, string Count,
int Offset, int Size> {
// E.g. "ld1r { v0.8b }, [x1], #1"
// "ld1r.8b\t$Vt, [$Rn], #1"
// may get mapped to
// (LD1Rv8b_POST VecListOne8b:$Vt, GPR64sp:$Rn, XZR)
def : InstAlias<asm # "\t$Vt, [$Rn], #" # Offset,
(!cast<Instruction>(NAME # "v" # layout # "_POST")
GPR64sp:$Rn,
!cast<RegisterOperand>("VecList" # Count # layout):$Vt,
XZR), 1>;
// E.g. "ld1r.8b { v0 }, [x1], #1"
// "ld1r.8b\t$Vt, [$Rn], #1"
// may get mapped to
// (LD1Rv8b_POST VecListOne64:$Vt, GPR64sp:$Rn, XZR)
def : InstAlias<asm # "." # layout # "\t$Vt, [$Rn], #" # Offset,
(!cast<Instruction>(NAME # "v" # layout # "_POST")
GPR64sp:$Rn,
!cast<RegisterOperand>("VecList" # Count # Size):$Vt,
XZR), 0>;
// E.g. "ld1r.8b { v0 }, [x1]"
// "ld1r.8b\t$Vt, [$Rn]"
// may get mapped to
// (LD1Rv8b VecListOne64:$Vt, GPR64sp:$Rn)
def : InstAlias<asm # "." # layout # "\t$Vt, [$Rn]",
(!cast<Instruction>(NAME # "v" # layout)
!cast<RegisterOperand>("VecList" # Count # Size):$Vt,
GPR64sp:$Rn), 0>;
// E.g. "ld1r.8b { v0 }, [x1], x2"
// "ld1r.8b\t$Vt, [$Rn], $Xm"
// may get mapped to
// (LD1Rv8b_POST VecListOne64:$Vt, GPR64sp:$Rn, GPR64pi1:$Xm)
def : InstAlias<asm # "." # layout # "\t$Vt, [$Rn], $Xm",
(!cast<Instruction>(NAME # "v" # layout # "_POST")
GPR64sp:$Rn,
!cast<RegisterOperand>("VecList" # Count # Size):$Vt,
!cast<RegisterOperand>("GPR64pi" # Offset):$Xm), 0>;
}
multiclass SIMDLdR<bit R, bits<3> opcode, bit S, string asm, string Count,
int Offset1, int Offset2, int Offset4, int Offset8> {
def v8b : BaseSIMDLdR<0, R, opcode, S, 0b00, asm,
!cast<Operand>("VecList" # Count # "8b")>;
def v16b: BaseSIMDLdR<1, R, opcode, S, 0b00, asm,
!cast<Operand>("VecList" # Count #"16b")>;
def v4h : BaseSIMDLdR<0, R, opcode, S, 0b01, asm,
!cast<Operand>("VecList" # Count #"4h")>;
def v8h : BaseSIMDLdR<1, R, opcode, S, 0b01, asm,
!cast<Operand>("VecList" # Count #"8h")>;
def v2s : BaseSIMDLdR<0, R, opcode, S, 0b10, asm,
!cast<Operand>("VecList" # Count #"2s")>;
def v4s : BaseSIMDLdR<1, R, opcode, S, 0b10, asm,
!cast<Operand>("VecList" # Count #"4s")>;
def v1d : BaseSIMDLdR<0, R, opcode, S, 0b11, asm,
!cast<Operand>("VecList" # Count #"1d")>;
def v2d : BaseSIMDLdR<1, R, opcode, S, 0b11, asm,
!cast<Operand>("VecList" # Count #"2d")>;
def v8b_POST : BaseSIMDLdRPost<0, R, opcode, S, 0b00, asm,
!cast<Operand>("VecList" # Count # "8b"),
!cast<Operand>("GPR64pi" # Offset1)>;
def v16b_POST: BaseSIMDLdRPost<1, R, opcode, S, 0b00, asm,
!cast<Operand>("VecList" # Count # "16b"),
!cast<Operand>("GPR64pi" # Offset1)>;
def v4h_POST : BaseSIMDLdRPost<0, R, opcode, S, 0b01, asm,
!cast<Operand>("VecList" # Count # "4h"),
!cast<Operand>("GPR64pi" # Offset2)>;
def v8h_POST : BaseSIMDLdRPost<1, R, opcode, S, 0b01, asm,
!cast<Operand>("VecList" # Count # "8h"),
!cast<Operand>("GPR64pi" # Offset2)>;
def v2s_POST : BaseSIMDLdRPost<0, R, opcode, S, 0b10, asm,
!cast<Operand>("VecList" # Count # "2s"),
!cast<Operand>("GPR64pi" # Offset4)>;
def v4s_POST : BaseSIMDLdRPost<1, R, opcode, S, 0b10, asm,
!cast<Operand>("VecList" # Count # "4s"),
!cast<Operand>("GPR64pi" # Offset4)>;
def v1d_POST : BaseSIMDLdRPost<0, R, opcode, S, 0b11, asm,
!cast<Operand>("VecList" # Count # "1d"),
!cast<Operand>("GPR64pi" # Offset8)>;
def v2d_POST : BaseSIMDLdRPost<1, R, opcode, S, 0b11, asm,
!cast<Operand>("VecList" # Count # "2d"),
!cast<Operand>("GPR64pi" # Offset8)>;
defm : SIMDLdrAliases<asm, "8b", Count, Offset1, 64>;
defm : SIMDLdrAliases<asm, "16b", Count, Offset1, 128>;
defm : SIMDLdrAliases<asm, "4h", Count, Offset2, 64>;
defm : SIMDLdrAliases<asm, "8h", Count, Offset2, 128>;
defm : SIMDLdrAliases<asm, "2s", Count, Offset4, 64>;
defm : SIMDLdrAliases<asm, "4s", Count, Offset4, 128>;
defm : SIMDLdrAliases<asm, "1d", Count, Offset8, 64>;
defm : SIMDLdrAliases<asm, "2d", Count, Offset8, 128>;
}
class SIMDLdStSingleB<bit L, bit R, bits<3> opcode, string asm,
dag oops, dag iops, list<dag> pattern>
: BaseSIMDLdStSingle<L, R, opcode, asm, "\t$Vt$idx, [$Rn]", "", oops, iops,
pattern> {
// idx encoded in Q:S:size fields.
bits<4> idx;
let Inst{30} = idx{3};
let Inst{23} = 0;
let Inst{20-16} = 0b00000;
let Inst{12} = idx{2};
let Inst{11-10} = idx{1-0};
}
class SIMDLdStSingleBTied<bit L, bit R, bits<3> opcode, string asm,
dag oops, dag iops, list<dag> pattern>
: BaseSIMDLdStSingleTied<L, R, opcode, asm, "\t$Vt$idx, [$Rn]", "",
oops, iops, pattern> {
// idx encoded in Q:S:size fields.
bits<4> idx;
let Inst{30} = idx{3};
let Inst{23} = 0;
let Inst{20-16} = 0b00000;
let Inst{12} = idx{2};
let Inst{11-10} = idx{1-0};
}
class SIMDLdStSingleBPost<bit L, bit R, bits<3> opcode, string asm,
dag oops, dag iops>
: BaseSIMDLdStSingle<L, R, opcode, asm, "\t$Vt$idx, [$Rn], $Xm",
"$Rn = $wback", oops, iops, []> {
// idx encoded in Q:S:size fields.
bits<4> idx;
bits<5> Xm;
let Inst{30} = idx{3};
let Inst{23} = 1;
let Inst{20-16} = Xm;
let Inst{12} = idx{2};
let Inst{11-10} = idx{1-0};
}
class SIMDLdStSingleBTiedPost<bit L, bit R, bits<3> opcode, string asm,
dag oops, dag iops>
: BaseSIMDLdStSingleTied<L, R, opcode, asm, "\t$Vt$idx, [$Rn], $Xm",
"$Rn = $wback", oops, iops, []> {
// idx encoded in Q:S:size fields.
bits<4> idx;
bits<5> Xm;
let Inst{30} = idx{3};
let Inst{23} = 1;
let Inst{20-16} = Xm;
let Inst{12} = idx{2};
let Inst{11-10} = idx{1-0};
}
class SIMDLdStSingleH<bit L, bit R, bits<3> opcode, bit size, string asm,
dag oops, dag iops, list<dag> pattern>
: BaseSIMDLdStSingle<L, R, opcode, asm, "\t$Vt$idx, [$Rn]", "", oops, iops,
pattern> {
// idx encoded in Q:S:size<1> fields.
bits<3> idx;
let Inst{30} = idx{2};
let Inst{23} = 0;
let Inst{20-16} = 0b00000;
let Inst{12} = idx{1};
let Inst{11} = idx{0};
let Inst{10} = size;
}
class SIMDLdStSingleHTied<bit L, bit R, bits<3> opcode, bit size, string asm,
dag oops, dag iops, list<dag> pattern>
: BaseSIMDLdStSingleTied<L, R, opcode, asm, "\t$Vt$idx, [$Rn]", "",
oops, iops, pattern> {
// idx encoded in Q:S:size<1> fields.
bits<3> idx;
let Inst{30} = idx{2};
let Inst{23} = 0;
let Inst{20-16} = 0b00000;
let Inst{12} = idx{1};
let Inst{11} = idx{0};
let Inst{10} = size;
}
class SIMDLdStSingleHPost<bit L, bit R, bits<3> opcode, bit size, string asm,
dag oops, dag iops>
: BaseSIMDLdStSingle<L, R, opcode, asm, "\t$Vt$idx, [$Rn], $Xm",
"$Rn = $wback", oops, iops, []> {
// idx encoded in Q:S:size<1> fields.
bits<3> idx;
bits<5> Xm;
let Inst{30} = idx{2};
let Inst{23} = 1;
let Inst{20-16} = Xm;
let Inst{12} = idx{1};
let Inst{11} = idx{0};
let Inst{10} = size;
}
class SIMDLdStSingleHTiedPost<bit L, bit R, bits<3> opcode, bit size, string asm,
dag oops, dag iops>
: BaseSIMDLdStSingleTied<L, R, opcode, asm, "\t$Vt$idx, [$Rn], $Xm",
"$Rn = $wback", oops, iops, []> {
// idx encoded in Q:S:size<1> fields.
bits<3> idx;
bits<5> Xm;
let Inst{30} = idx{2};
let Inst{23} = 1;
let Inst{20-16} = Xm;
let Inst{12} = idx{1};
let Inst{11} = idx{0};
let Inst{10} = size;
}
class SIMDLdStSingleS<bit L, bit R, bits<3> opcode, bits<2> size, string asm,
dag oops, dag iops, list<dag> pattern>
: BaseSIMDLdStSingle<L, R, opcode, asm, "\t$Vt$idx, [$Rn]", "", oops, iops,
pattern> {
// idx encoded in Q:S fields.
bits<2> idx;
let Inst{30} = idx{1};
let Inst{23} = 0;
let Inst{20-16} = 0b00000;
let Inst{12} = idx{0};
let Inst{11-10} = size;
}
class SIMDLdStSingleSTied<bit L, bit R, bits<3> opcode, bits<2> size, string asm,
dag oops, dag iops, list<dag> pattern>
: BaseSIMDLdStSingleTied<L, R, opcode, asm, "\t$Vt$idx, [$Rn]", "",
oops, iops, pattern> {
// idx encoded in Q:S fields.
bits<2> idx;
let Inst{30} = idx{1};
let Inst{23} = 0;
let Inst{20-16} = 0b00000;
let Inst{12} = idx{0};
let Inst{11-10} = size;
}
class SIMDLdStSingleSPost<bit L, bit R, bits<3> opcode, bits<2> size,
string asm, dag oops, dag iops>
: BaseSIMDLdStSingle<L, R, opcode, asm, "\t$Vt$idx, [$Rn], $Xm",
"$Rn = $wback", oops, iops, []> {
// idx encoded in Q:S fields.
bits<2> idx;
bits<5> Xm;
let Inst{30} = idx{1};
let Inst{23} = 1;
let Inst{20-16} = Xm;
let Inst{12} = idx{0};
let Inst{11-10} = size;
}
class SIMDLdStSingleSTiedPost<bit L, bit R, bits<3> opcode, bits<2> size,
string asm, dag oops, dag iops>
: BaseSIMDLdStSingleTied<L, R, opcode, asm, "\t$Vt$idx, [$Rn], $Xm",
"$Rn = $wback", oops, iops, []> {
// idx encoded in Q:S fields.
bits<2> idx;
bits<5> Xm;
let Inst{30} = idx{1};
let Inst{23} = 1;
let Inst{20-16} = Xm;
let Inst{12} = idx{0};
let Inst{11-10} = size;
}
class SIMDLdStSingleD<bit L, bit R, bits<3> opcode, bits<2> size, string asm,
dag oops, dag iops, list<dag> pattern>
: BaseSIMDLdStSingle<L, R, opcode, asm, "\t$Vt$idx, [$Rn]", "", oops, iops,
pattern> {
// idx encoded in Q field.
bits<1> idx;
let Inst{30} = idx;
let Inst{23} = 0;
let Inst{20-16} = 0b00000;
let Inst{12} = 0;
let Inst{11-10} = size;
}
class SIMDLdStSingleDTied<bit L, bit R, bits<3> opcode, bits<2> size, string asm,
dag oops, dag iops, list<dag> pattern>
: BaseSIMDLdStSingleTied<L, R, opcode, asm, "\t$Vt$idx, [$Rn]", "",
oops, iops, pattern> {
// idx encoded in Q field.
bits<1> idx;
let Inst{30} = idx;
let Inst{23} = 0;
let Inst{20-16} = 0b00000;
let Inst{12} = 0;
let Inst{11-10} = size;
}
class SIMDLdStSingleDPost<bit L, bit R, bits<3> opcode, bits<2> size,
string asm, dag oops, dag iops>
: BaseSIMDLdStSingle<L, R, opcode, asm, "\t$Vt$idx, [$Rn], $Xm",
"$Rn = $wback", oops, iops, []> {
// idx encoded in Q field.
bits<1> idx;
bits<5> Xm;
let Inst{30} = idx;
let Inst{23} = 1;
let Inst{20-16} = Xm;
let Inst{12} = 0;
let Inst{11-10} = size;
}
class SIMDLdStSingleDTiedPost<bit L, bit R, bits<3> opcode, bits<2> size,
string asm, dag oops, dag iops>
: BaseSIMDLdStSingleTied<L, R, opcode, asm, "\t$Vt$idx, [$Rn], $Xm",
"$Rn = $wback", oops, iops, []> {
// idx encoded in Q field.
bits<1> idx;
bits<5> Xm;
let Inst{30} = idx;
let Inst{23} = 1;
let Inst{20-16} = Xm;
let Inst{12} = 0;
let Inst{11-10} = size;
}
let mayLoad = 1, mayStore = 0, hasSideEffects = 0 in
multiclass SIMDLdSingleBTied<bit R, bits<3> opcode, string asm,
RegisterOperand listtype,
RegisterOperand GPR64pi> {
def i8 : SIMDLdStSingleBTied<1, R, opcode, asm,
(outs listtype:$dst),
(ins listtype:$Vt, VectorIndexB:$idx,
GPR64sp:$Rn), []>;
def i8_POST : SIMDLdStSingleBTiedPost<1, R, opcode, asm,
(outs GPR64sp:$wback, listtype:$dst),
(ins listtype:$Vt, VectorIndexB:$idx,
GPR64sp:$Rn, GPR64pi:$Xm)>;
}
let mayLoad = 1, mayStore = 0, hasSideEffects = 0 in
multiclass SIMDLdSingleHTied<bit R, bits<3> opcode, bit size, string asm,
RegisterOperand listtype,
RegisterOperand GPR64pi> {
def i16 : SIMDLdStSingleHTied<1, R, opcode, size, asm,
(outs listtype:$dst),
(ins listtype:$Vt, VectorIndexH:$idx,
GPR64sp:$Rn), []>;
def i16_POST : SIMDLdStSingleHTiedPost<1, R, opcode, size, asm,
(outs GPR64sp:$wback, listtype:$dst),
(ins listtype:$Vt, VectorIndexH:$idx,
GPR64sp:$Rn, GPR64pi:$Xm)>;
}
let mayLoad = 1, mayStore = 0, hasSideEffects = 0 in
multiclass SIMDLdSingleSTied<bit R, bits<3> opcode, bits<2> size,string asm,
RegisterOperand listtype,
RegisterOperand GPR64pi> {
def i32 : SIMDLdStSingleSTied<1, R, opcode, size, asm,
(outs listtype:$dst),
(ins listtype:$Vt, VectorIndexS:$idx,
GPR64sp:$Rn), []>;
def i32_POST : SIMDLdStSingleSTiedPost<1, R, opcode, size, asm,
(outs GPR64sp:$wback, listtype:$dst),
(ins listtype:$Vt, VectorIndexS:$idx,
GPR64sp:$Rn, GPR64pi:$Xm)>;
}
let mayLoad = 1, mayStore = 0, hasSideEffects = 0 in
multiclass SIMDLdSingleDTied<bit R, bits<3> opcode, bits<2> size, string asm,
RegisterOperand listtype, RegisterOperand GPR64pi> {
def i64 : SIMDLdStSingleDTied<1, R, opcode, size, asm,
(outs listtype:$dst),
(ins listtype:$Vt, VectorIndexD:$idx,
GPR64sp:$Rn), []>;
def i64_POST : SIMDLdStSingleDTiedPost<1, R, opcode, size, asm,
(outs GPR64sp:$wback, listtype:$dst),
(ins listtype:$Vt, VectorIndexD:$idx,
GPR64sp:$Rn, GPR64pi:$Xm)>;
}
let mayLoad = 0, mayStore = 1, hasSideEffects = 0 in
multiclass SIMDStSingleB<bit R, bits<3> opcode, string asm,
RegisterOperand listtype, RegisterOperand GPR64pi> {
def i8 : SIMDLdStSingleB<0, R, opcode, asm,
(outs), (ins listtype:$Vt, VectorIndexB:$idx,
GPR64sp:$Rn), []>;
def i8_POST : SIMDLdStSingleBPost<0, R, opcode, asm,
(outs GPR64sp:$wback),
(ins listtype:$Vt, VectorIndexB:$idx,
GPR64sp:$Rn, GPR64pi:$Xm)>;
}
let mayLoad = 0, mayStore = 1, hasSideEffects = 0 in
multiclass SIMDStSingleH<bit R, bits<3> opcode, bit size, string asm,
RegisterOperand listtype, RegisterOperand GPR64pi> {
def i16 : SIMDLdStSingleH<0, R, opcode, size, asm,
(outs), (ins listtype:$Vt, VectorIndexH:$idx,
GPR64sp:$Rn), []>;
def i16_POST : SIMDLdStSingleHPost<0, R, opcode, size, asm,
(outs GPR64sp:$wback),
(ins listtype:$Vt, VectorIndexH:$idx,
GPR64sp:$Rn, GPR64pi:$Xm)>;
}
let mayLoad = 0, mayStore = 1, hasSideEffects = 0 in
multiclass SIMDStSingleS<bit R, bits<3> opcode, bits<2> size,string asm,
RegisterOperand listtype, RegisterOperand GPR64pi> {
def i32 : SIMDLdStSingleS<0, R, opcode, size, asm,
(outs), (ins listtype:$Vt, VectorIndexS:$idx,
GPR64sp:$Rn), []>;
def i32_POST : SIMDLdStSingleSPost<0, R, opcode, size, asm,
(outs GPR64sp:$wback),
(ins listtype:$Vt, VectorIndexS:$idx,
GPR64sp:$Rn, GPR64pi:$Xm)>;
}
let mayLoad = 0, mayStore = 1, hasSideEffects = 0 in
multiclass SIMDStSingleD<bit R, bits<3> opcode, bits<2> size, string asm,
RegisterOperand listtype, RegisterOperand GPR64pi> {
def i64 : SIMDLdStSingleD<0, R, opcode, size, asm,
(outs), (ins listtype:$Vt, VectorIndexD:$idx,
GPR64sp:$Rn), []>;
def i64_POST : SIMDLdStSingleDPost<0, R, opcode, size, asm,
(outs GPR64sp:$wback),
(ins listtype:$Vt, VectorIndexD:$idx,
GPR64sp:$Rn, GPR64pi:$Xm)>;
}
multiclass SIMDLdStSingleAliases<string asm, string layout, string Type,
string Count, int Offset, Operand idxtype> {
// E.g. "ld1 { v0.8b }[0], [x1], #1"
// "ld1\t$Vt, [$Rn], #1"
// may get mapped to
// (LD1Rv8b_POST VecListOne8b:$Vt, GPR64sp:$Rn, XZR)
def : InstAlias<asm # "\t$Vt$idx, [$Rn], #" # Offset,
(!cast<Instruction>(NAME # Type # "_POST")
GPR64sp:$Rn,
!cast<RegisterOperand>("VecList" # Count # layout):$Vt,
idxtype:$idx, XZR), 1>;
// E.g. "ld1.8b { v0 }[0], [x1], #1"
// "ld1.8b\t$Vt, [$Rn], #1"
// may get mapped to
// (LD1Rv8b_POST VecListOne64:$Vt, GPR64sp:$Rn, XZR)
def : InstAlias<asm # "." # layout # "\t$Vt$idx, [$Rn], #" # Offset,
(!cast<Instruction>(NAME # Type # "_POST")
GPR64sp:$Rn,
!cast<RegisterOperand>("VecList" # Count # "128"):$Vt,
idxtype:$idx, XZR), 0>;
// E.g. "ld1.8b { v0 }[0], [x1]"
// "ld1.8b\t$Vt, [$Rn]"
// may get mapped to
// (LD1Rv8b VecListOne64:$Vt, GPR64sp:$Rn)
def : InstAlias<asm # "." # layout # "\t$Vt$idx, [$Rn]",
(!cast<Instruction>(NAME # Type)
!cast<RegisterOperand>("VecList" # Count # "128"):$Vt,
idxtype:$idx, GPR64sp:$Rn), 0>;
// E.g. "ld1.8b { v0 }[0], [x1], x2"
// "ld1.8b\t$Vt, [$Rn], $Xm"
// may get mapped to
// (LD1Rv8b_POST VecListOne64:$Vt, GPR64sp:$Rn, GPR64pi1:$Xm)
def : InstAlias<asm # "." # layout # "\t$Vt$idx, [$Rn], $Xm",
(!cast<Instruction>(NAME # Type # "_POST")
GPR64sp:$Rn,
!cast<RegisterOperand>("VecList" # Count # "128"):$Vt,
idxtype:$idx,
!cast<RegisterOperand>("GPR64pi" # Offset):$Xm), 0>;
}
multiclass SIMDLdSt1SingleAliases<string asm> {
defm : SIMDLdStSingleAliases<asm, "b", "i8", "One", 1, VectorIndexB>;
defm : SIMDLdStSingleAliases<asm, "h", "i16", "One", 2, VectorIndexH>;
defm : SIMDLdStSingleAliases<asm, "s", "i32", "One", 4, VectorIndexS>;
defm : SIMDLdStSingleAliases<asm, "d", "i64", "One", 8, VectorIndexD>;
}
multiclass SIMDLdSt2SingleAliases<string asm> {
defm : SIMDLdStSingleAliases<asm, "b", "i8", "Two", 2, VectorIndexB>;
defm : SIMDLdStSingleAliases<asm, "h", "i16", "Two", 4, VectorIndexH>;
defm : SIMDLdStSingleAliases<asm, "s", "i32", "Two", 8, VectorIndexS>;
defm : SIMDLdStSingleAliases<asm, "d", "i64", "Two", 16, VectorIndexD>;
}
multiclass SIMDLdSt3SingleAliases<string asm> {
defm : SIMDLdStSingleAliases<asm, "b", "i8", "Three", 3, VectorIndexB>;
defm : SIMDLdStSingleAliases<asm, "h", "i16", "Three", 6, VectorIndexH>;
defm : SIMDLdStSingleAliases<asm, "s", "i32", "Three", 12, VectorIndexS>;
defm : SIMDLdStSingleAliases<asm, "d", "i64", "Three", 24, VectorIndexD>;
}
multiclass SIMDLdSt4SingleAliases<string asm> {
defm : SIMDLdStSingleAliases<asm, "b", "i8", "Four", 4, VectorIndexB>;
defm : SIMDLdStSingleAliases<asm, "h", "i16", "Four", 8, VectorIndexH>;
defm : SIMDLdStSingleAliases<asm, "s", "i32", "Four", 16, VectorIndexS>;
defm : SIMDLdStSingleAliases<asm, "d", "i64", "Four", 32, VectorIndexD>;
}
} // end of 'let Predicates = [HasNEON]'
//----------------------------------------------------------------------------
// AdvSIMD v8.1 Rounding Double Multiply Add/Subtract
//----------------------------------------------------------------------------
let Predicates = [HasNEON, HasRDM] in {
class BaseSIMDThreeSameVectorTiedR0<bit Q, bit U, bits<2> size, bits<5> opcode,
RegisterOperand regtype, string asm,
string kind, list<dag> pattern>
: BaseSIMDThreeSameVectorTied<Q, U, {size,0}, opcode, regtype, asm, kind,
pattern> {
}
multiclass SIMDThreeSameVectorSQRDMLxHTiedHS<bit U, bits<5> opc, string asm,
SDPatternOperator Accum> {
def v4i16 : BaseSIMDThreeSameVectorTiedR0<0, U, 0b01, opc, V64, asm, ".4h",
[(set (v4i16 V64:$dst),
(Accum (v4i16 V64:$Rd),
(v4i16 (int_aarch64_neon_sqrdmulh (v4i16 V64:$Rn),
(v4i16 V64:$Rm)))))]>;
def v8i16 : BaseSIMDThreeSameVectorTiedR0<1, U, 0b01, opc, V128, asm, ".8h",
[(set (v8i16 V128:$dst),
(Accum (v8i16 V128:$Rd),
(v8i16 (int_aarch64_neon_sqrdmulh (v8i16 V128:$Rn),
(v8i16 V128:$Rm)))))]>;
def v2i32 : BaseSIMDThreeSameVectorTiedR0<0, U, 0b10, opc, V64, asm, ".2s",
[(set (v2i32 V64:$dst),
(Accum (v2i32 V64:$Rd),
(v2i32 (int_aarch64_neon_sqrdmulh (v2i32 V64:$Rn),
(v2i32 V64:$Rm)))))]>;
def v4i32 : BaseSIMDThreeSameVectorTiedR0<1, U, 0b10, opc, V128, asm, ".4s",
[(set (v4i32 V128:$dst),
(Accum (v4i32 V128:$Rd),
(v4i32 (int_aarch64_neon_sqrdmulh (v4i32 V128:$Rn),
(v4i32 V128:$Rm)))))]>;
}
multiclass SIMDIndexedSQRDMLxHSDTied<bit U, bits<4> opc, string asm,
SDPatternOperator Accum> {
def v4i16_indexed : BaseSIMDIndexedTied<0, U, 0, 0b01, opc,
V64, V64, V128_lo, VectorIndexH,
asm, ".4h", ".4h", ".4h", ".h",
[(set (v4i16 V64:$dst),
(Accum (v4i16 V64:$Rd),
(v4i16 (int_aarch64_neon_sqrdmulh
(v4i16 V64:$Rn),
(v4i16 (AArch64duplane16 (v8i16 V128_lo:$Rm),
VectorIndexH:$idx))))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v8i16_indexed : BaseSIMDIndexedTied<1, U, 0, 0b01, opc,
V128, V128, V128_lo, VectorIndexH,
asm, ".8h", ".8h", ".8h", ".h",
[(set (v8i16 V128:$dst),
(Accum (v8i16 V128:$Rd),
(v8i16 (int_aarch64_neon_sqrdmulh
(v8i16 V128:$Rn),
(v8i16 (AArch64duplane16 (v8i16 V128_lo:$Rm),
VectorIndexH:$idx))))))]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def v2i32_indexed : BaseSIMDIndexedTied<0, U, 0, 0b10, opc,
V64, V64, V128, VectorIndexS,
asm, ".2s", ".2s", ".2s", ".s",
[(set (v2i32 V64:$dst),
(Accum (v2i32 V64:$Rd),
(v2i32 (int_aarch64_neon_sqrdmulh
(v2i32 V64:$Rn),
(v2i32 (AArch64duplane32 (v4i32 V128:$Rm),
VectorIndexS:$idx))))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
// FIXME: it would be nice to use the scalar (v1i32) instruction here, but
// an intermediate EXTRACT_SUBREG would be untyped.
// FIXME: direct EXTRACT_SUBREG from v2i32 to i32 is illegal, that's why we
// got it lowered here as (i32 vector_extract (v4i32 insert_subvector(..)))
def : Pat<(i32 (Accum (i32 FPR32Op:$Rd),
(i32 (vector_extract
(v4i32 (insert_subvector
(undef),
(v2i32 (int_aarch64_neon_sqrdmulh
(v2i32 V64:$Rn),
(v2i32 (AArch64duplane32
(v4i32 V128:$Rm),
VectorIndexS:$idx)))),
(i32 0))),
(i64 0))))),
(EXTRACT_SUBREG
(v2i32 (!cast<Instruction>(NAME # v2i32_indexed)
(v2i32 (INSERT_SUBREG (v2i32 (IMPLICIT_DEF)),
FPR32Op:$Rd,
ssub)),
V64:$Rn,
V128:$Rm,
VectorIndexS:$idx)),
ssub)>;
def v4i32_indexed : BaseSIMDIndexedTied<1, U, 0, 0b10, opc,
V128, V128, V128, VectorIndexS,
asm, ".4s", ".4s", ".4s", ".s",
[(set (v4i32 V128:$dst),
(Accum (v4i32 V128:$Rd),
(v4i32 (int_aarch64_neon_sqrdmulh
(v4i32 V128:$Rn),
(v4i32 (AArch64duplane32 (v4i32 V128:$Rm),
VectorIndexS:$idx))))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
// FIXME: it would be nice to use the scalar (v1i32) instruction here, but
// an intermediate EXTRACT_SUBREG would be untyped.
def : Pat<(i32 (Accum (i32 FPR32Op:$Rd),
(i32 (vector_extract
(v4i32 (int_aarch64_neon_sqrdmulh
(v4i32 V128:$Rn),
(v4i32 (AArch64duplane32
(v4i32 V128:$Rm),
VectorIndexS:$idx)))),
(i64 0))))),
(EXTRACT_SUBREG
(v4i32 (!cast<Instruction>(NAME # v4i32_indexed)
(v4i32 (INSERT_SUBREG (v4i32 (IMPLICIT_DEF)),
FPR32Op:$Rd,
ssub)),
V128:$Rn,
V128:$Rm,
VectorIndexS:$idx)),
ssub)>;
def i16_indexed : BaseSIMDIndexedTied<1, U, 1, 0b01, opc,
FPR16Op, FPR16Op, V128_lo,
VectorIndexH, asm, ".h", "", "", ".h",
[]> {
bits<3> idx;
let Inst{11} = idx{2};
let Inst{21} = idx{1};
let Inst{20} = idx{0};
}
def i32_indexed : BaseSIMDIndexedTied<1, U, 1, 0b10, opc,
FPR32Op, FPR32Op, V128, VectorIndexS,
asm, ".s", "", "", ".s",
[(set (i32 FPR32Op:$dst),
(Accum (i32 FPR32Op:$Rd),
(i32 (int_aarch64_neon_sqrdmulh
(i32 FPR32Op:$Rn),
(i32 (vector_extract (v4i32 V128:$Rm),
VectorIndexS:$idx))))))]> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
}
} // let Predicates = [HasNeon, HasRDM]
//----------------------------------------------------------------------------
// ARMv8.3 Complex ADD/MLA instructions
//----------------------------------------------------------------------------
class ComplexRotationOperand<int Angle, int Remainder, string Type>
: AsmOperandClass {
let PredicateMethod = "isComplexRotation<" # Angle # ", " # Remainder # ">";
let DiagnosticType = "InvalidComplexRotation" # Type;
let Name = "ComplexRotation" # Type;
}
def complexrotateop : Operand<i32> {
let ParserMatchClass = ComplexRotationOperand<90, 0, "Even">;
let PrintMethod = "printComplexRotationOp<90, 0>";
}
def complexrotateopodd : Operand<i32> {
let ParserMatchClass = ComplexRotationOperand<180, 90, "Odd">;
let PrintMethod = "printComplexRotationOp<180, 90>";
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDThreeSameVectorComplex<bit Q, bit U, bits<2> size, bits<3> opcode,
RegisterOperand regtype, Operand rottype,
string asm, string kind, list<dag> pattern>
: I<(outs regtype:$Rd), (ins regtype:$Rn, regtype:$Rm, rottype:$rot), asm,
"{\t$Rd" # kind # ", $Rn" # kind # ", $Rm" # kind # ", $rot"
"|" # kind # "\t$Rd, $Rn, $Rm, $rot}", "", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
bits<1> rot;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28-24} = 0b01110;
let Inst{23-22} = size;
let Inst{21} = 0;
let Inst{20-16} = Rm;
let Inst{15-13} = opcode;
// Non-tied version (FCADD) only has one rotation bit
let Inst{12} = rot;
let Inst{11} = 0;
let Inst{10} = 1;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass SIMDThreeSameVectorComplexHSD<bit U, bits<3> opcode, Operand rottype,
string asm, SDPatternOperator OpNode>{
let Predicates = [HasV8_3a, HasNEON, HasFullFP16] in {
def v4f16 : BaseSIMDThreeSameVectorComplex<0, U, 0b01, opcode, V64, rottype,
asm, ".4h",
[(set (v4f16 V64:$dst), (OpNode (v4f16 V64:$Rd),
(v4f16 V64:$Rn),
(v4f16 V64:$Rm),
(rottype i32:$rot)))]>;
def v8f16 : BaseSIMDThreeSameVectorComplex<1, U, 0b01, opcode, V128, rottype,
asm, ".8h",
[(set (v8f16 V128:$dst), (OpNode (v8f16 V128:$Rd),
(v8f16 V128:$Rn),
(v8f16 V128:$Rm),
(rottype i32:$rot)))]>;
}
let Predicates = [HasV8_3a, HasNEON] in {
def v2f32 : BaseSIMDThreeSameVectorComplex<0, U, 0b10, opcode, V64, rottype,
asm, ".2s",
[(set (v2f32 V64:$dst), (OpNode (v2f32 V64:$Rd),
(v2f32 V64:$Rn),
(v2f32 V64:$Rm),
(rottype i32:$rot)))]>;
def v4f32 : BaseSIMDThreeSameVectorComplex<1, U, 0b10, opcode, V128, rottype,
asm, ".4s",
[(set (v4f32 V128:$dst), (OpNode (v4f32 V128:$Rd),
(v4f32 V128:$Rn),
(v4f32 V128:$Rm),
(rottype i32:$rot)))]>;
def v2f64 : BaseSIMDThreeSameVectorComplex<1, U, 0b11, opcode, V128, rottype,
asm, ".2d",
[(set (v2f64 V128:$dst), (OpNode (v2f64 V128:$Rd),
(v2f64 V128:$Rn),
(v2f64 V128:$Rm),
(rottype i32:$rot)))]>;
}
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDThreeSameVectorTiedComplex<bit Q, bit U, bits<2> size,
bits<3> opcode,
RegisterOperand regtype,
Operand rottype, string asm,
string kind, list<dag> pattern>
: I<(outs regtype:$dst),
(ins regtype:$Rd, regtype:$Rn, regtype:$Rm, rottype:$rot), asm,
"{\t$Rd" # kind # ", $Rn" # kind # ", $Rm" # kind # ", $rot"
"|" # kind # "\t$Rd, $Rn, $Rm, $rot}", "$Rd = $dst", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
bits<2> rot;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28-24} = 0b01110;
let Inst{23-22} = size;
let Inst{21} = 0;
let Inst{20-16} = Rm;
let Inst{15-13} = opcode;
let Inst{12-11} = rot;
let Inst{10} = 1;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
multiclass SIMDThreeSameVectorTiedComplexHSD<bit U, bits<3> opcode,
Operand rottype, string asm,
SDPatternOperator OpNode> {
let Predicates = [HasV8_3a, HasNEON, HasFullFP16] in {
def v4f16 : BaseSIMDThreeSameVectorTiedComplex<0, U, 0b01, opcode, V64,
rottype, asm, ".4h",
[(set (v4f16 V64:$dst), (OpNode (v4f16 V64:$Rd),
(v4f16 V64:$Rn),
(v4f16 V64:$Rm),
(rottype i32:$rot)))]>;
def v8f16 : BaseSIMDThreeSameVectorTiedComplex<1, U, 0b01, opcode, V128,
rottype, asm, ".8h",
[(set (v8f16 V128:$dst), (OpNode (v8f16 V128:$Rd),
(v8f16 V128:$Rn),
(v8f16 V128:$Rm),
(rottype i32:$rot)))]>;
}
let Predicates = [HasV8_3a, HasNEON] in {
def v2f32 : BaseSIMDThreeSameVectorTiedComplex<0, U, 0b10, opcode, V64,
rottype, asm, ".2s",
[(set (v2f32 V64:$dst), (OpNode (v2f32 V64:$Rd),
(v2f32 V64:$Rn),
(v2f32 V64:$Rm),
(rottype i32:$rot)))]>;
def v4f32 : BaseSIMDThreeSameVectorTiedComplex<1, U, 0b10, opcode, V128,
rottype, asm, ".4s",
[(set (v4f32 V128:$dst), (OpNode (v4f32 V128:$Rd),
(v4f32 V128:$Rn),
(v4f32 V128:$Rm),
(rottype i32:$rot)))]>;
def v2f64 : BaseSIMDThreeSameVectorTiedComplex<1, U, 0b11, opcode, V128,
rottype, asm, ".2d",
[(set (v2f64 V128:$dst), (OpNode (v2f64 V128:$Rd),
(v2f64 V128:$Rn),
(v2f64 V128:$Rm),
(rottype i32:$rot)))]>;
}
}
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class BaseSIMDIndexedTiedComplex<bit Q, bit U, bit Scalar, bits<2> size,
bit opc1, bit opc2, RegisterOperand dst_reg,
RegisterOperand lhs_reg,
RegisterOperand rhs_reg, Operand vec_idx,
Operand rottype, string asm, string apple_kind,
string dst_kind, string lhs_kind,
string rhs_kind, list<dag> pattern>
: I<(outs dst_reg:$dst),
(ins dst_reg:$Rd, lhs_reg:$Rn, rhs_reg:$Rm, vec_idx:$idx, rottype:$rot),
asm,
"{\t$Rd" # dst_kind # ", $Rn" # lhs_kind # ", $Rm" # rhs_kind #
"$idx, $rot" # "|" # apple_kind #
"\t$Rd, $Rn, $Rm$idx, $rot}", "$Rd = $dst", pattern>,
Sched<[WriteV]> {
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
bits<2> rot;
let Inst{31} = 0;
let Inst{30} = Q;
let Inst{29} = U;
let Inst{28} = Scalar;
let Inst{27-24} = 0b1111;
let Inst{23-22} = size;
// Bit 21 must be set by the derived class.
let Inst{20-16} = Rm;
let Inst{15} = opc1;
let Inst{14-13} = rot;
let Inst{12} = opc2;
// Bit 11 must be set by the derived class.
let Inst{10} = 0;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
// The complex instructions index by pairs of elements, so the VectorIndexes
// don't match the lane types, and the index bits are different to the other
// classes.
multiclass SIMDIndexedTiedComplexHSD<bit U, bit opc1, bit opc2, Operand rottype,
string asm, SDPatternOperator OpNode> {
let Predicates = [HasV8_3a,HasNEON,HasFullFP16] in {
def v4f16_indexed : BaseSIMDIndexedTiedComplex<0, 1, 0, 0b01, opc1, opc2, V64,
V64, V128, VectorIndexD, rottype, asm, ".4h", ".4h",
".4h", ".h", []> {
bits<1> idx;
let Inst{11} = 0;
let Inst{21} = idx{0};
}
def v8f16_indexed : BaseSIMDIndexedTiedComplex<1, 1, 0, 0b01, opc1, opc2,
V128, V128, V128, VectorIndexS, rottype, asm, ".8h",
".8h", ".8h", ".h", []> {
bits<2> idx;
let Inst{11} = idx{1};
let Inst{21} = idx{0};
}
} // Predicates = [HasV8_3a,HasNEON,HasFullFP16]
let Predicates = [HasV8_3a,HasNEON] in {
def v4f32_indexed : BaseSIMDIndexedTiedComplex<1, 1, 0, 0b10, opc1, opc2,
V128, V128, V128, VectorIndexD, rottype, asm, ".4s",
".4s", ".4s", ".s", []> {
bits<1> idx;
let Inst{11} = idx{0};
let Inst{21} = 0;
}
} // Predicates = [HasV8_3a,HasNEON]
}
//----------------------------------------------------------------------------
// Crypto extensions
//----------------------------------------------------------------------------
let Predicates = [HasCrypto] in {
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class AESBase<bits<4> opc, string asm, dag outs, dag ins, string cstr,
list<dag> pat>
: I<outs, ins, asm, "{\t$Rd.16b, $Rn.16b|.16b\t$Rd, $Rn}", cstr, pat>,
Sched<[WriteV]>{
bits<5> Rd;
bits<5> Rn;
let Inst{31-16} = 0b0100111000101000;
let Inst{15-12} = opc;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
class AESInst<bits<4> opc, string asm, Intrinsic OpNode>
: AESBase<opc, asm, (outs V128:$Rd), (ins V128:$Rn), "",
[(set (v16i8 V128:$Rd), (OpNode (v16i8 V128:$Rn)))]>;
class AESTiedInst<bits<4> opc, string asm, Intrinsic OpNode>
: AESBase<opc, asm, (outs V128:$dst), (ins V128:$Rd, V128:$Rn),
"$Rd = $dst",
[(set (v16i8 V128:$dst),
(OpNode (v16i8 V128:$Rd), (v16i8 V128:$Rn)))]>;
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class SHA3OpTiedInst<bits<3> opc, string asm, string dst_lhs_kind,
dag oops, dag iops, list<dag> pat>
: I<oops, iops, asm,
"{\t$Rd" # dst_lhs_kind # ", $Rn" # dst_lhs_kind # ", $Rm.4s" #
"|.4s\t$Rd, $Rn, $Rm}", "$Rd = $dst", pat>,
Sched<[WriteV]>{
bits<5> Rd;
bits<5> Rn;
bits<5> Rm;
let Inst{31-21} = 0b01011110000;
let Inst{20-16} = Rm;
let Inst{15} = 0;
let Inst{14-12} = opc;
let Inst{11-10} = 0b00;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
class SHATiedInstQSV<bits<3> opc, string asm, Intrinsic OpNode>
: SHA3OpTiedInst<opc, asm, "", (outs FPR128:$dst),
(ins FPR128:$Rd, FPR32:$Rn, V128:$Rm),
[(set (v4i32 FPR128:$dst),
(OpNode (v4i32 FPR128:$Rd), (i32 FPR32:$Rn),
(v4i32 V128:$Rm)))]>;
class SHATiedInstVVV<bits<3> opc, string asm, Intrinsic OpNode>
: SHA3OpTiedInst<opc, asm, ".4s", (outs V128:$dst),
(ins V128:$Rd, V128:$Rn, V128:$Rm),
[(set (v4i32 V128:$dst),
(OpNode (v4i32 V128:$Rd), (v4i32 V128:$Rn),
(v4i32 V128:$Rm)))]>;
class SHATiedInstQQV<bits<3> opc, string asm, Intrinsic OpNode>
: SHA3OpTiedInst<opc, asm, "", (outs FPR128:$dst),
(ins FPR128:$Rd, FPR128:$Rn, V128:$Rm),
[(set (v4i32 FPR128:$dst),
(OpNode (v4i32 FPR128:$Rd), (v4i32 FPR128:$Rn),
(v4i32 V128:$Rm)))]>;
let mayLoad = 0, mayStore = 0, hasSideEffects = 0 in
class SHA2OpInst<bits<4> opc, string asm, string kind,
string cstr, dag oops, dag iops,
list<dag> pat>
: I<oops, iops, asm, "{\t$Rd" # kind # ", $Rn" # kind #
"|" # kind # "\t$Rd, $Rn}", cstr, pat>,
Sched<[WriteV]>{
bits<5> Rd;
bits<5> Rn;
let Inst{31-16} = 0b0101111000101000;
let Inst{15-12} = opc;
let Inst{11-10} = 0b10;
let Inst{9-5} = Rn;
let Inst{4-0} = Rd;
}
class SHATiedInstVV<bits<4> opc, string asm, Intrinsic OpNode>
: SHA2OpInst<opc, asm, ".4s", "$Rd = $dst", (outs V128:$dst),
(ins V128:$Rd, V128:$Rn),
[(set (v4i32 V128:$dst),
(OpNode (v4i32 V128:$Rd), (v4i32 V128:$Rn)))]>;
class SHAInstSS<bits<4> opc, string asm, Intrinsic OpNode>
: SHA2OpInst<opc, asm, "", "", (outs FPR32:$Rd), (ins FPR32:$Rn),
[(set (i32 FPR32:$Rd), (OpNode (i32 FPR32:$Rn)))]>;
} // end of 'let Predicates = [HasCrypto]'
//----------------------------------------------------------------------------
// v8.1 atomic instructions extension:
// * CAS
// * CASP
// * SWP
// * LDOPregister<OP>, and aliases STOPregister<OP>
// Instruction encodings:
//
// 31 30|29 24|23|22|21|20 16|15|14 10|9 5|4 0
// CAS SZ |001000|1 |A |1 |Rs |R |11111 |Rn |Rt
// CASP 0|SZ|001000|0 |A |1 |Rs |R |11111 |Rn |Rt
// SWP SZ |111000|A |R |1 |Rs |1 |OPC|00|Rn |Rt
// LD SZ |111000|A |R |1 |Rs |0 |OPC|00|Rn |Rt
// ST SZ |111000|A |R |1 |Rs |0 |OPC|00|Rn |11111
// Instruction syntax:
//
// CAS{<order>}[<size>] <Ws>, <Wt>, [<Xn|SP>]
// CAS{<order>} <Xs>, <Xt>, [<Xn|SP>]
// CASP{<order>} <Ws>, <W(s+1)>, <Wt>, <W(t+1)>, [<Xn|SP>]
// CASP{<order>} <Xs>, <X(s+1)>, <Xt>, <X(t+1)>, [<Xn|SP>]
// SWP{<order>}[<size>] <Ws>, <Wt>, [<Xn|SP>]
// SWP{<order>} <Xs>, <Xt>, [<Xn|SP>]
// LD<OP>{<order>}[<size>] <Ws>, <Wt>, [<Xn|SP>]
// LD<OP>{<order>} <Xs>, <Xt>, [<Xn|SP>]
// ST<OP>{<order>}[<size>] <Ws>, [<Xn|SP>]
// ST<OP>{<order>} <Xs>, [<Xn|SP>]
let Predicates = [HasLSE], mayLoad = 1, mayStore = 1, hasSideEffects = 1 in
class BaseCASEncoding<dag oops, dag iops, string asm, string operands,
string cstr, list<dag> pattern>
: I<oops, iops, asm, operands, cstr, pattern> {
bits<2> Sz;
bit NP;
bit Acq;
bit Rel;
bits<5> Rs;
bits<5> Rn;
bits<5> Rt;
let Inst{31-30} = Sz;
let Inst{29-24} = 0b001000;
let Inst{23} = NP;
let Inst{22} = Acq;
let Inst{21} = 0b1;
let Inst{20-16} = Rs;
let Inst{15} = Rel;
let Inst{14-10} = 0b11111;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let Predicates = [HasLSE];
}
class BaseCAS<string order, string size, RegisterClass RC>
: BaseCASEncoding<(outs RC:$out),(ins RC:$Rs, RC:$Rt, GPR64sp:$Rn),
"cas" # order # size, "\t$Rs, $Rt, [$Rn]",
"$out = $Rs",[]>,
Sched<[WriteAtomic]> {
let NP = 1;
}
multiclass CompareAndSwap<bits<1> Acq, bits<1> Rel, string order> {
let Sz = 0b00, Acq = Acq, Rel = Rel in def B : BaseCAS<order, "b", GPR32>;
let Sz = 0b01, Acq = Acq, Rel = Rel in def H : BaseCAS<order, "h", GPR32>;
let Sz = 0b10, Acq = Acq, Rel = Rel in def W : BaseCAS<order, "", GPR32>;
let Sz = 0b11, Acq = Acq, Rel = Rel in def X : BaseCAS<order, "", GPR64>;
}
class BaseCASP<string order, string size, RegisterOperand RC>
: BaseCASEncoding<(outs RC:$out),(ins RC:$Rs, RC:$Rt, GPR64sp:$Rn),
"casp" # order # size, "\t$Rs, $Rt, [$Rn]",
"$out = $Rs",[]>,
Sched<[WriteAtomic]> {
let NP = 0;
}
multiclass CompareAndSwapPair<bits<1> Acq, bits<1> Rel, string order> {
let Sz = 0b00, Acq = Acq, Rel = Rel in
def W : BaseCASP<order, "", WSeqPairClassOperand>;
let Sz = 0b01, Acq = Acq, Rel = Rel in
def X : BaseCASP<order, "", XSeqPairClassOperand>;
}
let Predicates = [HasLSE] in
class BaseSWP<string order, string size, RegisterClass RC>
: I<(outs RC:$Rt),(ins RC:$Rs, GPR64sp:$Rn), "swp" # order # size,
"\t$Rs, $Rt, [$Rn]","",[]>,
Sched<[WriteAtomic]> {
bits<2> Sz;
bit Acq;
bit Rel;
bits<5> Rs;
bits<3> opc = 0b000;
bits<5> Rn;
bits<5> Rt;
let Inst{31-30} = Sz;
let Inst{29-24} = 0b111000;
let Inst{23} = Acq;
let Inst{22} = Rel;
let Inst{21} = 0b1;
let Inst{20-16} = Rs;
let Inst{15} = 0b1;
let Inst{14-12} = opc;
let Inst{11-10} = 0b00;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let Predicates = [HasLSE];
}
multiclass Swap<bits<1> Acq, bits<1> Rel, string order> {
let Sz = 0b00, Acq = Acq, Rel = Rel in def B : BaseSWP<order, "b", GPR32>;
let Sz = 0b01, Acq = Acq, Rel = Rel in def H : BaseSWP<order, "h", GPR32>;
let Sz = 0b10, Acq = Acq, Rel = Rel in def W : BaseSWP<order, "", GPR32>;
let Sz = 0b11, Acq = Acq, Rel = Rel in def X : BaseSWP<order, "", GPR64>;
}
let Predicates = [HasLSE], mayLoad = 1, mayStore = 1, hasSideEffects = 1 in
class BaseLDOPregister<string op, string order, string size, RegisterClass RC>
: I<(outs RC:$Rt),(ins RC:$Rs, GPR64sp:$Rn), "ld" # op # order # size,
"\t$Rs, $Rt, [$Rn]","",[]>,
Sched<[WriteAtomic]> {
bits<2> Sz;
bit Acq;
bit Rel;
bits<5> Rs;
bits<3> opc;
bits<5> Rn;
bits<5> Rt;
let Inst{31-30} = Sz;
let Inst{29-24} = 0b111000;
let Inst{23} = Acq;
let Inst{22} = Rel;
let Inst{21} = 0b1;
let Inst{20-16} = Rs;
let Inst{15} = 0b0;
let Inst{14-12} = opc;
let Inst{11-10} = 0b00;
let Inst{9-5} = Rn;
let Inst{4-0} = Rt;
let Predicates = [HasLSE];
}
multiclass LDOPregister<bits<3> opc, string op, bits<1> Acq, bits<1> Rel,
string order> {
let Sz = 0b00, Acq = Acq, Rel = Rel, opc = opc in
def B : BaseLDOPregister<op, order, "b", GPR32>;
let Sz = 0b01, Acq = Acq, Rel = Rel, opc = opc in
def H : BaseLDOPregister<op, order, "h", GPR32>;
let Sz = 0b10, Acq = Acq, Rel = Rel, opc = opc in
def W : BaseLDOPregister<op, order, "", GPR32>;
let Sz = 0b11, Acq = Acq, Rel = Rel, opc = opc in
def X : BaseLDOPregister<op, order, "", GPR64>;
}
// Differing SrcRHS and DstRHS allow you to cover CLR & SUB by giving a more
// complex DAG for DstRHS.
let Predicates = [HasLSE] in
multiclass LDOPregister_patterns_ord_dag<string inst, string suffix, string op,
string size, dag SrcRHS, dag DstRHS> {
def : Pat<(!cast<SDNode>(op#"_"#size#"_monotonic") GPR64sp:$Rn, SrcRHS),
(!cast<Instruction>(inst # suffix) DstRHS, GPR64sp:$Rn)>;
def : Pat<(!cast<SDNode>(op#"_"#size#"_acquire") GPR64sp:$Rn, SrcRHS),
(!cast<Instruction>(inst # "A" # suffix) DstRHS, GPR64sp:$Rn)>;
def : Pat<(!cast<SDNode>(op#"_"#size#"_release") GPR64sp:$Rn, SrcRHS),
(!cast<Instruction>(inst # "L" # suffix) DstRHS, GPR64sp:$Rn)>;
def : Pat<(!cast<SDNode>(op#"_"#size#"_acq_rel") GPR64sp:$Rn, SrcRHS),
(!cast<Instruction>(inst # "AL" # suffix) DstRHS, GPR64sp:$Rn)>;
def : Pat<(!cast<SDNode>(op#"_"#size#"_seq_cst") GPR64sp:$Rn, SrcRHS),
(!cast<Instruction>(inst # "AL" # suffix) DstRHS, GPR64sp:$Rn)>;
}
multiclass LDOPregister_patterns_ord<string inst, string suffix, string op,
string size, dag RHS> {
defm : LDOPregister_patterns_ord_dag<inst, suffix, op, size, RHS, RHS>;
}
multiclass LDOPregister_patterns_ord_mod<string inst, string suffix, string op,
string size, dag LHS, dag RHS> {
defm : LDOPregister_patterns_ord_dag<inst, suffix, op, size, LHS, RHS>;
}
multiclass LDOPregister_patterns<string inst, string op> {
defm : LDOPregister_patterns_ord<inst, "X", op, "64", (i64 GPR64:$Rm)>;
defm : LDOPregister_patterns_ord<inst, "W", op, "32", (i32 GPR32:$Rm)>;
defm : LDOPregister_patterns_ord<inst, "H", op, "16", (i32 GPR32:$Rm)>;
defm : LDOPregister_patterns_ord<inst, "B", op, "8", (i32 GPR32:$Rm)>;
}
multiclass LDOPregister_patterns_mod<string inst, string op, string mod> {
defm : LDOPregister_patterns_ord_mod<inst, "X", op, "64",
(i64 GPR64:$Rm),
(i64 (!cast<Instruction>(mod#Xrr) XZR, GPR64:$Rm))>;
defm : LDOPregister_patterns_ord_mod<inst, "W", op, "32",
(i32 GPR32:$Rm),
(i32 (!cast<Instruction>(mod#Wrr) WZR, GPR32:$Rm))>;
defm : LDOPregister_patterns_ord_mod<inst, "H", op, "16",
(i32 GPR32:$Rm),
(i32 (!cast<Instruction>(mod#Wrr) WZR, GPR32:$Rm))>;
defm : LDOPregister_patterns_ord_mod<inst, "B", op, "8",
(i32 GPR32:$Rm),
(i32 (!cast<Instruction>(mod#Wrr) WZR, GPR32:$Rm))>;
}
let Predicates = [HasLSE] in
multiclass CASregister_patterns_ord_dag<string inst, string suffix, string op,
string size, dag OLD, dag NEW> {
def : Pat<(!cast<SDNode>(op#"_"#size#"_monotonic") GPR64sp:$Rn, OLD, NEW),
(!cast<Instruction>(inst # suffix) OLD, NEW, GPR64sp:$Rn)>;
def : Pat<(!cast<SDNode>(op#"_"#size#"_acquire") GPR64sp:$Rn, OLD, NEW),
(!cast<Instruction>(inst # "A" # suffix) OLD, NEW, GPR64sp:$Rn)>;
def : Pat<(!cast<SDNode>(op#"_"#size#"_release") GPR64sp:$Rn, OLD, NEW),
(!cast<Instruction>(inst # "L" # suffix) OLD, NEW, GPR64sp:$Rn)>;
def : Pat<(!cast<SDNode>(op#"_"#size#"_acq_rel") GPR64sp:$Rn, OLD, NEW),
(!cast<Instruction>(inst # "AL" # suffix) OLD, NEW, GPR64sp:$Rn)>;
def : Pat<(!cast<SDNode>(op#"_"#size#"_seq_cst") GPR64sp:$Rn, OLD, NEW),
(!cast<Instruction>(inst # "AL" # suffix) OLD, NEW, GPR64sp:$Rn)>;
}
multiclass CASregister_patterns_ord<string inst, string suffix, string op,
string size, dag OLD, dag NEW> {
defm : CASregister_patterns_ord_dag<inst, suffix, op, size, OLD, NEW>;
}
multiclass CASregister_patterns<string inst, string op> {
defm : CASregister_patterns_ord<inst, "X", op, "64",
(i64 GPR64:$Rold), (i64 GPR64:$Rnew)>;
defm : CASregister_patterns_ord<inst, "W", op, "32",
(i32 GPR32:$Rold), (i32 GPR32:$Rnew)>;
defm : CASregister_patterns_ord<inst, "H", op, "16",
(i32 GPR32:$Rold), (i32 GPR32:$Rnew)>;
defm : CASregister_patterns_ord<inst, "B", op, "8",
(i32 GPR32:$Rold), (i32 GPR32:$Rnew)>;
}
let Predicates = [HasLSE] in
class BaseSTOPregister<string asm, RegisterClass OP, Register Reg,
Instruction inst> :
InstAlias<asm # "\t$Rs, [$Rn]", (inst Reg, OP:$Rs, GPR64sp:$Rn)>;
multiclass STOPregister<string asm, string instr> {
def : BaseSTOPregister<asm # "lb", GPR32, WZR,
!cast<Instruction>(instr # "LB")>;
def : BaseSTOPregister<asm # "lh", GPR32, WZR,
!cast<Instruction>(instr # "LH")>;
def : BaseSTOPregister<asm # "l", GPR32, WZR,
!cast<Instruction>(instr # "LW")>;
def : BaseSTOPregister<asm # "l", GPR64, XZR,
!cast<Instruction>(instr # "LX")>;
def : BaseSTOPregister<asm # "b", GPR32, WZR,
!cast<Instruction>(instr # "B")>;
def : BaseSTOPregister<asm # "h", GPR32, WZR,
!cast<Instruction>(instr # "H")>;
def : BaseSTOPregister<asm, GPR32, WZR,
!cast<Instruction>(instr # "W")>;
def : BaseSTOPregister<asm, GPR64, XZR,
!cast<Instruction>(instr # "X")>;
}
//----------------------------------------------------------------------------
// Allow the size specifier tokens to be upper case, not just lower.
def : TokenAlias<".4B", ".4b">; // Add dot product
def : TokenAlias<".8B", ".8b">;
def : TokenAlias<".4H", ".4h">;
def : TokenAlias<".2S", ".2s">;
def : TokenAlias<".1D", ".1d">;
def : TokenAlias<".16B", ".16b">;
def : TokenAlias<".8H", ".8h">;
def : TokenAlias<".4S", ".4s">;
def : TokenAlias<".2D", ".2d">;
def : TokenAlias<".1Q", ".1q">;
def : TokenAlias<".2H", ".2h">;
def : TokenAlias<".B", ".b">;
def : TokenAlias<".H", ".h">;
def : TokenAlias<".S", ".s">;
def : TokenAlias<".D", ".d">;
def : TokenAlias<".Q", ".q">;