forked from OSchip/llvm-project
476 lines
19 KiB
TableGen
476 lines
19 KiB
TableGen
//===- HexagonInstrInfoVector.td - Hexagon Vector Patterns -*- tablegen -*-===//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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//
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// This file describes the Hexagon Vector instructions in TableGen format.
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//
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//===----------------------------------------------------------------------===//
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def V2I1: PatLeaf<(v2i1 PredRegs:$R)>;
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def V4I1: PatLeaf<(v4i1 PredRegs:$R)>;
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def V8I1: PatLeaf<(v8i1 PredRegs:$R)>;
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def V4I8: PatLeaf<(v4i8 IntRegs:$R)>;
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def V2I16: PatLeaf<(v2i16 IntRegs:$R)>;
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def V8I8: PatLeaf<(v8i8 DoubleRegs:$R)>;
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def V4I16: PatLeaf<(v4i16 DoubleRegs:$R)>;
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def V2I32: PatLeaf<(v2i32 DoubleRegs:$R)>;
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multiclass bitconvert_32<ValueType a, ValueType b> {
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def : Pat <(b (bitconvert (a IntRegs:$src))),
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(b IntRegs:$src)>;
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def : Pat <(a (bitconvert (b IntRegs:$src))),
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(a IntRegs:$src)>;
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}
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multiclass bitconvert_64<ValueType a, ValueType b> {
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def : Pat <(b (bitconvert (a DoubleRegs:$src))),
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(b DoubleRegs:$src)>;
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def : Pat <(a (bitconvert (b DoubleRegs:$src))),
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(a DoubleRegs:$src)>;
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}
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// Bit convert vector types to integers.
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defm : bitconvert_32<v4i8, i32>;
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defm : bitconvert_32<v2i16, i32>;
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defm : bitconvert_64<v8i8, i64>;
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defm : bitconvert_64<v4i16, i64>;
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defm : bitconvert_64<v2i32, i64>;
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// Vector shift support. Vector shifting in Hexagon is rather different
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// from internal representation of LLVM.
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// LLVM assumes all shifts (in vector case) will have the form
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// <VT> = SHL/SRA/SRL <VT> by <VT>
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// while Hexagon has the following format:
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// <VT> = SHL/SRA/SRL <VT> by <IT/i32>
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// As a result, special care is needed to guarantee correctness and
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// performance.
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class vshift_v4i16<SDNode Op, string Str, bits<3>MajOp, bits<3>MinOp>
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: S_2OpInstImm<Str, MajOp, MinOp, u4Imm,
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[(set (v4i16 DoubleRegs:$dst),
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(Op (v4i16 DoubleRegs:$src1), u4ImmPred:$src2))]> {
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bits<4> src2;
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let Inst{11-8} = src2;
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}
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class vshift_v2i32<SDNode Op, string Str, bits<3>MajOp, bits<3>MinOp>
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: S_2OpInstImm<Str, MajOp, MinOp, u5Imm,
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[(set (v2i32 DoubleRegs:$dst),
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(Op (v2i32 DoubleRegs:$src1), u5ImmPred:$src2))]> {
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bits<5> src2;
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let Inst{12-8} = src2;
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}
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def : Pat<(v2i16 (add (v2i16 IntRegs:$src1), (v2i16 IntRegs:$src2))),
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(A2_svaddh IntRegs:$src1, IntRegs:$src2)>;
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def : Pat<(v2i16 (sub (v2i16 IntRegs:$src1), (v2i16 IntRegs:$src2))),
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(A2_svsubh IntRegs:$src1, IntRegs:$src2)>;
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def S2_asr_i_vw : vshift_v2i32<sra, "vasrw", 0b010, 0b000>;
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def S2_lsr_i_vw : vshift_v2i32<srl, "vlsrw", 0b010, 0b001>;
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def S2_asl_i_vw : vshift_v2i32<shl, "vaslw", 0b010, 0b010>;
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def S2_asr_i_vh : vshift_v4i16<sra, "vasrh", 0b100, 0b000>;
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def S2_lsr_i_vh : vshift_v4i16<srl, "vlsrh", 0b100, 0b001>;
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def S2_asl_i_vh : vshift_v4i16<shl, "vaslh", 0b100, 0b010>;
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def HexagonVSPLATB: SDNode<"HexagonISD::VSPLATB", SDTUnaryOp>;
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def HexagonVSPLATH: SDNode<"HexagonISD::VSPLATH", SDTUnaryOp>;
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// Replicate the low 8-bits from 32-bits input register into each of the
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// four bytes of 32-bits destination register.
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def: Pat<(v4i8 (HexagonVSPLATB I32:$Rs)), (S2_vsplatrb I32:$Rs)>;
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// Replicate the low 16-bits from 32-bits input register into each of the
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// four halfwords of 64-bits destination register.
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def: Pat<(v4i16 (HexagonVSPLATH I32:$Rs)), (S2_vsplatrh I32:$Rs)>;
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class VArith_pat <InstHexagon MI, SDNode Op, PatFrag Type>
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: Pat <(Op Type:$Rss, Type:$Rtt),
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(MI Type:$Rss, Type:$Rtt)>;
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def: VArith_pat <A2_vaddub, add, V8I8>;
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def: VArith_pat <A2_vaddh, add, V4I16>;
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def: VArith_pat <A2_vaddw, add, V2I32>;
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def: VArith_pat <A2_vsubub, sub, V8I8>;
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def: VArith_pat <A2_vsubh, sub, V4I16>;
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def: VArith_pat <A2_vsubw, sub, V2I32>;
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def: VArith_pat <A2_and, and, V2I16>;
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def: VArith_pat <A2_xor, xor, V2I16>;
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def: VArith_pat <A2_or, or, V2I16>;
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def: VArith_pat <A2_andp, and, V8I8>;
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def: VArith_pat <A2_andp, and, V4I16>;
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def: VArith_pat <A2_andp, and, V2I32>;
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def: VArith_pat <A2_orp, or, V8I8>;
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def: VArith_pat <A2_orp, or, V4I16>;
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def: VArith_pat <A2_orp, or, V2I32>;
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def: VArith_pat <A2_xorp, xor, V8I8>;
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def: VArith_pat <A2_xorp, xor, V4I16>;
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def: VArith_pat <A2_xorp, xor, V2I32>;
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def: Pat<(v2i32 (sra V2I32:$b, (i64 (HexagonCOMBINE (i32 u5ImmPred:$c),
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(i32 u5ImmPred:$c))))),
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(S2_asr_i_vw V2I32:$b, imm:$c)>;
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def: Pat<(v2i32 (srl V2I32:$b, (i64 (HexagonCOMBINE (i32 u5ImmPred:$c),
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(i32 u5ImmPred:$c))))),
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(S2_lsr_i_vw V2I32:$b, imm:$c)>;
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def: Pat<(v2i32 (shl V2I32:$b, (i64 (HexagonCOMBINE (i32 u5ImmPred:$c),
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(i32 u5ImmPred:$c))))),
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(S2_asl_i_vw V2I32:$b, imm:$c)>;
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def: Pat<(v4i16 (sra V4I16:$b, (v4i16 (HexagonVSPLATH (i32 (u4ImmPred:$c)))))),
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(S2_asr_i_vh V4I16:$b, imm:$c)>;
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def: Pat<(v4i16 (srl V4I16:$b, (v4i16 (HexagonVSPLATH (i32 (u4ImmPred:$c)))))),
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(S2_lsr_i_vh V4I16:$b, imm:$c)>;
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def: Pat<(v4i16 (shl V4I16:$b, (v4i16 (HexagonVSPLATH (i32 (u4ImmPred:$c)))))),
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(S2_asl_i_vh V4I16:$b, imm:$c)>;
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def SDTHexagon_v2i32_v2i32_i32 : SDTypeProfile<1, 2,
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[SDTCisSameAs<0, 1>, SDTCisVT<0, v2i32>, SDTCisInt<2>]>;
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def SDTHexagon_v4i16_v4i16_i32 : SDTypeProfile<1, 2,
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[SDTCisSameAs<0, 1>, SDTCisVT<0, v4i16>, SDTCisInt<2>]>;
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def HexagonVSRAW: SDNode<"HexagonISD::VSRAW", SDTHexagon_v2i32_v2i32_i32>;
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def HexagonVSRAH: SDNode<"HexagonISD::VSRAH", SDTHexagon_v4i16_v4i16_i32>;
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def HexagonVSRLW: SDNode<"HexagonISD::VSRLW", SDTHexagon_v2i32_v2i32_i32>;
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def HexagonVSRLH: SDNode<"HexagonISD::VSRLH", SDTHexagon_v4i16_v4i16_i32>;
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def HexagonVSHLW: SDNode<"HexagonISD::VSHLW", SDTHexagon_v2i32_v2i32_i32>;
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def HexagonVSHLH: SDNode<"HexagonISD::VSHLH", SDTHexagon_v4i16_v4i16_i32>;
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def: Pat<(v2i32 (HexagonVSRAW V2I32:$Rs, u5ImmPred:$u5)),
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(S2_asr_i_vw V2I32:$Rs, imm:$u5)>;
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def: Pat<(v4i16 (HexagonVSRAH V4I16:$Rs, u4ImmPred:$u4)),
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(S2_asr_i_vh V4I16:$Rs, imm:$u4)>;
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def: Pat<(v2i32 (HexagonVSRLW V2I32:$Rs, u5ImmPred:$u5)),
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(S2_lsr_i_vw V2I32:$Rs, imm:$u5)>;
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def: Pat<(v4i16 (HexagonVSRLH V4I16:$Rs, u4ImmPred:$u4)),
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(S2_lsr_i_vh V4I16:$Rs, imm:$u4)>;
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def: Pat<(v2i32 (HexagonVSHLW V2I32:$Rs, u5ImmPred:$u5)),
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(S2_asl_i_vw V2I32:$Rs, imm:$u5)>;
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def: Pat<(v4i16 (HexagonVSHLH V4I16:$Rs, u4ImmPred:$u4)),
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(S2_asl_i_vh V4I16:$Rs, imm:$u4)>;
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// Vector shift words by register
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def S2_asr_r_vw : T_S3op_shiftVect < "vasrw", 0b00, 0b00>;
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def S2_lsr_r_vw : T_S3op_shiftVect < "vlsrw", 0b00, 0b01>;
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def S2_asl_r_vw : T_S3op_shiftVect < "vaslw", 0b00, 0b10>;
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def S2_lsl_r_vw : T_S3op_shiftVect < "vlslw", 0b00, 0b11>;
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// Vector shift halfwords by register
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def S2_asr_r_vh : T_S3op_shiftVect < "vasrh", 0b01, 0b00>;
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def S2_lsr_r_vh : T_S3op_shiftVect < "vlsrh", 0b01, 0b01>;
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def S2_asl_r_vh : T_S3op_shiftVect < "vaslh", 0b01, 0b10>;
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def S2_lsl_r_vh : T_S3op_shiftVect < "vlslh", 0b01, 0b11>;
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class vshift_rr_pat<InstHexagon MI, SDNode Op, PatFrag Value>
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: Pat <(Op Value:$Rs, I32:$Rt),
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(MI Value:$Rs, I32:$Rt)>;
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def: vshift_rr_pat <S2_asr_r_vw, HexagonVSRAW, V2I32>;
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def: vshift_rr_pat <S2_asr_r_vh, HexagonVSRAH, V4I16>;
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def: vshift_rr_pat <S2_lsr_r_vw, HexagonVSRLW, V2I32>;
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def: vshift_rr_pat <S2_lsr_r_vh, HexagonVSRLH, V4I16>;
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def: vshift_rr_pat <S2_asl_r_vw, HexagonVSHLW, V2I32>;
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def: vshift_rr_pat <S2_asl_r_vh, HexagonVSHLH, V4I16>;
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def SDTHexagonVecCompare_v8i8 : SDTypeProfile<1, 2,
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[SDTCisSameAs<1, 2>, SDTCisVT<0, i1>, SDTCisVT<1, v8i8>]>;
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def SDTHexagonVecCompare_v4i16 : SDTypeProfile<1, 2,
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[SDTCisSameAs<1, 2>, SDTCisVT<0, i1>, SDTCisVT<1, v4i16>]>;
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def SDTHexagonVecCompare_v2i32 : SDTypeProfile<1, 2,
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[SDTCisSameAs<1, 2>, SDTCisVT<0, i1>, SDTCisVT<1, v2i32>]>;
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def HexagonVCMPBEQ: SDNode<"HexagonISD::VCMPBEQ", SDTHexagonVecCompare_v8i8>;
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def HexagonVCMPBGT: SDNode<"HexagonISD::VCMPBGT", SDTHexagonVecCompare_v8i8>;
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def HexagonVCMPBGTU: SDNode<"HexagonISD::VCMPBGTU", SDTHexagonVecCompare_v8i8>;
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def HexagonVCMPHEQ: SDNode<"HexagonISD::VCMPHEQ", SDTHexagonVecCompare_v4i16>;
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def HexagonVCMPHGT: SDNode<"HexagonISD::VCMPHGT", SDTHexagonVecCompare_v4i16>;
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def HexagonVCMPHGTU: SDNode<"HexagonISD::VCMPHGTU", SDTHexagonVecCompare_v4i16>;
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def HexagonVCMPWEQ: SDNode<"HexagonISD::VCMPWEQ", SDTHexagonVecCompare_v2i32>;
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def HexagonVCMPWGT: SDNode<"HexagonISD::VCMPWGT", SDTHexagonVecCompare_v2i32>;
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def HexagonVCMPWGTU: SDNode<"HexagonISD::VCMPWGTU", SDTHexagonVecCompare_v2i32>;
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class vcmp_i1_pat<InstHexagon MI, SDNode Op, PatFrag Value>
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: Pat <(i1 (Op Value:$Rs, Value:$Rt)),
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(MI Value:$Rs, Value:$Rt)>;
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def: vcmp_i1_pat<A2_vcmpbeq, HexagonVCMPBEQ, V8I8>;
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def: vcmp_i1_pat<A4_vcmpbgt, HexagonVCMPBGT, V8I8>;
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def: vcmp_i1_pat<A2_vcmpbgtu, HexagonVCMPBGTU, V8I8>;
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def: vcmp_i1_pat<A2_vcmpheq, HexagonVCMPHEQ, V4I16>;
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def: vcmp_i1_pat<A2_vcmphgt, HexagonVCMPHGT, V4I16>;
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def: vcmp_i1_pat<A2_vcmphgtu, HexagonVCMPHGTU, V4I16>;
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def: vcmp_i1_pat<A2_vcmpweq, HexagonVCMPWEQ, V2I32>;
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def: vcmp_i1_pat<A2_vcmpwgt, HexagonVCMPWGT, V2I32>;
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def: vcmp_i1_pat<A2_vcmpwgtu, HexagonVCMPWGTU, V2I32>;
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class vcmp_vi1_pat<InstHexagon MI, PatFrag Op, PatFrag InVal, ValueType OutTy>
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: Pat <(OutTy (Op InVal:$Rs, InVal:$Rt)),
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(MI InVal:$Rs, InVal:$Rt)>;
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def: vcmp_vi1_pat<A2_vcmpweq, seteq, V2I32, v2i1>;
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def: vcmp_vi1_pat<A2_vcmpwgt, setgt, V2I32, v2i1>;
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def: vcmp_vi1_pat<A2_vcmpwgtu, setugt, V2I32, v2i1>;
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def: vcmp_vi1_pat<A2_vcmpheq, seteq, V4I16, v4i1>;
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def: vcmp_vi1_pat<A2_vcmphgt, setgt, V4I16, v4i1>;
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def: vcmp_vi1_pat<A2_vcmphgtu, setugt, V4I16, v4i1>;
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// Hexagon doesn't have a vector multiply with C semantics.
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// Instead, generate a pseudo instruction that gets expaneded into two
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// scalar MPYI instructions.
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// This is expanded by ExpandPostRAPseudos.
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let isPseudo = 1 in
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def PS_vmulw : PseudoM<(outs DoubleRegs:$Rd),
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(ins DoubleRegs:$Rs, DoubleRegs:$Rt), "",
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[(set V2I32:$Rd, (mul V2I32:$Rs, V2I32:$Rt))]>;
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let isPseudo = 1 in
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def PS_vmulw_acc : PseudoM<(outs DoubleRegs:$Rd),
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(ins DoubleRegs:$Rx, DoubleRegs:$Rs, DoubleRegs:$Rt), "",
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[(set V2I32:$Rd, (add V2I32:$Rx, (mul V2I32:$Rs, V2I32:$Rt)))],
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"$Rd = $Rx">;
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// Adds two v4i8: Hexagon does not have an insn for this one, so we
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// use the double add v8i8, and use only the low part of the result.
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def: Pat<(v4i8 (add (v4i8 IntRegs:$Rs), (v4i8 IntRegs:$Rt))),
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(LoReg (A2_vaddub (Zext64 $Rs), (Zext64 $Rt)))>;
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// Subtract two v4i8: Hexagon does not have an insn for this one, so we
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// use the double sub v8i8, and use only the low part of the result.
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def: Pat<(v4i8 (sub (v4i8 IntRegs:$Rs), (v4i8 IntRegs:$Rt))),
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(LoReg (A2_vsubub (Zext64 $Rs), (Zext64 $Rt)))>;
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//
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// No 32 bit vector mux.
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//
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def: Pat<(v4i8 (select I1:$Pu, V4I8:$Rs, V4I8:$Rt)),
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(LoReg (C2_vmux I1:$Pu, (Zext64 $Rs), (Zext64 $Rt)))>;
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def: Pat<(v2i16 (select I1:$Pu, V2I16:$Rs, V2I16:$Rt)),
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(LoReg (C2_vmux I1:$Pu, (Zext64 $Rs), (Zext64 $Rt)))>;
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//
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// 64-bit vector mux.
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//
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def: Pat<(v8i8 (vselect V8I1:$Pu, V8I8:$Rs, V8I8:$Rt)),
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(C2_vmux V8I1:$Pu, V8I8:$Rs, V8I8:$Rt)>;
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def: Pat<(v4i16 (vselect V4I1:$Pu, V4I16:$Rs, V4I16:$Rt)),
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(C2_vmux V4I1:$Pu, V4I16:$Rs, V4I16:$Rt)>;
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def: Pat<(v2i32 (vselect V2I1:$Pu, V2I32:$Rs, V2I32:$Rt)),
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(C2_vmux V2I1:$Pu, V2I32:$Rs, V2I32:$Rt)>;
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//
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// No 32 bit vector compare.
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//
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def: Pat<(i1 (seteq V4I8:$Rs, V4I8:$Rt)),
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(A2_vcmpbeq (Zext64 $Rs), (Zext64 $Rt))>;
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def: Pat<(i1 (setgt V4I8:$Rs, V4I8:$Rt)),
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(A4_vcmpbgt (Zext64 $Rs), (Zext64 $Rt))>;
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def: Pat<(i1 (setugt V4I8:$Rs, V4I8:$Rt)),
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(A2_vcmpbgtu (Zext64 $Rs), (Zext64 $Rt))>;
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def: Pat<(i1 (seteq V2I16:$Rs, V2I16:$Rt)),
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(A2_vcmpheq (Zext64 $Rs), (Zext64 $Rt))>;
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def: Pat<(i1 (setgt V2I16:$Rs, V2I16:$Rt)),
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(A2_vcmphgt (Zext64 $Rs), (Zext64 $Rt))>;
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def: Pat<(i1 (setugt V2I16:$Rs, V2I16:$Rt)),
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(A2_vcmphgtu (Zext64 $Rs), (Zext64 $Rt))>;
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class InvertCmp_pat<InstHexagon InvMI, PatFrag CmpOp, PatFrag Value,
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ValueType CmpTy>
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: Pat<(CmpTy (CmpOp Value:$Rs, Value:$Rt)),
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(InvMI Value:$Rt, Value:$Rs)>;
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// Map from a compare operation to the corresponding instruction with the
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// order of operands reversed, e.g. x > y --> cmp.lt(y,x).
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def: InvertCmp_pat<A4_vcmpbgt, setlt, V8I8, i1>;
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def: InvertCmp_pat<A4_vcmpbgt, setlt, V8I8, v8i1>;
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def: InvertCmp_pat<A2_vcmphgt, setlt, V4I16, i1>;
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def: InvertCmp_pat<A2_vcmphgt, setlt, V4I16, v4i1>;
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def: InvertCmp_pat<A2_vcmpwgt, setlt, V2I32, i1>;
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def: InvertCmp_pat<A2_vcmpwgt, setlt, V2I32, v2i1>;
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def: InvertCmp_pat<A2_vcmpbgtu, setult, V8I8, i1>;
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def: InvertCmp_pat<A2_vcmpbgtu, setult, V8I8, v8i1>;
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def: InvertCmp_pat<A2_vcmphgtu, setult, V4I16, i1>;
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def: InvertCmp_pat<A2_vcmphgtu, setult, V4I16, v4i1>;
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def: InvertCmp_pat<A2_vcmpwgtu, setult, V2I32, i1>;
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def: InvertCmp_pat<A2_vcmpwgtu, setult, V2I32, v2i1>;
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// Map from vcmpne(Rss) -> !vcmpew(Rss).
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// rs != rt -> !(rs == rt).
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def: Pat<(v2i1 (setne V2I32:$Rs, V2I32:$Rt)),
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(C2_not (v2i1 (A2_vcmpbeq V2I32:$Rs, V2I32:$Rt)))>;
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// Truncate: from vector B copy all 'E'ven 'B'yte elements:
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// A[0] = B[0]; A[1] = B[2]; A[2] = B[4]; A[3] = B[6];
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def: Pat<(v4i8 (trunc V4I16:$Rs)),
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(S2_vtrunehb V4I16:$Rs)>;
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// Truncate: from vector B copy all 'O'dd 'B'yte elements:
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// A[0] = B[1]; A[1] = B[3]; A[2] = B[5]; A[3] = B[7];
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// S2_vtrunohb
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// Truncate: from vectors B and C copy all 'E'ven 'H'alf-word elements:
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// A[0] = B[0]; A[1] = B[2]; A[2] = C[0]; A[3] = C[2];
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// S2_vtruneh
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def: Pat<(v2i16 (trunc V2I32:$Rs)),
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(LoReg (S2_packhl (HiReg $Rs), (LoReg $Rs)))>;
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def HexagonVSXTBH : SDNode<"HexagonISD::VSXTBH", SDTUnaryOp>;
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def HexagonVSXTBW : SDNode<"HexagonISD::VSXTBW", SDTUnaryOp>;
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def: Pat<(i64 (HexagonVSXTBH I32:$Rs)), (S2_vsxtbh I32:$Rs)>;
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def: Pat<(i64 (HexagonVSXTBW I32:$Rs)), (S2_vsxthw I32:$Rs)>;
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def: Pat<(v4i16 (zext V4I8:$Rs)), (S2_vzxtbh V4I8:$Rs)>;
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def: Pat<(v2i32 (zext V2I16:$Rs)), (S2_vzxthw V2I16:$Rs)>;
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def: Pat<(v4i16 (anyext V4I8:$Rs)), (S2_vzxtbh V4I8:$Rs)>;
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def: Pat<(v2i32 (anyext V2I16:$Rs)), (S2_vzxthw V2I16:$Rs)>;
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def: Pat<(v4i16 (sext V4I8:$Rs)), (S2_vsxtbh V4I8:$Rs)>;
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def: Pat<(v2i32 (sext V2I16:$Rs)), (S2_vsxthw V2I16:$Rs)>;
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// Sign extends a v2i8 into a v2i32.
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def: Pat<(v2i32 (sext_inreg V2I32:$Rs, v2i8)),
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(A2_combinew (A2_sxtb (HiReg $Rs)), (A2_sxtb (LoReg $Rs)))>;
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// Sign extends a v2i16 into a v2i32.
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def: Pat<(v2i32 (sext_inreg V2I32:$Rs, v2i16)),
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(A2_combinew (A2_sxth (HiReg $Rs)), (A2_sxth (LoReg $Rs)))>;
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// Multiplies two v2i16 and returns a v2i32. We are using here the
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// saturating multiply, as hexagon does not provide a non saturating
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// vector multiply, and saturation does not impact the result that is
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// in double precision of the operands.
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// Multiplies two v2i16 vectors: as Hexagon does not have a multiply
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// with the C semantics for this one, this pattern uses the half word
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// multiply vmpyh that takes two v2i16 and returns a v2i32. This is
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// then truncated to fit this back into a v2i16 and to simulate the
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// wrap around semantics for unsigned in C.
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def vmpyh: OutPatFrag<(ops node:$Rs, node:$Rt),
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(M2_vmpy2s_s0 (i32 $Rs), (i32 $Rt))>;
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def: Pat<(v2i16 (mul V2I16:$Rs, V2I16:$Rt)),
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(LoReg (S2_vtrunewh (v2i32 (A2_combineii 0, 0)),
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(v2i32 (vmpyh V2I16:$Rs, V2I16:$Rt))))>;
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// Multiplies two v4i16 vectors.
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def: Pat<(v4i16 (mul V4I16:$Rs, V4I16:$Rt)),
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(S2_vtrunewh (vmpyh (HiReg $Rs), (HiReg $Rt)),
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(vmpyh (LoReg $Rs), (LoReg $Rt)))>;
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def VMPYB_no_V5: OutPatFrag<(ops node:$Rs, node:$Rt),
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(S2_vtrunewh (vmpyh (HiReg (S2_vsxtbh $Rs)), (HiReg (S2_vsxtbh $Rt))),
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(vmpyh (LoReg (S2_vsxtbh $Rs)), (LoReg (S2_vsxtbh $Rt))))>;
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// Multiplies two v4i8 vectors.
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def: Pat<(v4i8 (mul V4I8:$Rs, V4I8:$Rt)),
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(S2_vtrunehb (M5_vmpybsu V4I8:$Rs, V4I8:$Rt))>,
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Requires<[HasV5T]>;
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def: Pat<(v4i8 (mul V4I8:$Rs, V4I8:$Rt)),
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(S2_vtrunehb (VMPYB_no_V5 V4I8:$Rs, V4I8:$Rt))>;
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// Multiplies two v8i8 vectors.
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def: Pat<(v8i8 (mul V8I8:$Rs, V8I8:$Rt)),
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(A2_combinew (S2_vtrunehb (M5_vmpybsu (HiReg $Rs), (HiReg $Rt))),
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(S2_vtrunehb (M5_vmpybsu (LoReg $Rs), (LoReg $Rt))))>,
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Requires<[HasV5T]>;
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def: Pat<(v8i8 (mul V8I8:$Rs, V8I8:$Rt)),
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(A2_combinew (S2_vtrunehb (VMPYB_no_V5 (HiReg $Rs), (HiReg $Rt))),
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(S2_vtrunehb (VMPYB_no_V5 (LoReg $Rs), (LoReg $Rt))))>;
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class shuffler<SDNode Op, string Str>
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: SInst<(outs DoubleRegs:$a), (ins DoubleRegs:$b, DoubleRegs:$c),
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"$a = " # Str # "($b, $c)",
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[(set (i64 DoubleRegs:$a),
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(i64 (Op (i64 DoubleRegs:$b), (i64 DoubleRegs:$c))))],
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"", S_3op_tc_1_SLOT23>;
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def SDTHexagonBinOp64 : SDTypeProfile<1, 2,
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[SDTCisSameAs<0, 1>, SDTCisSameAs<0, 2>, SDTCisVT<0, i64>]>;
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def HexagonSHUFFEB: SDNode<"HexagonISD::SHUFFEB", SDTHexagonBinOp64>;
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def HexagonSHUFFEH: SDNode<"HexagonISD::SHUFFEH", SDTHexagonBinOp64>;
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def HexagonSHUFFOB: SDNode<"HexagonISD::SHUFFOB", SDTHexagonBinOp64>;
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def HexagonSHUFFOH: SDNode<"HexagonISD::SHUFFOH", SDTHexagonBinOp64>;
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class ShufflePat<InstHexagon MI, SDNode Op>
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: Pat<(i64 (Op DoubleRegs:$src1, DoubleRegs:$src2)),
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(i64 (MI DoubleRegs:$src1, DoubleRegs:$src2))>;
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// Shuffles even bytes for i=0..3: A[2*i].b = C[2*i].b; A[2*i+1].b = B[2*i].b
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def: ShufflePat<S2_shuffeb, HexagonSHUFFEB>;
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// Shuffles odd bytes for i=0..3: A[2*i].b = C[2*i+1].b; A[2*i+1].b = B[2*i+1].b
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def: ShufflePat<S2_shuffob, HexagonSHUFFOB>;
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// Shuffles even half for i=0,1: A[2*i].h = C[2*i].h; A[2*i+1].h = B[2*i].h
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def: ShufflePat<S2_shuffeh, HexagonSHUFFEH>;
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// Shuffles odd half for i=0,1: A[2*i].h = C[2*i+1].h; A[2*i+1].h = B[2*i+1].h
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def: ShufflePat<S2_shuffoh, HexagonSHUFFOH>;
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// Truncated store from v4i16 to v4i8.
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def truncstorev4i8: PatFrag<(ops node:$val, node:$ptr),
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(truncstore node:$val, node:$ptr),
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[{ return cast<StoreSDNode>(N)->getMemoryVT() == MVT::v4i8; }]>;
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// Truncated store from v2i32 to v2i16.
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def truncstorev2i16: PatFrag<(ops node:$val, node:$ptr),
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(truncstore node:$val, node:$ptr),
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[{ return cast<StoreSDNode>(N)->getMemoryVT() == MVT::v2i16; }]>;
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def: Pat<(truncstorev2i16 V2I32:$Rs, I32:$Rt),
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(S2_storeri_io I32:$Rt, 0, (LoReg (S2_packhl (HiReg $Rs),
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(LoReg $Rs))))>;
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def: Pat<(truncstorev4i8 V4I16:$Rs, I32:$Rt),
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(S2_storeri_io I32:$Rt, 0, (S2_vtrunehb V4I16:$Rs))>;
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// Zero and sign extended load from v2i8 into v2i16.
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def zextloadv2i8: PatFrag<(ops node:$ptr), (zextload node:$ptr),
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[{ return cast<LoadSDNode>(N)->getMemoryVT() == MVT::v2i8; }]>;
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def sextloadv2i8: PatFrag<(ops node:$ptr), (sextload node:$ptr),
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[{ return cast<LoadSDNode>(N)->getMemoryVT() == MVT::v2i8; }]>;
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def: Pat<(v2i16 (zextloadv2i8 I32:$Rs)),
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(LoReg (v4i16 (S2_vzxtbh (L2_loadruh_io I32:$Rs, 0))))>;
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def: Pat<(v2i16 (sextloadv2i8 I32:$Rs)),
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(LoReg (v4i16 (S2_vsxtbh (L2_loadrh_io I32:$Rs, 0))))>;
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def: Pat<(v2i32 (zextloadv2i8 I32:$Rs)),
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(S2_vzxthw (LoReg (v4i16 (S2_vzxtbh (L2_loadruh_io I32:$Rs, 0)))))>;
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def: Pat<(v2i32 (sextloadv2i8 I32:$Rs)),
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(S2_vsxthw (LoReg (v4i16 (S2_vsxtbh (L2_loadrh_io I32:$Rs, 0)))))>;
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