diff --git a/llvm/lib/Target/AArch64/AArch64ISelLowering.h b/llvm/lib/Target/AArch64/AArch64ISelLowering.h --- a/llvm/lib/Target/AArch64/AArch64ISelLowering.h +++ b/llvm/lib/Target/AArch64/AArch64ISelLowering.h @@ -53,6 +53,8 @@ SBC, // adc, sbc instructions // Arithmetic instructions + ADD_PRED, + FADD_PRED, SDIV_PRED, UDIV_PRED, SMIN_PRED, diff --git a/llvm/lib/Target/AArch64/AArch64ISelLowering.cpp b/llvm/lib/Target/AArch64/AArch64ISelLowering.cpp --- a/llvm/lib/Target/AArch64/AArch64ISelLowering.cpp +++ b/llvm/lib/Target/AArch64/AArch64ISelLowering.cpp @@ -1038,13 +1038,10 @@ setOperationAction(ISD::EXTRACT_SUBVECTOR, VT, Custom); // Lower fixed length vector operations to scalable equivalents. + setOperationAction(ISD::ADD, VT, Custom); + setOperationAction(ISD::FADD, VT, Custom); setOperationAction(ISD::LOAD, VT, Custom); setOperationAction(ISD::STORE, VT, Custom); - - // NOTE: This is a temporary measure to maintain functionality required by - // Analysis/CostModel/AArch64/sve-fixed-length.ll - setOperationAction(ISD::ADD, VT, Legal); - setOperationAction(ISD::FADD, VT, Legal); } void AArch64TargetLowering::addDRTypeForNEON(MVT VT) { @@ -1351,6 +1348,7 @@ case AArch64ISD::CSINC: return "AArch64ISD::CSINC"; case AArch64ISD::THREAD_POINTER: return "AArch64ISD::THREAD_POINTER"; case AArch64ISD::TLSDESC_CALLSEQ: return "AArch64ISD::TLSDESC_CALLSEQ"; + case AArch64ISD::ADD_PRED: return "AArch64ISD::ADD_PRED"; case AArch64ISD::SDIV_PRED: return "AArch64ISD::SDIV_PRED"; case AArch64ISD::UDIV_PRED: return "AArch64ISD::UDIV_PRED"; case AArch64ISD::SMIN_PRED: return "AArch64ISD::SMIN_PRED"; @@ -1444,6 +1442,7 @@ case AArch64ISD::REV: return "AArch64ISD::REV"; case AArch64ISD::REINTERPRET_CAST: return "AArch64ISD::REINTERPRET_CAST"; case AArch64ISD::TBL: return "AArch64ISD::TBL"; + case AArch64ISD::FADD_PRED: return "AArch64ISD::FADD_PRED"; case AArch64ISD::FADDA_PRED: return "AArch64ISD::FADDA_PRED"; case AArch64ISD::FADDV_PRED: return "AArch64ISD::FADDV_PRED"; case AArch64ISD::FMAXV_PRED: return "AArch64ISD::FMAXV_PRED"; @@ -3422,6 +3421,8 @@ case ISD::UMULO: return LowerXALUO(Op, DAG); case ISD::FADD: + if (useSVEForFixedLengthVectorVT(Op.getValueType())) + return LowerToPredicatedOp(Op, DAG, AArch64ISD::FADD_PRED); return LowerF128Call(Op, DAG, RTLIB::ADD_F128); case ISD::FSUB: return LowerF128Call(Op, DAG, RTLIB::SUB_F128); @@ -3524,7 +3525,11 @@ case ISD::LOAD: if (useSVEForFixedLengthVectorVT(Op.getValueType())) return LowerFixedLengthVectorLoadToSVE(Op, DAG); - llvm_unreachable("Unexpected Load."); + llvm_unreachable("Unexpected request to lower ISD::LOAD"); + case ISD::ADD: + if (useSVEForFixedLengthVectorVT(Op.getValueType())) + return LowerToPredicatedOp(Op, DAG, AArch64ISD::ADD_PRED); + llvm_unreachable("Unexpected request to lower ISD::ADD"); } } @@ -7850,24 +7855,6 @@ return DAG.getNode(ISD::BITCAST, DL, VT, TBL); } -SDValue AArch64TargetLowering::LowerToPredicatedOp(SDValue Op, - SelectionDAG &DAG, - unsigned NewOp) const { - EVT VT = Op.getValueType(); - SDLoc DL(Op); - - assert(Op.getOperand(0).getValueType().isScalableVector() && - Op.getOperand(1).getValueType().isScalableVector() && - "Only scalable vectors are supported"); - - auto PredTy = - VT.getVectorVT(*DAG.getContext(), MVT::i1, VT.getVectorElementCount()); - SDValue Mask = getPTrue(DAG, DL, PredTy, AArch64SVEPredPattern::all); - - SmallVector Operands = {Mask}; - Operands.append(Op->op_begin(), Op->op_end()); - return DAG.getNode(NewOp, DL, VT, Operands); -} static bool resolveBuildVector(BuildVectorSDNode *BVN, APInt &CnstBits, APInt &UndefBits) { @@ -14794,6 +14781,21 @@ DAG.getTargetConstant(PgPattern, DL, MVT::i64)); } +static SDValue getPredicateForScalableVector(SelectionDAG &DAG, SDLoc &DL, + EVT VT) { + assert(VT.isScalableVector() && DAG.getTargetLoweringInfo().isTypeLegal(VT) && + "Expected legal scalable vector!"); + auto PredTy = VT.changeVectorElementType(MVT::i1); + return getPTrue(DAG, DL, PredTy, AArch64SVEPredPattern::all); +} + +static SDValue getPredicateForVector(SelectionDAG &DAG, SDLoc &DL, EVT VT) { + if (VT.isFixedLengthVector()) + return getPredicateForFixedLengthVector(DAG, DL, VT); + + return getPredicateForScalableVector(DAG, DL, VT); +} + // Grow V to consume an entire SVE register. static SDValue convertToScalableVector(SelectionDAG &DAG, EVT VT, SDValue V) { assert(VT.isScalableVector() && @@ -14852,3 +14854,47 @@ Store->getMemOperand(), Store->getAddressingMode(), Store->isTruncatingStore()); } + +SDValue AArch64TargetLowering::LowerToPredicatedOp(SDValue Op, + SelectionDAG &DAG, + unsigned NewOp) const { + EVT VT = Op.getValueType(); + SDLoc DL(Op); + auto Pg = getPredicateForVector(DAG, DL, VT); + + if (useSVEForFixedLengthVectorVT(VT)) { + EVT ContainerVT = getContainerForFixedLengthVector(DAG, VT); + + // Create list of operands by convereting existing ones to scalable types. + SmallVector Operands = {Pg}; + for (const SDValue &V : Op->op_values()) { + if (isa(V)) { + Operands.push_back(V); + continue; + } + + assert(useSVEForFixedLengthVectorVT(V.getValueType()) && + "Only fixed length vectors are supported!"); + Operands.push_back(convertToScalableVector(DAG, ContainerVT, V)); + } + + auto ScalableRes = DAG.getNode(NewOp, DL, ContainerVT, Operands); + return convertFromScalableVector(DAG, VT, ScalableRes); + } + + assert(VT.isScalableVector() && "Only expect to lower scalable vector op!"); + + SmallVector Operands = {Pg}; + for (const SDValue &V : Op->op_values()) { + if (isa(V)) { + Operands.push_back(V); + continue; + } + + assert(V.getValueType().isScalableVector() && + "Only scalable vectors are supported!"); + Operands.push_back(V); + } + + return DAG.getNode(NewOp, DL, VT, Operands); +} diff --git a/llvm/lib/Target/AArch64/AArch64SVEInstrInfo.td b/llvm/lib/Target/AArch64/AArch64SVEInstrInfo.td --- a/llvm/lib/Target/AArch64/AArch64SVEInstrInfo.td +++ b/llvm/lib/Target/AArch64/AArch64SVEInstrInfo.td @@ -152,6 +152,8 @@ SDTCVecEltisVT<1,i1>, SDTCisSameAs<2,3> ]>; +def AArch64add_pred : SDNode<"AArch64ISD::ADD_PRED", SDT_AArch64Arith>; +def AArch64fadd_pred : SDNode<"AArch64ISD::FADD_PRED", SDT_AArch64Arith>; def AArch64sdiv_pred : SDNode<"AArch64ISD::SDIV_PRED", SDT_AArch64Arith>; def AArch64udiv_pred : SDNode<"AArch64ISD::UDIV_PRED", SDT_AArch64Arith>; def AArch64smin_pred : SDNode<"AArch64ISD::SMIN_PRED", SDT_AArch64Arith>; @@ -204,7 +206,7 @@ defm SUB_ZPmZ : sve_int_bin_pred_arit_0<0b001, "sub", "SUB_ZPZZ", int_aarch64_sve_sub, DestructiveBinaryCommWithRev, "SUBR_ZPmZ", 1>; defm SUBR_ZPmZ : sve_int_bin_pred_arit_0<0b011, "subr", "SUBR_ZPZZ", int_aarch64_sve_subr, DestructiveBinaryCommWithRev, "SUB_ZPmZ", 0>; - defm ADD_ZPZZ : sve_int_bin_pred_zx; + defm ADD_ZPZZ : sve_int_bin_pred_zx; defm SUB_ZPZZ : sve_int_bin_pred_zx; defm SUBR_ZPZZ : sve_int_bin_pred_zx; @@ -322,7 +324,7 @@ defm FDIVR_ZPmZ : sve_fp_2op_p_zds<0b1100, "fdivr", "FDIVR_ZPZZ", int_aarch64_sve_fdivr, DestructiveBinaryCommWithRev, "FDIV_ZPmZ", 0>; defm FDIV_ZPmZ : sve_fp_2op_p_zds<0b1101, "fdiv", "FDIV_ZPZZ", int_aarch64_sve_fdiv, DestructiveBinaryCommWithRev, "FDIVR_ZPmZ", 1>; - defm FADD_ZPZZ : sve_fp_2op_p_zds_zx; + defm FADD_ZPZZ : sve_fp_2op_p_zds_zx; defm FSUB_ZPZZ : sve_fp_2op_p_zds_zx; defm FMUL_ZPZZ : sve_fp_2op_p_zds_zx; defm FSUBR_ZPZZ : sve_fp_2op_p_zds_zx; diff --git a/llvm/lib/Target/AArch64/AArch64TargetTransformInfo.cpp b/llvm/lib/Target/AArch64/AArch64TargetTransformInfo.cpp --- a/llvm/lib/Target/AArch64/AArch64TargetTransformInfo.cpp +++ b/llvm/lib/Target/AArch64/AArch64TargetTransformInfo.cpp @@ -601,6 +601,16 @@ // These nodes are marked as 'custom' for combining purposes only. // We know that they are legal. See LowerAdd in ISelLowering. return (Cost + 1) * LT.first; + + case ISD::FADD: + // These nodes are marked as 'custom' just to lowering them to SVE. + // We know said lowering will incur no additional cost. + if (isa(Ty) && !Ty->getScalarType()->isFP128Ty()) + return (Cost + 2) * LT.first; + + return Cost + BaseT::getArithmeticInstrCost(Opcode, Ty, CostKind, Opd1Info, + Opd2Info, + Opd1PropInfo, Opd2PropInfo); } } diff --git a/llvm/lib/Target/AArch64/SVEInstrFormats.td b/llvm/lib/Target/AArch64/SVEInstrFormats.td --- a/llvm/lib/Target/AArch64/SVEInstrFormats.td +++ b/llvm/lib/Target/AArch64/SVEInstrFormats.td @@ -1598,14 +1598,23 @@ def : SVE_3_Op_Pat(NAME # _D)>; } -multiclass sve_fp_2op_p_zds_zx { +multiclass sve_fp_2op_p_zds_zx { + def _UNDEF_H : PredTwoOpPseudo; + def _UNDEF_S : PredTwoOpPseudo; + def _UNDEF_D : PredTwoOpPseudo; + def _ZERO_H : PredTwoOpPseudo; def _ZERO_S : PredTwoOpPseudo; def _ZERO_D : PredTwoOpPseudo; - def : SVE_3_Op_Pat_SelZero(NAME # _ZERO_H)>; - def : SVE_3_Op_Pat_SelZero(NAME # _ZERO_S)>; - def : SVE_3_Op_Pat_SelZero(NAME # _ZERO_D)>; + def : SVE_3_Op_Pat(NAME # _UNDEF_H)>; + def : SVE_3_Op_Pat(NAME # _UNDEF_S)>; + def : SVE_3_Op_Pat(NAME # _UNDEF_D)>; + + def : SVE_3_Op_Pat_SelZero(NAME # _ZERO_H)>; + def : SVE_3_Op_Pat_SelZero(NAME # _ZERO_S)>; + def : SVE_3_Op_Pat_SelZero(NAME # _ZERO_D)>; } class sve_fp_ftmad sz, string asm, ZPRRegOp zprty> @@ -4859,16 +4868,27 @@ def : SVE_3_Op_Pat(NAME # _D)>; } -multiclass sve_int_bin_pred_zx { +multiclass sve_int_bin_pred_zx { + def _UNDEF_B : PredTwoOpPseudo; + def _UNDEF_H : PredTwoOpPseudo; + def _UNDEF_S : PredTwoOpPseudo; + def _UNDEF_D : PredTwoOpPseudo; + def _ZERO_B : PredTwoOpPseudo; def _ZERO_H : PredTwoOpPseudo; def _ZERO_S : PredTwoOpPseudo; def _ZERO_D : PredTwoOpPseudo; - def : SVE_3_Op_Pat_SelZero(NAME # _ZERO_B)>; - def : SVE_3_Op_Pat_SelZero(NAME # _ZERO_H)>; - def : SVE_3_Op_Pat_SelZero(NAME # _ZERO_S)>; - def : SVE_3_Op_Pat_SelZero(NAME # _ZERO_D)>; + def : SVE_3_Op_Pat(NAME # _UNDEF_B)>; + def : SVE_3_Op_Pat(NAME # _UNDEF_H)>; + def : SVE_3_Op_Pat(NAME # _UNDEF_S)>; + def : SVE_3_Op_Pat(NAME # _UNDEF_D)>; + + def : SVE_3_Op_Pat_SelZero(NAME # _ZERO_B)>; + def : SVE_3_Op_Pat_SelZero(NAME # _ZERO_H)>; + def : SVE_3_Op_Pat_SelZero(NAME # _ZERO_S)>; + def : SVE_3_Op_Pat_SelZero(NAME # _ZERO_D)>; } multiclass sve_int_bin_pred_shift_wide opc, string asm, diff --git a/llvm/test/CodeGen/AArch64/sve-fixed-length-fp-arith.ll b/llvm/test/CodeGen/AArch64/sve-fixed-length-fp-arith.ll new file mode 100644 --- /dev/null +++ b/llvm/test/CodeGen/AArch64/sve-fixed-length-fp-arith.ll @@ -0,0 +1,300 @@ +; RUN: llc -aarch64-sve-vector-bits-min=128 < %s | FileCheck %s -D#VBYTES=16 -check-prefix=NO_SVE +; RUN: llc -aarch64-sve-vector-bits-min=256 < %s | FileCheck %s -D#VBYTES=32 -check-prefixes=CHECK,VBITS_LE_1024,VBITS_LE_512,VBITS_LE_256 +; RUN: llc -aarch64-sve-vector-bits-min=384 < %s | FileCheck %s -D#VBYTES=32 -check-prefixes=CHECK,VBITS_LE_1024,VBITS_LE_512,VBITS_LE_256 +; RUN: llc -aarch64-sve-vector-bits-min=512 < %s | FileCheck %s -D#VBYTES=64 -check-prefixes=CHECK,VBITS_LE_1024,VBITS_LE_512 +; RUN: llc -aarch64-sve-vector-bits-min=640 < %s | FileCheck %s -D#VBYTES=64 -check-prefixes=CHECK,VBITS_LE_1024,VBITS_LE_512 +; RUN: llc -aarch64-sve-vector-bits-min=768 < %s | FileCheck %s -D#VBYTES=64 -check-prefixes=CHECK,VBITS_LE_1024,VBITS_LE_512 +; RUN: llc -aarch64-sve-vector-bits-min=896 < %s | FileCheck %s -D#VBYTES=64 -check-prefixes=CHECK,VBITS_LE_1024,VBITS_LE_512 +; RUN: llc -aarch64-sve-vector-bits-min=1024 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=1152 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=1280 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=1408 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=1536 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=1664 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=1792 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=1920 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=2048 < %s | FileCheck %s -D#VBYTES=256 -check-prefixes=CHECK + +; VBYTES represents the useful byte size of a vector register from the code +; generator's point of view. It is clamped to power-of-2 values because +; only power-of-2 vector lengths are considered legal, regardless of the +; user specified vector length. + +target triple = "aarch64-unknown-linux-gnu" + +; Don't use SVE when its registers are no bigger than NEON. +; NO_SVE-NOT: ptrue + +; Don't use SVE for 64-bit vectors. +define <4 x half> @fadd_v4f16(<4 x half> %op1, <4 x half> %op2) #0 { +; CHECK-LABEL: @fadd_v4f16 +; CHECK: fadd v0.4h, v0.4h, v1.4h +; CHECK: ret + %res = fadd <4 x half> %op1, %op2 + ret <4 x half> %res +} + +; Don't use SVE for 128-bit vectors. +define <8 x half> @fadd_v8f16(<8 x half> %op1, <8 x half> %op2) #0 { +; CHECK-LABEL: @fadd_v8f16 +; CHECK: fadd v0.8h, v0.8h, v1.8h +; CHECK: ret + %res = fadd <8 x half> %op1, %op2 + ret <8 x half> %res +} + +define void @fadd_v16f16(<16 x half>* %a, <16 x half>* %b) #0 { +; CHECK-LABEL: @fadd_v16f16 +; CHECK: ptrue [[PG:p[0-9]+]].h, vl[[#min(div(VBYTES,2),16)]] +; CHECK-DAG: ld1h { [[OP1:z[0-9]+]].h }, [[PG]]/z, [x0] +; CHECK-DAG: ld1h { [[OP2:z[0-9]+]].h }, [[PG]]/z, [x1] +; CHECK: fadd [[RES:z[0-9]+]].h, [[PG]]/m, [[OP1]].h, [[OP2]].h +; CHECK: st1h { [[RES]].h }, [[PG]], [x0] +; CHECK: ret + %op1 = load <16 x half>, <16 x half>* %a + %op2 = load <16 x half>, <16 x half>* %b + %res = fadd <16 x half> %op1, %op2 + store <16 x half> %res, <16 x half>* %a + ret void +} + +define void @fadd_v32f16(<32 x half>* %a, <32 x half>* %b) #0 { +; CHECK-LABEL: @fadd_v32f16 +; CHECK-DAG: ptrue [[PG:p[0-9]+]].h, vl[[#min(div(VBYTES,2),32)]] +; CHECK-DAG: ld1h { [[OP1:z[0-9]+]].h }, [[PG]]/z, [x0] +; CHECK-DAG: ld1h { [[OP2:z[0-9]+]].h }, [[PG]]/z, [x1] +; CHECK-DAG: fadd [[RES:z[0-9]+]].h, [[PG]]/m, [[OP1]].h, [[OP2]].h +; CHECK-DAG: st1h { [[RES]].h }, [[PG]], [x0] +; VBITS_LE_256-DAG: add x[[A1:[0-9]+]], x0, #[[#VBYTES]] +; VBITS_LE_256-DAG: add x[[B1:[0-9]+]], x1, #[[#VBYTES]] +; VBITS_LE_256-DAG: ld1h { [[OP1_1:z[0-9]+]].h }, [[PG]]/z, [x[[A1]]] +; VBITS_LE_256-DAG: ld1h { [[OP2_1:z[0-9]+]].h }, [[PG]]/z, [x[[B1]]] +; VBITS_LE_256-DAG: fadd [[RES_1:z[0-9]+]].h, [[PG]]/m, [[OP1_1]].h, [[OP2_1]].h +; VBITS_LE_256-DAG: st1h { [[RES_1]].h }, [[PG]], [x[[A1]]] +; CHECK: ret + %op1 = load <32 x half>, <32 x half>* %a + %op2 = load <32 x half>, <32 x half>* %b + %res = fadd <32 x half> %op1, %op2 + store <32 x half> %res, <32 x half>* %a + ret void +} + +define void @fadd_v64f16(<64 x half>* %a, <64 x half>* %b) #0 { +; CHECK-LABEL: @fadd_v64f16 +; CHECK-DAG: ptrue [[PG:p[0-9]+]].h, vl[[#min(div(VBYTES,2),64)]] +; CHECK-DAG: ld1h { [[OP1:z[0-9]+]].h }, [[PG]]/z, [x0] +; CHECK-DAG: ld1h { [[OP2:z[0-9]+]].h }, [[PG]]/z, [x1] +; CHECK-DAG: fadd [[RES:z[0-9]+]].h, [[PG]]/m, [[OP1]].h, [[OP2]].h +; CHECK-DAG: st1h { [[RES]].h }, [[PG]], [x0] +; VBITS_LE_512-DAG: add x[[A1:[0-9]+]], x0, #[[#VBYTES]] +; VBITS_LE_512-DAG: add x[[B1:[0-9]+]], x1, #[[#VBYTES]] +; VBITS_LE_512-DAG: ld1h { [[OP1_1:z[0-9]+]].h }, [[PG]]/z, [x[[A1]]] +; VBITS_LE_512-DAG: ld1h { [[OP2_1:z[0-9]+]].h }, [[PG]]/z, [x[[B1]]] +; VBITS_LE_512-DAG: fadd [[RES_1:z[0-9]+]].h, [[PG]]/m, [[OP1_1]].h, [[OP2_1]].h +; VBITS_LE_512-DAG: st1h { [[RES_1]].h }, [[PG]], [x[[A1]]] +; VBITS_LE_256-DAG: add x[[A2:[0-9]+]], x0, #[[#mul(VBYTES,2)]] +; VBITS_LE_256-DAG: add x[[B2:[0-9]+]], x1, #[[#mul(VBYTES,2)]] +; VBITS_LE_256-DAG: ld1h { [[OP1_2:z[0-9]+]].h }, [[PG]]/z, [x[[A2]]] +; VBITS_LE_256-DAG: ld1h { [[OP2_2:z[0-9]+]].h }, [[PG]]/z, [x[[B2]]] +; VBITS_LE_256-DAG: fadd [[RES_2:z[0-9]+]].h, [[PG]]/m, [[OP1_2]].h, [[OP2_2]].h +; VBITS_LE_256-DAG: st1h { [[RES_2]].h }, [[PG]], [x[[A2]]] +; VBITS_LE_256-DAG: add x[[A3:[0-9]+]], x0, #[[#mul(VBYTES,3)]] +; VBITS_LE_256-DAG: add x[[B3:[0-9]+]], x1, #[[#mul(VBYTES,3)]] +; VBITS_LE_256-DAG: ld1h { [[OP1_3:z[0-9]+]].h }, [[PG]]/z, [x[[A3]]] +; VBITS_LE_256-DAG: ld1h { [[OP2_3:z[0-9]+]].h }, [[PG]]/z, [x[[B3]]] +; VBITS_LE_256-DAG: fadd [[RES_3:z[0-9]+]].h, [[PG]]/m, [[OP1_3]].h, [[OP2_3]].h +; VBITS_LE_256-DAG: st1h { [[RES_3]].h }, [[PG]], [x[[A3]]] +; CHECK: ret + %op1 = load <64 x half>, <64 x half>* %a + %op2 = load <64 x half>, <64 x half>* %b + %res = fadd <64 x half> %op1, %op2 + store <64 x half> %res, <64 x half>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#f16 tests +; already cover the general legalisation cases. +define void @fadd_v128f16(<128 x half>* %a, <128 x half>* %b) #0 { +; CHECK-LABEL: @fadd_v128f16 +; CHECK: ptrue [[PG:p[0-9]+]].h, vl[[#min(div(VBYTES,2),128)]] +; CHECK-DAG: ld1h { [[OP1:z[0-9]+]].h }, [[PG]]/z, [x0] +; CHECK-DAG: ld1h { [[OP2:z[0-9]+]].h }, [[PG]]/z, [x1] +; CHECK: fadd [[RES:z[0-9]+]].h, [[PG]]/m, [[OP1]].h, [[OP2]].h +; CHECK: st1h { [[RES]].h }, [[PG]], [x0] +; CHECK: ret + %op1 = load <128 x half>, <128 x half>* %a + %op2 = load <128 x half>, <128 x half>* %b + %res = fadd <128 x half> %op1, %op2 + store <128 x half> %res, <128 x half>* %a + ret void +} + +; Don't use SVE for 64-bit vectors. +define <2 x float> @fadd_v2f32(<2 x float> %op1, <2 x float> %op2) #0 { +; CHECK-LABEL: @fadd_v2f32 +; CHECK: fadd v0.2s, v0.2s, v1.2s +; CHECK: ret + %res = fadd <2 x float> %op1, %op2 + ret <2 x float> %res +} + +; Don't use SVE for 128-bit vectors. +define <4 x float> @fadd_v4f32(<4 x float> %op1, <4 x float> %op2) #0 { +; CHECK-LABEL: @fadd_v4f32 +; CHECK: fadd v0.4s, v0.4s, v1.4s +; CHECK: ret + %res = fadd <4 x float> %op1, %op2 + ret <4 x float> %res +} + +define void @fadd_v8f32(<8 x float>* %a, <8 x float>* %b) #0 { +; CHECK-LABEL: @fadd_v8f32 +; CHECK: ptrue [[PG:p[0-9]+]].s, vl[[#min(div(VBYTES,4),8)]] +; CHECK-DAG: ld1w { [[OP1:z[0-9]+]].s }, [[PG]]/z, [x0] +; CHECK-DAG: ld1w { [[OP2:z[0-9]+]].s }, [[PG]]/z, [x1] +; CHECK: fadd [[RES:z[0-9]+]].s, [[PG]]/m, [[OP1]].s, [[OP2]].s +; CHECK: st1w { [[RES]].s }, [[PG]], [x0] +; CHECK: ret + %op1 = load <8 x float>, <8 x float>* %a + %op2 = load <8 x float>, <8 x float>* %b + %res = fadd <8 x float> %op1, %op2 + store <8 x float> %res, <8 x float>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#f16 tests +; already cover the general legalisation cases. +define void @fadd_v16f32(<16 x float>* %a, <16 x float>* %b) #0 { +; CHECK-LABEL: @fadd_v16f32 +; CHECK: ptrue [[PG:p[0-9]+]].s, vl[[#min(div(VBYTES,4),16)]] +; CHECK-DAG: ld1w { [[OP1:z[0-9]+]].s }, [[PG]]/z, [x0] +; CHECK-DAG: ld1w { [[OP2:z[0-9]+]].s }, [[PG]]/z, [x1] +; CHECK: fadd [[RES:z[0-9]+]].s, [[PG]]/m, [[OP1]].s, [[OP2]].s +; CHECK: st1w { [[RES]].s }, [[PG]], [x0] +; CHECK: ret + %op1 = load <16 x float>, <16 x float>* %a + %op2 = load <16 x float>, <16 x float>* %b + %res = fadd <16 x float> %op1, %op2 + store <16 x float> %res, <16 x float>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#f16 tests +; already cover the general legalisation cases. +define void @fadd_v32f32(<32 x float>* %a, <32 x float>* %b) #0 { +; CHECK-LABEL: @fadd_v32f32 +; CHECK: ptrue [[PG:p[0-9]+]].s, vl[[#min(div(VBYTES,4),32)]] +; CHECK-DAG: ld1w { [[OP1:z[0-9]+]].s }, [[PG]]/z, [x0] +; CHECK-DAG: ld1w { [[OP2:z[0-9]+]].s }, [[PG]]/z, [x1] +; CHECK: fadd [[RES:z[0-9]+]].s, [[PG]]/m, [[OP1]].s, [[OP2]].s +; CHECK: st1w { [[RES]].s }, [[PG]], [x0] +; CHECK: ret + %op1 = load <32 x float>, <32 x float>* %a + %op2 = load <32 x float>, <32 x float>* %b + %res = fadd <32 x float> %op1, %op2 + store <32 x float> %res, <32 x float>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#f16 tests +; already cover the general legalisation cases. +define void @fadd_v64f32(<64 x float>* %a, <64 x float>* %b) #0 { +; CHECK-LABEL: @fadd_v64f32 +; CHECK: ptrue [[PG:p[0-9]+]].s, vl[[#min(div(VBYTES,4),64)]] +; CHECK-DAG: ld1w { [[OP1:z[0-9]+]].s }, [[PG]]/z, [x0] +; CHECK-DAG: ld1w { [[OP2:z[0-9]+]].s }, [[PG]]/z, [x1] +; CHECK: fadd [[RES:z[0-9]+]].s, [[PG]]/m, [[OP1]].s, [[OP2]].s +; CHECK: st1w { [[RES]].s }, [[PG]], [x0] +; CHECK: ret + %op1 = load <64 x float>, <64 x float>* %a + %op2 = load <64 x float>, <64 x float>* %b + %res = fadd <64 x float> %op1, %op2 + store <64 x float> %res, <64 x float>* %a + ret void +} + +; Don't use SVE for 64-bit vectors. +define <1 x double> @fadd_v1f64(<1 x double> %op1, <1 x double> %op2) #0 { +; CHECK-LABEL: @fadd_v1f64 +; CHECK: fadd d0, d0, d1 +; CHECK: ret + %res = fadd <1 x double> %op1, %op2 + ret <1 x double> %res +} + +; Don't use SVE for 128-bit vectors. +define <2 x double> @fadd_v2f64(<2 x double> %op1, <2 x double> %op2) #0 { +; CHECK-LABEL: @fadd_v2f64 +; CHECK: fadd v0.2d, v0.2d, v1.2d +; CHECK: ret + %res = fadd <2 x double> %op1, %op2 + ret <2 x double> %res +} + +define void @fadd_v4f64(<4 x double>* %a, <4 x double>* %b) #0 { +; CHECK-LABEL: @fadd_v4f64 +; CHECK: ptrue [[PG:p[0-9]+]].d, vl[[#min(div(VBYTES,8),4)]] +; CHECK-DAG: ld1d { [[OP1:z[0-9]+]].d }, [[PG]]/z, [x0] +; CHECK-DAG: ld1d { [[OP2:z[0-9]+]].d }, [[PG]]/z, [x1] +; CHECK: fadd [[RES:z[0-9]+]].d, [[PG]]/m, [[OP1]].d, [[OP2]].d +; CHECK: st1d { [[RES]].d }, [[PG]], [x0] +; CHECK: ret + %op1 = load <4 x double>, <4 x double>* %a + %op2 = load <4 x double>, <4 x double>* %b + %res = fadd <4 x double> %op1, %op2 + store <4 x double> %res, <4 x double>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#f16 tests +; already cover the general legalisation cases. +define void @fadd_v8f64(<8 x double>* %a, <8 x double>* %b) #0 { +; CHECK-LABEL: @fadd_v8f64 +; CHECK: ptrue [[PG:p[0-9]+]].d, vl[[#min(div(VBYTES,8),8)]] +; CHECK-DAG: ld1d { [[OP1:z[0-9]+]].d }, [[PG]]/z, [x0] +; CHECK-DAG: ld1d { [[OP2:z[0-9]+]].d }, [[PG]]/z, [x1] +; CHECK: fadd [[RES:z[0-9]+]].d, [[PG]]/m, [[OP1]].d, [[OP2]].d +; CHECK: st1d { [[RES]].d }, [[PG]], [x0] +; CHECK: ret + %op1 = load <8 x double>, <8 x double>* %a + %op2 = load <8 x double>, <8 x double>* %b + %res = fadd <8 x double> %op1, %op2 + store <8 x double> %res, <8 x double>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#f16 tests +; already cover the general legalisation cases. +define void @fadd_v16f64(<16 x double>* %a, <16 x double>* %b) #0 { +; CHECK-LABEL: @fadd_v16f64 +; CHECK: ptrue [[PG:p[0-9]+]].d, vl[[#min(div(VBYTES,8),16)]] +; CHECK-DAG: ld1d { [[OP1:z[0-9]+]].d }, [[PG]]/z, [x0] +; CHECK-DAG: ld1d { [[OP2:z[0-9]+]].d }, [[PG]]/z, [x1] +; CHECK: fadd [[RES:z[0-9]+]].d, [[PG]]/m, [[OP1]].d, [[OP2]].d +; CHECK: st1d { [[RES]].d }, [[PG]], [x0] +; CHECK: ret + %op1 = load <16 x double>, <16 x double>* %a + %op2 = load <16 x double>, <16 x double>* %b + %res = fadd <16 x double> %op1, %op2 + store <16 x double> %res, <16 x double>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#f16 tests +; already cover the general legalisation cases. +define void @fadd_v32f64(<32 x double>* %a, <32 x double>* %b) #0 { +; CHECK-LABEL: @fadd_v32f64 +; CHECK: ptrue [[PG:p[0-9]+]].d, vl[[#min(div(VBYTES,8),32)]] +; CHECK-DAG: ld1d { [[OP1:z[0-9]+]].d }, [[PG]]/z, [x0] +; CHECK-DAG: ld1d { [[OP2:z[0-9]+]].d }, [[PG]]/z, [x1] +; CHECK: fadd [[RES:z[0-9]+]].d, [[PG]]/m, [[OP1]].d, [[OP2]].d +; CHECK: st1d { [[RES]].d }, [[PG]], [x0] +; CHECK: ret + %op1 = load <32 x double>, <32 x double>* %a + %op2 = load <32 x double>, <32 x double>* %b + %res = fadd <32 x double> %op1, %op2 + store <32 x double> %res, <32 x double>* %a + ret void +} + +attributes #0 = { "target-features"="+sve" } diff --git a/llvm/test/CodeGen/AArch64/sve-fixed-length-int-arith.ll b/llvm/test/CodeGen/AArch64/sve-fixed-length-int-arith.ll new file mode 100644 --- /dev/null +++ b/llvm/test/CodeGen/AArch64/sve-fixed-length-int-arith.ll @@ -0,0 +1,413 @@ +; RUN: llc -aarch64-sve-vector-bits-min=128 < %s | FileCheck %s -D#VBYTES=16 -check-prefix=NO_SVE +; RUN: llc -aarch64-sve-vector-bits-min=256 < %s | FileCheck %s -D#VBYTES=32 -check-prefixes=CHECK,VBITS_LE_1024,VBITS_LE_512,VBITS_LE_256 +; RUN: llc -aarch64-sve-vector-bits-min=384 < %s | FileCheck %s -D#VBYTES=32 -check-prefixes=CHECK,VBITS_LE_1024,VBITS_LE_512,VBITS_LE_256 +; RUN: llc -aarch64-sve-vector-bits-min=512 < %s | FileCheck %s -D#VBYTES=64 -check-prefixes=CHECK,VBITS_LE_1024,VBITS_LE_512 +; RUN: llc -aarch64-sve-vector-bits-min=640 < %s | FileCheck %s -D#VBYTES=64 -check-prefixes=CHECK,VBITS_LE_1024,VBITS_LE_512 +; RUN: llc -aarch64-sve-vector-bits-min=768 < %s | FileCheck %s -D#VBYTES=64 -check-prefixes=CHECK,VBITS_LE_1024,VBITS_LE_512 +; RUN: llc -aarch64-sve-vector-bits-min=896 < %s | FileCheck %s -D#VBYTES=64 -check-prefixes=CHECK,VBITS_LE_1024,VBITS_LE_512 +; RUN: llc -aarch64-sve-vector-bits-min=1024 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=1152 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=1280 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=1408 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=1536 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=1664 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=1792 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=1920 < %s | FileCheck %s -D#VBYTES=128 -check-prefixes=CHECK,VBITS_LE_1024 +; RUN: llc -aarch64-sve-vector-bits-min=2048 < %s | FileCheck %s -D#VBYTES=256 -check-prefixes=CHECK + +; VBYTES represents the useful byte size of a vector register from the code +; generator's point of view. It is clamped to power-of-2 values because +; only power-of-2 vector lengths are considered legal, regardless of the +; user specified vector length. + +target triple = "aarch64-unknown-linux-gnu" + +; Don't use SVE when its registers are no bigger than NEON. +; NO_SVE-NOT: ptrue + +; Don't use SVE for 64-bit vectors. +define <8 x i8> @add_v8i8(<8 x i8> %op1, <8 x i8> %op2) #0 { +; CHECK-LABEL: @add_v8i8 +; CHECK: add v0.8b, v0.8b, v1.8b +; CHECK: ret + %res = add <8 x i8> %op1, %op2 + ret <8 x i8> %res +} + +; Don't use SVE for 128-bit vectors. +define <16 x i8> @add_v16i8(<16 x i8> %op1, <16 x i8> %op2) #0 { +; CHECK-LABEL: @add_v16i8 +; CHECK: add v0.16b, v0.16b, v1.16b +; CHECK: ret + %res = add <16 x i8> %op1, %op2 + ret <16 x i8> %res +} + +define void @add_v32i8(<32 x i8>* %a, <32 x i8>* %b) #0 { +; CHECK-LABEL: @add_v32i8 +; CHECK: ptrue [[PG:p[0-9]+]].b, vl[[#min(VBYTES,32)]] +; CHECK-DAG: ld1b { [[OP1:z[0-9]+]].b }, [[PG]]/z, [x0] +; CHECK-DAG: ld1b { [[OP2:z[0-9]+]].b }, [[PG]]/z, [x1] +; CHECK: add [[RES:z[0-9]+]].b, [[PG]]/m, [[OP1]].b, [[OP2]].b +; CHECK: st1b { [[RES]].b }, [[PG]], [x0] +; CHECK: ret + %op1 = load <32 x i8>, <32 x i8>* %a + %op2 = load <32 x i8>, <32 x i8>* %b + %res = add <32 x i8> %op1, %op2 + store <32 x i8> %res, <32 x i8>* %a + ret void +} + +define void @add_v64i8(<64 x i8>* %a, <64 x i8>* %b) #0 { +; CHECK-LABEL: @add_v64i8 +; CHECK-DAG: ptrue [[PG:p[0-9]+]].b, vl[[#min(VBYTES,64)]] +; CHECK-DAG: ld1b { [[OP1:z[0-9]+]].b }, [[PG]]/z, [x0] +; CHECK-DAG: ld1b { [[OP2:z[0-9]+]].b }, [[PG]]/z, [x1] +; CHECK-DAG: add [[RES:z[0-9]+]].b, [[PG]]/m, [[OP1]].b, [[OP2]].b +; CHECK-DAG: st1b { [[RES]].b }, [[PG]], [x0] +; VBITS_LE_256-DAG: mov w[[OFF_1:[0-9]+]], #[[#VBYTES]] +; VBITS_LE_256-DAG: ld1b { [[OP1_1:z[0-9]+]].b }, [[PG]]/z, [x0, x[[OFF_1]]] +; VBITS_LE_256-DAG: ld1b { [[OP2_1:z[0-9]+]].b }, [[PG]]/z, [x1, x[[OFF_1]]] +; VBITS_LE_256-DAG: add [[RES_1:z[0-9]+]].b, [[PG]]/m, [[OP1_1]].b, [[OP2_1]].b +; VBITS_LE_256-DAG: st1b { [[RES_1]].b }, [[PG]], [x0, x[[OFF_1]]] +; CHECK: ret + %op1 = load <64 x i8>, <64 x i8>* %a + %op2 = load <64 x i8>, <64 x i8>* %b + %res = add <64 x i8> %op1, %op2 + store <64 x i8> %res, <64 x i8>* %a + ret void +} + +define void @add_v128i8(<128 x i8>* %a, <128 x i8>* %b) #0 { +; CHECK-LABEL: @add_v128i8 +; CHECK-DAG: ptrue [[PG:p[0-9]+]].b, vl[[#min(VBYTES,128)]] +; CHECK-DAG: ld1b { [[OP1:z[0-9]+]].b }, [[PG]]/z, [x0] +; CHECK-DAG: ld1b { [[OP2:z[0-9]+]].b }, [[PG]]/z, [x1] +; CHECK-DAG: add [[RES:z[0-9]+]].b, [[PG]]/m, [[OP1]].b, [[OP2]].b +; CHECK-DAG: st1b { [[RES]].b }, [[PG]], [x0] +; VBITS_LE_512-DAG: mov w[[OFF_1:[0-9]+]], #[[#VBYTES]] +; VBITS_LE_512-DAG: ld1b { [[OP1_1:z[0-9]+]].b }, [[PG]]/z, [x0, x[[OFF_1]]] +; VBITS_LE_512-DAG: ld1b { [[OP2_1:z[0-9]+]].b }, [[PG]]/z, [x1, x[[OFF_1]]] +; VBITS_LE_512-DAG: add [[RES_1:z[0-9]+]].b, [[PG]]/m, [[OP1_1]].b, [[OP2_1]].b +; VBITS_LE_512-DAG: st1b { [[RES_1]].b }, [[PG]], [x0, x[[OFF_1]]] +; VBITS_LE_256-DAG: mov w[[OFF_2:[0-9]+]], #[[#mul(VBYTES,2)]] +; VBITS_LE_256-DAG: ld1b { [[OP1_2:z[0-9]+]].b }, [[PG]]/z, [x0, x[[OFF_2]]] +; VBITS_LE_256-DAG: ld1b { [[OP2_2:z[0-9]+]].b }, [[PG]]/z, [x1, x[[OFF_2]]] +; VBITS_LE_256-DAG: add [[RES_2:z[0-9]+]].b, [[PG]]/m, [[OP1_2]].b, [[OP2_2]].b +; VBITS_LE_256-DAG: st1b { [[RES_2]].b }, [[PG]], [x0, x[[OFF_2]]] +; VBITS_LE_256-DAG: mov w[[OFF_3:[0-9]+]], #[[#mul(VBYTES,3)]] +; VBITS_LE_256-DAG: ld1b { [[OP1_3:z[0-9]+]].b }, [[PG]]/z, [x0, x[[OFF_3]]] +; VBITS_LE_256-DAG: ld1b { [[OP2_3:z[0-9]+]].b }, [[PG]]/z, [x1, x[[OFF_3]]] +; VBITS_LE_256-DAG: add [[RES_3:z[0-9]+]].b, [[PG]]/m, [[OP1_3]].b, [[OP2_3]].b +; VBITS_LE_256-DAG: st1b { [[RES_3]].b }, [[PG]], [x0, x[[OFF_3]]] +; CHECK: ret + %op1 = load <128 x i8>, <128 x i8>* %a + %op2 = load <128 x i8>, <128 x i8>* %b + %res = add <128 x i8> %op1, %op2 + store <128 x i8> %res, <128 x i8>* %a + ret void +} + +define void @add_v256i8(<256 x i8>* %a, <256 x i8>* %b) #0 { +; CHECK-LABEL: @add_v256i8 +; CHECK-DAG: ptrue [[PG:p[0-9]+]].b, vl[[#min(VBYTES,256)]] +; CHECK-DAG: ld1b { [[OP1:z[0-9]+]].b }, [[PG]]/z, [x0] +; CHECK-DAG: ld1b { [[OP2:z[0-9]+]].b }, [[PG]]/z, [x1] +; CHECK-DAG: add [[RES:z[0-9]+]].b, [[PG]]/m, [[OP1]].b, [[OP2]].b +; CHECK-DAG: st1b { [[RES]].b }, [[PG]], [x0] +; VBITS_LE_1024-DAG: mov w[[OFF_1:[0-9]+]], #[[#VBYTES]] +; VBITS_LE_1024-DAG: ld1b { [[OP1_1:z[0-9]+]].b }, [[PG]]/z, [x0, x[[OFF_1]]] +; VBITS_LE_1024-DAG: ld1b { [[OP2_1:z[0-9]+]].b }, [[PG]]/z, [x1, x[[OFF_1]]] +; VBITS_LE_1024-DAG: add [[RES_1:z[0-9]+]].b, [[PG]]/m, [[OP1_1]].b, [[OP2_1]].b +; VBITS_LE_1024-DAG: st1b { [[RES_1]].b }, [[PG]], [x0, x[[OFF_1]]] +; VBITS_LE_512-DAG: mov w[[OFF_2:[0-9]+]], #[[#mul(VBYTES,2)]] +; VBITS_LE_512-DAG: ld1b { [[OP1_2:z[0-9]+]].b }, [[PG]]/z, [x0, x[[OFF_2]]] +; VBITS_LE_512-DAG: ld1b { [[OP2_2:z[0-9]+]].b }, [[PG]]/z, [x1, x[[OFF_2]]] +; VBITS_LE_512-DAG: add [[RES_2:z[0-9]+]].b, [[PG]]/m, [[OP1_2]].b, [[OP2_2]].b +; VBITS_LE_512-DAG: st1b { [[RES_2]].b }, [[PG]], [x0, x[[OFF_2]]] +; VBITS_LE_512-DAG: mov w[[OFF_3:[0-9]+]], #[[#mul(VBYTES,3)]] +; VBITS_LE_512-DAG: ld1b { [[OP1_3:z[0-9]+]].b }, [[PG]]/z, [x0, x[[OFF_3]]] +; VBITS_LE_512-DAG: ld1b { [[OP2_3:z[0-9]+]].b }, [[PG]]/z, [x1, x[[OFF_3]]] +; VBITS_LE_512-DAG: add [[RES_3:z[0-9]+]].b, [[PG]]/m, [[OP1_3]].b, [[OP2_3]].b +; VBITS_LE_512-DAG: st1b { [[RES_3]].b }, [[PG]], [x0, x[[OFF_3]]] +; VBITS_LE_256-DAG: mov w[[OFF_4:[0-9]+]], #[[#mul(VBYTES,4)]] +; VBITS_LE_256-DAG: ld1b { [[OP1_4:z[0-9]+]].b }, [[PG]]/z, [x0, x[[OFF_4]]] +; VBITS_LE_256-DAG: ld1b { [[OP2_4:z[0-9]+]].b }, [[PG]]/z, [x1, x[[OFF_4]]] +; VBITS_LE_256-DAG: add [[RES_4:z[0-9]+]].b, [[PG]]/m, [[OP1_4]].b, [[OP2_4]].b +; VBITS_LE_256-DAG: st1b { [[RES_4]].b }, [[PG]], [x0, x[[OFF_4]]] +; VBITS_LE_256-DAG: mov w[[OFF_5:[0-9]+]], #[[#mul(VBYTES,5)]] +; VBITS_LE_256-DAG: ld1b { [[OP1_5:z[0-9]+]].b }, [[PG]]/z, [x0, x[[OFF_5]]] +; VBITS_LE_256-DAG: ld1b { [[OP2_5:z[0-9]+]].b }, [[PG]]/z, [x1, x[[OFF_5]]] +; VBITS_LE_256-DAG: add [[RES_5:z[0-9]+]].b, [[PG]]/m, [[OP1_5]].b, [[OP2_5]].b +; VBITS_LE_256-DAG: st1b { [[RES_5]].b }, [[PG]], [x0, x[[OFF_5]]] +; VBITS_LE_256-DAG: mov w[[OFF_6:[0-9]+]], #[[#mul(VBYTES,6)]] +; VBITS_LE_256-DAG: ld1b { [[OP1_6:z[0-9]+]].b }, [[PG]]/z, [x0, x[[OFF_6]]] +; VBITS_LE_256-DAG: ld1b { [[OP2_6:z[0-9]+]].b }, [[PG]]/z, [x1, x[[OFF_6]]] +; VBITS_LE_256-DAG: add [[RES_6:z[0-9]+]].b, [[PG]]/m, [[OP1_6]].b, [[OP2_6]].b +; VBITS_LE_256-DAG: st1b { [[RES_6]].b }, [[PG]], [x0, x[[OFF_6]]] +; VBITS_LE_256-DAG: mov w[[OFF_7:[0-9]+]], #[[#mul(VBYTES,7)]] +; VBITS_LE_256-DAG: ld1b { [[OP1_7:z[0-9]+]].b }, [[PG]]/z, [x0, x[[OFF_7]]] +; VBITS_LE_256-DAG: ld1b { [[OP2_7:z[0-9]+]].b }, [[PG]]/z, [x1, x[[OFF_7]]] +; VBITS_LE_256-DAG: add [[RES_7:z[0-9]+]].b, [[PG]]/m, [[OP1_7]].b, [[OP2_7]].b +; VBITS_LE_256-DAG: st1b { [[RES_7]].b }, [[PG]], [x0, x[[OFF_7]]] +; CHECK: ret + %op1 = load <256 x i8>, <256 x i8>* %a + %op2 = load <256 x i8>, <256 x i8>* %b + %res = add <256 x i8> %op1, %op2 + store <256 x i8> %res, <256 x i8>* %a + ret void +} + +; Don't use SVE for 64-bit vectors. +define <4 x i16> @add_v4i16(<4 x i16> %op1, <4 x i16> %op2) #0 { +; CHECK-LABEL: @add_v4i16 +; CHECK: add v0.4h, v0.4h, v1.4h +; CHECK: ret + %res = add <4 x i16> %op1, %op2 + ret <4 x i16> %res +} + +; Don't use SVE for 128-bit vectors. +define <8 x i16> @add_v8i16(<8 x i16> %op1, <8 x i16> %op2) #0 { +; CHECK-LABEL: @add_v8i16 +; CHECK: add v0.8h, v0.8h, v1.8h +; CHECK: ret + %res = add <8 x i16> %op1, %op2 + ret <8 x i16> %res +} + +define void @add_v16i16(<16 x i16>* %a, <16 x i16>* %b) #0 { +; CHECK-LABEL: @add_v16i16 +; CHECK: ptrue [[PG:p[0-9]+]].h, vl[[#min(div(VBYTES,2),16)]] +; CHECK-DAG: ld1h { [[OP1:z[0-9]+]].h }, [[PG]]/z, [x0] +; CHECK-DAG: ld1h { [[OP2:z[0-9]+]].h }, [[PG]]/z, [x1] +; CHECK: add [[RES:z[0-9]+]].h, [[PG]]/m, [[OP1]].h, [[OP2]].h +; CHECK: st1h { [[RES]].h }, [[PG]], [x0] +; CHECK: ret + %op1 = load <16 x i16>, <16 x i16>* %a + %op2 = load <16 x i16>, <16 x i16>* %b + %res = add <16 x i16> %op1, %op2 + store <16 x i16> %res, <16 x i16>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#i8 tests +; already cover the general legalisation cases. +define void @add_v32i16(<32 x i16>* %a, <32 x i16>* %b) #0 { +; CHECK-LABEL: @add_v32i16 +; CHECK: ptrue [[PG:p[0-9]+]].h, vl[[#min(div(VBYTES,2),32)]] +; CHECK-DAG: ld1h { [[OP1:z[0-9]+]].h }, [[PG]]/z, [x0] +; CHECK-DAG: ld1h { [[OP2:z[0-9]+]].h }, [[PG]]/z, [x1] +; CHECK: add [[RES:z[0-9]+]].h, [[PG]]/m, [[OP1]].h, [[OP2]].h +; CHECK: st1h { [[RES]].h }, [[PG]], [x0] +; CHECK: ret + %op1 = load <32 x i16>, <32 x i16>* %a + %op2 = load <32 x i16>, <32 x i16>* %b + %res = add <32 x i16> %op1, %op2 + store <32 x i16> %res, <32 x i16>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#i8 tests +; already cover the general legalisation cases. +define void @add_v64i16(<64 x i16>* %a, <64 x i16>* %b) #0 { +; CHECK-LABEL: @add_v64i16 +; CHECK: ptrue [[PG:p[0-9]+]].h, vl[[#min(div(VBYTES,2),64)]] +; CHECK-DAG: ld1h { [[OP1:z[0-9]+]].h }, [[PG]]/z, [x0] +; CHECK-DAG: ld1h { [[OP2:z[0-9]+]].h }, [[PG]]/z, [x1] +; CHECK: add [[RES:z[0-9]+]].h, [[PG]]/m, [[OP1]].h, [[OP2]].h +; CHECK: st1h { [[RES]].h }, [[PG]], [x0] +; CHECK: ret + %op1 = load <64 x i16>, <64 x i16>* %a + %op2 = load <64 x i16>, <64 x i16>* %b + %res = add <64 x i16> %op1, %op2 + store <64 x i16> %res, <64 x i16>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#i8 tests +; already cover the general legalisation cases. +define void @add_v128i16(<128 x i16>* %a, <128 x i16>* %b) #0 { +; CHECK-LABEL: @add_v128i16 +; CHECK: ptrue [[PG:p[0-9]+]].h, vl[[#min(div(VBYTES,2),128)]] +; CHECK-DAG: ld1h { [[OP1:z[0-9]+]].h }, [[PG]]/z, [x0] +; CHECK-DAG: ld1h { [[OP2:z[0-9]+]].h }, [[PG]]/z, [x1] +; CHECK: add [[RES:z[0-9]+]].h, [[PG]]/m, [[OP1]].h, [[OP2]].h +; CHECK: st1h { [[RES]].h }, [[PG]], [x0] +; CHECK: ret + %op1 = load <128 x i16>, <128 x i16>* %a + %op2 = load <128 x i16>, <128 x i16>* %b + %res = add <128 x i16> %op1, %op2 + store <128 x i16> %res, <128 x i16>* %a + ret void +} + +; Don't use SVE for 64-bit vectors. +define <2 x i32> @add_v2i32(<2 x i32> %op1, <2 x i32> %op2) #0 { +; CHECK-LABEL: @add_v2i32 +; CHECK: add v0.2s, v0.2s, v1.2s +; CHECK: ret + %res = add <2 x i32> %op1, %op2 + ret <2 x i32> %res +} + +; Don't use SVE for 128-bit vectors. +define <4 x i32> @add_v4i32(<4 x i32> %op1, <4 x i32> %op2) #0 { +; CHECK-LABEL: @add_v4i32 +; CHECK: add v0.4s, v0.4s, v1.4s +; CHECK: ret + %res = add <4 x i32> %op1, %op2 + ret <4 x i32> %res +} + +define void @add_v8i32(<8 x i32>* %a, <8 x i32>* %b) #0 { +; CHECK-LABEL: @add_v8i32 +; CHECK: ptrue [[PG:p[0-9]+]].s, vl[[#min(div(VBYTES,4),8)]] +; CHECK-DAG: ld1w { [[OP1:z[0-9]+]].s }, [[PG]]/z, [x0] +; CHECK-DAG: ld1w { [[OP2:z[0-9]+]].s }, [[PG]]/z, [x1] +; CHECK: add [[RES:z[0-9]+]].s, [[PG]]/m, [[OP1]].s, [[OP2]].s +; CHECK: st1w { [[RES]].s }, [[PG]], [x0] +; CHECK: ret + %op1 = load <8 x i32>, <8 x i32>* %a + %op2 = load <8 x i32>, <8 x i32>* %b + %res = add <8 x i32> %op1, %op2 + store <8 x i32> %res, <8 x i32>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#i8 tests +; already cover the general legalisation cases. +define void @add_v16i32(<16 x i32>* %a, <16 x i32>* %b) #0 { +; CHECK-LABEL: @add_v16i32 +; CHECK: ptrue [[PG:p[0-9]+]].s, vl[[#min(div(VBYTES,4),16)]] +; CHECK-DAG: ld1w { [[OP1:z[0-9]+]].s }, [[PG]]/z, [x0] +; CHECK-DAG: ld1w { [[OP2:z[0-9]+]].s }, [[PG]]/z, [x1] +; CHECK: add [[RES:z[0-9]+]].s, [[PG]]/m, [[OP1]].s, [[OP2]].s +; CHECK: st1w { [[RES]].s }, [[PG]], [x0] +; CHECK: ret + %op1 = load <16 x i32>, <16 x i32>* %a + %op2 = load <16 x i32>, <16 x i32>* %b + %res = add <16 x i32> %op1, %op2 + store <16 x i32> %res, <16 x i32>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#i8 tests +; already cover the general legalisation cases. +define void @add_v32i32(<32 x i32>* %a, <32 x i32>* %b) #0 { +; CHECK-LABEL: @add_v32i32 +; CHECK: ptrue [[PG:p[0-9]+]].s, vl[[#min(div(VBYTES,4),32)]] +; CHECK-DAG: ld1w { [[OP1:z[0-9]+]].s }, [[PG]]/z, [x0] +; CHECK-DAG: ld1w { [[OP2:z[0-9]+]].s }, [[PG]]/z, [x1] +; CHECK: add [[RES:z[0-9]+]].s, [[PG]]/m, [[OP1]].s, [[OP2]].s +; CHECK: st1w { [[RES]].s }, [[PG]], [x0] +; CHECK: ret + %op1 = load <32 x i32>, <32 x i32>* %a + %op2 = load <32 x i32>, <32 x i32>* %b + %res = add <32 x i32> %op1, %op2 + store <32 x i32> %res, <32 x i32>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#i8 tests +; already cover the general legalisation cases. +define void @add_v64i32(<64 x i32>* %a, <64 x i32>* %b) #0 { +; CHECK-LABEL: @add_v64i32 +; CHECK: ptrue [[PG:p[0-9]+]].s, vl[[#min(div(VBYTES,4),64)]] +; CHECK-DAG: ld1w { [[OP1:z[0-9]+]].s }, [[PG]]/z, [x0] +; CHECK-DAG: ld1w { [[OP2:z[0-9]+]].s }, [[PG]]/z, [x1] +; CHECK: add [[RES:z[0-9]+]].s, [[PG]]/m, [[OP1]].s, [[OP2]].s +; CHECK: st1w { [[RES]].s }, [[PG]], [x0] +; CHECK: ret + %op1 = load <64 x i32>, <64 x i32>* %a + %op2 = load <64 x i32>, <64 x i32>* %b + %res = add <64 x i32> %op1, %op2 + store <64 x i32> %res, <64 x i32>* %a + ret void +} + +; Don't use SVE for 64-bit vectors. +define <1 x i64> @add_v1i64(<1 x i64> %op1, <1 x i64> %op2) #0 { +; CHECK-LABEL: @add_v1i64 +; CHECK: add d0, d0, d1 +; CHECK: ret + %res = add <1 x i64> %op1, %op2 + ret <1 x i64> %res +} + +; Don't use SVE for 128-bit vectors. +define <2 x i64> @add_v2i64(<2 x i64> %op1, <2 x i64> %op2) #0 { +; CHECK-LABEL: @add_v2i64 +; CHECK: add v0.2d, v0.2d, v1.2d +; CHECK: ret + %res = add <2 x i64> %op1, %op2 + ret <2 x i64> %res +} + +define void @add_v4i64(<4 x i64>* %a, <4 x i64>* %b) #0 { +; CHECK-LABEL: @add_v4i64 +; CHECK: ptrue [[PG:p[0-9]+]].d, vl[[#min(div(VBYTES,8),4)]] +; CHECK-DAG: ld1d { [[OP1:z[0-9]+]].d }, [[PG]]/z, [x0] +; CHECK-DAG: ld1d { [[OP2:z[0-9]+]].d }, [[PG]]/z, [x1] +; CHECK: add [[RES:z[0-9]+]].d, [[PG]]/m, [[OP1]].d, [[OP2]].d +; CHECK: st1d { [[RES]].d }, [[PG]], [x0] +; CHECK: ret + %op1 = load <4 x i64>, <4 x i64>* %a + %op2 = load <4 x i64>, <4 x i64>* %b + %res = add <4 x i64> %op1, %op2 + store <4 x i64> %res, <4 x i64>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#i8 tests +; already cover the general legalisation cases. +define void @add_v8i64(<8 x i64>* %a, <8 x i64>* %b) #0 { +; CHECK-LABEL: @add_v8i64 +; CHECK: ptrue [[PG:p[0-9]+]].d, vl[[#min(div(VBYTES,8),8)]] +; CHECK-DAG: ld1d { [[OP1:z[0-9]+]].d }, [[PG]]/z, [x0] +; CHECK-DAG: ld1d { [[OP2:z[0-9]+]].d }, [[PG]]/z, [x1] +; CHECK: add [[RES:z[0-9]+]].d, [[PG]]/m, [[OP1]].d, [[OP2]].d +; CHECK: st1d { [[RES]].d }, [[PG]], [x0] +; CHECK: ret + %op1 = load <8 x i64>, <8 x i64>* %a + %op2 = load <8 x i64>, <8 x i64>* %b + %res = add <8 x i64> %op1, %op2 + store <8 x i64> %res, <8 x i64>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#i8 tests +; already cover the general legalisation cases. +define void @add_v16i64(<16 x i64>* %a, <16 x i64>* %b) #0 { +; CHECK-LABEL: @add_v16i64 +; CHECK: ptrue [[PG:p[0-9]+]].d, vl[[#min(div(VBYTES,8),16)]] +; CHECK-DAG: ld1d { [[OP1:z[0-9]+]].d }, [[PG]]/z, [x0] +; CHECK-DAG: ld1d { [[OP2:z[0-9]+]].d }, [[PG]]/z, [x1] +; CHECK: add [[RES:z[0-9]+]].d, [[PG]]/m, [[OP1]].d, [[OP2]].d +; CHECK: st1d { [[RES]].d }, [[PG]], [x0] +; CHECK: ret + %op1 = load <16 x i64>, <16 x i64>* %a + %op2 = load <16 x i64>, <16 x i64>* %b + %res = add <16 x i64> %op1, %op2 + store <16 x i64> %res, <16 x i64>* %a + ret void +} + +; NOTE: Check lines only cover the first VBYTES because the add_v#i8 tests +; already cover the general legalisation cases. +define void @add_v32i64(<32 x i64>* %a, <32 x i64>* %b) #0 { +; CHECK-LABEL: @add_v32i64 +; CHECK: ptrue [[PG:p[0-9]+]].d, vl[[#min(div(VBYTES,8),32)]] +; CHECK-DAG: ld1d { [[OP1:z[0-9]+]].d }, [[PG]]/z, [x0] +; CHECK-DAG: ld1d { [[OP2:z[0-9]+]].d }, [[PG]]/z, [x1] +; CHECK: add [[RES:z[0-9]+]].d, [[PG]]/m, [[OP1]].d, [[OP2]].d +; CHECK: st1d { [[RES]].d }, [[PG]], [x0] +; CHECK: ret + %op1 = load <32 x i64>, <32 x i64>* %a + %op2 = load <32 x i64>, <32 x i64>* %b + %res = add <32 x i64> %op1, %op2 + store <32 x i64> %res, <32 x i64>* %a + ret void +} + +attributes #0 = { "target-features"="+sve" }