doxygen/X86ISelLowering_8cpp_source.html

//===-- X86ISelLowering.cpp - X86 DAG Lowering Implementation -------------===//

//

// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.

// See https://llvm.org/LICENSE.txt for license information.

// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception

//

//===----------------------------------------------------------------------===//

//

// This file defines the interfaces that X86 uses to lower LLVM code into a

// selection DAG.

//

//===----------------------------------------------------------------------===//


#include "X86ISelLowering.h"

#include "MCTargetDesc/X86ShuffleDecode.h"

#include "X86.h"

#include "X86FrameLowering.h"

#include "X86InstrBuilder.h"

#include "X86IntrinsicsInfo.h"

#include "X86MachineFunctionInfo.h"

#include "X86TargetMachine.h"

#include "llvm/ADT/SmallBitVector.h"

#include "llvm/ADT/SmallSet.h"

#include "llvm/ADT/SmallVector.h"

#include "llvm/ADT/Statistic.h"

#include "llvm/ADT/StringExtras.h"

#include "llvm/ADT/StringSwitch.h"

#include "llvm/Analysis/BlockFrequencyInfo.h"

#include "llvm/Analysis/ProfileSummaryInfo.h"

#include "llvm/Analysis/VectorUtils.h"

#include "llvm/CodeGen/LivePhysRegs.h"

#include "llvm/CodeGen/MachineFrameInfo.h"

#include "llvm/CodeGen/MachineFunction.h"

#include "llvm/CodeGen/MachineInstrBuilder.h"

#include "llvm/CodeGen/MachineJumpTableInfo.h"

#include "llvm/CodeGen/MachineLoopInfo.h"

#include "llvm/CodeGen/MachineModuleInfo.h"

#include "llvm/CodeGen/MachineRegisterInfo.h"

#include "llvm/CodeGen/SDPatternMatch.h"

#include "llvm/CodeGen/SelectionDAGNodes.h"

#include "llvm/CodeGen/TargetLowering.h"

#include "llvm/CodeGen/WinEHFuncInfo.h"

#include "llvm/IR/CallingConv.h"

#include "llvm/IR/Constants.h"

#include "llvm/IR/DerivedTypes.h"

#include "llvm/IR/EHPersonalities.h"

#include "llvm/IR/Function.h"

#include "llvm/IR/GlobalAlias.h"

#include "llvm/IR/GlobalVariable.h"

#include "llvm/IR/IRBuilder.h"

#include "llvm/IR/Instructions.h"

#include "llvm/IR/Intrinsics.h"

#include "llvm/IR/PatternMatch.h"

#include "llvm/MC/MCAsmInfo.h"

#include "llvm/MC/MCContext.h"

#include "llvm/MC/MCExpr.h"

#include "llvm/MC/MCSymbol.h"

#include "llvm/Support/CommandLine.h"

#include "llvm/Support/Debug.h"

#include "llvm/Support/ErrorHandling.h"

#include "llvm/Support/KnownBits.h"

#include "llvm/Support/MathExtras.h"

#include "llvm/Target/TargetOptions.h"

#include <algorithm>

#include <bitset>

#include <cctype>

#include <numeric>

using namespace llvm;


#define DEBUG_TYPE "x86-isel"


static cl::opt<int> ExperimentalPrefInnermostLoopAlignment(

    "x86-experimental-pref-innermost-loop-alignment", cl::init(4),

    cl::desc(

        "Sets the preferable loop alignment for experiments (as log2 bytes) "

        "for innermost loops only. If specified, this option overrides "

        "alignment set by x86-experimental-pref-loop-alignment."),

    cl::Hidden);


static cl::opt<int> BrMergingBaseCostThresh(

    "x86-br-merging-base-cost", cl::init(2),

    cl::desc(

        "Sets the cost threshold for when multiple conditionals will be merged "

        "into one branch versus be split in multiple branches. Merging "

        "conditionals saves branches at the cost of additional instructions. "

        "This value sets the instruction cost limit, below which conditionals "

        "will be merged, and above which conditionals will be split. Set to -1 "

        "to never merge branches."),

    cl::Hidden);


static cl::opt<int> BrMergingCcmpBias(

    "x86-br-merging-ccmp-bias", cl::init(6),

    cl::desc("Increases 'x86-br-merging-base-cost' in cases that the target "

             "supports conditional compare instructions."),

    cl::Hidden);


static cl::opt<bool>

    WidenShift("x86-widen-shift", cl::init(true),

               cl::desc("Replace narrow shifts with wider shifts."),

               cl::Hidden);


static cl::opt<int> BrMergingLikelyBias(

    "x86-br-merging-likely-bias", cl::init(0),

    cl::desc("Increases 'x86-br-merging-base-cost' in cases that it is likely "

             "that all conditionals will be executed. For example for merging "

             "the conditionals (a == b && c > d), if its known that a == b is "

             "likely, then it is likely that if the conditionals are split "

             "both sides will be executed, so it may be desirable to increase "

             "the instruction cost threshold. Set to -1 to never merge likely "

             "branches."),

    cl::Hidden);


static cl::opt<int> BrMergingUnlikelyBias(

    "x86-br-merging-unlikely-bias", cl::init(-1),

    cl::desc(

        "Decreases 'x86-br-merging-base-cost' in cases that it is unlikely "

        "that all conditionals will be executed. For example for merging "

        "the conditionals (a == b && c > d), if its known that a == b is "

        "unlikely, then it is unlikely that if the conditionals are split "

        "both sides will be executed, so it may be desirable to decrease "

        "the instruction cost threshold. Set to -1 to never merge unlikely "

        "branches."),

    cl::Hidden);


static cl::opt<bool> MulConstantOptimization(

    "mul-constant-optimization", cl::init(true),

    cl::desc("Replace 'mul x, Const' with more effective instructions like "

             "SHIFT, LEA, etc."),

    cl::Hidden);


X86TargetLowering::X86TargetLowering(const X86TargetMachine &TM,

                                     const X86Subtarget &STI)

    : TargetLowering(TM, STI), Subtarget(STI) {

  bool UseX87 = !Subtarget.useSoftFloat() && Subtarget.hasX87();

  MVT PtrVT = MVT::getIntegerVT(TM.getPointerSizeInBits(0));


  // Set up the TargetLowering object.


  // X86 is weird. It always uses i8 for shift amounts and setcc results.

  setBooleanContents(ZeroOrOneBooleanContent);

  // X86-SSE is even stranger. It uses -1 or 0 for vector masks.

  setBooleanVectorContents(ZeroOrNegativeOneBooleanContent);


  // X86 instruction cache is coherent with its data cache so we can use the

  // default expansion to a no-op.

  setOperationAction(ISD::CLEAR_CACHE, MVT::Other, Expand);


  // For 64-bit, since we have so many registers, use the ILP scheduler.

  // For 32-bit, use the register pressure specific scheduling.

  // For Atom, always use ILP scheduling.

  if (Subtarget.isAtom())

    setSchedulingPreference(Sched::ILP);

  else if (Subtarget.is64Bit())

    setSchedulingPreference(Sched::ILP);

  else

    setSchedulingPreference(Sched::RegPressure);

  const X86RegisterInfo *RegInfo = Subtarget.getRegisterInfo();

  setStackPointerRegisterToSaveRestore(RegInfo->getStackRegister());


  // Bypass expensive divides and use cheaper ones.

  if (TM.getOptLevel() >= CodeGenOptLevel::Default) {

    if (Subtarget.hasSlowDivide32())

      addBypassSlowDiv(32, 8);

    if (Subtarget.hasSlowDivide64() && Subtarget.is64Bit())

      addBypassSlowDiv(64, 32);

  }


  if (Subtarget.canUseCMPXCHG16B())

    setMaxAtomicSizeInBitsSupported(128);

  else if (Subtarget.canUseCMPXCHG8B())

    setMaxAtomicSizeInBitsSupported(64);

  else

    setMaxAtomicSizeInBitsSupported(32);


  setMaxDivRemBitWidthSupported(Subtarget.is64Bit() ? 128 : 64);


  setMaxLargeFPConvertBitWidthSupported(128);


  // Set up the register classes.

  addRegisterClass(MVT::i8, &X86::GR8RegClass);

  addRegisterClass(MVT::i16, &X86::GR16RegClass);

  addRegisterClass(MVT::i32, &X86::GR32RegClass);

  if (Subtarget.is64Bit())

    addRegisterClass(MVT::i64, &X86::GR64RegClass);


  for (MVT VT : MVT::integer_valuetypes())

    setLoadExtAction(ISD::SEXTLOAD, VT, MVT::i1, Promote);


  // We don't accept any truncstore of integer registers.

  setTruncStoreAction(MVT::i64, MVT::i32, Expand);

  setTruncStoreAction(MVT::i64, MVT::i16, Expand);

  setTruncStoreAction(MVT::i64, MVT::i8 , Expand);

  setTruncStoreAction(MVT::i32, MVT::i16, Expand);

  setTruncStoreAction(MVT::i32, MVT::i8 , Expand);

  setTruncStoreAction(MVT::i16, MVT::i8,  Expand);


  setTruncStoreAction(MVT::f64, MVT::f32, Expand);


  // SETOEQ and SETUNE require checking two conditions.

  for (auto VT : {MVT::f32, MVT::f64, MVT::f80}) {

    setCondCodeAction(ISD::SETOEQ, VT, Expand);

    setCondCodeAction(ISD::SETUNE, VT, Expand);

  }


  // Integer absolute.

  if (Subtarget.canUseCMOV()) {

    setOperationAction(ISD::ABS            , MVT::i16  , Custom);

    setOperationAction(ISD::ABS            , MVT::i32  , Custom);

    if (Subtarget.is64Bit())

      setOperationAction(ISD::ABS          , MVT::i64  , Custom);

  }


  // Absolute difference.

  for (auto Op : {ISD::ABDS, ISD::ABDU}) {

    setOperationAction(Op                  , MVT::i8   , Custom);

    setOperationAction(Op                  , MVT::i16  , Custom);

    setOperationAction(Op                  , MVT::i32  , Custom);

    if (Subtarget.is64Bit())

     setOperationAction(Op                 , MVT::i64  , Custom);

  }


  // Signed saturation subtraction.

  setOperationAction(ISD::SSUBSAT          , MVT::i8   , Custom);

  setOperationAction(ISD::SSUBSAT          , MVT::i16  , Custom);

  setOperationAction(ISD::SSUBSAT          , MVT::i32  , Custom);

  if (Subtarget.is64Bit())

    setOperationAction(ISD::SSUBSAT        , MVT::i64  , Custom);


  // Funnel shifts.

  for (auto ShiftOp : {ISD::FSHL, ISD::FSHR}) {

    // For slow shld targets we only lower for code size.

    LegalizeAction ShiftDoubleAction = Subtarget.isSHLDSlow() ? Custom : Legal;


    setOperationAction(ShiftOp             , MVT::i8   , Custom);

    setOperationAction(ShiftOp             , MVT::i16  , Custom);

    setOperationAction(ShiftOp             , MVT::i32  , ShiftDoubleAction);

    if (Subtarget.is64Bit())

      setOperationAction(ShiftOp           , MVT::i64  , ShiftDoubleAction);

  }


  if (!Subtarget.useSoftFloat()) {

    // Promote all UINT_TO_FP to larger SINT_TO_FP's, as X86 doesn't have this

    // operation.

    setOperationAction(ISD::UINT_TO_FP,        MVT::i8, Promote);

    setOperationAction(ISD::STRICT_UINT_TO_FP, MVT::i8, Promote);

    setOperationAction(ISD::UINT_TO_FP,        MVT::i16, Promote);

    setOperationAction(ISD::STRICT_UINT_TO_FP, MVT::i16, Promote);

    // We have an algorithm for SSE2, and we turn this into a 64-bit

    // FILD or VCVTUSI2SS/SD for other targets.

    setOperationAction(ISD::UINT_TO_FP,        MVT::i32, Custom);

    setOperationAction(ISD::STRICT_UINT_TO_FP, MVT::i32, Custom);

    // We have an algorithm for SSE2->double, and we turn this into a

    // 64-bit FILD followed by conditional FADD for other targets.

    setOperationAction(ISD::UINT_TO_FP,        MVT::i64, Custom);

    setOperationAction(ISD::STRICT_UINT_TO_FP, MVT::i64, Custom);


    // Promote i8 SINT_TO_FP to larger SINT_TO_FP's, as X86 doesn't have

    // this operation.

    setOperationAction(ISD::SINT_TO_FP,        MVT::i8, Promote);

    setOperationAction(ISD::STRICT_SINT_TO_FP, MVT::i8, Promote);

    // SSE has no i16 to fp conversion, only i32. We promote in the handler

    // to allow f80 to use i16 and f64 to use i16 with sse1 only

    setOperationAction(ISD::SINT_TO_FP,        MVT::i16, Custom);

    setOperationAction(ISD::STRICT_SINT_TO_FP, MVT::i16, Custom);

    // f32 and f64 cases are Legal with SSE1/SSE2, f80 case is not

    setOperationAction(ISD::SINT_TO_FP,        MVT::i32, Custom);

    setOperationAction(ISD::STRICT_SINT_TO_FP, MVT::i32, Custom);

    // In 32-bit mode these are custom lowered.  In 64-bit mode F32 and F64

    // are Legal, f80 is custom lowered.

    setOperationAction(ISD::SINT_TO_FP,        MVT::i64, Custom);

    setOperationAction(ISD::STRICT_SINT_TO_FP, MVT::i64, Custom);


    // Promote i8 FP_TO_SINT to larger FP_TO_SINTS's, as X86 doesn't have

    // this operation.

    setOperationAction(ISD::FP_TO_SINT,        MVT::i8,  Promote);

    // FIXME: This doesn't generate invalid exception when it should. PR44019.

    setOperationAction(ISD::STRICT_FP_TO_SINT, MVT::i8,  Promote);

    setOperationAction(ISD::FP_TO_SINT,        MVT::i16, Custom);

    setOperationAction(ISD::STRICT_FP_TO_SINT, MVT::i16, Custom);

    setOperationAction(ISD::FP_TO_SINT,        MVT::i32, Custom);

    setOperationAction(ISD::STRICT_FP_TO_SINT, MVT::i32, Custom);

    // In 32-bit mode these are custom lowered.  In 64-bit mode F32 and F64

    // are Legal, f80 is custom lowered.

    setOperationAction(ISD::FP_TO_SINT,        MVT::i64, Custom);

    setOperationAction(ISD::STRICT_FP_TO_SINT, MVT::i64, Custom);


    // Handle FP_TO_UINT by promoting the destination to a larger signed

    // conversion.

    setOperationAction(ISD::FP_TO_UINT,        MVT::i8,  Promote);

    // FIXME: This doesn't generate invalid exception when it should. PR44019.

    setOperationAction(ISD::STRICT_FP_TO_UINT, MVT::i8,  Promote);

    setOperationAction(ISD::FP_TO_UINT,        MVT::i16, Promote);

    // FIXME: This doesn't generate invalid exception when it should. PR44019.

    setOperationAction(ISD::STRICT_FP_TO_UINT, MVT::i16, Promote);

    setOperationAction(ISD::FP_TO_UINT,        MVT::i32, Custom);

    setOperationAction(ISD::STRICT_FP_TO_UINT, MVT::i32, Custom);

    setOperationAction(ISD::FP_TO_UINT,        MVT::i64, Custom);

    setOperationAction(ISD::STRICT_FP_TO_UINT, MVT::i64, Custom);


    setOperationAction(ISD::LRINT,             MVT::f32, Custom);

    setOperationAction(ISD::LRINT,             MVT::f64, Custom);

    setOperationAction(ISD::LLRINT,            MVT::f32, Custom);

    setOperationAction(ISD::LLRINT,            MVT::f64, Custom);


    if (!Subtarget.is64Bit() && Subtarget.hasX87()) {

      setOperationAction(ISD::LRINT,  MVT::i64, Custom);

      setOperationAction(ISD::LLRINT, MVT::i64, Custom);

    }

  }


  if (Subtarget.hasSSE2()) {

    // Custom lowering for saturating float to int conversions.

    // We handle promotion to larger result types manually.

    for (MVT VT : { MVT::i8, MVT::i16, MVT::i32 }) {

      setOperationAction(ISD::FP_TO_UINT_SAT, VT, Custom);

      setOperationAction(ISD::FP_TO_SINT_SAT, VT, Custom);

    }

    if (Subtarget.is64Bit()) {

      setOperationAction(ISD::FP_TO_UINT_SAT, MVT::i64, Custom);

      setOperationAction(ISD::FP_TO_SINT_SAT, MVT::i64, Custom);

    }

  }

  if (Subtarget.hasAVX10_2()) {

    setOperationAction(ISD::FP_TO_UINT_SAT, MVT::v2i32, Custom);

    setOperationAction(ISD::FP_TO_SINT_SAT, MVT::v2i32, Custom);

    setOperationAction(ISD::FP_TO_UINT_SAT, MVT::v8i64, Legal);

    setOperationAction(ISD::FP_TO_SINT_SAT, MVT::v8i64, Legal);

    for (MVT VT : {MVT::i32, MVT::v4i32, MVT::v8i32, MVT::v16i32, MVT::v2i64,

                   MVT::v4i64}) {

      setOperationAction(ISD::FP_TO_UINT_SAT, VT, Legal);

      setOperationAction(ISD::FP_TO_SINT_SAT, VT, Legal);

    }

    if (Subtarget.is64Bit()) {

      setOperationAction(ISD::FP_TO_UINT_SAT, MVT::i64, Legal);

      setOperationAction(ISD::FP_TO_SINT_SAT, MVT::i64, Legal);

    }

  }


  // Handle address space casts between mixed sized pointers.

  setOperationAction(ISD::ADDRSPACECAST, MVT::i32, Custom);

  setOperationAction(ISD::ADDRSPACECAST, MVT::i64, Custom);


  // TODO: when we have SSE, these could be more efficient, by using movd/movq.

  if (!Subtarget.hasSSE2()) {

    setOperationAction(ISD::BITCAST        , MVT::f32  , Expand);

    setOperationAction(ISD::BITCAST        , MVT::i32  , Expand);

    if (Subtarget.is64Bit()) {

      setOperationAction(ISD::BITCAST      , MVT::f64  , Expand);

      // Without SSE, i64->f64 goes through memory.

      setOperationAction(ISD::BITCAST      , MVT::i64  , Expand);

    }

  } else if (!Subtarget.is64Bit())

    setOperationAction(ISD::BITCAST      , MVT::i64  , Custom);


  // Scalar integer divide and remainder are lowered to use operations that

  // produce two results, to match the available instructions. This exposes

  // the two-result form to trivial CSE, which is able to combine x/y and x%y

  // into a single instruction.

  //

  // Scalar integer multiply-high is also lowered to use two-result

  // operations, to match the available instructions. However, plain multiply

  // (low) operations are left as Legal, as there are single-result

  // instructions for this in x86. Using the two-result multiply instructions

  // when both high and low results are needed must be arranged by dagcombine.

  for (auto VT : { MVT::i8, MVT::i16, MVT::i32, MVT::i64 }) {

    setOperationAction(ISD::MULHS, VT, Expand);

    setOperationAction(ISD::MULHU, VT, Expand);

    setOperationAction(ISD::SDIV, VT, Expand);

    setOperationAction(ISD::UDIV, VT, Expand);

    setOperationAction(ISD::SREM, VT, Expand);

    setOperationAction(ISD::UREM, VT, Expand);

  }


  setOperationAction(ISD::BR_JT            , MVT::Other, Expand);

  setOperationAction(ISD::BRCOND           , MVT::Other, Custom);

  for (auto VT : { MVT::f32, MVT::f64, MVT::f80, MVT::f128,

                   MVT::i8,  MVT::i16, MVT::i32, MVT::i64 }) {

    setOperationAction(ISD::BR_CC,     VT, Expand);

    setOperationAction(ISD::SELECT_CC, VT, Expand);

  }

  if (Subtarget.is64Bit())

    setOperationAction(ISD::SIGN_EXTEND_INREG, MVT::i32, Legal);

  setOperationAction(ISD::SIGN_EXTEND_INREG, MVT::i16  , Legal);

  setOperationAction(ISD::SIGN_EXTEND_INREG, MVT::i8   , Legal);

  setOperationAction(ISD::SIGN_EXTEND_INREG, MVT::i1   , Expand);


  setOperationAction(ISD::FREM, MVT::f32, LibCall);

  setOperationAction(ISD::FREM, MVT::f64, LibCall);

  setOperationAction(ISD::FREM, MVT::f80, LibCall);

  setOperationAction(ISD::FREM, MVT::f128, LibCall);


  if (!Subtarget.useSoftFloat() && Subtarget.hasX87()) {

    setOperationAction(ISD::GET_ROUNDING   , MVT::i32  , Custom);

    setOperationAction(ISD::SET_ROUNDING   , MVT::Other, Custom);

    setOperationAction(ISD::GET_FPENV_MEM  , MVT::Other, Custom);

    setOperationAction(ISD::SET_FPENV_MEM  , MVT::Other, Custom);

    setOperationAction(ISD::RESET_FPENV    , MVT::Other, Custom);

  }


  // Promote the i8 variants and force them on up to i32 which has a shorter

  // encoding.

  setOperationPromotedToType(ISD::CTTZ           , MVT::i8   , MVT::i32);

  setOperationPromotedToType(ISD::CTTZ_ZERO_UNDEF, MVT::i8   , MVT::i32);

  // Promoted i16. tzcntw has a false dependency on Intel CPUs. For BSF, we emit

  // a REP prefix to encode it as TZCNT for modern CPUs so it makes sense to

  // promote that too.

  setOperationPromotedToType(ISD::CTTZ           , MVT::i16  , MVT::i32);

  setOperationPromotedToType(ISD::CTTZ_ZERO_UNDEF, MVT::i16  , MVT::i32);


  if (!Subtarget.hasBMI()) {

    setOperationAction(ISD::CTTZ           , MVT::i32  , Custom);

    setOperationAction(ISD::CTTZ_ZERO_UNDEF, MVT::i32  , Legal);

    if (Subtarget.is64Bit()) {

      setOperationAction(ISD::CTTZ         , MVT::i64  , Custom);

      setOperationAction(ISD::CTTZ_ZERO_UNDEF, MVT::i64, Legal);

    }

  }


  if (Subtarget.hasLZCNT()) {

    // When promoting the i8 variants, force them to i32 for a shorter

    // encoding.

    setOperationPromotedToType(ISD::CTLZ           , MVT::i8   , MVT::i32);

    setOperationPromotedToType(ISD::CTLZ_ZERO_UNDEF, MVT::i8   , MVT::i32);

  } else {

    for (auto VT : {MVT::i8, MVT::i16, MVT::i32, MVT::i64}) {

      if (VT == MVT::i64 && !Subtarget.is64Bit())

        continue;

      setOperationAction(ISD::CTLZ           , VT, Custom);

      setOperationAction(ISD::CTLZ_ZERO_UNDEF, VT, Custom);

    }

  }


  for (auto Op : {ISD::FP16_TO_FP, ISD::STRICT_FP16_TO_FP, ISD::FP_TO_FP16,

                  ISD::STRICT_FP_TO_FP16}) {

    // Special handling for half-precision floating point conversions.

    // If we don't have F16C support, then lower half float conversions

    // into library calls.

    setOperationAction(

        Op, MVT::f32,

        (!Subtarget.useSoftFloat() && Subtarget.hasF16C()) ? Custom : Expand);

    // There's never any support for operations beyond MVT::f32.

    setOperationAction(Op, MVT::f64, Expand);

    setOperationAction(Op, MVT::f80, Expand);

    setOperationAction(Op, MVT::f128, Expand);

  }


  for (auto VT : {MVT::f32, MVT::f64, MVT::f80, MVT::f128}) {

    setOperationAction(ISD::STRICT_FP_TO_BF16, VT, Expand);

    setOperationAction(ISD::STRICT_BF16_TO_FP, VT, Expand);

  }


  for (MVT VT : {MVT::f32, MVT::f64, MVT::f80, MVT::f128}) {

    setLoadExtAction(ISD::EXTLOAD, VT, MVT::f16, Expand);

    setLoadExtAction(ISD::EXTLOAD, VT, MVT::bf16, Expand);

    setTruncStoreAction(VT, MVT::f16, Expand);

    setTruncStoreAction(VT, MVT::bf16, Expand);


    setOperationAction(ISD::BF16_TO_FP, VT, Expand);

    setOperationAction(ISD::FP_TO_BF16, VT, Custom);

  }


  setOperationAction(ISD::PARITY, MVT::i8, Custom);

  setOperationAction(ISD::PARITY, MVT::i16, Custom);

  setOperationAction(ISD::PARITY, MVT::i32, Custom);

  if (Subtarget.is64Bit())

    setOperationAction(ISD::PARITY, MVT::i64, Custom);

  if (Subtarget.hasPOPCNT()) {

    setOperationPromotedToType(ISD::CTPOP, MVT::i8, MVT::i32);

    // popcntw is longer to encode than popcntl and also has a false dependency

    // on the dest that popcntl hasn't had since Cannon Lake.

    setOperationPromotedToType(ISD::CTPOP, MVT::i16, MVT::i32);

  } else {

    setOperationAction(ISD::CTPOP          , MVT::i8   , Custom);

    setOperationAction(ISD::CTPOP          , MVT::i16  , Custom);

    setOperationAction(ISD::CTPOP          , MVT::i32  , Custom);

    setOperationAction(ISD::CTPOP          , MVT::i64  , Custom);

  }


  setOperationAction(ISD::READCYCLECOUNTER , MVT::i64  , Custom);


  if (!Subtarget.hasMOVBE())

    setOperationAction(ISD::BSWAP          , MVT::i16  , Expand);


  // X86 wants to expand cmov itself.

  for (auto VT : { MVT::f32, MVT::f64, MVT::f80, MVT::f128 }) {

    setOperationAction(ISD::SELECT, VT, Custom);

    setOperationAction(ISD::SETCC, VT, Custom);

    setOperationAction(ISD::STRICT_FSETCC, VT, Custom);

    setOperationAction(ISD::STRICT_FSETCCS, VT, Custom);

  }

  for (auto VT : { MVT::i8, MVT::i16, MVT::i32, MVT::i64 }) {

    if (VT == MVT::i64 && !Subtarget.is64Bit())

      continue;

    setOperationAction(ISD::SELECT, VT, Custom);

    setOperationAction(ISD::SETCC,  VT, Custom);

  }


  setOperationAction(ISD::COND_LOOP, MVT::Other, Custom);


  // Custom action for SELECT MMX and expand action for SELECT_CC MMX

  setOperationAction(ISD::SELECT, MVT::x86mmx, Custom);

  setOperationAction(ISD::SELECT_CC, MVT::x86mmx, Expand);


  setOperationAction(ISD::EH_RETURN       , MVT::Other, Custom);

  // NOTE: EH_SJLJ_SETJMP/_LONGJMP are not recommended, since

  // LLVM/Clang supports zero-cost DWARF and SEH exception handling.

  setOperationAction(ISD::EH_SJLJ_SETJMP, MVT::i32, Custom);

  setOperationAction(ISD::EH_SJLJ_LONGJMP, MVT::Other, Custom);

  setOperationAction(ISD::EH_SJLJ_SETUP_DISPATCH, MVT::Other, Custom);


  // Darwin ABI issue.

  for (auto VT : { MVT::i32, MVT::i64 }) {

    if (VT == MVT::i64 && !Subtarget.is64Bit())

      continue;

    setOperationAction(ISD::ConstantPool    , VT, Custom);

    setOperationAction(ISD::JumpTable       , VT, Custom);

    setOperationAction(ISD::GlobalAddress   , VT, Custom);

    setOperationAction(ISD::GlobalTLSAddress, VT, Custom);

    setOperationAction(ISD::ExternalSymbol  , VT, Custom);

    setOperationAction(ISD::BlockAddress    , VT, Custom);

  }


  // 64-bit shl, sra, srl (iff 32-bit x86)

  for (auto VT : { MVT::i32, MVT::i64 }) {

    if (VT == MVT::i64 && !Subtarget.is64Bit())

      continue;

    setOperationAction(ISD::SHL_PARTS, VT, Custom);

    setOperationAction(ISD::SRA_PARTS, VT, Custom);

    setOperationAction(ISD::SRL_PARTS, VT, Custom);

  }


  if (Subtarget.hasSSEPrefetch())

    setOperationAction(ISD::PREFETCH      , MVT::Other, Custom);


  setOperationAction(ISD::ATOMIC_FENCE  , MVT::Other, Custom);


  // Expand certain atomics

  for (auto VT : { MVT::i8, MVT::i16, MVT::i32, MVT::i64 }) {

    setOperationAction(ISD::ATOMIC_CMP_SWAP_WITH_SUCCESS, VT, Custom);

    setOperationAction(ISD::ATOMIC_LOAD_SUB, VT, Custom);

    setOperationAction(ISD::ATOMIC_LOAD_ADD, VT, Custom);

    setOperationAction(ISD::ATOMIC_LOAD_OR, VT, Custom);

    setOperationAction(ISD::ATOMIC_LOAD_XOR, VT, Custom);

    setOperationAction(ISD::ATOMIC_LOAD_AND, VT, Custom);

    setOperationAction(ISD::ATOMIC_STORE, VT, Custom);

  }


  if (!Subtarget.is64Bit())

    setOperationAction(ISD::ATOMIC_LOAD, MVT::i64, Custom);


  if (Subtarget.is64Bit() && Subtarget.hasAVX()) {

    // All CPUs supporting AVX will atomically load/store aligned 128-bit

    // values, so we can emit [V]MOVAPS/[V]MOVDQA.

    setOperationAction(ISD::ATOMIC_LOAD, MVT::i128, Custom);

    setOperationAction(ISD::ATOMIC_STORE, MVT::i128, Custom);

  }


  if (Subtarget.canUseCMPXCHG16B())

    setOperationAction(ISD::ATOMIC_CMP_SWAP_WITH_SUCCESS, MVT::i128, Custom);


  // FIXME - use subtarget debug flags

  if (!Subtarget.isTargetDarwin() && !Subtarget.isTargetELF() &&

      !Subtarget.isTargetCygMing() && !Subtarget.isTargetWin64() &&

      TM.Options.ExceptionModel != ExceptionHandling::SjLj) {

    setOperationAction(ISD::EH_LABEL, MVT::Other, Expand);

  }


  setOperationAction(ISD::FRAME_TO_ARGS_OFFSET, MVT::i32, Custom);

  setOperationAction(ISD::FRAME_TO_ARGS_OFFSET, MVT::i64, Custom);


  setOperationAction(ISD::INIT_TRAMPOLINE, MVT::Other, Custom);

  setOperationAction(ISD::ADJUST_TRAMPOLINE, MVT::Other, Custom);


  setOperationAction(ISD::TRAP, MVT::Other, Legal);

  setOperationAction(ISD::DEBUGTRAP, MVT::Other, Legal);

  if (Subtarget.isTargetPS())

    setOperationAction(ISD::UBSANTRAP, MVT::Other, Expand);

  else

    setOperationAction(ISD::UBSANTRAP, MVT::Other, Legal);


  // VASTART needs to be custom lowered to use the VarArgsFrameIndex

  setOperationAction(ISD::VASTART           , MVT::Other, Custom);

  setOperationAction(ISD::VAEND             , MVT::Other, Expand);

  bool Is64Bit = Subtarget.is64Bit();

  setOperationAction(ISD::VAARG,  MVT::Other, Is64Bit ? Custom : Expand);

  setOperationAction(ISD::VACOPY, MVT::Other, Is64Bit ? Custom : Expand);


  setOperationAction(ISD::STACKSAVE,          MVT::Other, Expand);

  setOperationAction(ISD::STACKRESTORE,       MVT::Other, Expand);


  setOperationAction(ISD::DYNAMIC_STACKALLOC, PtrVT, Custom);


  // GC_TRANSITION_START and GC_TRANSITION_END need custom lowering.

  setOperationAction(ISD::GC_TRANSITION_START, MVT::Other, Custom);

  setOperationAction(ISD::GC_TRANSITION_END, MVT::Other, Custom);


  setOperationAction(ISD::STRICT_FP_EXTEND, MVT::f64, Legal);


  auto setF16Action = [&] (MVT VT, LegalizeAction Action) {

    setOperationAction(ISD::FABS, VT, Action);

    setOperationAction(ISD::FNEG, VT, Action);

    setOperationAction(ISD::FCOPYSIGN, VT, Expand);

    setOperationAction(ISD::FREM, VT, Action);

    setOperationAction(ISD::FMA, VT, Action);

    setOperationAction(ISD::FMINNUM, VT, Action);

    setOperationAction(ISD::FMAXNUM, VT, Action);

    setOperationAction(ISD::FMINIMUM, VT, Action);

    setOperationAction(ISD::FMAXIMUM, VT, Action);

    setOperationAction(ISD::FMINIMUMNUM, VT, Action);

    setOperationAction(ISD::FMAXIMUMNUM, VT, Action);

    setOperationAction(ISD::FSIN, VT, Action);

    setOperationAction(ISD::FCOS, VT, Action);

    setOperationAction(ISD::FSINCOS, VT, Action);

    setOperationAction(ISD::FTAN, VT, Action);

    setOperationAction(ISD::FSQRT, VT, Action);

    setOperationAction(ISD::FPOW, VT, Action);

    setOperationAction(ISD::FPOWI, VT, Action);

    setOperationAction(ISD::FLOG, VT, Action);

    setOperationAction(ISD::FLOG2, VT, Action);

    setOperationAction(ISD::FLOG10, VT, Action);

    setOperationAction(ISD::FEXP, VT, Action);

    setOperationAction(ISD::FEXP2, VT, Action);

    setOperationAction(ISD::FEXP10, VT, Action);

    setOperationAction(ISD::FCEIL, VT, Action);

    setOperationAction(ISD::FFLOOR, VT, Action);

    setOperationAction(ISD::FNEARBYINT, VT, Action);

    setOperationAction(ISD::FRINT, VT, Action);

    setOperationAction(ISD::BR_CC, VT, Action);

    setOperationAction(ISD::SETCC, VT, Action);

    setOperationAction(ISD::SELECT, VT, Custom);

    setOperationAction(ISD::SELECT_CC, VT, Action);

    setOperationAction(ISD::FROUND, VT, Action);

    setOperationAction(ISD::FROUNDEVEN, VT, Action);

    setOperationAction(ISD::FTRUNC, VT, Action);

    setOperationAction(ISD::FLDEXP, VT, Action);

    setOperationAction(ISD::FSINCOSPI, VT, Action);

  };


  if (!Subtarget.useSoftFloat() && Subtarget.hasSSE2()) {

    // f16, f32 and f64 use SSE.

    // Set up the FP register classes.

    addRegisterClass(MVT::f16, Subtarget.hasAVX512() ? &X86::FR16XRegClass

                                                     : &X86::FR16RegClass);

    addRegisterClass(MVT::f32, Subtarget.hasAVX512() ? &X86::FR32XRegClass

                                                     : &X86::FR32RegClass);

    addRegisterClass(MVT::f64, Subtarget.hasAVX512() ? &X86::FR64XRegClass

                                                     : &X86::FR64RegClass);


    // Disable f32->f64 extload as we can only generate this in one instruction

    // under optsize. So its easier to pattern match (fpext (load)) for that

    // case instead of needing to emit 2 instructions for extload in the

    // non-optsize case.

    setLoadExtAction(ISD::EXTLOAD, MVT::f64, MVT::f32, Expand);


    for (auto VT : { MVT::f32, MVT::f64 }) {

      // Use ANDPD to simulate FABS.

      setOperationAction(ISD::FABS, VT, Custom);


      // Use XORP to simulate FNEG.

      setOperationAction(ISD::FNEG, VT, Custom);


      // Use ANDPD and ORPD to simulate FCOPYSIGN.

      setOperationAction(ISD::FCOPYSIGN, VT, Custom);


      // These might be better off as horizontal vector ops.

      setOperationAction(ISD::FADD, VT, Custom);

      setOperationAction(ISD::FSUB, VT, Custom);


      // We don't support sin/cos/fmod

      setOperationAction(ISD::FSIN   , VT, Expand);

      setOperationAction(ISD::FCOS   , VT, Expand);

      setOperationAction(ISD::FSINCOS, VT, Expand);

    }


    // Half type will be promoted by default.

    setF16Action(MVT::f16, Promote);

    setOperationAction(ISD::FADD, MVT::f16, Promote);

    setOperationAction(ISD::FSUB, MVT::f16, Promote);

    setOperationAction(ISD::FMUL, MVT::f16, Promote);

    setOperationAction(ISD::FDIV, MVT::f16, Promote);

    setOperationAction(ISD::FABS, MVT::f16, Custom);

    setOperationAction(ISD::FNEG, MVT::f16, Custom);

    setOperationAction(ISD::FCOPYSIGN, MVT::f16, Custom);

    setOperationAction(ISD::FP_ROUND, MVT::f16, Custom);

    setOperationAction(ISD::FP_EXTEND, MVT::f32, Custom);

    setOperationAction(ISD::FP_EXTEND, MVT::f64, Custom);


    setOperationAction(ISD::STRICT_FADD, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FSUB, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FMUL, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FDIV, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FMA, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FMINNUM, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FMAXNUM, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FMINIMUM, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FMAXIMUM, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FSQRT, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FPOW, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FLDEXP, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FLOG, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FLOG2, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FLOG10, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FEXP, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FEXP2, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FCEIL, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FFLOOR, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FNEARBYINT, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FRINT, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FSETCC, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FSETCCS, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FROUND, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FROUNDEVEN, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FTRUNC, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FP_ROUND, MVT::f16, Custom);

    setOperationAction(ISD::STRICT_FP_EXTEND, MVT::f32, Custom);

    setOperationAction(ISD::STRICT_FP_EXTEND, MVT::f64, Custom);


    setOperationAction(ISD::LLROUND, MVT::f16, Expand);

    setOperationAction(ISD::LROUND, MVT::f16, Expand);

    setOperationAction(ISD::LRINT, MVT::f16, Expand);

    setOperationAction(ISD::LLRINT, MVT::f16, Expand);


    setOperationAction(ISD::STRICT_LLROUND, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_LROUND, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_LRINT, MVT::f16, Promote);

    setOperationAction(ISD::STRICT_LLRINT, MVT::f16, Promote);


    // Lower this to MOVMSK plus an AND.

    setOperationAction(ISD::FGETSIGN, MVT::i64, Custom);

    setOperationAction(ISD::FGETSIGN, MVT::i32, Custom);


  } else if (!Subtarget.useSoftFloat() && Subtarget.hasSSE1() &&

             (UseX87 || Is64Bit)) {

    // Use SSE for f32, x87 for f64.

    // Set up the FP register classes.

    addRegisterClass(MVT::f32, &X86::FR32RegClass);

    if (UseX87)

      addRegisterClass(MVT::f64, &X86::RFP64RegClass);


    // Use ANDPS to simulate FABS.

    setOperationAction(ISD::FABS , MVT::f32, Custom);


    // Use XORP to simulate FNEG.

    setOperationAction(ISD::FNEG , MVT::f32, Custom);


    if (UseX87)

      setOperationAction(ISD::UNDEF, MVT::f64, Expand);


    // Use ANDPS and ORPS to simulate FCOPYSIGN.

    if (UseX87)

      setOperationAction(ISD::FCOPYSIGN, MVT::f64, Expand);

    setOperationAction(ISD::FCOPYSIGN, MVT::f32, Custom);


    // We don't support sin/cos/fmod

    setOperationAction(ISD::FSIN   , MVT::f32, Expand);

    setOperationAction(ISD::FCOS   , MVT::f32, Expand);

    setOperationAction(ISD::FSINCOS, MVT::f32, Expand);


    if (UseX87) {

      // Always expand sin/cos functions even though x87 has an instruction.

      setOperationAction(ISD::FSIN, MVT::f64, Expand);

      setOperationAction(ISD::FCOS, MVT::f64, Expand);

      setOperationAction(ISD::FSINCOS, MVT::f64, Expand);

    }

  } else if (UseX87) {

    // f32 and f64 in x87.

    // Set up the FP register classes.

    addRegisterClass(MVT::f64, &X86::RFP64RegClass);

    addRegisterClass(MVT::f32, &X86::RFP32RegClass);


    for (auto VT : { MVT::f32, MVT::f64 }) {

      setOperationAction(ISD::UNDEF,     VT, Expand);

      setOperationAction(ISD::FCOPYSIGN, VT, Expand);


      // Always expand sin/cos functions even though x87 has an instruction.

      setOperationAction(ISD::FSIN   , VT, Expand);

      setOperationAction(ISD::FCOS   , VT, Expand);

      setOperationAction(ISD::FSINCOS, VT, Expand);

    }

  }


  // Expand FP32 immediates into loads from the stack, save special cases.

  if (isTypeLegal(MVT::f32)) {

    if (UseX87 && (getRegClassFor(MVT::f32) == &X86::RFP32RegClass)) {

      addLegalFPImmediate(APFloat(+0.0f)); // FLD0

      addLegalFPImmediate(APFloat(+1.0f)); // FLD1

      addLegalFPImmediate(APFloat(-0.0f)); // FLD0/FCHS

      addLegalFPImmediate(APFloat(-1.0f)); // FLD1/FCHS

    } else // SSE immediates.

      addLegalFPImmediate(APFloat(+0.0f)); // xorps

  }

  // Expand FP64 immediates into loads from the stack, save special cases.

  if (isTypeLegal(MVT::f64)) {

    if (UseX87 && getRegClassFor(MVT::f64) == &X86::RFP64RegClass) {

      addLegalFPImmediate(APFloat(+0.0)); // FLD0

      addLegalFPImmediate(APFloat(+1.0)); // FLD1

      addLegalFPImmediate(APFloat(-0.0)); // FLD0/FCHS

      addLegalFPImmediate(APFloat(-1.0)); // FLD1/FCHS

    } else // SSE immediates.

      addLegalFPImmediate(APFloat(+0.0)); // xorpd

  }

  // Support fp16 0 immediate.

  if (isTypeLegal(MVT::f16))

    addLegalFPImmediate(APFloat::getZero(APFloat::IEEEhalf()));


  // Handle constrained floating-point operations of scalar.

  setOperationAction(ISD::STRICT_FADD,      MVT::f32, Legal);

  setOperationAction(ISD::STRICT_FADD,      MVT::f64, Legal);

  setOperationAction(ISD::STRICT_FSUB,      MVT::f32, Legal);

  setOperationAction(ISD::STRICT_FSUB,      MVT::f64, Legal);

  setOperationAction(ISD::STRICT_FMUL,      MVT::f32, Legal);

  setOperationAction(ISD::STRICT_FMUL,      MVT::f64, Legal);

  setOperationAction(ISD::STRICT_FDIV,      MVT::f32, Legal);

  setOperationAction(ISD::STRICT_FDIV,      MVT::f64, Legal);

  setOperationAction(ISD::STRICT_FP_ROUND,  MVT::f32, Legal);

  setOperationAction(ISD::STRICT_FP_ROUND,  MVT::f64, Legal);

  setOperationAction(ISD::STRICT_FSQRT,     MVT::f32, Legal);

  setOperationAction(ISD::STRICT_FSQRT,     MVT::f64, Legal);


  // We don't support FMA.

  setOperationAction(ISD::FMA, MVT::f64, Expand);

  setOperationAction(ISD::FMA, MVT::f32, Expand);


  // f80 always uses X87.

  if (UseX87) {

    addRegisterClass(MVT::f80, &X86::RFP80RegClass);

    setOperationAction(ISD::UNDEF,     MVT::f80, Expand);

    setOperationAction(ISD::FCOPYSIGN, MVT::f80, Expand);

    {

      APFloat TmpFlt = APFloat::getZero(APFloat::x87DoubleExtended());

      addLegalFPImmediate(TmpFlt);  // FLD0

      TmpFlt.changeSign();

      addLegalFPImmediate(TmpFlt);  // FLD0/FCHS


      bool ignored;

      APFloat TmpFlt2(+1.0);

      TmpFlt2.convert(APFloat::x87DoubleExtended(), APFloat::rmNearestTiesToEven,

                      &ignored);

      addLegalFPImmediate(TmpFlt2);  // FLD1

      TmpFlt2.changeSign();

      addLegalFPImmediate(TmpFlt2);  // FLD1/FCHS

    }


    // Always expand sin/cos functions even though x87 has an instruction.

    // clang-format off

    setOperationAction(ISD::FSIN   , MVT::f80, Expand);

    setOperationAction(ISD::FCOS   , MVT::f80, Expand);

    setOperationAction(ISD::FSINCOS, MVT::f80, Expand);

    setOperationAction(ISD::FTAN   , MVT::f80, Expand);

    setOperationAction(ISD::FASIN  , MVT::f80, Expand);

    setOperationAction(ISD::FACOS  , MVT::f80, Expand);

    setOperationAction(ISD::FATAN  , MVT::f80, Expand);

    setOperationAction(ISD::FATAN2 , MVT::f80, Expand);

    setOperationAction(ISD::FSINH  , MVT::f80, Expand);

    setOperationAction(ISD::FCOSH  , MVT::f80, Expand);

    setOperationAction(ISD::FTANH  , MVT::f80, Expand);

    // clang-format on


    setOperationAction(ISD::FFLOOR, MVT::f80, Expand);

    setOperationAction(ISD::FCEIL,  MVT::f80, Expand);

    setOperationAction(ISD::FTRUNC, MVT::f80, Expand);

    setOperationAction(ISD::FRINT,  MVT::f80, Expand);

    setOperationAction(ISD::FNEARBYINT, MVT::f80, Expand);

    setOperationAction(ISD::FROUNDEVEN, MVT::f80, Expand);

    setOperationAction(ISD::FMA, MVT::f80, Expand);

    setOperationAction(ISD::LROUND, MVT::f80, LibCall);

    setOperationAction(ISD::LLROUND, MVT::f80, LibCall);

    setOperationAction(ISD::LRINT, MVT::f80, Custom);

    setOperationAction(ISD::LLRINT, MVT::f80, Custom);


    // Handle constrained floating-point operations of scalar.

    setOperationAction(ISD::STRICT_FADD     , MVT::f80, Legal);

    setOperationAction(ISD::STRICT_FSUB     , MVT::f80, Legal);

    setOperationAction(ISD::STRICT_FMUL     , MVT::f80, Legal);

    setOperationAction(ISD::STRICT_FDIV     , MVT::f80, Legal);

    setOperationAction(ISD::STRICT_FSQRT    , MVT::f80, Legal);

    setOperationAction(ISD::FCANONICALIZE, MVT::f80, Expand);

    if (isTypeLegal(MVT::f16)) {

      setOperationAction(ISD::FP_EXTEND, MVT::f80, Custom);

      setOperationAction(ISD::STRICT_FP_EXTEND, MVT::f80, Custom);

    } else {

      setOperationAction(ISD::STRICT_FP_EXTEND, MVT::f80, Legal);

    }

    // FIXME: When the target is 64-bit, STRICT_FP_ROUND will be overwritten

    // as Custom.

    setOperationAction(ISD::STRICT_FP_ROUND, MVT::f80, Legal);

  }


  // f128 uses xmm registers, but most operations require libcalls.

  if (!Subtarget.useSoftFloat() && Subtarget.is64Bit() && Subtarget.hasSSE1()) {

    addRegisterClass(MVT::f128, Subtarget.hasVLX() ? &X86::VR128XRegClass

                                                   : &X86::VR128RegClass);


    addLegalFPImmediate(APFloat::getZero(APFloat::IEEEquad())); // xorps


    setOperationAction(ISD::FADD,        MVT::f128, LibCall);

    setOperationAction(ISD::STRICT_FADD, MVT::f128, LibCall);

    setOperationAction(ISD::FSUB,        MVT::f128, LibCall);

    setOperationAction(ISD::STRICT_FSUB, MVT::f128, LibCall);

    setOperationAction(ISD::FDIV,        MVT::f128, LibCall);

    setOperationAction(ISD::STRICT_FDIV, MVT::f128, LibCall);

    setOperationAction(ISD::FMUL,        MVT::f128, LibCall);

    setOperationAction(ISD::STRICT_FMUL, MVT::f128, LibCall);

    setOperationAction(ISD::FMA,         MVT::f128, LibCall);

    setOperationAction(ISD::STRICT_FMA,  MVT::f128, LibCall);


    setOperationAction(ISD::FABS, MVT::f128, Custom);

    setOperationAction(ISD::FNEG, MVT::f128, Custom);

    setOperationAction(ISD::FCOPYSIGN, MVT::f128, Custom);


    // clang-format off

    setOperationAction(ISD::FSIN,         MVT::f128, LibCall);

    setOperationAction(ISD::STRICT_FSIN,  MVT::f128, LibCall);

    setOperationAction(ISD::FCOS,         MVT::f128, LibCall);

    setOperationAction(ISD::STRICT_FCOS,  MVT::f128, LibCall);

    setOperationAction(ISD::FSINCOS,      MVT::f128, LibCall);

    setOperationAction(ISD::FTAN,         MVT::f128, LibCall);

    setOperationAction(ISD::STRICT_FTAN,  MVT::f128, LibCall);

    // clang-format on

    // No STRICT_FSINCOS

    setOperationAction(ISD::FSQRT,        MVT::f128, LibCall);

    setOperationAction(ISD::STRICT_FSQRT, MVT::f128, LibCall);


    setOperationAction(ISD::FP_EXTEND,        MVT::f128, Custom);

    setOperationAction(ISD::STRICT_FP_EXTEND, MVT::f128, Custom);

    // We need to custom handle any FP_ROUND with an f128 input, but

    // LegalizeDAG uses the result type to know when to run a custom handler.

    // So we have to list all legal floating point result types here.

    if (isTypeLegal(MVT::f32)) {

      setOperationAction(ISD::FP_ROUND, MVT::f32, Custom);

      setOperationAction(ISD::STRICT_FP_ROUND, MVT::f32, Custom);

    }

    if (isTypeLegal(MVT::f64)) {

      setOperationAction(ISD::FP_ROUND, MVT::f64, Custom);

      setOperationAction(ISD::STRICT_FP_ROUND, MVT::f64, Custom);

    }

    if (isTypeLegal(MVT::f80)) {

      setOperationAction(ISD::FP_ROUND, MVT::f80, Custom);

      setOperationAction(ISD::STRICT_FP_ROUND, MVT::f80, Custom);

      setOperationAction(ISD::FCANONICALIZE, MVT::f80, Expand);

    }


    setOperationAction(ISD::SETCC, MVT::f128, Custom);


    setLoadExtAction(ISD::EXTLOAD, MVT::f128, MVT::f32, Expand);

    setLoadExtAction(ISD::EXTLOAD, MVT::f128, MVT::f64, Expand);

    setLoadExtAction(ISD::EXTLOAD, MVT::f128, MVT::f80, Expand);

    setTruncStoreAction(MVT::f128, MVT::f32, Expand);

    setTruncStoreAction(MVT::f128, MVT::f64, Expand);

    setTruncStoreAction(MVT::f128, MVT::f80, Expand);

  }


  // Always use a library call for pow.

  setOperationAction(ISD::FPOW             , MVT::f32  , Expand);

  setOperationAction(ISD::FPOW             , MVT::f64  , Expand);

  setOperationAction(ISD::FPOW             , MVT::f80  , Expand);

  setOperationAction(ISD::FPOW             , MVT::f128 , Expand);


  setOperationAction(ISD::FLOG, MVT::f80, Expand);

  setOperationAction(ISD::FLOG2, MVT::f80, Expand);

  setOperationAction(ISD::FLOG10, MVT::f80, Expand);

  setOperationAction(ISD::FEXP, MVT::f80, Expand);

  setOperationAction(ISD::FEXP2, MVT::f80, Expand);

  setOperationAction(ISD::FEXP10, MVT::f80, Expand);

  setOperationAction(ISD::FMINNUM, MVT::f80, Expand);

  setOperationAction(ISD::FMAXNUM, MVT::f80, Expand);


  // Some FP actions are always expanded for vector types.

  for (auto VT : { MVT::v8f16, MVT::v16f16, MVT::v32f16,

                   MVT::v4f32, MVT::v8f32,  MVT::v16f32,

                   MVT::v2f64, MVT::v4f64,  MVT::v8f64 }) {

    // clang-format off

    setOperationAction(ISD::FSIN,      VT, Expand);

    setOperationAction(ISD::FSINCOS,   VT, Expand);

    setOperationAction(ISD::FCOS,      VT, Expand);

    setOperationAction(ISD::FTAN,      VT, Expand);

    setOperationAction(ISD::FREM,      VT, Expand);

    setOperationAction(ISD::FCOPYSIGN, VT, Expand);

    setOperationAction(ISD::FPOW,      VT, Expand);

    setOperationAction(ISD::FLOG,      VT, Expand);

    setOperationAction(ISD::FLOG2,     VT, Expand);

    setOperationAction(ISD::FLOG10,    VT, Expand);

    setOperationAction(ISD::FEXP,      VT, Expand);

    setOperationAction(ISD::FEXP2,     VT, Expand);

    setOperationAction(ISD::FEXP10,    VT, Expand);

    // clang-format on

  }


  // First set operation action for all vector types to either promote

  // (for widening) or expand (for scalarization). Then we will selectively

  // turn on ones that can be effectively codegen'd.

  for (MVT VT : MVT::fixedlen_vector_valuetypes()) {

    setOperationAction(ISD::SDIV, VT, Expand);

    setOperationAction(ISD::UDIV, VT, Expand);

    setOperationAction(ISD::SREM, VT, Expand);

    setOperationAction(ISD::UREM, VT, Expand);

    setOperationAction(ISD::EXTRACT_VECTOR_ELT, VT,Expand);

    setOperationAction(ISD::INSERT_VECTOR_ELT, VT, Expand);

    setOperationAction(ISD::EXTRACT_SUBVECTOR, VT,Expand);

    setOperationAction(ISD::INSERT_SUBVECTOR, VT,Expand);

    setOperationAction(ISD::FMA,  VT, Expand);

    setOperationAction(ISD::FFLOOR, VT, Expand);

    setOperationAction(ISD::FCEIL, VT, Expand);

    setOperationAction(ISD::FTRUNC, VT, Expand);

    setOperationAction(ISD::FRINT, VT, Expand);

    setOperationAction(ISD::FNEARBYINT, VT, Expand);

    setOperationAction(ISD::FROUNDEVEN, VT, Expand);

    setOperationAction(ISD::SMUL_LOHI, VT, Expand);

    setOperationAction(ISD::MULHS, VT, Expand);

    setOperationAction(ISD::UMUL_LOHI, VT, Expand);

    setOperationAction(ISD::MULHU, VT, Expand);

    setOperationAction(ISD::SDIVREM, VT, Expand);

    setOperationAction(ISD::UDIVREM, VT, Expand);

    setOperationAction(ISD::CTPOP, VT, Expand);

    setOperationAction(ISD::CTTZ, VT, Expand);

    setOperationAction(ISD::CTLZ, VT, Expand);

    setOperationAction(ISD::ROTL, VT, Expand);

    setOperationAction(ISD::ROTR, VT, Expand);

    setOperationAction(ISD::BSWAP, VT, Expand);

    setOperationAction(ISD::SETCC, VT, Expand);

    setOperationAction(ISD::FP_TO_UINT, VT, Expand);

    setOperationAction(ISD::FP_TO_SINT, VT, Expand);

    setOperationAction(ISD::UINT_TO_FP, VT, Expand);

    setOperationAction(ISD::SINT_TO_FP, VT, Expand);

    setOperationAction(ISD::SIGN_EXTEND_INREG, VT,Expand);

    setOperationAction(ISD::TRUNCATE, VT, Expand);

    setOperationAction(ISD::SIGN_EXTEND, VT, Expand);

    setOperationAction(ISD::ZERO_EXTEND, VT, Expand);

    setOperationAction(ISD::ANY_EXTEND, VT, Expand);

    setOperationAction(ISD::SELECT_CC, VT, Expand);

    for (MVT InnerVT : MVT::fixedlen_vector_valuetypes()) {

      setTruncStoreAction(InnerVT, VT, Expand);


      setLoadExtAction(ISD::SEXTLOAD, InnerVT, VT, Expand);

      setLoadExtAction(ISD::ZEXTLOAD, InnerVT, VT, Expand);


      // N.b. ISD::EXTLOAD legality is basically ignored except for i1-like

      // types, we have to deal with them whether we ask for Expansion or not.

      // Setting Expand causes its own optimisation problems though, so leave

      // them legal.

      if (VT.getVectorElementType() == MVT::i1)

        setLoadExtAction(ISD::EXTLOAD, InnerVT, VT, Expand);


      // EXTLOAD for MVT::f16 vectors is not legal because f16 vectors are

      // split/scalarized right now.

      if (VT.getVectorElementType() == MVT::f16 ||

          VT.getVectorElementType() == MVT::bf16)

        setLoadExtAction(ISD::EXTLOAD, InnerVT, VT, Expand);

    }

  }


  // FIXME: In order to prevent SSE instructions being expanded to MMX ones

  // with -msoft-float, disable use of MMX as well.

  if (!Subtarget.useSoftFloat() && Subtarget.hasMMX()) {

    addRegisterClass(MVT::x86mmx, &X86::VR64RegClass);

    // No operations on x86mmx supported, everything uses intrinsics.

  }


  if (!Subtarget.useSoftFloat() && Subtarget.hasSSE1()) {

    addRegisterClass(MVT::v4f32, Subtarget.hasVLX() ? &X86::VR128XRegClass

                                                    : &X86::VR128RegClass);


    setOperationAction(ISD::FMAXIMUM,           MVT::f32, Custom);

    setOperationAction(ISD::FMINIMUM,           MVT::f32, Custom);

    setOperationAction(ISD::FMAXIMUMNUM,        MVT::f32, Custom);

    setOperationAction(ISD::FMINIMUMNUM,        MVT::f32, Custom);


    setOperationAction(ISD::FNEG,               MVT::v4f32, Custom);

    setOperationAction(ISD::FABS,               MVT::v4f32, Custom);

    setOperationAction(ISD::FCOPYSIGN,          MVT::v4f32, Custom);

    setOperationAction(ISD::BUILD_VECTOR,       MVT::v4f32, Custom);

    setOperationAction(ISD::VECTOR_SHUFFLE,     MVT::v4f32, Custom);

    setOperationAction(ISD::VSELECT,            MVT::v4f32, Custom);

    setOperationAction(ISD::EXTRACT_VECTOR_ELT, MVT::v4f32, Custom);

    setOperationAction(ISD::SELECT,             MVT::v4f32, Custom);

    setOperationAction(ISD::FCANONICALIZE, MVT::v4f32, Expand);


    setOperationAction(ISD::LOAD,               MVT::v2f32, Custom);

    setOperationAction(ISD::STORE,              MVT::v2f32, Custom);

    setOperationAction(ISD::FCANONICALIZE, MVT::v2f32, Expand);


    setOperationAction(ISD::STRICT_FADD,        MVT::v4f32, Legal);

    setOperationAction(ISD::STRICT_FSUB,        MVT::v4f32, Legal);

    setOperationAction(ISD::STRICT_FMUL,        MVT::v4f32, Legal);

    setOperationAction(ISD::STRICT_FDIV,        MVT::v4f32, Legal);

    setOperationAction(ISD::STRICT_FSQRT,       MVT::v4f32, Legal);

  }


  if (!Subtarget.useSoftFloat() && Subtarget.hasSSE2()) {

    addRegisterClass(MVT::v2f64, Subtarget.hasVLX() ? &X86::VR128XRegClass

                                                    : &X86::VR128RegClass);


    // FIXME: Unfortunately, -soft-float and -no-implicit-float mean XMM

    // registers cannot be used even for integer operations.

    addRegisterClass(MVT::v16i8, Subtarget.hasVLX() ? &X86::VR128XRegClass

                                                    : &X86::VR128RegClass);

    addRegisterClass(MVT::v8i16, Subtarget.hasVLX() ? &X86::VR128XRegClass

                                                    : &X86::VR128RegClass);

    addRegisterClass(MVT::v8f16, Subtarget.hasVLX() ? &X86::VR128XRegClass

                                                    : &X86::VR128RegClass);

    addRegisterClass(MVT::v4i32, Subtarget.hasVLX() ? &X86::VR128XRegClass

                                                    : &X86::VR128RegClass);

    addRegisterClass(MVT::v2i64, Subtarget.hasVLX() ? &X86::VR128XRegClass

                                                    : &X86::VR128RegClass);


    for (auto VT : { MVT::f64, MVT::v4f32, MVT::v2f64 }) {

      setOperationAction(ISD::FMAXIMUM, VT, Custom);

      setOperationAction(ISD::FMINIMUM, VT, Custom);

      setOperationAction(ISD::FMAXIMUMNUM, VT, Custom);

      setOperationAction(ISD::FMINIMUMNUM, VT, Custom);

    }


    setOperationAction(ISD::MUL,                MVT::v2i8,  Custom);

    setOperationAction(ISD::MUL,                MVT::v4i8,  Custom);

    setOperationAction(ISD::MUL,                MVT::v8i8,  Custom);


    setOperationAction(ISD::MUL,                MVT::v16i8, Custom);

    setOperationAction(ISD::MUL,                MVT::v4i32, Custom);

    setOperationAction(ISD::MUL,                MVT::v2i64, Custom);

    setOperationAction(ISD::MULHU,              MVT::v4i32, Custom);

    setOperationAction(ISD::MULHS,              MVT::v4i32, Custom);

    setOperationAction(ISD::MULHU,              MVT::v16i8, Custom);

    setOperationAction(ISD::MULHS,              MVT::v16i8, Custom);

    setOperationAction(ISD::MULHU,              MVT::v8i16, Legal);

    setOperationAction(ISD::MULHS,              MVT::v8i16, Legal);

    setOperationAction(ISD::MUL,                MVT::v8i16, Legal);

    setOperationAction(ISD::AVGCEILU,           MVT::v16i8, Legal);

    setOperationAction(ISD::AVGCEILU,           MVT::v8i16, Legal);


    setOperationAction(ISD::SMULO,              MVT::v16i8, Custom);

    setOperationAction(ISD::UMULO,              MVT::v16i8, Custom);

    setOperationAction(ISD::UMULO,              MVT::v2i32, Custom);


    setOperationAction(ISD::FNEG,               MVT::v2f64, Custom);

    setOperationAction(ISD::FCANONICALIZE, MVT::v2f64, Expand);

    setOperationAction(ISD::FABS,               MVT::v2f64, Custom);

    setOperationAction(ISD::FCOPYSIGN,          MVT::v2f64, Custom);


    setOperationAction(ISD::LRINT, MVT::v4f32, Custom);

    setOperationAction(ISD::LRINT, MVT::v2i32, Custom);


    setOperationAction(ISD::AND, MVT::i128, Custom);

    setOperationAction(ISD::OR, MVT::i128, Custom);

    setOperationAction(ISD::XOR, MVT::i128, Custom);

    setOperationAction(ISD::SELECT, MVT::i128, Custom);


    if (Subtarget.hasPCLMUL()) {

      for (auto VT : {MVT::i64, MVT::v4i32, MVT::v2i64}) {

        setOperationAction(ISD::CLMUL, VT, Custom);

        setOperationAction(ISD::CLMULH, VT, Custom);

      }

      setOperationAction(ISD::CLMUL, MVT::i32, Custom);

      setOperationAction(ISD::CLMUL, MVT::i16, Custom);

      setOperationAction(ISD::CLMUL, MVT::i8, Custom);

    }


    for (auto VT : { MVT::v16i8, MVT::v8i16, MVT::v4i32, MVT::v2i64 }) {

      setOperationAction(ISD::SMAX, VT, VT == MVT::v8i16 ? Legal : Custom);

      setOperationAction(ISD::SMIN, VT, VT == MVT::v8i16 ? Legal : Custom);

      setOperationAction(ISD::UMAX, VT, VT == MVT::v16i8 ? Legal : Custom);

      setOperationAction(ISD::UMIN, VT, VT == MVT::v16i8 ? Legal : Custom);

    }


    setOperationAction(ISD::UADDSAT,            MVT::v16i8, Legal);

    setOperationAction(ISD::SADDSAT,            MVT::v16i8, Legal);

    setOperationAction(ISD::USUBSAT,            MVT::v16i8, Legal);

    setOperationAction(ISD::SSUBSAT,            MVT::v16i8, Legal);

    setOperationAction(ISD::UADDSAT,            MVT::v8i16, Legal);

    setOperationAction(ISD::SADDSAT,            MVT::v8i16, Legal);

    setOperationAction(ISD::USUBSAT,            MVT::v8i16, Legal);

    setOperationAction(ISD::SSUBSAT,            MVT::v8i16, Legal);

    setOperationAction(ISD::USUBSAT,            MVT::v4i32, Custom);

    setOperationAction(ISD::USUBSAT,            MVT::v2i64, Custom);


    setOperationAction(ISD::INSERT_VECTOR_ELT,  MVT::v16i8, Custom);

    setOperationAction(ISD::INSERT_VECTOR_ELT,  MVT::v8i16, Custom);

    setOperationAction(ISD::INSERT_VECTOR_ELT,  MVT::v4i32, Custom);

    setOperationAction(ISD::INSERT_VECTOR_ELT,  MVT::v4f32, Custom);


    for (auto VT : { MVT::v16i8, MVT::v8i16, MVT::v4i32, MVT::v2i64 }) {

      setOperationAction(ISD::SETCC, VT, Custom);

      setOperationAction(ISD::CTPOP, VT, Custom);

      setOperationAction(ISD::ABS, VT, Custom);

      setOperationAction(ISD::ABDS, VT, Custom);

      setOperationAction(ISD::ABDU, VT, Custom);


      // The condition codes aren't legal in SSE/AVX and under AVX512 we use

      // setcc all the way to isel and prefer SETGT in some isel patterns.

      setCondCodeAction(ISD::SETLT, VT, Custom);

      setCondCodeAction(ISD::SETLE, VT, Custom);

    }


    setOperationAction(ISD::SETCC,          MVT::v2f64, Custom);

    setOperationAction(ISD::SETCC,          MVT::v4f32, Custom);

    setOperationAction(ISD::STRICT_FSETCC,  MVT::v2f64, Custom);

    setOperationAction(ISD::STRICT_FSETCC,  MVT::v4f32, Custom);

    setOperationAction(ISD::STRICT_FSETCCS, MVT::v2f64, Custom);

    setOperationAction(ISD::STRICT_FSETCCS, MVT::v4f32, Custom);


    for (auto VT : { MVT::v16i8, MVT::v8i16, MVT::v4i32 }) {

      setOperationAction(ISD::SCALAR_TO_VECTOR,   VT, Custom);

      setOperationAction(ISD::BUILD_VECTOR,       VT, Custom);

      setOperationAction(ISD::VECTOR_SHUFFLE,     VT, Custom);

      setOperationAction(ISD::VSELECT,            VT, Custom);

      setOperationAction(ISD::EXTRACT_VECTOR_ELT, VT, Custom);

    }


    for (auto VT : { MVT::v8f16, MVT::v2f64, MVT::v2i64 }) {

      setOperationAction(ISD::BUILD_VECTOR,       VT, Custom);

      setOperationAction(ISD::VECTOR_SHUFFLE,     VT, Custom);

      setOperationAction(ISD::VSELECT,            VT, Custom);


      if (VT == MVT::v2i64 && !Subtarget.is64Bit())

        continue;


      setOperationAction(ISD::INSERT_VECTOR_ELT,  VT, Custom);

      setOperationAction(ISD::EXTRACT_VECTOR_ELT, VT, Custom);

    }

    setF16Action(MVT::v8f16, Expand);

    setOperationAction(ISD::FADD, MVT::v8f16, Expand);

    setOperationAction(ISD::FSUB, MVT::v8f16, Expand);

    setOperationAction(ISD::FMUL, MVT::v8f16, Expand);

    setOperationAction(ISD::FDIV, MVT::v8f16, Expand);

    setOperationAction(ISD::FNEG, MVT::v8f16, Custom);

    setOperationAction(ISD::FABS, MVT::v8f16, Custom);

    setOperationAction(ISD::FCOPYSIGN, MVT::v8f16, Custom);


    // Custom lower v2i64 and v2f64 selects.

    setOperationAction(ISD::SELECT,             MVT::v2f64, Custom);

    setOperationAction(ISD::SELECT,             MVT::v2i64, Custom);

    setOperationAction(ISD::SELECT,             MVT::v4i32, Custom);

    setOperationAction(ISD::SELECT,             MVT::v8i16, Custom);

    setOperationAction(ISD::SELECT,             MVT::v8f16, Custom);

    setOperationAction(ISD::SELECT,             MVT::v16i8, Custom);


    setOperationAction(ISD::FP_TO_SINT,         MVT::v4i32, Custom);

    setOperationAction(ISD::FP_TO_UINT,         MVT::v4i32, Custom);

    setOperationAction(ISD::FP_TO_SINT,         MVT::v2i32, Custom);

    setOperationAction(ISD::FP_TO_UINT,         MVT::v2i32, Custom);

    setOperationAction(ISD::STRICT_FP_TO_SINT,  MVT::v4i32, Custom);

    setOperationAction(ISD::STRICT_FP_TO_SINT,  MVT::v2i32, Custom);


    // Custom legalize these to avoid over promotion or custom promotion.

    for (auto VT : {MVT::v2i8, MVT::v4i8, MVT::v8i8, MVT::v2i16, MVT::v4i16}) {

      setOperationAction(ISD::FP_TO_SINT,        VT, Custom);

      setOperationAction(ISD::FP_TO_UINT,        VT, Custom);

      setOperationAction(ISD::STRICT_FP_TO_SINT, VT, Custom);

      setOperationAction(ISD::STRICT_FP_TO_UINT, VT, Custom);

    }


    setOperationAction(ISD::SINT_TO_FP,         MVT::v4i32, Custom);

    setOperationAction(ISD::STRICT_SINT_TO_FP,  MVT::v4i32, Custom);

    setOperationAction(ISD::SINT_TO_FP,         MVT::v2i32, Custom);

    setOperationAction(ISD::STRICT_SINT_TO_FP,  MVT::v2i32, Custom);


    setOperationAction(ISD::UINT_TO_FP,         MVT::v2i32, Custom);

    setOperationAction(ISD::STRICT_UINT_TO_FP,  MVT::v2i32, Custom);


    setOperationAction(ISD::UINT_TO_FP,         MVT::v4i32, Custom);

    setOperationAction(ISD::STRICT_UINT_TO_FP,  MVT::v4i32, Custom);


    // Fast v2f32 UINT_TO_FP( v2i32 ) custom conversion.

    setOperationAction(ISD::SINT_TO_FP,         MVT::v2f32, Custom);

    setOperationAction(ISD::STRICT_SINT_TO_FP,  MVT::v2f32, Custom);

    setOperationAction(ISD::UINT_TO_FP,         MVT::v2f32, Custom);

    setOperationAction(ISD::STRICT_UINT_TO_FP,  MVT::v2f32, Custom);


    setOperationAction(ISD::FP_EXTEND,          MVT::v2f32, Custom);

    setOperationAction(ISD::STRICT_FP_EXTEND,   MVT::v2f32, Custom);

    setOperationAction(ISD::FP_ROUND,           MVT::v2f32, Custom);

    setOperationAction(ISD::STRICT_FP_ROUND,    MVT::v2f32, Custom);


    // We want to legalize this to an f64 load rather than an i64 load on

    // 64-bit targets and two 32-bit loads on a 32-bit target. Similar for

    // store.

    setOperationAction(ISD::LOAD,               MVT::v2i32, Custom);

    setOperationAction(ISD::LOAD,               MVT::v4i16, Custom);

    setOperationAction(ISD::LOAD,               MVT::v8i8,  Custom);

    setOperationAction(ISD::STORE,              MVT::v2i32, Custom);

    setOperationAction(ISD::STORE,              MVT::v4i16, Custom);

    setOperationAction(ISD::STORE,              MVT::v8i8,  Custom);


    // Add 32-bit vector stores to help vectorization opportunities.

    setOperationAction(ISD::STORE,              MVT::v2i16, Custom);

    setOperationAction(ISD::STORE,              MVT::v4i8,  Custom);


    setOperationAction(ISD::BITCAST,            MVT::v2i32, Custom);

    setOperationAction(ISD::BITCAST,            MVT::v4i16, Custom);

    setOperationAction(ISD::BITCAST,            MVT::v8i8,  Custom);

    if (!Subtarget.hasAVX512())

      setOperationAction(ISD::BITCAST, MVT::v16i1, Custom);


    setOperationAction(ISD::SIGN_EXTEND_VECTOR_INREG, MVT::v2i64, Custom);

    setOperationAction(ISD::SIGN_EXTEND_VECTOR_INREG, MVT::v4i32, Custom);

    setOperationAction(ISD::SIGN_EXTEND_VECTOR_INREG, MVT::v8i16, Custom);


    setOperationAction(ISD::SIGN_EXTEND, MVT::v4i64, Custom);


    setOperationAction(ISD::TRUNCATE,    MVT::v2i8,  Custom);

    setOperationAction(ISD::TRUNCATE,    MVT::v2i16, Custom);

    setOperationAction(ISD::TRUNCATE,    MVT::v2i32, Custom);

    setOperationAction(ISD::TRUNCATE,    MVT::v2i64, Custom);

    setOperationAction(ISD::TRUNCATE,    MVT::v4i8,  Custom);

    setOperationAction(ISD::TRUNCATE,    MVT::v4i16, Custom);

    setOperationAction(ISD::TRUNCATE,    MVT::v4i32, Custom);

    setOperationAction(ISD::TRUNCATE,    MVT::v4i64, Custom);

    setOperationAction(ISD::TRUNCATE,    MVT::v8i8,  Custom);

    setOperationAction(ISD::TRUNCATE,    MVT::v8i16, Custom);

    setOperationAction(ISD::TRUNCATE,    MVT::v8i32, Custom);

    setOperationAction(ISD::TRUNCATE,    MVT::v8i64, Custom);

    setOperationAction(ISD::TRUNCATE,    MVT::v16i8, Custom);

    setOperationAction(ISD::TRUNCATE,    MVT::v16i16, Custom);

    setOperationAction(ISD::TRUNCATE,    MVT::v16i32, Custom);

    setOperationAction(ISD::TRUNCATE,    MVT::v16i64, Custom);


    // In the customized shift lowering, the legal v4i32/v2i64 cases

    // in AVX2 will be recognized.

    for (auto VT : { MVT::v16i8, MVT::v8i16, MVT::v4i32, MVT::v2i64 }) {

      setOperationAction(ISD::SRL,              VT, Custom);

      setOperationAction(ISD::SHL,              VT, Custom);

      setOperationAction(ISD::SRA,              VT, Custom);

      if (VT == MVT::v2i64) continue;

      setOperationAction(ISD::ROTL,             VT, Custom);

      setOperationAction(ISD::ROTR,             VT, Custom);

      setOperationAction(ISD::FSHL,             VT, Custom);

      setOperationAction(ISD::FSHR,             VT, Custom);

    }


    setOperationAction(ISD::STRICT_FSQRT,       MVT::v2f64, Legal);

    setOperationAction(ISD::STRICT_FADD,        MVT::v2f64, Legal);

    setOperationAction(ISD::STRICT_FSUB,        MVT::v2f64, Legal);

    setOperationAction(ISD::STRICT_FMUL,        MVT::v2f64, Legal);

    setOperationAction(ISD::STRICT_FDIV,        MVT::v2f64, Legal);

  }


  if (!Subtarget.useSoftFloat() && Subtarget.hasGFNI()) {

    setOperationAction(ISD::BITREVERSE, MVT::i8, Custom);

    setOperationAction(ISD::BITREVERSE, MVT::i16, Custom);

    setOperationAction(ISD::BITREVERSE, MVT::i32, Custom);

    setOperationAction(ISD::BITREVERSE, MVT::i64, Custom);


    for (auto VT : {MVT::v16i8, MVT::v8i16, MVT::v4i32, MVT::v2i64}) {

      setOperationAction(ISD::BITREVERSE, VT, Custom);

    }


    setOperationAction(ISD::CTLZ, MVT::v16i8, Custom);

    setOperationAction(ISD::CTTZ, MVT::v16i8, Custom);

  }


  if (!Subtarget.useSoftFloat() && Subtarget.hasSSSE3()) {

    setOperationAction(ISD::ABS,                MVT::v16i8, Legal);

    setOperationAction(ISD::ABS,                MVT::v8i16, Legal);

    setOperationAction(ISD::ABS,                MVT::v4i32, Legal);


    for (auto VT : {MVT::v16i8, MVT::v8i16, MVT::v4i32, MVT::v2i64}) {

      setOperationAction(ISD::BITREVERSE,       VT, Custom);

      setOperationAction(ISD::CTLZ,             VT, Custom);

    }

    setOperationAction(ISD::BITREVERSE,        MVT::i128, Custom);


    // These might be better off as horizontal vector ops.

    setOperationAction(ISD::ADD,                MVT::i16, Custom);

    setOperationAction(ISD::ADD,                MVT::i32, Custom);

    setOperationAction(ISD::SUB,                MVT::i16, Custom);

    setOperationAction(ISD::SUB,                MVT::i32, Custom);

  }


  if (!Subtarget.useSoftFloat() && Subtarget.hasSSE41()) {

    for (MVT RoundedTy : {MVT::f32, MVT::f64, MVT::v4f32, MVT::v2f64}) {

      setOperationAction(ISD::FFLOOR,            RoundedTy,  Legal);

      setOperationAction(ISD::STRICT_FFLOOR,     RoundedTy,  Legal);

      setOperationAction(ISD::FCEIL,             RoundedTy,  Legal);

      setOperationAction(ISD::STRICT_FCEIL,      RoundedTy,  Legal);

      setOperationAction(ISD::FTRUNC,            RoundedTy,  Legal);

      setOperationAction(ISD::STRICT_FTRUNC,     RoundedTy,  Legal);

      setOperationAction(ISD::FRINT,             RoundedTy,  Legal);

      setOperationAction(ISD::STRICT_FRINT,      RoundedTy,  Legal);

      setOperationAction(ISD::FNEARBYINT,        RoundedTy,  Legal);

      setOperationAction(ISD::STRICT_FNEARBYINT, RoundedTy,  Legal);

      setOperationAction(ISD::FROUNDEVEN,        RoundedTy,  Legal);

      setOperationAction(ISD::STRICT_FROUNDEVEN, RoundedTy,  Legal);


      setOperationAction(ISD::FROUND,            RoundedTy,  Custom);

    }


    setOperationAction(ISD::SMAX,               MVT::v16i8, Legal);

    setOperationAction(ISD::SMAX,               MVT::v4i32, Legal);

    setOperationAction(ISD::UMAX,               MVT::v8i16, Legal);

    setOperationAction(ISD::UMAX,               MVT::v4i32, Legal);

    setOperationAction(ISD::SMIN,               MVT::v16i8, Legal);

    setOperationAction(ISD::SMIN,               MVT::v4i32, Legal);

    setOperationAction(ISD::UMIN,               MVT::v8i16, Legal);

    setOperationAction(ISD::UMIN,               MVT::v4i32, Legal);


    setOperationAction(ISD::UADDSAT,            MVT::v4i32, Custom);

    setOperationAction(ISD::SADDSAT,            MVT::v2i64, Custom);

    setOperationAction(ISD::SSUBSAT,            MVT::v2i64, Custom);


    // FIXME: Do we need to handle scalar-to-vector here?

    setOperationAction(ISD::MUL,                MVT::v4i32, Legal);

    setOperationAction(ISD::SMULO,              MVT::v2i32, Custom);


    // We directly match byte blends in the backend as they match the VSELECT

    // condition form.

    setOperationAction(ISD::VSELECT,            MVT::v16i8, Legal);


    // SSE41 brings specific instructions for doing vector sign extend even in

    // cases where we don't have SRA.

    for (auto VT : { MVT::v8i16, MVT::v4i32, MVT::v2i64 }) {

      setOperationAction(ISD::SIGN_EXTEND_VECTOR_INREG, VT, Legal);

      setOperationAction(ISD::ZERO_EXTEND_VECTOR_INREG, VT, Legal);

    }


    // SSE41 also has vector sign/zero extending loads, PMOV[SZ]X

    for (auto LoadExtOp : { ISD::SEXTLOAD, ISD::ZEXTLOAD }) {

      setLoadExtAction(LoadExtOp, MVT::v8i16, MVT::v8i8,  Legal);

      setLoadExtAction(LoadExtOp, MVT::v4i32, MVT::v4i8,  Legal);

      setLoadExtAction(LoadExtOp, MVT::v2i64, MVT::v2i8,  Legal);

      setLoadExtAction(LoadExtOp, MVT::v4i32, MVT::v4i16, Legal);

      setLoadExtAction(LoadExtOp, MVT::v2i64, MVT::v2i16, Legal);

      setLoadExtAction(LoadExtOp, MVT::v2i64, MVT::v2i32, Legal);

    }


    if (Subtarget.is64Bit() && !Subtarget.hasAVX512()) {

      // We need to scalarize v4i64->v432 uint_to_fp using cvtsi2ss, but we can

      // do the pre and post work in the vector domain.

      setOperationAction(ISD::UINT_TO_FP,        MVT::v4i64, Custom);

      setOperationAction(ISD::STRICT_UINT_TO_FP, MVT::v4i64, Custom);

      // We need to mark SINT_TO_FP as Custom even though we want to expand it

      // so that DAG combine doesn't try to turn it into uint_to_fp.

      setOperationAction(ISD::SINT_TO_FP,        MVT::v4i64, Custom);

      setOperationAction(ISD::STRICT_SINT_TO_FP, MVT::v4i64, Custom);

    }

  }


  if (!Subtarget.useSoftFloat() && Subtarget.hasSSE42()) {

    setOperationAction(ISD::UADDSAT,            MVT::v2i64, Custom);

  }


  if (!Subtarget.useSoftFloat() && Subtarget.hasXOP()) {

    for (MVT VT : { MVT::v16i8, MVT::v8i16,  MVT::v4i32, MVT::v2i64,

                    MVT::v32i8, MVT::v16i16, MVT::v8i32, MVT::v4i64 }) {

      setOperationAction(ISD::ROTL, VT, VT.is128BitVector() ? Legal : Custom);

      setOperationAction(ISD::ROTR, VT, Custom);

    }


    // XOP can efficiently perform BITREVERSE with VPPERM.

    for (auto VT : { MVT::i8, MVT::i16, MVT::i32, MVT::i64 })

      setOperationAction(ISD::BITREVERSE, VT, Custom);

  }


  if (!Subtarget.useSoftFloat() && Subtarget.hasAVX()) {

    bool HasInt256 = Subtarget.hasInt256();


    addRegisterClass(MVT::v32i8,  Subtarget.hasVLX() ? &X86::VR256XRegClass

                                                     : &X86::VR256RegClass);

    addRegisterClass(MVT::v16i16, Subtarget.hasVLX() ? &X86::VR256XRegClass

                                                     : &X86::VR256RegClass);

    addRegisterClass(MVT::v16f16, Subtarget.hasVLX() ? &X86::VR256XRegClass

                                                     : &X86::VR256RegClass);

    addRegisterClass(MVT::v8i32,  Subtarget.hasVLX() ? &X86::VR256XRegClass

                                                     : &X86::VR256RegClass);

    addRegisterClass(MVT::v8f32,  Subtarget.hasVLX() ? &X86::VR256XRegClass

                                                     : &X86::VR256RegClass);

    addRegisterClass(MVT::v4i64,  Subtarget.hasVLX() ? &X86::VR256XRegClass

                                                     : &X86::VR256RegClass);

    addRegisterClass(MVT::v4f64,  Subtarget.hasVLX() ? &X86::VR256XRegClass

                                                     : &X86::VR256RegClass);


    for (auto VT : { MVT::v8f32, MVT::v4f64 }) {

      setOperationAction(ISD::FFLOOR,            VT, Legal);

      setOperationAction(ISD::STRICT_FFLOOR,     VT, Legal);

      setOperationAction(ISD::FCEIL,             VT, Legal);

      setOperationAction(ISD::STRICT_FCEIL,      VT, Legal);

      setOperationAction(ISD::FTRUNC,            VT, Legal);

      setOperationAction(ISD::STRICT_FTRUNC,     VT, Legal);

      setOperationAction(ISD::FRINT,             VT, Legal);

      setOperationAction(ISD::STRICT_FRINT,      VT, Legal);

      setOperationAction(ISD::FNEARBYINT,        VT, Legal);

      setOperationAction(ISD::STRICT_FNEARBYINT, VT, Legal);

      setOperationAction(ISD::FROUNDEVEN,        VT, Legal);

      setOperationAction(ISD::STRICT_FROUNDEVEN, VT, Legal);


      setOperationAction(ISD::FROUND,            VT, Custom);


      setOperationAction(ISD::FNEG,              VT, Custom);

      setOperationAction(ISD::FABS,              VT, Custom);

      setOperationAction(ISD::FCOPYSIGN,         VT, Custom);


      setOperationAction(ISD::FMAXIMUM,          VT, Custom);

      setOperationAction(ISD::FMINIMUM,          VT, Custom);

      setOperationAction(ISD::FMAXIMUMNUM,       VT, Custom);

      setOperationAction(ISD::FMINIMUMNUM,       VT, Custom);

      setOperationAction(ISD::FCANONICALIZE, VT, Expand);

    }


    setOperationAction(ISD::LRINT, MVT::v8f32, Custom);

    setOperationAction(ISD::LRINT, MVT::v4f64, Custom);


    setOperationAction(ISD::AND, MVT::i256, Custom);

    setOperationAction(ISD::OR, MVT::i256, Custom);

    setOperationAction(ISD::XOR, MVT::i256, Custom);

    setOperationAction(ISD::SELECT, MVT::i256, Custom);

    setOperationAction(ISD::BITREVERSE, MVT::i256, Custom);


    // (fp_to_int:v8i16 (v8f32 ..)) requires the result type to be promoted

    // even though v8i16 is a legal type.

    setOperationPromotedToType(ISD::FP_TO_SINT,        MVT::v8i16, MVT::v8i32);

    setOperationPromotedToType(ISD::FP_TO_UINT,        MVT::v8i16, MVT::v8i32);

    setOperationPromotedToType(ISD::STRICT_FP_TO_SINT, MVT::v8i16, MVT::v8i32);

    setOperationPromotedToType(ISD::STRICT_FP_TO_UINT, MVT::v8i16, MVT::v8i32);

    setOperationAction(ISD::FP_TO_SINT,                MVT::v8i32, Custom);

    setOperationAction(ISD::FP_TO_UINT,                MVT::v8i32, Custom);

    setOperationAction(ISD::STRICT_FP_TO_SINT,         MVT::v8i32, Custom);


    setOperationAction(ISD::SINT_TO_FP,         MVT::v8i32, Custom);

    setOperationAction(ISD::STRICT_SINT_TO_FP,  MVT::v8i32, Custom);

    setOperationAction(ISD::FP_EXTEND,          MVT::v8f32, Expand);

    setOperationAction(ISD::FP_ROUND,           MVT::v8f16, Expand);

    setOperationAction(ISD::FP_EXTEND,          MVT::v4f64, Custom);

    setOperationAction(ISD::STRICT_FP_EXTEND,   MVT::v4f64, Custom);


    setOperationAction(ISD::STRICT_FP_ROUND,    MVT::v4f32, Legal);

    setOperationAction(ISD::STRICT_FADD,        MVT::v8f32, Legal);

    setOperationAction(ISD::STRICT_FADD,        MVT::v4f64, Legal);

    setOperationAction(ISD::STRICT_FSUB,        MVT::v8f32, Legal);

    setOperationAction(ISD::STRICT_FSUB,        MVT::v4f64, Legal);

    setOperationAction(ISD::STRICT_FMUL,        MVT::v8f32, Legal);

    setOperationAction(ISD::STRICT_FMUL,        MVT::v4f64, Legal);

    setOperationAction(ISD::STRICT_FDIV,        MVT::v8f32, Legal);

    setOperationAction(ISD::STRICT_FDIV,        MVT::v4f64, Legal);

    setOperationAction(ISD::STRICT_FSQRT,       MVT::v8f32, Legal);

    setOperationAction(ISD::STRICT_FSQRT,       MVT::v4f64, Legal);


    if (!Subtarget.hasAVX512())

      setOperationAction(ISD::BITCAST, MVT::v32i1, Custom);


    // In the customized shift lowering, the legal v8i32/v4i64 cases

    // in AVX2 will be recognized.

    for (auto VT : { MVT::v32i8, MVT::v16i16, MVT::v8i32, MVT::v4i64 }) {

      setOperationAction(ISD::SRL,             VT, Custom);

      setOperationAction(ISD::SHL,             VT, Custom);

      setOperationAction(ISD::SRA,             VT, Custom);

      setOperationAction(ISD::ABDS,            VT, Custom);

      setOperationAction(ISD::ABDU,            VT, Custom);

      if (VT == MVT::v4i64) continue;

      setOperationAction(ISD::ROTL,            VT, Custom);

      setOperationAction(ISD::ROTR,            VT, Custom);

      setOperationAction(ISD::FSHL,            VT, Custom);

      setOperationAction(ISD::FSHR,            VT, Custom);

    }


    // These types need custom splitting if their input is a 128-bit vector.

    setOperationAction(ISD::SIGN_EXTEND,       MVT::v8i64,  Custom);

    setOperationAction(ISD::SIGN_EXTEND,       MVT::v16i32, Custom);

    setOperationAction(ISD::ZERO_EXTEND,       MVT::v8i64,  Custom);

    setOperationAction(ISD::ZERO_EXTEND,       MVT::v16i32, Custom);


    setOperationAction(ISD::SELECT,            MVT::v4f64, Custom);

    setOperationAction(ISD::SELECT,            MVT::v4i64, Custom);

    setOperationAction(ISD::SELECT,            MVT::v8i32, Custom);

    setOperationAction(ISD::SELECT,            MVT::v16i16, Custom);

    setOperationAction(ISD::SELECT,            MVT::v16f16, Custom);

    setOperationAction(ISD::SELECT,            MVT::v32i8, Custom);

    setOperationAction(ISD::SELECT,            MVT::v8f32, Custom);


    for (auto VT : { MVT::v16i16, MVT::v8i32, MVT::v4i64 }) {

      setOperationAction(ISD::SIGN_EXTEND,     VT, Custom);

      setOperationAction(ISD::ZERO_EXTEND,     VT, Custom);

      setOperationAction(ISD::ANY_EXTEND,      VT, Custom);

    }


    setOperationAction(ISD::TRUNCATE,          MVT::v32i8, Custom);

    setOperationAction(ISD::TRUNCATE,          MVT::v32i16, Custom);

    setOperationAction(ISD::TRUNCATE,          MVT::v32i32, Custom);

    setOperationAction(ISD::TRUNCATE,          MVT::v32i64, Custom);


    for (auto VT : { MVT::v32i8, MVT::v16i16, MVT::v8i32, MVT::v4i64 }) {

      setOperationAction(ISD::SETCC,           VT, Custom);

      setOperationAction(ISD::CTPOP,           VT, Custom);

      setOperationAction(ISD::CTLZ,            VT, Custom);

      setOperationAction(ISD::BITREVERSE,      VT, Custom);


      // The condition codes aren't legal in SSE/AVX and under AVX512 we use

      // setcc all the way to isel and prefer SETGT in some isel patterns.

      setCondCodeAction(ISD::SETLT, VT, Custom);

      setCondCodeAction(ISD::SETLE, VT, Custom);

    }


    setOperationAction(ISD::SETCC,          MVT::v4f64, Custom);

    setOperationAction(ISD::SETCC,          MVT::v8f32, Custom);

    setOperationAction(ISD::STRICT_FSETCC,  MVT::v4f64, Custom);

    setOperationAction(ISD::STRICT_FSETCC,  MVT::v8f32, Custom);

    setOperationAction(ISD::STRICT_FSETCCS, MVT::v4f64, Custom);

    setOperationAction(ISD::STRICT_FSETCCS, MVT::v8f32, Custom);


    if (Subtarget.hasAnyFMA()) {

      for (auto VT : { MVT::f32, MVT::f64, MVT::v4f32, MVT::v8f32,

                       MVT::v2f64, MVT::v4f64 }) {

        setOperationAction(ISD::FMA, VT, Legal);

        setOperationAction(ISD::STRICT_FMA, VT, Legal);

      }

    }


    for (auto VT : { MVT::v32i8, MVT::v16i16, MVT::v8i32, MVT::v4i64 }) {

      setOperationAction(ISD::ADD, VT, HasInt256 ? Legal : Custom);

      setOperationAction(ISD::SUB, VT, HasInt256 ? Legal : Custom);

    }


    setOperationAction(ISD::MUL,       MVT::v4i64,  Custom);

    setOperationAction(ISD::MUL,       MVT::v8i32,  HasInt256 ? Legal : Custom);

    setOperationAction(ISD::MUL,       MVT::v16i16, HasInt256 ? Legal : Custom);

    setOperationAction(ISD::MUL,       MVT::v32i8,  Custom);


    setOperationAction(ISD::MULHU,     MVT::v8i32,  Custom);

    setOperationAction(ISD::MULHS,     MVT::v8i32,  Custom);

    setOperationAction(ISD::MULHU,     MVT::v16i16, HasInt256 ? Legal : Custom);

    setOperationAction(ISD::MULHS,     MVT::v16i16, HasInt256 ? Legal : Custom);

    setOperationAction(ISD::MULHU,     MVT::v32i8,  Custom);

    setOperationAction(ISD::MULHS,     MVT::v32i8,  Custom);

    setOperationAction(ISD::AVGCEILU,  MVT::v16i16, HasInt256 ? Legal : Custom);

    setOperationAction(ISD::AVGCEILU,  MVT::v32i8,  HasInt256 ? Legal : Custom);


    setOperationAction(ISD::SMULO,     MVT::v32i8, Custom);

    setOperationAction(ISD::UMULO,     MVT::v32i8, Custom);


    setOperationAction(ISD::ABS,       MVT::v4i64,  Custom);

    setOperationAction(ISD::SMAX,      MVT::v4i64,  Custom);

    setOperationAction(ISD::UMAX,      MVT::v4i64,  Custom);

    setOperationAction(ISD::SMIN,      MVT::v4i64,  Custom);

    setOperationAction(ISD::UMIN,      MVT::v4i64,  Custom);


    setOperationAction(ISD::UADDSAT,   MVT::v32i8,  HasInt256 ? Legal : Custom);

    setOperationAction(ISD::SADDSAT,   MVT::v32i8,  HasInt256 ? Legal : Custom);

    setOperationAction(ISD::USUBSAT,   MVT::v32i8,  HasInt256 ? Legal : Custom);

    setOperationAction(ISD::SSUBSAT,   MVT::v32i8,  HasInt256 ? Legal : Custom);

    setOperationAction(ISD::UADDSAT,   MVT::v16i16, HasInt256 ? Legal : Custom);

    setOperationAction(ISD::SADDSAT,   MVT::v16i16, HasInt256 ? Legal : Custom);

    setOperationAction(ISD::USUBSAT,   MVT::v16i16, HasInt256 ? Legal : Custom);

    setOperationAction(ISD::SSUBSAT,   MVT::v16i16, HasInt256 ? Legal : Custom);

    setOperationAction(ISD::UADDSAT,   MVT::v8i32, Custom);

    setOperationAction(ISD::USUBSAT,   MVT::v8i32, Custom);

    setOperationAction(ISD::UADDSAT,   MVT::v4i64, Custom);

    setOperationAction(ISD::USUBSAT,   MVT::v4i64, Custom);


    for (auto VT : { MVT::v32i8, MVT::v16i16, MVT::v8i32 }) {

      setOperationAction(ISD::ABS,  VT, HasInt256 ? Legal : Custom);

      setOperationAction(ISD::SMAX, VT, HasInt256 ? Legal : Custom);

      setOperationAction(ISD::UMAX, VT, HasInt256 ? Legal : Custom);

      setOperationAction(ISD::SMIN, VT, HasInt256 ? Legal : Custom);

      setOperationAction(ISD::UMIN, VT, HasInt256 ? Legal : Custom);

    }


    for (auto VT : {MVT::v16i16, MVT::v8i32, MVT::v4i64}) {

      setOperationAction(ISD::SIGN_EXTEND_VECTOR_INREG, VT, Custom);

      setOperationAction(ISD::ZERO_EXTEND_VECTOR_INREG, VT, Custom);

    }


    if (HasInt256) {

      // The custom lowering for UINT_TO_FP for v8i32 becomes interesting

      // when we have a 256bit-wide blend with immediate.

      setOperationAction(ISD::UINT_TO_FP, MVT::v8i32, Custom);

      setOperationAction(ISD::STRICT_UINT_TO_FP, MVT::v8i32, Custom);


      // AVX2 also has wider vector sign/zero extending loads, VPMOV[SZ]X

      for (auto LoadExtOp : { ISD::SEXTLOAD, ISD::ZEXTLOAD }) {

        setLoadExtAction(LoadExtOp, MVT::v16i16, MVT::v16i8, Legal);

        setLoadExtAction(LoadExtOp, MVT::v8i32,  MVT::v8i8,  Legal);

        setLoadExtAction(LoadExtOp, MVT::v4i64,  MVT::v4i8,  Legal);

        setLoadExtAction(LoadExtOp, MVT::v8i32,  MVT::v8i16, Legal);

        setLoadExtAction(LoadExtOp, MVT::v4i64,  MVT::v4i16, Legal);

        setLoadExtAction(LoadExtOp, MVT::v4i64,  MVT::v4i32, Legal);

      }

    }


    for (auto VT : { MVT::v4i32, MVT::v8i32, MVT::v2i64, MVT::v4i64,

                     MVT::v4f32, MVT::v8f32, MVT::v2f64, MVT::v4f64 }) {

      setOperationAction(ISD::MLOAD,  VT, Subtarget.hasVLX() ? Legal : Custom);

      setOperationAction(ISD::MSTORE, VT, Legal);

    }


    // Extract subvector is special because the value type

    // (result) is 128-bit but the source is 256-bit wide.

    for (auto VT : { MVT::v16i8, MVT::v8i16, MVT::v4i32, MVT::v2i64,

                     MVT::v8f16, MVT::v4f32, MVT::v2f64 }) {

      setOperationAction(ISD::EXTRACT_SUBVECTOR, VT, Legal);

    }


    // Custom lower several nodes for 256-bit types.

    for (MVT VT : { MVT::v32i8, MVT::v16i16, MVT::v8i32, MVT::v4i64,

                    MVT::v16f16, MVT::v8f32, MVT::v4f64 }) {

      setOperationAction(ISD::BUILD_VECTOR,       VT, Custom);

      setOperationAction(ISD::VECTOR_SHUFFLE,     VT, Custom);

      setOperationAction(ISD::VSELECT,            VT, Custom);

      setOperationAction(ISD::INSERT_VECTOR_ELT,  VT, Custom);

      setOperationAction(ISD::EXTRACT_VECTOR_ELT, VT, Custom);

      setOperationAction(ISD::SCALAR_TO_VECTOR,   VT, Custom);

      setOperationAction(ISD::INSERT_SUBVECTOR,   VT, Legal);

      setOperationAction(ISD::CONCAT_VECTORS,     VT, Custom);

      setOperationAction(ISD::STORE,              VT, Custom);

    }

    setF16Action(MVT::v16f16, Expand);

    setOperationAction(ISD::FNEG, MVT::v16f16, Custom);

    setOperationAction(ISD::FABS, MVT::v16f16, Custom);

    setOperationAction(ISD::FCOPYSIGN, MVT::v16f16, Custom);

    setOperationAction(ISD::FADD, MVT::v16f16, Expand);

    setOperationAction(ISD::FSUB, MVT::v16f16, Expand);

    setOperationAction(ISD::FMUL, MVT::v16f16, Expand);

    setOperationAction(ISD::FDIV, MVT::v16f16, Expand);


    // Only PCLMUL required as we always unroll clmul vectors.

    if (Subtarget.hasPCLMUL()) {

      for (auto VT : {MVT::v8i32, MVT::v4i64}) {

        setOperationAction(ISD::CLMUL, VT, Custom);

        setOperationAction(ISD::CLMULH, VT, Custom);

      }

    }


    if (HasInt256) {

      setOperationAction(ISD::VSELECT, MVT::v32i8, Legal);


      // Custom legalize 2x32 to get a little better code.

      setOperationAction(ISD::MGATHER, MVT::v2f32, Custom);

      setOperationAction(ISD::MGATHER, MVT::v2i32, Custom);


      for (auto VT : { MVT::v4i32, MVT::v8i32, MVT::v2i64, MVT::v4i64,

                       MVT::v4f32, MVT::v8f32, MVT::v2f64, MVT::v4f64 })

        setOperationAction(ISD::MGATHER,  VT, Custom);

    }


    if (Subtarget.hasGFNI()) {

      setOperationAction(ISD::CTLZ, MVT::v32i8, Custom);

      setOperationAction(ISD::CTTZ, MVT::v32i8, Custom);

    }

  }


  if (!Subtarget.useSoftFloat() && !Subtarget.hasFP16() &&

      Subtarget.hasF16C()) {

    for (MVT VT : { MVT::f16, MVT::v2f16, MVT::v4f16, MVT::v8f16 }) {

      setOperationAction(ISD::FP_ROUND,           VT, Custom);

      setOperationAction(ISD::STRICT_FP_ROUND,    VT, Custom);

    }

    for (MVT VT : { MVT::f32, MVT::v2f32, MVT::v4f32, MVT::v8f32 }) {

      setOperationAction(ISD::FP_EXTEND,          VT, Custom);

      setOperationAction(ISD::STRICT_FP_EXTEND,   VT, Custom);

    }

    for (unsigned Opc : {ISD::FADD, ISD::FSUB, ISD::FMUL, ISD::FDIV}) {

      setOperationPromotedToType(Opc, MVT::v8f16, MVT::v8f32);

      setOperationPromotedToType(Opc, MVT::v16f16, MVT::v16f32);

    }

    setOperationAction(ISD::SETCC, MVT::v8f16, Custom);

    setOperationAction(ISD::SETCC, MVT::v16f16, Custom);

  }


  // This block controls legalization of the mask vector sizes that are

  // available with AVX512. 512-bit vectors are in a separate block controlled

  // by useAVX512Regs.

  if (!Subtarget.useSoftFloat() && Subtarget.hasAVX512()) {

    addRegisterClass(MVT::v1i1,   &X86::VK1RegClass);

    addRegisterClass(MVT::v2i1,   &X86::VK2RegClass);

    addRegisterClass(MVT::v4i1,   &X86::VK4RegClass);

    addRegisterClass(MVT::v8i1,   &X86::VK8RegClass);

    addRegisterClass(MVT::v16i1,  &X86::VK16RegClass);


    setOperationAction(ISD::SELECT,             MVT::v1i1, Custom);

    setOperationAction(ISD::EXTRACT_VECTOR_ELT, MVT::v1i1, Custom);

    setOperationAction(ISD::BUILD_VECTOR,       MVT::v1i1, Custom);


    setOperationPromotedToType(ISD::FP_TO_SINT,        MVT::v8i1,  MVT::v8i32);

    setOperationPromotedToType(ISD::FP_TO_UINT,        MVT::v8i1,  MVT::v8i32);

    setOperationPromotedToType(ISD::FP_TO_SINT,        MVT::v4i1,  MVT::v4i32);

    setOperationPromotedToType(ISD::FP_TO_UINT,        MVT::v4i1,  MVT::v4i32);

    setOperationPromotedToType(ISD::STRICT_FP_TO_SINT, MVT::v8i1,  MVT::v8i32);

    setOperationPromotedToType(ISD::STRICT_FP_TO_UINT, MVT::v8i1,  MVT::v8i32);

    setOperationPromotedToType(ISD::STRICT_FP_TO_SINT, MVT::v4i1,  MVT::v4i32);

    setOperationPromotedToType(ISD::STRICT_FP_TO_UINT, MVT::v4i1,  MVT::v4i32);

    setOperationAction(ISD::FP_TO_SINT,                MVT::v2i1,  Custom);

    setOperationAction(ISD::FP_TO_UINT,                MVT::v2i1,  Custom);

    setOperationAction(ISD::STRICT_FP_TO_SINT,         MVT::v2i1,  Custom);

    setOperationAction(ISD::STRICT_FP_TO_UINT,         MVT::v2i1,  Custom);

    setOperationAction(ISD::FCANONICALIZE, MVT::v8f16, Expand);

    setOperationAction(ISD::FCANONICALIZE, MVT::v16f16, Expand);

    setOperationAction(ISD::FCANONICALIZE, MVT::v32f16, Expand);


    // There is no byte sized k-register load or store without AVX512DQ.

    if (!Subtarget.hasDQI()) {

      setOperationAction(ISD::LOAD, MVT::v1i1, Custom);

      setOperationAction(ISD::LOAD, MVT::v2i1, Custom);

      setOperationAction(ISD::LOAD, MVT::v4i1, Custom);

      setOperationAction(ISD::LOAD, MVT::v8i1, Custom);


      setOperationAction(ISD::STORE, MVT::v1i1, Custom);

      setOperationAction(ISD::STORE, MVT::v2i1, Custom);

      setOperationAction(ISD::STORE, MVT::v4i1, Custom);

      setOperationAction(ISD::STORE, MVT::v8i1, Custom);

    }


    // Extends of v16i1/v8i1/v4i1/v2i1 to 128-bit vectors.

    for (auto VT : { MVT::v16i8, MVT::v8i16, MVT::v4i32, MVT::v2i64 }) {

      setOperationAction(ISD::SIGN_EXTEND, VT, Custom);

      setOperationAction(ISD::ZERO_EXTEND, VT, Custom);

      setOperationAction(ISD::ANY_EXTEND,  VT, Custom);

    }


    for (auto VT : { MVT::v1i1, MVT::v2i1, MVT::v4i1, MVT::v8i1, MVT::v16i1 })

      setOperationAction(ISD::VSELECT,          VT, Expand);


    for (auto VT : { MVT::v2i1, MVT::v4i1, MVT::v8i1, MVT::v16i1 }) {

      setOperationAction(ISD::SETCC,            VT, Custom);

      setOperationAction(ISD::SELECT,           VT, Custom);

      setOperationAction(ISD::TRUNCATE,         VT, Custom);


      setOperationAction(ISD::BUILD_VECTOR,     VT, Custom);

      setOperationAction(ISD::CONCAT_VECTORS,   VT, Custom);

      setOperationAction(ISD::EXTRACT_VECTOR_ELT, VT, Custom);

      setOperationAction(ISD::INSERT_SUBVECTOR, VT, Custom);

      setOperationAction(ISD::INSERT_VECTOR_ELT, VT, Custom);

      setOperationAction(ISD::VECTOR_SHUFFLE,   VT,  Custom);

    }


    for (auto VT : { MVT::v1i1, MVT::v2i1, MVT::v4i1, MVT::v8i1 })

      setOperationAction(ISD::EXTRACT_SUBVECTOR, VT, Custom);

  }

  if (Subtarget.hasDQI() && Subtarget.hasVLX()) {

    for (MVT VT : {MVT::v4f32, MVT::v8f32, MVT::v2f64, MVT::v4f64}) {

      setOperationAction(ISD::LRINT, VT, Legal);

      setOperationAction(ISD::LLRINT, VT, Legal);

    }

  }


  // This block controls legalization for 512-bit operations with 8/16/32/64 bit

  // elements. 512-bits can be disabled based on prefer-vector-width and

  // required-vector-width function attributes.

  if (!Subtarget.useSoftFloat() && Subtarget.useAVX512Regs()) {

    bool HasBWI = Subtarget.hasBWI();


    addRegisterClass(MVT::v16i32, &X86::VR512RegClass);

    addRegisterClass(MVT::v16f32, &X86::VR512RegClass);

    addRegisterClass(MVT::v8i64,  &X86::VR512RegClass);

    addRegisterClass(MVT::v8f64,  &X86::VR512RegClass);

    addRegisterClass(MVT::v32i16, &X86::VR512RegClass);

    addRegisterClass(MVT::v32f16, &X86::VR512RegClass);

    addRegisterClass(MVT::v64i8,  &X86::VR512RegClass);


    for (auto ExtType : {ISD::ZEXTLOAD, ISD::SEXTLOAD}) {

      setLoadExtAction(ExtType, MVT::v16i32, MVT::v16i8,  Legal);

      setLoadExtAction(ExtType, MVT::v16i32, MVT::v16i16, Legal);

      setLoadExtAction(ExtType, MVT::v8i64,  MVT::v8i8,   Legal);

      setLoadExtAction(ExtType, MVT::v8i64,  MVT::v8i16,  Legal);

      setLoadExtAction(ExtType, MVT::v8i64,  MVT::v8i32,  Legal);

      if (HasBWI)

        setLoadExtAction(ExtType, MVT::v32i16, MVT::v32i8, Legal);

    }


    for (MVT VT : { MVT::v16f32, MVT::v8f64 }) {

      setOperationAction(ISD::FMAXIMUM, VT, Custom);

      setOperationAction(ISD::FMINIMUM, VT, Custom);

      setOperationAction(ISD::FMAXIMUMNUM, VT, Custom);

      setOperationAction(ISD::FMINIMUMNUM, VT, Custom);

      setOperationAction(ISD::FNEG,  VT, Custom);

      setOperationAction(ISD::FABS,  VT, Custom);

      setOperationAction(ISD::FMA,   VT, Legal);

      setOperationAction(ISD::STRICT_FMA, VT, Legal);

      setOperationAction(ISD::FCOPYSIGN, VT, Custom);

      setOperationAction(ISD::FCANONICALIZE, VT, Expand);

    }

    setOperationAction(ISD::LRINT, MVT::v16f32,

                       Subtarget.hasDQI() ? Legal : Custom);

    setOperationAction(ISD::LRINT, MVT::v8f64,

                       Subtarget.hasDQI() ? Legal : Custom);

    if (Subtarget.hasDQI())

      setOperationAction(ISD::LLRINT, MVT::v8f64, Legal);


    setOperationAction(ISD::AND, MVT::i512, Custom);

    setOperationAction(ISD::OR, MVT::i512, Custom);

    setOperationAction(ISD::XOR, MVT::i512, Custom);

    setOperationAction(ISD::ADD, MVT::i512, Custom);

    setOperationAction(ISD::SUB, MVT::i512, Custom);

    setOperationAction(ISD::SRL, MVT::i512, Custom);

    setOperationAction(ISD::SHL, MVT::i512, Custom);

    setOperationAction(ISD::SRA, MVT::i512, Custom);

    setOperationAction(ISD::FSHR, MVT::i512, Custom);

    setOperationAction(ISD::FSHL, MVT::i512, Custom);

    setOperationAction(ISD::FSHR, MVT::i256, Custom);

    setOperationAction(ISD::FSHL, MVT::i256, Custom);

    setOperationAction(ISD::SELECT, MVT::i512, Custom);

    setOperationAction(ISD::BITREVERSE, MVT::i512, Custom);


    for (MVT VT : { MVT::v16i1, MVT::v16i8 }) {

      setOperationPromotedToType(ISD::FP_TO_SINT       , VT, MVT::v16i32);

      setOperationPromotedToType(ISD::FP_TO_UINT       , VT, MVT::v16i32);

      setOperationPromotedToType(ISD::STRICT_FP_TO_SINT, VT, MVT::v16i32);

      setOperationPromotedToType(ISD::STRICT_FP_TO_UINT, VT, MVT::v16i32);

    }


    for (MVT VT : { MVT::v16i16, MVT::v16i32 }) {

      setOperationAction(ISD::FP_TO_SINT,        VT, Custom);

      setOperationAction(ISD::FP_TO_UINT,        VT, Custom);

      setOperationAction(ISD::STRICT_FP_TO_SINT, VT, Custom);

      setOperationAction(ISD::STRICT_FP_TO_UINT, VT, Custom);

    }


    setOperationAction(ISD::SINT_TO_FP,        MVT::v16i32, Custom);

    setOperationAction(ISD::UINT_TO_FP,        MVT::v16i32, Custom);

    setOperationAction(ISD::STRICT_SINT_TO_FP, MVT::v16i32, Custom);

    setOperationAction(ISD::STRICT_UINT_TO_FP, MVT::v16i32, Custom);

    setOperationAction(ISD::FP_EXTEND,         MVT::v8f64,  Custom);

    setOperationAction(ISD::STRICT_FP_EXTEND,  MVT::v8f64,  Custom);


    setOperationAction(ISD::STRICT_FADD,      MVT::v16f32, Legal);

    setOperationAction(ISD::STRICT_FADD,      MVT::v8f64,  Legal);

    setOperationAction(ISD::STRICT_FSUB,      MVT::v16f32, Legal);

    setOperationAction(ISD::STRICT_FSUB,      MVT::v8f64,  Legal);

    setOperationAction(ISD::STRICT_FMUL,      MVT::v16f32, Legal);

    setOperationAction(ISD::STRICT_FMUL,      MVT::v8f64,  Legal);

    setOperationAction(ISD::STRICT_FDIV,      MVT::v16f32, Legal);

    setOperationAction(ISD::STRICT_FDIV,      MVT::v8f64,  Legal);

    setOperationAction(ISD::STRICT_FSQRT,     MVT::v16f32, Legal);

    setOperationAction(ISD::STRICT_FSQRT,     MVT::v8f64,  Legal);

    setOperationAction(ISD::STRICT_FP_ROUND,  MVT::v8f32,  Legal);


    setTruncStoreAction(MVT::v8i64,   MVT::v8i8,   Legal);

    setTruncStoreAction(MVT::v8i64,   MVT::v8i16,  Legal);

    setTruncStoreAction(MVT::v8i64,   MVT::v8i32,  Legal);

    setTruncStoreAction(MVT::v16i32,  MVT::v16i8,  Legal);

    setTruncStoreAction(MVT::v16i32,  MVT::v16i16, Legal);

    if (HasBWI)

      setTruncStoreAction(MVT::v32i16,  MVT::v32i8, Legal);


    // With 512-bit vectors and no VLX, we prefer to widen MLOAD/MSTORE

    // to 512-bit rather than use the AVX2 instructions so that we can use

    // k-masks.

    if (!Subtarget.hasVLX()) {

      for (auto VT : {MVT::v4i32, MVT::v8i32, MVT::v2i64, MVT::v4i64,

           MVT::v4f32, MVT::v8f32, MVT::v2f64, MVT::v4f64}) {

        setOperationAction(ISD::MLOAD,  VT, Custom);

        setOperationAction(ISD::MSTORE, VT, Custom);

      }

    }


    setOperationAction(ISD::TRUNCATE,    MVT::v8i32,  Legal);

    setOperationAction(ISD::TRUNCATE,    MVT::v16i16, Legal);

    setOperationAction(ISD::TRUNCATE,    MVT::v32i8,  HasBWI ? Legal : Custom);

    setOperationAction(ISD::ZERO_EXTEND, MVT::v32i16, Custom);

    setOperationAction(ISD::ZERO_EXTEND, MVT::v16i32, Custom);

    setOperationAction(ISD::ZERO_EXTEND, MVT::v8i64,  Custom);

    setOperationAction(ISD::ANY_EXTEND,  MVT::v32i16, Custom);

    setOperationAction(ISD::ANY_EXTEND,  MVT::v16i32, Custom);

    setOperationAction(ISD::ANY_EXTEND,  MVT::v8i64,  Custom);

    setOperationAction(ISD::SIGN_EXTEND, MVT::v32i16, Custom);

    setOperationAction(ISD::SIGN_EXTEND, MVT::v16i32, Custom);

    setOperationAction(ISD::SIGN_EXTEND, MVT::v8i64,  Custom);


    if (HasBWI) {

      // Extends from v64i1 masks to 512-bit vectors.

      setOperationAction(ISD::SIGN_EXTEND,        MVT::v64i8, Custom);

      setOperationAction(ISD::ZERO_EXTEND,        MVT::v64i8, Custom);

      setOperationAction(ISD::ANY_EXTEND,         MVT::v64i8, Custom);

    }


    for (auto VT : { MVT::v16f32, MVT::v8f64 }) {

      setOperationAction(ISD::FFLOOR,            VT, Legal);

      setOperationAction(ISD::STRICT_FFLOOR,     VT, Legal);

      setOperationAction(ISD::FCEIL,             VT, Legal);

      setOperationAction(ISD::STRICT_FCEIL,      VT, Legal);

      setOperationAction(ISD::FTRUNC,            VT, Legal);

      setOperationAction(ISD::STRICT_FTRUNC,     VT, Legal);

      setOperationAction(ISD::FRINT,             VT, Legal);

      setOperationAction(ISD::STRICT_FRINT,      VT, Legal);

      setOperationAction(ISD::FNEARBYINT,        VT, Legal);

      setOperationAction(ISD::STRICT_FNEARBYINT, VT, Legal);

      setOperationAction(ISD::FROUNDEVEN,        VT, Legal);

      setOperationAction(ISD::STRICT_FROUNDEVEN, VT, Legal);


      setOperationAction(ISD::FROUND,            VT, Custom);

    }


    for (auto VT : {MVT::v32i16, MVT::v16i32, MVT::v8i64}) {

      setOperationAction(ISD::SIGN_EXTEND_VECTOR_INREG, VT, Custom);

      setOperationAction(ISD::ZERO_EXTEND_VECTOR_INREG, VT, Custom);

    }


    setOperationAction(ISD::ADD, MVT::v32i16, HasBWI ? Legal : Custom);

    setOperationAction(ISD::SUB, MVT::v32i16, HasBWI ? Legal : Custom);

    setOperationAction(ISD::ADD, MVT::v64i8,  HasBWI ? Legal : Custom);

    setOperationAction(ISD::SUB, MVT::v64i8,  HasBWI ? Legal : Custom);


    setOperationAction(ISD::MUL, MVT::v8i64,  Custom);

    setOperationAction(ISD::MUL, MVT::v16i32, Legal);

    setOperationAction(ISD::MUL, MVT::v32i16, HasBWI ? Legal : Custom);

    setOperationAction(ISD::MUL, MVT::v64i8,  Custom);


    setOperationAction(ISD::MULHU, MVT::v16i32, Custom);

    setOperationAction(ISD::MULHS, MVT::v16i32, Custom);

    setOperationAction(ISD::MULHS, MVT::v32i16, HasBWI ? Legal : Custom);

    setOperationAction(ISD::MULHU, MVT::v32i16, HasBWI ? Legal : Custom);

    setOperationAction(ISD::MULHS, MVT::v64i8,  Custom);

    setOperationAction(ISD::MULHU, MVT::v64i8,  Custom);

    setOperationAction(ISD::AVGCEILU, MVT::v32i16, HasBWI ? Legal : Custom);

    setOperationAction(ISD::AVGCEILU, MVT::v64i8,  HasBWI ? Legal : Custom);


    setOperationAction(ISD::SMULO, MVT::v64i8, Custom);

    setOperationAction(ISD::UMULO, MVT::v64i8, Custom);


    for (auto VT : { MVT::v64i8, MVT::v32i16, MVT::v16i32, MVT::v8i64 }) {

      setOperationAction(ISD::SRL,              VT, Custom);

      setOperationAction(ISD::SHL,              VT, Custom);

      setOperationAction(ISD::SRA,              VT, Custom);

      setOperationAction(ISD::ROTL,             VT, Custom);

      setOperationAction(ISD::ROTR,             VT, Custom);

      setOperationAction(ISD::SETCC,            VT, Custom);

      setOperationAction(ISD::ABDS,             VT, Custom);

      setOperationAction(ISD::ABDU,             VT, Custom);

      setOperationAction(ISD::BITREVERSE,       VT, Custom);


      // The condition codes aren't legal in SSE/AVX and under AVX512 we use

      // setcc all the way to isel and prefer SETGT in some isel patterns.

      setCondCodeAction(ISD::SETLT, VT, Custom);

      setCondCodeAction(ISD::SETLE, VT, Custom);

    }


    setOperationAction(ISD::SETCC,          MVT::v8f64, Custom);

    setOperationAction(ISD::SETCC,          MVT::v16f32, Custom);

    setOperationAction(ISD::STRICT_FSETCC,  MVT::v8f64, Custom);

    setOperationAction(ISD::STRICT_FSETCC,  MVT::v16f32, Custom);

    setOperationAction(ISD::STRICT_FSETCCS, MVT::v8f64, Custom);

    setOperationAction(ISD::STRICT_FSETCCS, MVT::v16f32, Custom);


    for (auto VT : { MVT::v16i32, MVT::v8i64 }) {

      setOperationAction(ISD::SMAX,             VT, Legal);

      setOperationAction(ISD::UMAX,             VT, Legal);

      setOperationAction(ISD::SMIN,             VT, Legal);

      setOperationAction(ISD::UMIN,             VT, Legal);

      setOperationAction(ISD::ROTL,             VT, Legal);

      setOperationAction(ISD::ROTR,             VT, Legal);

      setOperationAction(ISD::ABS,              VT, Legal);

      setOperationAction(ISD::CTPOP,            VT, Custom);

    }


    for (auto VT : { MVT::v64i8, MVT::v32i16 }) {

      setOperationAction(ISD::ABS,     VT, HasBWI ? Legal : Custom);

      setOperationAction(ISD::CTPOP,   VT, Subtarget.hasBITALG() ? Legal : Custom);

      setOperationAction(ISD::CTLZ,    VT, Custom);

      setOperationAction(ISD::SMAX,    VT, HasBWI ? Legal : Custom);

      setOperationAction(ISD::UMAX,    VT, HasBWI ? Legal : Custom);

      setOperationAction(ISD::SMIN,    VT, HasBWI ? Legal : Custom);

      setOperationAction(ISD::UMIN,    VT, HasBWI ? Legal : Custom);

      setOperationAction(ISD::UADDSAT, VT, HasBWI ? Legal : Custom);

      setOperationAction(ISD::SADDSAT, VT, HasBWI ? Legal : Custom);

      setOperationAction(ISD::USUBSAT, VT, HasBWI ? Legal : Custom);

      setOperationAction(ISD::SSUBSAT, VT, HasBWI ? Legal : Custom);

    }


    setOperationAction(ISD::FSHL,       MVT::v64i8, Custom);

    setOperationAction(ISD::FSHR,       MVT::v64i8, Custom);

    setOperationAction(ISD::FSHL,      MVT::v32i16, Custom);

    setOperationAction(ISD::FSHR,      MVT::v32i16, Custom);

    setOperationAction(ISD::FSHL,      MVT::v16i32, Custom);

    setOperationAction(ISD::FSHR,      MVT::v16i32, Custom);


    if (Subtarget.hasDQI() || Subtarget.hasFP16())

      for (auto Opc : {ISD::SINT_TO_FP, ISD::UINT_TO_FP, ISD::STRICT_SINT_TO_FP,

                       ISD::STRICT_UINT_TO_FP, ISD::FP_TO_SINT, ISD::FP_TO_UINT,

                       ISD::STRICT_FP_TO_SINT, ISD::STRICT_FP_TO_UINT})

        setOperationAction(Opc,           MVT::v8i64, Custom);


    if (Subtarget.hasDQI())

      setOperationAction(ISD::MUL,        MVT::v8i64, Legal);


    if (Subtarget.hasCDI()) {

      // NonVLX sub-targets extend 128/256 vectors to use the 512 version.

      for (auto VT : { MVT::v16i32, MVT::v8i64} ) {

        setOperationAction(ISD::CTLZ,            VT, Legal);

      }

    } // Subtarget.hasCDI()


    if (Subtarget.hasVPOPCNTDQ()) {

      for (auto VT : { MVT::v16i32, MVT::v8i64 })

        setOperationAction(ISD::CTPOP, VT, Legal);

      setOperationAction(ISD::CTPOP, MVT::i512, Custom);

    }


    // Extract subvector is special because the value type

    // (result) is 256-bit but the source is 512-bit wide.

    // 128-bit was made Legal under AVX1.

    for (auto VT : { MVT::v32i8, MVT::v16i16, MVT::v8i32, MVT::v4i64,

                     MVT::v16f16, MVT::v8f32, MVT::v4f64 })

      setOperationAction(ISD::EXTRACT_SUBVECTOR, VT, Legal);


    for (auto VT : { MVT::v64i8, MVT::v32i16, MVT::v16i32, MVT::v8i64,

                     MVT::v32f16, MVT::v16f32, MVT::v8f64 }) {

      setOperationAction(ISD::CONCAT_VECTORS,     VT, Custom);

      setOperationAction(ISD::INSERT_SUBVECTOR,   VT, Legal);

      setOperationAction(ISD::SELECT,             VT, Custom);

      setOperationAction(ISD::VSELECT,            VT, Custom);

      setOperationAction(ISD::BUILD_VECTOR,       VT, Custom);

      setOperationAction(ISD::EXTRACT_VECTOR_ELT, VT, Custom);

      setOperationAction(ISD::VECTOR_SHUFFLE,     VT, Custom);

      setOperationAction(ISD::SCALAR_TO_VECTOR,   VT, Custom);

      setOperationAction(ISD::INSERT_VECTOR_ELT,  VT, Custom);

    }

    setF16Action(MVT::v32f16, Expand);

    setOperationAction(ISD::FP_ROUND, MVT::v16f16, Custom);

    setOperationAction(ISD::STRICT_FP_ROUND, MVT::v16f16, Custom);

    setOperationAction(ISD::FP_EXTEND, MVT::v16f32, Custom);

    setOperationAction(ISD::STRICT_FP_EXTEND, MVT::v16f32, Custom);

    for (unsigned Opc : {ISD::FADD, ISD::FSUB, ISD::FMUL, ISD::FDIV})

      setOperationPromotedToType(Opc, MVT::v32f16, MVT::v32f32);

    setOperationAction(ISD::SETCC, MVT::v32f16, Custom);


    for (auto VT : { MVT::v16i32, MVT::v8i64, MVT::v16f32, MVT::v8f64 }) {

      setOperationAction(ISD::MLOAD,               VT, Legal);

      setOperationAction(ISD::MSTORE,              VT, Legal);

      setOperationAction(ISD::MGATHER,             VT, Custom);

      setOperationAction(ISD::MSCATTER,            VT, Custom);

    }

    if (HasBWI) {

      for (auto VT : { MVT::v64i8, MVT::v32i16 }) {

        setOperationAction(ISD::MLOAD,        VT, Legal);

        setOperationAction(ISD::MSTORE,       VT, Legal);

      }

    } else {

      setOperationAction(ISD::STORE, MVT::v32i16, Custom);

      setOperationAction(ISD::STORE, MVT::v64i8,  Custom);

    }


    if (Subtarget.hasVBMI2()) {

      for (auto VT : {MVT::v32i16, MVT::v16i32, MVT::v8i64}) {

        setOperationAction(ISD::FSHL, VT, Legal);

        setOperationAction(ISD::FSHR, VT, Legal);

      }


      setOperationAction(ISD::ROTL, MVT::v32i16, Legal);

      setOperationAction(ISD::ROTR, MVT::v32i16, Legal);

    }


    // Only PCLMUL required as we always unroll clmul vectors.

    if (Subtarget.hasPCLMUL()) {

      for (auto VT : {MVT::v16i32, MVT::v8i64}) {

        setOperationAction(ISD::CLMUL, VT, Custom);

        setOperationAction(ISD::CLMULH, VT, Custom);

      }

    }


    setOperationAction(ISD::FNEG, MVT::v32f16, Custom);

    setOperationAction(ISD::FABS, MVT::v32f16, Custom);

    setOperationAction(ISD::FCOPYSIGN, MVT::v32f16, Custom);


    if (Subtarget.hasGFNI()) {

      setOperationAction(ISD::CTLZ, MVT::v64i8, Custom);

      setOperationAction(ISD::CTTZ, MVT::v64i8, Custom);

    }

  }// useAVX512Regs


  if (!Subtarget.useSoftFloat() && Subtarget.hasVBMI2()) {

    for (auto VT : {MVT::v8i16, MVT::v4i32, MVT::v2i64, MVT::v16i16, MVT::v8i32,

                    MVT::v4i64}) {

      setOperationAction(ISD::FSHL, VT, Legal);

      setOperationAction(ISD::FSHR, VT, Legal);

    }


    setOperationAction(ISD::ROTL, MVT::v16i16, Legal);

    setOperationAction(ISD::ROTR, MVT::v16i16, Legal);

    setOperationAction(ISD::ROTL, MVT::v8i16, Legal);

    setOperationAction(ISD::ROTR, MVT::v8i16, Legal);

  }


  // This block controls legalization for operations that don't have

  // pre-AVX512 equivalents. Without VLX we use 512-bit operations for

  // narrower widths.

  if (!Subtarget.useSoftFloat() && Subtarget.hasAVX512()) {

    for (MVT VT : {MVT::f16, MVT::f32, MVT::f64, MVT::v8f16, MVT::v4f32,

                   MVT::v2f64, MVT::v16f16, MVT::v8f32, MVT::v4f64, MVT::v32f16,

                   MVT::v16f32, MVT::v8f64})

      setOperationAction(ISD::FLDEXP, VT, Custom);


    // These operations are handled on non-VLX by artificially widening in

    // isel patterns.

    setOperationAction(ISD::STRICT_FP_TO_UINT,  MVT::v8i32, Custom);

    setOperationAction(ISD::STRICT_FP_TO_UINT,  MVT::v4i32, Custom);

    setOperationAction(ISD::STRICT_FP_TO_UINT,  MVT::v2i32, Custom);


    if (Subtarget.hasDQI()) {

      // Fast v2f32 SINT_TO_FP( v2i64 ) custom conversion.

      // v2f32 UINT_TO_FP is already custom under SSE2.

      assert(isOperationCustom(ISD::UINT_TO_FP, MVT::v2f32) &&

             isOperationCustom(ISD::STRICT_UINT_TO_FP, MVT::v2f32) &&

             "Unexpected operation action!");

      // v2i64 FP_TO_S/UINT(v2f32) custom conversion.

      setOperationAction(ISD::FP_TO_SINT,        MVT::v2f32, Custom);

      setOperationAction(ISD::FP_TO_UINT,        MVT::v2f32, Custom);

      setOperationAction(ISD::STRICT_FP_TO_SINT, MVT::v2f32, Custom);

      setOperationAction(ISD::STRICT_FP_TO_UINT, MVT::v2f32, Custom);

    }


    for (auto VT : { MVT::v2i64, MVT::v4i64 }) {

      setOperationAction(ISD::SMAX, VT, Legal);

      setOperationAction(ISD::UMAX, VT, Legal);

      setOperationAction(ISD::SMIN, VT, Legal);

      setOperationAction(ISD::UMIN, VT, Legal);

      setOperationAction(ISD::ABS,  VT, Legal);

    }


    for (auto VT : { MVT::v4i32, MVT::v8i32, MVT::v2i64, MVT::v4i64 }) {

      setOperationAction(ISD::ROTL,     VT, Legal);

      setOperationAction(ISD::ROTR,     VT, Legal);

    }


    // Custom legalize 2x32 to get a little better code.

    setOperationAction(ISD::MSCATTER, MVT::v2f32, Custom);

    setOperationAction(ISD::MSCATTER, MVT::v2i32, Custom);


    for (auto VT : { MVT::v4i32, MVT::v8i32, MVT::v2i64, MVT::v4i64,

                     MVT::v4f32, MVT::v8f32, MVT::v2f64, MVT::v4f64 })

      setOperationAction(ISD::MSCATTER, VT, Custom);


    if (Subtarget.hasDQI()) {

      for (auto Opc : {ISD::SINT_TO_FP, ISD::UINT_TO_FP, ISD::STRICT_SINT_TO_FP,

                       ISD::STRICT_UINT_TO_FP, ISD::FP_TO_SINT, ISD::FP_TO_UINT,

                       ISD::STRICT_FP_TO_SINT, ISD::STRICT_FP_TO_UINT}) {

        setOperationAction(Opc, MVT::v2i64, Custom);

        setOperationAction(Opc, MVT::v4i64, Custom);

      }

      setOperationAction(ISD::MUL, MVT::v2i64, Legal);

      setOperationAction(ISD::MUL, MVT::v4i64, Legal);

    }


    if (Subtarget.hasCDI()) {

      for (auto VT : {MVT::i256, MVT::i512}) {

        if (VT == MVT::i512 && !Subtarget.useAVX512Regs())

          continue;

        setOperationAction(ISD::CTLZ, VT, Custom);

        setOperationAction(ISD::CTTZ, VT, Custom);

        setOperationAction(ISD::CTLZ_ZERO_UNDEF, VT, Custom);

        setOperationAction(ISD::CTTZ_ZERO_UNDEF, VT, Custom);

      }

      for (auto VT : { MVT::v4i32, MVT::v8i32, MVT::v2i64, MVT::v4i64 }) {

        setOperationAction(ISD::CTLZ,            VT, Legal);

      }

    } // Subtarget.hasCDI()


    if (Subtarget.hasVPOPCNTDQ()) {

      for (auto VT : {MVT::v4i32, MVT::v8i32, MVT::v2i64, MVT::v4i64})

        setOperationAction(ISD::CTPOP, VT, Legal);

      setOperationAction(ISD::CTPOP, MVT::i256, Custom);

    }


    // We can try to convert vectors to different sizes to leverage legal

    // `vpcompress` cases. So we mark these supported vector sizes as Custom and

    // then specialize to Legal below.

    for (MVT VT : {MVT::v8i32, MVT::v8f32, MVT::v4i32, MVT::v4f32, MVT::v4i64,

                   MVT::v4f64, MVT::v2i64, MVT::v2f64, MVT::v16i8, MVT::v8i16,

                   MVT::v16i16, MVT::v8i8})

      setOperationAction(ISD::VECTOR_COMPRESS, VT, Custom);


    // Legal vpcompress depends on various AVX512 extensions.

    // Legal in AVX512F

    for (MVT VT : {MVT::v16i32, MVT::v16f32, MVT::v8i64, MVT::v8f64})

      setOperationAction(ISD::VECTOR_COMPRESS, VT, Legal);


    // Legal in AVX512F + AVX512VL

    if (Subtarget.hasVLX())

      for (MVT VT : {MVT::v8i32, MVT::v8f32, MVT::v4i32, MVT::v4f32, MVT::v4i64,

                     MVT::v4f64, MVT::v2i64, MVT::v2f64})

        setOperationAction(ISD::VECTOR_COMPRESS, VT, Legal);


    // Legal in AVX512F + AVX512VBMI2

    if (Subtarget.hasVBMI2())

      for (MVT VT : {MVT::v32i16, MVT::v64i8})

        setOperationAction(ISD::VECTOR_COMPRESS, VT, Legal);


    // Legal in AVX512F + AVX512VL + AVX512VBMI2

    if (Subtarget.hasVBMI2() && Subtarget.hasVLX())

      for (MVT VT : {MVT::v16i8, MVT::v8i16, MVT::v32i8, MVT::v16i16})

        setOperationAction(ISD::VECTOR_COMPRESS, VT, Legal);

  }


  // This block control legalization of v32i1/v64i1 which are available with

  // AVX512BW..

  if (!Subtarget.useSoftFloat() && Subtarget.hasBWI()) {

    addRegisterClass(MVT::v32i1,  &X86::VK32RegClass);

    addRegisterClass(MVT::v64i1,  &X86::VK64RegClass);


    for (auto VT : { MVT::v32i1, MVT::v64i1 }) {

      setOperationAction(ISD::VSELECT,            VT, Expand);

      setOperationAction(ISD::TRUNCATE,           VT, Custom);

      setOperationAction(ISD::SETCC,              VT, Custom);

      setOperationAction(ISD::EXTRACT_VECTOR_ELT, VT, Custom);

      setOperationAction(ISD::INSERT_VECTOR_ELT,  VT, Custom);

      setOperationAction(ISD::SELECT,             VT, Custom);

      setOperationAction(ISD::BUILD_VECTOR,       VT, Custom);

      setOperationAction(ISD::VECTOR_SHUFFLE,     VT, Custom);

      setOperationAction(ISD::CONCAT_VECTORS,     VT, Custom);

      setOperationAction(ISD::INSERT_SUBVECTOR,   VT, Custom);

    }


    for (auto VT : { MVT::v16i1, MVT::v32i1 })

      setOperationAction(ISD::EXTRACT_SUBVECTOR, VT, Custom);


    // Extends from v32i1 masks to 256-bit vectors.

    setOperationAction(ISD::SIGN_EXTEND,        MVT::v32i8, Custom);

    setOperationAction(ISD::ZERO_EXTEND,        MVT::v32i8, Custom);

    setOperationAction(ISD::ANY_EXTEND,         MVT::v32i8, Custom);


    for (auto VT : {MVT::v32i8, MVT::v16i8, MVT::v16i16, MVT::v8i16,

                    MVT::v16f16, MVT::v8f16}) {

      setOperationAction(ISD::MLOAD,  VT, Subtarget.hasVLX() ? Legal : Custom);

      setOperationAction(ISD::MSTORE, VT, Subtarget.hasVLX() ? Legal : Custom);

    }


    // These operations are handled on non-VLX by artificially widening in

    // isel patterns.

    // TODO: Custom widen in lowering on non-VLX and drop the isel patterns?


    if (Subtarget.hasBITALG()) {

      for (auto VT : { MVT::v16i8, MVT::v32i8, MVT::v8i16, MVT::v16i16 })

        setOperationAction(ISD::CTPOP, VT, Legal);

    }

  }


  if (!Subtarget.useSoftFloat() && Subtarget.hasFP16()) {

    auto setGroup = [&] (MVT VT) {

      setOperationAction(ISD::FADD,               VT, Legal);

      setOperationAction(ISD::STRICT_FADD,        VT, Legal);

      setOperationAction(ISD::FSUB,               VT, Legal);

      setOperationAction(ISD::STRICT_FSUB,        VT, Legal);

      setOperationAction(ISD::FMUL,               VT, Legal);

      setOperationAction(ISD::STRICT_FMUL,        VT, Legal);

      setOperationAction(ISD::FDIV,               VT, Legal);

      setOperationAction(ISD::STRICT_FDIV,        VT, Legal);

      setOperationAction(ISD::FSQRT,              VT, Legal);

      setOperationAction(ISD::STRICT_FSQRT,       VT, Legal);


      setOperationAction(ISD::FFLOOR,             VT, Legal);

      setOperationAction(ISD::STRICT_FFLOOR,      VT, Legal);

      setOperationAction(ISD::FCEIL,              VT, Legal);

      setOperationAction(ISD::STRICT_FCEIL,       VT, Legal);

      setOperationAction(ISD::FTRUNC,             VT, Legal);

      setOperationAction(ISD::STRICT_FTRUNC,      VT, Legal);

      setOperationAction(ISD::FRINT,              VT, Legal);

      setOperationAction(ISD::STRICT_FRINT,       VT, Legal);

      setOperationAction(ISD::FNEARBYINT,         VT, Legal);

      setOperationAction(ISD::STRICT_FNEARBYINT,  VT, Legal);

      setOperationAction(ISD::FROUNDEVEN, VT, Legal);

      setOperationAction(ISD::STRICT_FROUNDEVEN, VT, Legal);


      setOperationAction(ISD::FROUND,             VT, Custom);


      setOperationAction(ISD::LOAD,               VT, Legal);

      setOperationAction(ISD::STORE,              VT, Legal);


      setOperationAction(ISD::FMA,                VT, Legal);

      setOperationAction(ISD::STRICT_FMA,         VT, Legal);

      setOperationAction(ISD::VSELECT,            VT, Legal);

      setOperationAction(ISD::BUILD_VECTOR,       VT, Custom);

      setOperationAction(ISD::SELECT,             VT, Custom);


      setOperationAction(ISD::FNEG,               VT, Custom);

      setOperationAction(ISD::FABS,               VT, Custom);

      setOperationAction(ISD::FCOPYSIGN,          VT, Custom);

      setOperationAction(ISD::EXTRACT_VECTOR_ELT, VT, Custom);

      setOperationAction(ISD::VECTOR_SHUFFLE,     VT, Custom);


      setOperationAction(ISD::SETCC,              VT, Custom);

      setOperationAction(ISD::STRICT_FSETCC,      VT, Custom);

      setOperationAction(ISD::STRICT_FSETCCS,     VT, Custom);

    };


    // AVX512_FP16 scalar operations

    setGroup(MVT::f16);

    setOperationAction(ISD::FREM,                 MVT::f16, Promote);

    setOperationAction(ISD::STRICT_FREM,          MVT::f16, Promote);

    setOperationAction(ISD::SELECT_CC,            MVT::f16, Expand);

    setOperationAction(ISD::BR_CC,                MVT::f16, Expand);

    setOperationAction(ISD::STRICT_FROUND,        MVT::f16, Promote);

    setOperationAction(ISD::FROUNDEVEN,           MVT::f16, Legal);

    setOperationAction(ISD::STRICT_FROUNDEVEN,    MVT::f16, Legal);

    setOperationAction(ISD::FP_ROUND,             MVT::f16, Custom);

    setOperationAction(ISD::STRICT_FP_ROUND,      MVT::f16, Custom);

    setOperationAction(ISD::FMAXIMUM,             MVT::f16, Custom);

    setOperationAction(ISD::FMINIMUM,             MVT::f16, Custom);

    setOperationAction(ISD::FMAXIMUMNUM,          MVT::f16, Custom);

    setOperationAction(ISD::FMINIMUMNUM,          MVT::f16, Custom);

    setOperationAction(ISD::FP_EXTEND,            MVT::f32, Legal);

    setOperationAction(ISD::STRICT_FP_EXTEND,     MVT::f32, Legal);

    setOperationAction(ISD::LRINT,                MVT::f16, Legal);

    setOperationAction(ISD::LLRINT,               MVT::f16, Legal);


    setCondCodeAction(ISD::SETOEQ, MVT::f16, Expand);

    setCondCodeAction(ISD::SETUNE, MVT::f16, Expand);


    if (Subtarget.useAVX512Regs()) {

      setGroup(MVT::v32f16);

      setOperationAction(ISD::SCALAR_TO_VECTOR,       MVT::v32f16, Custom);

      setOperationAction(ISD::SINT_TO_FP,             MVT::v32i16, Legal);

      setOperationAction(ISD::STRICT_SINT_TO_FP,      MVT::v32i16, Legal);

      setOperationAction(ISD::UINT_TO_FP,             MVT::v32i16, Legal);

      setOperationAction(ISD::STRICT_UINT_TO_FP,      MVT::v32i16, Legal);

      setOperationAction(ISD::FP_ROUND,               MVT::v16f16, Legal);

      setOperationAction(ISD::STRICT_FP_ROUND,        MVT::v16f16, Legal);

      setOperationAction(ISD::FP_EXTEND,              MVT::v16f32, Custom);

      setOperationAction(ISD::STRICT_FP_EXTEND,       MVT::v16f32, Legal);

      setOperationAction(ISD::FP_EXTEND,              MVT::v8f64,  Custom);

      setOperationAction(ISD::STRICT_FP_EXTEND,       MVT::v8f64,  Legal);

      setOperationAction(ISD::INSERT_VECTOR_ELT,      MVT::v32f16, Custom);


      setOperationAction(ISD::FP_TO_SINT,             MVT::v32i16, Custom);

      setOperationAction(ISD::STRICT_FP_TO_SINT,      MVT::v32i16, Custom);

      setOperationAction(ISD::FP_TO_UINT,             MVT::v32i16, Custom);

      setOperationAction(ISD::STRICT_FP_TO_UINT,      MVT::v32i16, Custom);

      setOperationPromotedToType(ISD::FP_TO_SINT,     MVT::v32i8,  MVT::v32i16);

      setOperationPromotedToType(ISD::STRICT_FP_TO_SINT, MVT::v32i8,

                                 MVT::v32i16);

      setOperationPromotedToType(ISD::FP_TO_UINT,     MVT::v32i8,  MVT::v32i16);

      setOperationPromotedToType(ISD::STRICT_FP_TO_UINT, MVT::v32i8,

                                 MVT::v32i16);

      setOperationPromotedToType(ISD::FP_TO_SINT,     MVT::v32i1,  MVT::v32i16);

      setOperationPromotedToType(ISD::STRICT_FP_TO_SINT, MVT::v32i1,

                                 MVT::v32i16);

      setOperationPromotedToType(ISD::FP_TO_UINT,     MVT::v32i1,  MVT::v32i16);

      setOperationPromotedToType(ISD::STRICT_FP_TO_UINT, MVT::v32i1,

                                 MVT::v32i16);


      setOperationAction(ISD::EXTRACT_SUBVECTOR,      MVT::v16f16, Legal);

      setOperationAction(ISD::INSERT_SUBVECTOR,       MVT::v32f16, Legal);

      setOperationAction(ISD::CONCAT_VECTORS,         MVT::v32f16, Custom);


      setLoadExtAction(ISD::EXTLOAD, MVT::v8f64,  MVT::v8f16,  Legal);

      setLoadExtAction(ISD::EXTLOAD, MVT::v16f32, MVT::v16f16, Legal);


      setOperationAction(ISD::FMINIMUM, MVT::v32f16, Custom);

      setOperationAction(ISD::FMAXIMUM, MVT::v32f16, Custom);

      setOperationAction(ISD::FMINIMUMNUM, MVT::v32f16, Custom);

      setOperationAction(ISD::FMAXIMUMNUM, MVT::v32f16, Custom);

      setOperationAction(ISD::LRINT, MVT::v32f16, Legal);

      setOperationAction(ISD::LLRINT, MVT::v8f16, Legal);

    }


    setOperationAction(ISD::FP_TO_SINT,         MVT::v8i16, Custom);

    setOperationAction(ISD::STRICT_FP_TO_SINT,  MVT::v8i16, Custom);

    setOperationAction(ISD::FP_TO_UINT,         MVT::v8i16, Custom);

    setOperationAction(ISD::STRICT_FP_TO_UINT,  MVT::v8i16, Custom);


    if (Subtarget.hasVLX()) {

      setGroup(MVT::v8f16);

      setGroup(MVT::v16f16);


      setOperationAction(ISD::SCALAR_TO_VECTOR,   MVT::v8f16,  Legal);

      setOperationAction(ISD::SCALAR_TO_VECTOR,   MVT::v16f16, Custom);

      setOperationAction(ISD::SINT_TO_FP,         MVT::v16i16, Legal);

      setOperationAction(ISD::STRICT_SINT_TO_FP,  MVT::v16i16, Legal);

      setOperationAction(ISD::SINT_TO_FP,         MVT::v8i16,  Legal);

      setOperationAction(ISD::STRICT_SINT_TO_FP,  MVT::v8i16,  Legal);

      setOperationAction(ISD::UINT_TO_FP,         MVT::v16i16, Legal);

      setOperationAction(ISD::STRICT_UINT_TO_FP,  MVT::v16i16, Legal);

      setOperationAction(ISD::UINT_TO_FP,         MVT::v8i16,  Legal);

      setOperationAction(ISD::STRICT_UINT_TO_FP,  MVT::v8i16,  Legal);


      setOperationAction(ISD::FP_ROUND,           MVT::v8f16, Legal);

      setOperationAction(ISD::STRICT_FP_ROUND,    MVT::v8f16, Legal);

      setOperationAction(ISD::FP_EXTEND,          MVT::v8f32, Custom);

      setOperationAction(ISD::STRICT_FP_EXTEND,   MVT::v8f32, Legal);

      setOperationAction(ISD::FP_EXTEND,          MVT::v4f64, Custom);

      setOperationAction(ISD::STRICT_FP_EXTEND,   MVT::v4f64, Legal);


      // INSERT_VECTOR_ELT v8f16 extended to VECTOR_SHUFFLE

      setOperationAction(ISD::INSERT_VECTOR_ELT,    MVT::v8f16,  Custom);

      setOperationAction(ISD::INSERT_VECTOR_ELT,    MVT::v16f16, Custom);


      setOperationAction(ISD::EXTRACT_SUBVECTOR,    MVT::v8f16, Legal);

      setOperationAction(ISD::INSERT_SUBVECTOR,     MVT::v16f16, Legal);

      setOperationAction(ISD::CONCAT_VECTORS,       MVT::v16f16, Custom);


      setLoadExtAction(ISD::EXTLOAD, MVT::v4f64, MVT::v4f16, Legal);

      setLoadExtAction(ISD::EXTLOAD, MVT::v2f64, MVT::v2f16, Legal);

      setLoadExtAction(ISD::EXTLOAD, MVT::v8f32, MVT::v8f16, Legal);

      setLoadExtAction(ISD::EXTLOAD, MVT::v4f32, MVT::v4f16, Legal);


      // Need to custom widen these to prevent scalarization.

      setOperationAction(ISD::LOAD,  MVT::v4f16, Custom);

      setOperationAction(ISD::STORE, MVT::v4f16, Custom);


      setOperationAction(ISD::FMINIMUM, MVT::v8f16, Custom);

      setOperationAction(ISD::FMAXIMUM, MVT::v8f16, Custom);

      setOperationAction(ISD::FMINIMUMNUM, MVT::v8f16, Custom);

      setOperationAction(ISD::FMAXIMUMNUM, MVT::v8f16, Custom);


      setOperationAction(ISD::FMINIMUM, MVT::v16f16, Custom);

      setOperationAction(ISD::FMAXIMUM, MVT::v16f16, Custom);

      setOperationAction(ISD::FMINIMUMNUM, MVT::v16f16, Custom);

      setOperationAction(ISD::FMAXIMUMNUM, MVT::v16f16, Custom);

      setOperationAction(ISD::LRINT, MVT::v8f16, Legal);

      setOperationAction(ISD::LRINT, MVT::v16f16, Legal);

    }

  }


  if (!Subtarget.useSoftFloat() &&

      (Subtarget.hasAVXNECONVERT() || Subtarget.hasBF16())) {

    addRegisterClass(MVT::v8bf16, Subtarget.hasAVX512() ? &X86::VR128XRegClass

                                                        : &X86::VR128RegClass);

    addRegisterClass(MVT::v16bf16, Subtarget.hasAVX512() ? &X86::VR256XRegClass

                                                         : &X86::VR256RegClass);

    // We set the type action of bf16 to TypeSoftPromoteHalf, but we don't

    // provide the method to promote BUILD_VECTOR and INSERT_VECTOR_ELT.

    // Set the operation action Custom to do the customization later.

    setOperationAction(ISD::BUILD_VECTOR, MVT::bf16, Custom);

    setOperationAction(ISD::INSERT_VECTOR_ELT, MVT::bf16, Custom);

    for (auto VT : {MVT::v8bf16, MVT::v16bf16}) {

      setF16Action(VT, Expand);

      if (!Subtarget.hasBF16())

        setOperationAction(ISD::VSELECT, VT, Custom);

      setOperationAction(ISD::BUILD_VECTOR, VT, Custom);

      setOperationAction(ISD::VECTOR_SHUFFLE, VT, Custom);

      setOperationAction(ISD::INSERT_SUBVECTOR, VT, Legal);

      setOperationAction(ISD::CONCAT_VECTORS, VT, Custom);

    }

    for (unsigned Opc : {ISD::FADD, ISD::FSUB, ISD::FMUL, ISD::FDIV}) {

      setOperationPromotedToType(Opc, MVT::v8bf16, MVT::v8f32);

      setOperationPromotedToType(Opc, MVT::v16bf16, MVT::v16f32);

    }

    setOperationAction(ISD::SETCC, MVT::v8bf16, Custom);

    setOperationAction(ISD::SETCC, MVT::v16bf16, Custom);

    setOperationAction(ISD::FP_ROUND, MVT::v8bf16, Custom);

    addLegalFPImmediate(APFloat::getZero(APFloat::BFloat()));

  }


  if (!Subtarget.useSoftFloat() && Subtarget.hasBF16() &&

      Subtarget.useAVX512Regs()) {

    addRegisterClass(MVT::v32bf16, &X86::VR512RegClass);

    setF16Action(MVT::v32bf16, Expand);

    for (unsigned Opc : {ISD::FADD, ISD::FSUB, ISD::FMUL, ISD::FDIV})

      setOperationPromotedToType(Opc, MVT::v32bf16, MVT::v32f32);

    setOperationAction(ISD::SETCC, MVT::v32bf16, Custom);

    setOperationAction(ISD::BUILD_VECTOR, MVT::v32bf16, Custom);

    setOperationAction(ISD::FP_ROUND, MVT::v16bf16, Custom);

    setOperationAction(ISD::VECTOR_SHUFFLE, MVT::v32bf16, Custom);

    setOperationAction(ISD::INSERT_SUBVECTOR, MVT::v32bf16, Legal);

    setOperationAction(ISD::CONCAT_VECTORS, MVT::v32bf16, Custom);

  }


  if (!Subtarget.useSoftFloat() && Subtarget.hasAVX10_2()) {

    setOperationAction(ISD::FADD, MVT::v32bf16, Legal);

    setOperationAction(ISD::FSUB, MVT::v32bf16, Legal);

    setOperationAction(ISD::FMUL, MVT::v32bf16, Legal);

    setOperationAction(ISD::FDIV, MVT::v32bf16, Legal);

    setOperationAction(ISD::FSQRT, MVT::v32bf16, Legal);

    setOperationAction(ISD::FMA, MVT::v32bf16, Legal);

    setOperationAction(ISD::SETCC, MVT::v32bf16, Custom);

    setOperationAction(ISD::FMINIMUM, MVT::v32bf16, Custom);

    setOperationAction(ISD::FMAXIMUM, MVT::v32bf16, Custom);

    setOperationAction(ISD::FMINIMUMNUM, MVT::v32bf16, Custom);

    setOperationAction(ISD::FMAXIMUMNUM, MVT::v32bf16, Custom);

    for (auto VT : {MVT::v8bf16, MVT::v16bf16}) {

      setOperationAction(ISD::FADD, VT, Legal);

      setOperationAction(ISD::FSUB, VT, Legal);

      setOperationAction(ISD::FMUL, VT, Legal);

      setOperationAction(ISD::FDIV, VT, Legal);

      setOperationAction(ISD::FSQRT, VT, Legal);

      setOperationAction(ISD::FMA, VT, Legal);

      setOperationAction(ISD::SETCC, VT, Custom);

      setOperationAction(ISD::FMINIMUM, VT, Custom);

      setOperationAction(ISD::FMAXIMUM, VT, Custom);

      setOperationAction(ISD::FMINIMUMNUM, VT, Custom);

      setOperationAction(ISD::FMAXIMUMNUM, VT, Custom);

    }

    for (auto VT : {MVT::f16, MVT::f32, MVT::f64}) {

      setCondCodeAction(ISD::SETOEQ, VT, Custom);

      setCondCodeAction(ISD::SETUNE, VT, Custom);

    }

  }


  if (!Subtarget.useSoftFloat() && Subtarget.hasVLX()) {

    setTruncStoreAction(MVT::v4i64, MVT::v4i8,  Legal);

    setTruncStoreAction(MVT::v4i64, MVT::v4i16, Legal);

    setTruncStoreAction(MVT::v4i64, MVT::v4i32, Legal);

    setTruncStoreAction(MVT::v8i32, MVT::v8i8,  Legal);

    setTruncStoreAction(MVT::v8i32, MVT::v8i16, Legal);


    setTruncStoreAction(MVT::v2i64, MVT::v2i8,  Legal);

    setTruncStoreAction(MVT::v2i64, MVT::v2i16, Legal);

    setTruncStoreAction(MVT::v2i64, MVT::v2i32, Legal);

    setTruncStoreAction(MVT::v4i32, MVT::v4i8,  Legal);

    setTruncStoreAction(MVT::v4i32, MVT::v4i16, Legal);


    if (Subtarget.hasBWI()) {

      setTruncStoreAction(MVT::v16i16,  MVT::v16i8, Legal);

      setTruncStoreAction(MVT::v8i16,   MVT::v8i8,  Legal);

    }


    if (Subtarget.hasFP16()) {

      // vcvttph2[u]dq v4f16 -> v4i32/64, v2f16 -> v2i32/64

      setOperationAction(ISD::FP_TO_SINT,        MVT::v2f16, Custom);

      setOperationAction(ISD::STRICT_FP_TO_SINT, MVT::v2f16, Custom);

      setOperationAction(ISD::FP_TO_UINT,        MVT::v2f16, Custom);

      setOperationAction(ISD::STRICT_FP_TO_UINT, MVT::v2f16, Custom);

      setOperationAction(ISD::FP_TO_SINT,        MVT::v4f16, Custom);

      setOperationAction(ISD::STRICT_FP_TO_SINT, MVT::v4f16, Custom);

      setOperationAction(ISD::FP_TO_UINT,        MVT::v4f16, Custom);

      setOperationAction(ISD::STRICT_FP_TO_UINT, MVT::v4f16, Custom);

      // vcvt[u]dq2ph v4i32/64 -> v4f16, v2i32/64 -> v2f16

      setOperationAction(ISD::SINT_TO_FP,        MVT::v2f16, Custom);

      setOperationAction(ISD::STRICT_SINT_TO_FP, MVT::v2f16, Custom);

      setOperationAction(ISD::UINT_TO_FP,        MVT::v2f16, Custom);

      setOperationAction(ISD::STRICT_UINT_TO_FP, MVT::v2f16, Custom);

      setOperationAction(ISD::SINT_TO_FP,        MVT::v4f16, Custom);

      setOperationAction(ISD::STRICT_SINT_TO_FP, MVT::v4f16, Custom);

      setOperationAction(ISD::UINT_TO_FP,        MVT::v4f16, Custom);

      setOperationAction(ISD::STRICT_UINT_TO_FP, MVT::v4f16, Custom);

      // vcvtps2phx v4f32 -> v4f16, v2f32 -> v2f16

      setOperationAction(ISD::FP_ROUND,          MVT::v2f16, Custom);

      setOperationAction(ISD::STRICT_FP_ROUND,   MVT::v2f16, Custom);

      setOperationAction(ISD::FP_ROUND,          MVT::v4f16, Custom);

      setOperationAction(ISD::STRICT_FP_ROUND,   MVT::v4f16, Custom);

      // vcvtph2psx v4f16 -> v4f32, v2f16 -> v2f32

      setOperationAction(ISD::FP_EXTEND,         MVT::v2f16, Custom);

      setOperationAction(ISD::STRICT_FP_EXTEND,  MVT::v2f16, Custom);

      setOperationAction(ISD::FP_EXTEND,         MVT::v4f16, Custom);

      setOperationAction(ISD::STRICT_FP_EXTEND,  MVT::v4f16, Custom);

    }

  }


  if (!Subtarget.useSoftFloat() && Subtarget.hasAMXTILE()) {

    addRegisterClass(MVT::x86amx, &X86::TILERegClass);

  }


  // We want to custom lower some of our intrinsics.

  setOperationAction(ISD::INTRINSIC_WO_CHAIN, MVT::Other, Custom);

  setOperationAction(ISD::INTRINSIC_W_CHAIN, MVT::Other, Custom);

  setOperationAction(ISD::INTRINSIC_VOID, MVT::Other, Custom);

  if (!Subtarget.is64Bit()) {

    setOperationAction(ISD::INTRINSIC_W_CHAIN, MVT::i64, Custom);

  }


  // Only custom-lower 64-bit SADDO and friends on 64-bit because we don't

  // handle type legalization for these operations here.

  //

  // FIXME: We really should do custom legalization for addition and

  // subtraction on x86-32 once PR3203 is fixed.  We really can't do much better

  // than generic legalization for 64-bit multiplication-with-overflow, though.

  for (auto VT : { MVT::i8, MVT::i16, MVT::i32, MVT::i64 }) {

    if (VT == MVT::i64 && !Subtarget.is64Bit())

      continue;

    // Add/Sub/Mul with overflow operations are custom lowered.

    setOperationAction(ISD::SADDO, VT, Custom);

    setOperationAction(ISD::UADDO, VT, Custom);

    setOperationAction(ISD::SSUBO, VT, Custom);

    setOperationAction(ISD::USUBO, VT, Custom);

    setOperationAction(ISD::SMULO, VT, Custom);

    setOperationAction(ISD::UMULO, VT, Custom);


    // Support carry in as value rather than glue.

    setOperationAction(ISD::UADDO_CARRY, VT, Custom);

    setOperationAction(ISD::USUBO_CARRY, VT, Custom);

    setOperationAction(ISD::SETCCCARRY, VT, Custom);

    setOperationAction(ISD::SADDO_CARRY, VT, Custom);

    setOperationAction(ISD::SSUBO_CARRY, VT, Custom);

  }


  // Combine sin / cos into _sincos_stret if it is available.

  setOperationAction(ISD::FSINCOS, MVT::f64, Expand);

  setOperationAction(ISD::FSINCOS, MVT::f32, Expand);


  if (Subtarget.isTargetWin64()) {

    setOperationAction(ISD::SDIV, MVT::i128, Custom);

    setOperationAction(ISD::UDIV, MVT::i128, Custom);

    setOperationAction(ISD::SREM, MVT::i128, Custom);

    setOperationAction(ISD::UREM, MVT::i128, Custom);

    setOperationAction(ISD::FP_TO_SINT, MVT::i128, Custom);

    setOperationAction(ISD::FP_TO_UINT, MVT::i128, Custom);

    setOperationAction(ISD::SINT_TO_FP, MVT::i128, Custom);

    setOperationAction(ISD::UINT_TO_FP, MVT::i128, Custom);

    setOperationAction(ISD::STRICT_FP_TO_SINT, MVT::i128, Custom);

    setOperationAction(ISD::STRICT_FP_TO_UINT, MVT::i128, Custom);

    setOperationAction(ISD::STRICT_SINT_TO_FP, MVT::i128, Custom);

    setOperationAction(ISD::STRICT_UINT_TO_FP, MVT::i128, Custom);

  }


  // On 32 bit MSVC, `fmodf(f32)` is not defined - only `fmod(f64)`

  // is. We should promote the value to 64-bits to solve this.

  // This is what the CRT headers do - `fmodf` is an inline header

  // function casting to f64 and calling `fmod`.

  if (Subtarget.is32Bit() &&

      (Subtarget.isTargetWindowsMSVC() || Subtarget.isTargetWindowsItanium()))

    // clang-format off

   for (ISD::NodeType Op :

         {ISD::FACOS,  ISD::STRICT_FACOS,

          ISD::FASIN,  ISD::STRICT_FASIN,

          ISD::FATAN,  ISD::STRICT_FATAN,

          ISD::FATAN2, ISD::STRICT_FATAN2,

          ISD::FCEIL,  ISD::STRICT_FCEIL,

          ISD::FCOS,   ISD::STRICT_FCOS,

          ISD::FCOSH,  ISD::STRICT_FCOSH,

          ISD::FEXP,   ISD::STRICT_FEXP,

          ISD::FFLOOR, ISD::STRICT_FFLOOR,

          ISD::FREM,   ISD::STRICT_FREM,

          ISD::FLOG,   ISD::STRICT_FLOG,

          ISD::FLOG10, ISD::STRICT_FLOG10,

          ISD::FPOW,   ISD::STRICT_FPOW,

          ISD::FSIN,   ISD::STRICT_FSIN,

          ISD::FSINH,  ISD::STRICT_FSINH,

          ISD::FTAN,   ISD::STRICT_FTAN,

          ISD::FTANH,  ISD::STRICT_FTANH,

          // TODO: Add ISD:::STRICT_FMODF too once implemented.

          ISD::FMODF})

     if (isOperationExpandOrLibCall(Op, MVT::f32))

        setOperationAction(Op, MVT::f32, Promote);

  // clang-format on


  // On MSVC, both 32-bit and 64-bit, ldexpf(f32) is not defined.  MinGW has

  // it, but it's just a wrapper around ldexp.

  if (Subtarget.isOSWindows()) {

    for (ISD::NodeType Op : {ISD::FLDEXP, ISD::STRICT_FLDEXP, ISD::FFREXP})

      if (isOperationExpand(Op, MVT::f32))

        setOperationAction(Op, MVT::f32, Promote);

  }


  setOperationPromotedToType(ISD::ATOMIC_LOAD, MVT::f16, MVT::i16);

  setOperationPromotedToType(ISD::ATOMIC_LOAD, MVT::f32, MVT::i32);

  setOperationPromotedToType(ISD::ATOMIC_LOAD, MVT::f64, MVT::i64);


  // We have target-specific dag combine patterns for the following nodes:

  setTargetDAGCombine({ISD::VECTOR_SHUFFLE,

                       ISD::SCALAR_TO_VECTOR,

                       ISD::INSERT_VECTOR_ELT,

                       ISD::EXTRACT_VECTOR_ELT,

                       ISD::CONCAT_VECTORS,

                       ISD::INSERT_SUBVECTOR,

                       ISD::EXTRACT_SUBVECTOR,

                       ISD::BITCAST,

                       ISD::VSELECT,

                       ISD::SELECT,

                       ISD::SHL,

                       ISD::SRA,

                       ISD::SRL,

                       ISD::OR,

                       ISD::AND,

                       ISD::AVGCEILS,

                       ISD::AVGCEILU,

                       ISD::AVGFLOORS,

                       ISD::AVGFLOORU,

                       ISD::BITREVERSE,

                       ISD::ADD,

                       ISD::SADDSAT,

                       ISD::SSUBSAT,

                       ISD::FADD,

                       ISD::FSUB,

                       ISD::FNEG,

                       ISD::FMA,

                       ISD::STRICT_FMA,

                       ISD::FMINNUM,

                       ISD::FMAXNUM,

                       ISD::SUB,

                       ISD::LOAD,

                       ISD::LRINT,

                       ISD::LLRINT,

                       ISD::MLOAD,

                       ISD::STORE,

                       ISD::MSTORE,

                       ISD::TRUNCATE,

                       ISD::ZERO_EXTEND,

                       ISD::ANY_EXTEND,

                       ISD::SIGN_EXTEND,

                       ISD::SIGN_EXTEND_INREG,

                       ISD::ANY_EXTEND_VECTOR_INREG,

                       ISD::SIGN_EXTEND_VECTOR_INREG,

                       ISD::ZERO_EXTEND_VECTOR_INREG,

                       ISD::SINT_TO_FP,

                       ISD::UINT_TO_FP,

                       ISD::FP_TO_SINT,

                       ISD::STRICT_SINT_TO_FP,

                       ISD::STRICT_UINT_TO_FP,

                       ISD::FP_TO_SINT_SAT,

                       ISD::FP_TO_UINT_SAT,

                       ISD::SETCC,

                       ISD::MUL,

                       ISD::XOR,

                       ISD::MSCATTER,

                       ISD::MGATHER,

                       ISD::FP16_TO_FP,

                       ISD::FP_EXTEND,

                       ISD::STRICT_FP_EXTEND,

                       ISD::FP_ROUND,

                       ISD::STRICT_FP_ROUND,

                       ISD::ROTL,

                       ISD::ROTR,

                       ISD::FSHL,

                       ISD::FSHR,

                       ISD::INTRINSIC_VOID,

                       ISD::INTRINSIC_WO_CHAIN,

                       ISD::INTRINSIC_W_CHAIN});


  computeRegisterProperties(Subtarget.getRegisterInfo());


  MaxStoresPerMemset = 16; // For @llvm.memset -> sequence of stores

  MaxStoresPerMemsetOptSize = 8;

  MaxStoresPerMemcpy = 8; // For @llvm.memcpy -> sequence of stores

  MaxStoresPerMemcpyOptSize = 4;

  MaxStoresPerMemmove = 8; // For @llvm.memmove -> sequence of stores

  MaxStoresPerMemmoveOptSize = 4;


  // TODO: These control memcmp expansion in CGP and could be raised higher, but

  // that needs to benchmarked and balanced with the potential use of vector

  // load/store types (PR33329, PR33914).

  MaxLoadsPerMemcmp = 2;

  MaxLoadsPerMemcmpOptSize = 2;


  // Default loop alignment, which can be overridden by -align-loops.

  setPrefLoopAlignment(Align(16));


  // An out-of-order CPU can speculatively execute past a predictable branch,

  // but a conditional move could be stalled by an expensive earlier operation.

  PredictableSelectIsExpensive = Subtarget.getSchedModel().isOutOfOrder();

  EnableExtLdPromotion = true;

  setPrefFunctionAlignment(Align(16));


  verifyIntrinsicTables();


  // Default to having -disable-strictnode-mutation on

  IsStrictFPEnabled = true;

}


// This has so far only been implemented for 64-bit MachO.


bool X86TargetLowering::useLoadStackGuardNode(const Module &M) const {

  return Subtarget.isTargetMachO() && Subtarget.is64Bit();

}


bool X86TargetLowering::useStackGuardXorFP() const {

  // Currently only MSVC CRTs XOR the frame pointer into the stack guard value.

  return Subtarget.getTargetTriple().isOSMSVCRT() && !Subtarget.isTargetMachO();

}


SDValue X86TargetLowering::emitStackGuardXorFP(SelectionDAG &DAG, SDValue Val,

                                               const SDLoc &DL) const {

  EVT PtrTy = getPointerTy(DAG.getDataLayout());

  unsigned XorOp = Subtarget.is64Bit() ? X86::XOR64_FP : X86::XOR32_FP;

  MachineSDNode *Node = DAG.getMachineNode(XorOp, DL, PtrTy, Val);

  return SDValue(Node, 0);

}


TargetLoweringBase::LegalizeTypeAction


X86TargetLowering::getPreferredVectorAction(MVT VT) const {

  if ((VT == MVT::v32i1 || VT == MVT::v64i1) && Subtarget.hasAVX512() &&

      !Subtarget.hasBWI())

    return TypeSplitVector;


  // Since v8f16 is legal, widen anything over v4f16.

  if (!VT.isScalableVector() && VT.getVectorNumElements() != 1 &&

      VT.getVectorNumElements() <= 4 && !Subtarget.hasF16C() &&

      VT.getVectorElementType() == MVT::f16)

    return TypeSplitVector;


  if (!VT.isScalableVector() && VT.getVectorNumElements() != 1 &&

      VT.getVectorElementType() != MVT::i1)

    return TypeWidenVector;


  return TargetLoweringBase::getPreferredVectorAction(VT);

}


FastISel *X86TargetLowering::createFastISel(

    FunctionLoweringInfo &funcInfo, const TargetLibraryInfo *libInfo,

    const LibcallLoweringInfo *libcallLowering) const {

  return X86::createFastISel(funcInfo, libInfo, libcallLowering);

}


//===----------------------------------------------------------------------===//

//                           Other Lowering Hooks

//===----------------------------------------------------------------------===//


bool X86::mayFoldLoad(SDValue Op, const X86Subtarget &Subtarget,

                      bool AssumeSingleUse, bool IgnoreAlignment) {

  if (!AssumeSingleUse && !Op.hasOneUse())

    return false;

  if (!ISD::isNormalLoad(Op.getNode()))

    return false;


  // If this is an unaligned vector, make sure the target supports folding it.

  auto *Ld = cast<LoadSDNode>(Op.getNode());

  if (!IgnoreAlignment && !Subtarget.hasAVX() &&

      !Subtarget.hasSSEUnalignedMem() && Ld->getValueSizeInBits(0) == 128 &&

      Ld->getAlign() < Align(16))

    return false;


  // TODO: If this is a non-temporal load and the target has an instruction

  //       for it, it should not be folded. See "useNonTemporalLoad()".


  return true;

}


bool X86::mayFoldLoadIntoBroadcastFromMem(SDValue Op, MVT EltVT,

                                          const X86Subtarget &Subtarget,

                                          bool AssumeSingleUse) {

  assert(Subtarget.hasAVX() && "Expected AVX for broadcast from memory");

  if (!X86::mayFoldLoad(Op, Subtarget, AssumeSingleUse))

    return false;


  // We can not replace a wide volatile load with a broadcast-from-memory,

  // because that would narrow the load, which isn't legal for volatiles.

  auto *Ld = cast<LoadSDNode>(Op.getNode());

  return !Ld->isVolatile() ||

         Ld->getValueSizeInBits(0) == EltVT.getScalarSizeInBits();

}


bool X86::mayFoldIntoStore(SDValue Op) {

  if (!Op.hasOneUse())

    return false;

  // Peek through (oneuse) bitcast users

  SDNode *User = *Op->user_begin();

  while (User->getOpcode() == ISD::BITCAST) {

    if (!User->hasOneUse())

      return false;

    User = *User->user_begin();

  }

  return ISD::isNormalStore(User);

}


bool X86::mayFoldIntoZeroExtend(SDValue Op) {

  if (Op.hasOneUse()) {

    unsigned Opcode = Op.getNode()->user_begin()->getOpcode();

    return (ISD::ZERO_EXTEND == Opcode);

  }

  return false;

}


// Return true if its cheap to bitcast this to a vector type.


static bool mayFoldIntoVector(SDValue Op, const SelectionDAG &DAG,

                              const X86Subtarget &Subtarget) {

  if (peekThroughBitcasts(Op).getValueType().isVector())

    return true;

  if (isa<ConstantSDNode>(Op) || isa<ConstantFPSDNode>(Op))

    return true;


  EVT VT = Op.getValueType();

  unsigned Opcode = Op.getOpcode();

  if ((VT == MVT::i128 || VT == MVT::i256 || VT == MVT::i512) &&

      DAG.getTargetLoweringInfo().getOperationAction(Opcode, VT) ==

          TargetLowering::LegalizeAction::Custom) {

    // Check for larger than legal scalar integer ops that might have been

    // custom lowered to vector instruction.

    switch (Opcode) {

    case ISD::BITREVERSE:

      return true;

    case ISD::SHL:

    case ISD::SRL:

    case ISD::SRA:

      return mayFoldIntoVector(Op.getOperand(0), DAG, Subtarget);

    case ISD::AND:

    case ISD::OR:

    case ISD::XOR:

    case ISD::ADD:

    case ISD::SUB:

    case ISD::FSHL:

    case ISD::FSHR:

      return mayFoldIntoVector(Op.getOperand(0), DAG, Subtarget) &&

             mayFoldIntoVector(Op.getOperand(1), DAG, Subtarget);

    case ISD::SELECT:

      return mayFoldIntoVector(Op.getOperand(1), DAG, Subtarget) &&

             mayFoldIntoVector(Op.getOperand(2), DAG, Subtarget);

    }

  }

  return X86::mayFoldLoad(Op, Subtarget, /*AssumeSingleUse=*/true,

                          /*IgnoreAlignment=*/true);

}


static bool isLogicOp(unsigned Opcode) {

  // TODO: Add support for X86ISD::FAND/FOR/FXOR/FANDN with test coverage.

  return ISD::isBitwiseLogicOp(Opcode) || X86ISD::ANDNP == Opcode;

}


static bool isTargetShuffle(unsigned Opcode) {

  switch(Opcode) {

  default: return false;

  case X86ISD::BLENDI:

  case X86ISD::PSHUFB:

  case X86ISD::PSHUFD:

  case X86ISD::PSHUFHW:

  case X86ISD::PSHUFLW:

  case X86ISD::SHUFP:

  case X86ISD::INSERTPS:

  case X86ISD::EXTRQI:

  case X86ISD::INSERTQI:

  case X86ISD::VALIGN:

  case X86ISD::PALIGNR:

  case X86ISD::VSHLDQ:

  case X86ISD::VSRLDQ:

  case X86ISD::MOVLHPS:

  case X86ISD::MOVHLPS:

  case X86ISD::MOVSHDUP:

  case X86ISD::MOVSLDUP:

  case X86ISD::MOVDDUP:

  case X86ISD::MOVSS:

  case X86ISD::MOVSD:

  case X86ISD::MOVSH:

  case X86ISD::UNPCKL:

  case X86ISD::UNPCKH:

  case X86ISD::VBROADCAST:

  case X86ISD::VPERMILPI:

  case X86ISD::VPERMILPV:

  case X86ISD::VPERM2X128:

  case X86ISD::SHUF128:

  case X86ISD::VPERMIL2:

  case X86ISD::VPERMI:

  case X86ISD::VPPERM:

  case X86ISD::VPERMV:

  case X86ISD::VPERMV3:

  case X86ISD::VZEXT_MOVL:

  case X86ISD::COMPRESS:

  case X86ISD::EXPAND:

    return true;

  }

}


static bool isTargetShuffleVariableMask(unsigned Opcode) {

  switch (Opcode) {

  default: return false;

  // Target Shuffles.

  case X86ISD::PSHUFB:

  case X86ISD::VPERMILPV:

  case X86ISD::VPERMIL2:

  case X86ISD::VPPERM:

  case X86ISD::VPERMV:

  case X86ISD::VPERMV3:

    return true;

  // 'Faux' Target Shuffles.

  case ISD::OR:

  case ISD::AND:

  case X86ISD::ANDNP:

    return true;

  }

}


SDValue X86TargetLowering::getReturnAddressFrameIndex(SelectionDAG &DAG) const {

  MachineFunction &MF = DAG.getMachineFunction();

  const X86RegisterInfo *RegInfo = Subtarget.getRegisterInfo();

  X86MachineFunctionInfo *FuncInfo = MF.getInfo<X86MachineFunctionInfo>();

  int ReturnAddrIndex = FuncInfo->getRAIndex();


  if (ReturnAddrIndex == 0) {

    // Set up a frame object for the return address.

    unsigned SlotSize = RegInfo->getSlotSize();

    ReturnAddrIndex = MF.getFrameInfo().CreateFixedObject(SlotSize,

                                                          -(int64_t)SlotSize,

                                                          false);

    FuncInfo->setRAIndex(ReturnAddrIndex);

  }


  return DAG.getFrameIndex(ReturnAddrIndex, getPointerTy(DAG.getDataLayout()));

}


bool X86::isOffsetSuitableForCodeModel(int64_t Offset, CodeModel::Model CM,

                                       bool HasSymbolicDisplacement) {

  // Offset should fit into 32 bit immediate field.

  if (!isInt<32>(Offset))

    return false;


  // If we don't have a symbolic displacement - we don't have any extra

  // restrictions.

  if (!HasSymbolicDisplacement)

    return true;


  // We can fold large offsets in the large code model because we always use

  // 64-bit offsets.

  if (CM == CodeModel::Large)

    return true;


  // For kernel code model we know that all object resist in the negative half

  // of 32bits address space. We may not accept negative offsets, since they may

  // be just off and we may accept pretty large positive ones.

  if (CM == CodeModel::Kernel)

    return Offset >= 0;


  // For other non-large code models we assume that latest small object is 16MB

  // before end of 31 bits boundary. We may also accept pretty large negative

  // constants knowing that all objects are in the positive half of address

  // space.

  return Offset < 16 * 1024 * 1024;

}


/// Return true if the condition is an signed comparison operation.


static bool isX86CCSigned(X86::CondCode X86CC) {

  switch (X86CC) {

  default:

    llvm_unreachable("Invalid integer condition!");

  case X86::COND_E:

  case X86::COND_NE:

  case X86::COND_B:

  case X86::COND_A:

  case X86::COND_BE:

  case X86::COND_AE:

    return false;

  case X86::COND_G:

  case X86::COND_GE:

  case X86::COND_L:

  case X86::COND_LE:

    return true;

  }

}


static X86::CondCode TranslateIntegerX86CC(ISD::CondCode SetCCOpcode) {

  switch (SetCCOpcode) {

  // clang-format off

  default: llvm_unreachable("Invalid integer condition!");

  case ISD::SETEQ:  return X86::COND_E;

  case ISD::SETGT:  return X86::COND_G;

  case ISD::SETGE:  return X86::COND_GE;

  case ISD::SETLT:  return X86::COND_L;

  case ISD::SETLE:  return X86::COND_LE;

  case ISD::SETNE:  return X86::COND_NE;

  case ISD::SETULT: return X86::COND_B;

  case ISD::SETUGT: return X86::COND_A;

  case ISD::SETULE: return X86::COND_BE;

  case ISD::SETUGE: return X86::COND_AE;

  // clang-format on

  }

}


/// Do a one-to-one translation of a ISD::CondCode to the X86-specific

/// condition code, returning the condition code and the LHS/RHS of the

/// comparison to make.


static X86::CondCode TranslateX86CC(ISD::CondCode SetCCOpcode, const SDLoc &DL,

                                    bool isFP, SDValue &LHS, SDValue &RHS,

                                    SelectionDAG &DAG) {

  if (!isFP) {

    if (ConstantSDNode *RHSC = dyn_cast<ConstantSDNode>(RHS)) {

      if (SetCCOpcode == ISD::SETGT && RHSC->isAllOnes()) {

        // X > -1   -> X == 0, jump !sign.

        RHS = DAG.getConstant(0, DL, RHS.getValueType());

        return X86::COND_NS;

      }

      if (SetCCOpcode == ISD::SETLT && RHSC->isZero()) {

        // X < 0   -> X == 0, jump on sign.

        return X86::COND_S;

      }

      if (SetCCOpcode == ISD::SETGE && RHSC->isZero()) {

        // X >= 0   -> X == 0, jump on !sign.

        return X86::COND_NS;

      }

      if (SetCCOpcode == ISD::SETLT && RHSC->isOne()) {

        // X < 1   -> X <= 0

        RHS = DAG.getConstant(0, DL, RHS.getValueType());

        return X86::COND_LE;

      }

    }


    return TranslateIntegerX86CC(SetCCOpcode);

  }


  // First determine if it is required or is profitable to flip the operands.


  // If LHS is a foldable load, but RHS is not, flip the condition.

  if (ISD::isNON_EXTLoad(LHS.getNode()) &&

      !ISD::isNON_EXTLoad(RHS.getNode())) {

    SetCCOpcode = getSetCCSwappedOperands(SetCCOpcode);

    std::swap(LHS, RHS);

  }


  switch (SetCCOpcode) {

  default: break;

  case ISD::SETOLT:

  case ISD::SETOLE:

  case ISD::SETUGT:

  case ISD::SETUGE:

    std::swap(LHS, RHS);

    break;

  }


  // On a floating point condition, the flags are set as follows:

  // ZF  PF  CF   op

  //  0 | 0 | 0 | X > Y

  //  0 | 0 | 1 | X < Y

  //  1 | 0 | 0 | X == Y

  //  1 | 1 | 1 | unordered

  switch (SetCCOpcode) {

  // clang-format off

  default: llvm_unreachable("Condcode should be pre-legalized away");

  case ISD::SETUEQ:

  case ISD::SETEQ:   return X86::COND_E;

  case ISD::SETOLT:              // flipped

  case ISD::SETOGT:

  case ISD::SETGT:   return X86::COND_A;

  case ISD::SETOLE:              // flipped

  case ISD::SETOGE:

  case ISD::SETGE:   return X86::COND_AE;

  case ISD::SETUGT:              // flipped

  case ISD::SETULT:

  case ISD::SETLT:   return X86::COND_B;

  case ISD::SETUGE:              // flipped

  case ISD::SETULE:

  case ISD::SETLE:   return X86::COND_BE;

  case ISD::SETONE:

  case ISD::SETNE:   return X86::COND_NE;

  case ISD::SETUO:   return X86::COND_P;

  case ISD::SETO:    return X86::COND_NP;

  case ISD::SETOEQ:

  case ISD::SETUNE:  return X86::COND_INVALID;

  // clang-format on

  }

}


/// Is there a floating point cmov for the specific X86 condition code?

/// Current x86 isa includes the following FP cmov instructions:

/// fcmovb, fcomvbe, fcomve, fcmovu, fcmovae, fcmova, fcmovne, fcmovnu.


static bool hasFPCMov(unsigned X86CC) {

  switch (X86CC) {

  default:

    return false;

  case X86::COND_B:

  case X86::COND_BE:

  case X86::COND_E:

  case X86::COND_P:

  case X86::COND_A:

  case X86::COND_AE:

  case X86::COND_NE:

  case X86::COND_NP:

    return true;

  }

}


static bool useVPTERNLOG(const X86Subtarget &Subtarget, MVT VT) {

  return Subtarget.hasVLX() || Subtarget.canExtendTo512DQ() ||

         VT.is512BitVector();

}


void X86TargetLowering::getTgtMemIntrinsic(

    SmallVectorImpl<IntrinsicInfo> &Infos, const CallBase &I,

    MachineFunction &MF, unsigned Intrinsic) const {

  IntrinsicInfo Info;

  Info.flags = MachineMemOperand::MONone;

  Info.offset = 0;


  const IntrinsicData* IntrData = getIntrinsicWithChain(Intrinsic);

  if (!IntrData) {

    switch (Intrinsic) {

    case Intrinsic::x86_aesenc128kl:

    case Intrinsic::x86_aesdec128kl:

      Info.opc = ISD::INTRINSIC_W_CHAIN;

      Info.ptrVal = I.getArgOperand(1);

      Info.memVT = EVT::getIntegerVT(I.getType()->getContext(), 48);

      Info.align = Align(1);

      Info.flags |= MachineMemOperand::MOLoad;

      Infos.push_back(Info);

      return;

    case Intrinsic::x86_aesenc256kl:

    case Intrinsic::x86_aesdec256kl:

      Info.opc = ISD::INTRINSIC_W_CHAIN;

      Info.ptrVal = I.getArgOperand(1);

      Info.memVT = EVT::getIntegerVT(I.getType()->getContext(), 64);

      Info.align = Align(1);

      Info.flags |= MachineMemOperand::MOLoad;

      Infos.push_back(Info);

      return;

    case Intrinsic::x86_aesencwide128kl:

    case Intrinsic::x86_aesdecwide128kl:

      Info.opc = ISD::INTRINSIC_W_CHAIN;

      Info.ptrVal = I.getArgOperand(0);

      Info.memVT = EVT::getIntegerVT(I.getType()->getContext(), 48);

      Info.align = Align(1);

      Info.flags |= MachineMemOperand::MOLoad;

      Infos.push_back(Info);

      return;

    case Intrinsic::x86_aesencwide256kl:

    case Intrinsic::x86_aesdecwide256kl:

      Info.opc = ISD::INTRINSIC_W_CHAIN;

      Info.ptrVal = I.getArgOperand(0);

      Info.memVT = EVT::getIntegerVT(I.getType()->getContext(), 64);

      Info.align = Align(1);

      Info.flags |= MachineMemOperand::MOLoad;

      Infos.push_back(Info);

      return;

    case Intrinsic::x86_cmpccxadd32:

    case Intrinsic::x86_cmpccxadd64:

    case Intrinsic::x86_atomic_bts:

    case Intrinsic::x86_atomic_btc:

    case Intrinsic::x86_atomic_btr: {

      Info.opc = ISD::INTRINSIC_W_CHAIN;

      Info.ptrVal = I.getArgOperand(0);

      unsigned Size = I.getType()->getScalarSizeInBits();

      Info.memVT = EVT::getIntegerVT(I.getType()->getContext(), Size);

      Info.align = Align(Size);

      Info.flags |= MachineMemOperand::MOLoad | MachineMemOperand::MOStore |

                    MachineMemOperand::MOVolatile;

      Infos.push_back(Info);

      return;

    }

    case Intrinsic::x86_atomic_bts_rm:

    case Intrinsic::x86_atomic_btc_rm:

    case Intrinsic::x86_atomic_btr_rm: {

      Info.opc = ISD::INTRINSIC_W_CHAIN;

      Info.ptrVal = I.getArgOperand(0);

      unsigned Size = I.getArgOperand(1)->getType()->getScalarSizeInBits();

      Info.memVT = EVT::getIntegerVT(I.getType()->getContext(), Size);

      Info.align = Align(Size);

      Info.flags |= MachineMemOperand::MOLoad | MachineMemOperand::MOStore |

                    MachineMemOperand::MOVolatile;

      Infos.push_back(Info);

      return;

    }

    case Intrinsic::x86_aadd32:

    case Intrinsic::x86_aadd64:

    case Intrinsic::x86_aand32:

    case Intrinsic::x86_aand64:

    case Intrinsic::x86_aor32:

    case Intrinsic::x86_aor64:

    case Intrinsic::x86_axor32:

    case Intrinsic::x86_axor64:

    case Intrinsic::x86_atomic_add_cc:

    case Intrinsic::x86_atomic_sub_cc:

    case Intrinsic::x86_atomic_or_cc:

    case Intrinsic::x86_atomic_and_cc:

    case Intrinsic::x86_atomic_xor_cc: {

      Info.opc = ISD::INTRINSIC_W_CHAIN;

      Info.ptrVal = I.getArgOperand(0);

      unsigned Size = I.getArgOperand(1)->getType()->getScalarSizeInBits();

      Info.memVT = EVT::getIntegerVT(I.getType()->getContext(), Size);

      Info.align = Align(Size);

      Info.flags |= MachineMemOperand::MOLoad | MachineMemOperand::MOStore |

                    MachineMemOperand::MOVolatile;

      Infos.push_back(Info);

      return;

    }

    }

    return;

  }


  switch (IntrData->Type) {

  case TRUNCATE_TO_MEM_VI8:

  case TRUNCATE_TO_MEM_VI16:

  case TRUNCATE_TO_MEM_VI32: {

    Info.opc = ISD::INTRINSIC_VOID;

    Info.ptrVal = I.getArgOperand(0);

    MVT VT  = MVT::getVT(I.getArgOperand(1)->getType());

    MVT ScalarVT = MVT::INVALID_SIMPLE_VALUE_TYPE;

    if (IntrData->Type == TRUNCATE_TO_MEM_VI8)

      ScalarVT = MVT::i8;

    else if (IntrData->Type == TRUNCATE_TO_MEM_VI16)

      ScalarVT = MVT::i16;

    else if (IntrData->Type == TRUNCATE_TO_MEM_VI32)

      ScalarVT = MVT::i32;


    Info.memVT = MVT::getVectorVT(ScalarVT, VT.getVectorNumElements());

    Info.align = Align(1);

    Info.flags |= MachineMemOperand::MOStore;

    Infos.push_back(Info);

    return;

  }

  case GATHER:

  case GATHER_AVX2: {

    Info.opc = ISD::INTRINSIC_W_CHAIN;

    Info.ptrVal = nullptr;

    MVT DataVT = MVT::getVT(I.getType());

    MVT IndexVT = MVT::getVT(I.getArgOperand(2)->getType());

    unsigned NumElts = std::min(DataVT.getVectorNumElements(),

                                IndexVT.getVectorNumElements());

    Info.memVT = MVT::getVectorVT(DataVT.getVectorElementType(), NumElts);

    Info.align = Align(1);

    Info.flags |= MachineMemOperand::MOLoad;

    Infos.push_back(Info);

    return;

  }

  case SCATTER: {

    Info.opc = ISD::INTRINSIC_VOID;

    Info.ptrVal = nullptr;

    MVT DataVT = MVT::getVT(I.getArgOperand(3)->getType());

    MVT IndexVT = MVT::getVT(I.getArgOperand(2)->getType());

    unsigned NumElts = std::min(DataVT.getVectorNumElements(),

                                IndexVT.getVectorNumElements());

    Info.memVT = MVT::getVectorVT(DataVT.getVectorElementType(), NumElts);

    Info.align = Align(1);

    Info.flags |= MachineMemOperand::MOStore;

    Infos.push_back(Info);

    return;

  }

  default:

    return;

  }

}


/// Returns true if the target can instruction select the

/// specified FP immediate natively. If false, the legalizer will

/// materialize the FP immediate as a load from a constant pool.


bool X86TargetLowering::isFPImmLegal(const APFloat &Imm, EVT VT,

                                     bool ForCodeSize) const {

  for (const APFloat &FPImm : LegalFPImmediates)

    if (Imm.bitwiseIsEqual(FPImm))

      return true;

  return false;

}


bool X86TargetLowering::shouldReduceLoadWidth(

    SDNode *Load, ISD::LoadExtType ExtTy, EVT NewVT,

    std::optional<unsigned> ByteOffset) const {

  assert(cast<LoadSDNode>(Load)->isSimple() && "illegal to narrow");


  auto PeekThroughOneUserBitcasts = [](const SDNode *N) {

    while (N->getOpcode() == ISD::BITCAST && N->hasOneUse())

      N = *N->user_begin();

    return N;

  };


  // "ELF Handling for Thread-Local Storage" specifies that R_X86_64_GOTTPOFF

  // relocation target a movq or addq instruction: don't let the load shrink.

  SDValue BasePtr = cast<LoadSDNode>(Load)->getBasePtr();

  if (BasePtr.getOpcode() == X86ISD::WrapperRIP)

    if (const auto *GA = dyn_cast<GlobalAddressSDNode>(BasePtr.getOperand(0)))

      return GA->getTargetFlags() != X86II::MO_GOTTPOFF;


  // If this is an (1) AVX vector load with (2) multiple uses and (3) all of

  // those uses are extracted directly into a store, then the extract + store

  // can be store-folded, or (4) any use will be used by legal full width

  // instruction. Then, it's probably not worth splitting the load.

  EVT VT = Load->getValueType(0);

  if ((VT.is256BitVector() || VT.is512BitVector()) &&

      !SDValue(Load, 0).hasOneUse()) {

    bool FullWidthUse = false;

    bool AllExtractStores = true;

    for (SDUse &Use : Load->uses()) {

      // Skip uses of the chain value. Result 0 of the node is the load value.

      if (Use.getResNo() != 0)

        continue;


      const SDNode *User = PeekThroughOneUserBitcasts(Use.getUser());


      // If this use is an extract + store, it's probably not worth splitting.

      if (User->getOpcode() == ISD::EXTRACT_SUBVECTOR &&

          all_of(User->uses(), [&](const SDUse &U) {

            const SDNode *Inner = PeekThroughOneUserBitcasts(U.getUser());

            return Inner->getOpcode() == ISD::STORE;

          }))

        continue;


      AllExtractStores = false;


      // If any use is a full width legal/target bin op, then assume its legal

      // and won't split.

      if (isBinOp(User->getOpcode()) &&

          (isOperationLegal(User->getOpcode(), User->getValueType(0)) ||

           User->getOpcode() > ISD::BUILTIN_OP_END))

        FullWidthUse = true;

    }


    if (AllExtractStores)

      return false;


    // If we have an user that uses the full vector width, then this use is

    // only worth splitting if the offset isn't 0 (to avoid an

    // EXTRACT_SUBVECTOR) or we're loading a scalar integer.

    if (FullWidthUse)

      return (ByteOffset.value_or(0) > 0) || NewVT.isScalarInteger();

  }


  return true;

}


/// Returns true if it is beneficial to convert a load of a constant

/// to just the constant itself.


bool X86TargetLowering::shouldConvertConstantLoadToIntImm(const APInt &Imm,

                                                          Type *Ty) const {

  assert(Ty->isIntegerTy());


  unsigned BitSize = Ty->getPrimitiveSizeInBits();

  if (BitSize == 0 || BitSize > 64)

    return false;

  return true;

}


bool X86TargetLowering::reduceSelectOfFPConstantLoads(EVT CmpOpVT) const {

  // If we are using XMM registers in the ABI and the condition of the select is

  // a floating-point compare and we have blendv or conditional move, then it is

  // cheaper to select instead of doing a cross-register move and creating a

  // load that depends on the compare result.

  bool IsFPSetCC = CmpOpVT.isFloatingPoint() && CmpOpVT != MVT::f128;

  return !IsFPSetCC || !Subtarget.isTarget64BitLP64() || !Subtarget.hasAVX();

}


bool X86TargetLowering::convertSelectOfConstantsToMath(EVT VT) const {

  // TODO: It might be a win to ease or lift this restriction, but the generic

  // folds in DAGCombiner conflict with vector folds for an AVX512 target.

  if (VT.isVector() && Subtarget.hasAVX512())

    return false;


  return true;

}


bool X86TargetLowering::decomposeMulByConstant(LLVMContext &Context, EVT VT,

                                               SDValue C) const {

  // TODO: We handle scalars using custom code, but generic combining could make

  // that unnecessary.

  APInt MulC;

  if (!ISD::isConstantSplatVector(C.getNode(), MulC))

    return false;


  if (VT.isVector() && VT.getScalarSizeInBits() == 8) {

    // Check whether a vXi8 multiply can be decomposed into two shifts

    // (decomposing 2^m ± 2^n as 2^(a+b) ± 2^b). Similar to

    // DAGCombiner::visitMUL, consider the constant `2` decomposable as

    // (2^0 + 1).

    APInt ShiftedMulC = MulC.abs();

    unsigned TZeros = ShiftedMulC == 2 ? 0 : ShiftedMulC.countr_zero();

    ShiftedMulC.lshrInPlace(TZeros);

    if ((ShiftedMulC - 1).isPowerOf2() || (ShiftedMulC + 1).isPowerOf2())

      return true;

  }


  // Find the type this will be legalized too. Otherwise we might prematurely

  // convert this to shl+add/sub and then still have to type legalize those ops.

  // Another choice would be to defer the decision for illegal types until

  // after type legalization. But constant splat vectors of i64 can't make it

  // through type legalization on 32-bit targets so we would need to special

  // case vXi64.

  while (getTypeAction(Context, VT) != TypeLegal)

    VT = getTypeToTransformTo(Context, VT);


  // If vector multiply is legal, assume that's faster than shl + add/sub.

  // Multiply is a complex op with higher latency and lower throughput in

  // most implementations, sub-vXi32 vector multiplies are always fast,

  // vXi32 mustn't have a SlowMULLD implementation, and anything larger (vXi64)

  // is always going to be slow.

  unsigned EltSizeInBits = VT.getScalarSizeInBits();

  if (isOperationLegal(ISD::MUL, VT) && EltSizeInBits <= 32 &&

      (EltSizeInBits != 32 || !Subtarget.isPMULLDSlow()))

    return false;


  // shl+add, shl+sub, shl+add+neg

  return (MulC + 1).isPowerOf2() || (MulC - 1).isPowerOf2() ||

         (1 - MulC).isPowerOf2() || (-(MulC + 1)).isPowerOf2();

}


bool X86TargetLowering::isExtractSubvectorCheap(EVT ResVT, EVT SrcVT,

                                                unsigned Index) const {

  if (!isOperationLegalOrCustom(ISD::EXTRACT_SUBVECTOR, ResVT))

    return false;


  // Mask vectors support all subregister combinations and operations that

  // extract half of vector.

  if (ResVT.getVectorElementType() == MVT::i1)

    return Index == 0 || ((ResVT.getSizeInBits() == SrcVT.getSizeInBits()*2) &&

                          (Index == ResVT.getVectorNumElements()));


  return (Index % ResVT.getVectorNumElements()) == 0;

}


bool X86TargetLowering::shouldScalarizeBinop(SDValue VecOp) const {

  unsigned Opc = VecOp.getOpcode();


  // Assume target opcodes can't be scalarized.

  // TODO - do we have any exceptions?

  if (Opc >= ISD::BUILTIN_OP_END || !isBinOp(Opc))

    return false;


  // If the vector op is not supported, try to convert to scalar.

  EVT VecVT = VecOp.getValueType();

  if (!isOperationLegalOrCustomOrPromote(Opc, VecVT))

    return true;


  // If the vector op is supported, but the scalar op is not, the transform may

  // not be worthwhile.

  EVT ScalarVT = VecVT.getScalarType();

  return isOperationLegalOrCustomOrPromote(Opc, ScalarVT);

}


bool X86TargetLowering::shouldFormOverflowOp(unsigned Opcode, EVT VT,

                                             bool) const {

  // TODO: Allow vectors?

  if (VT.isVector())

    return false;

  return VT.isSimple() || !isOperationExpand(Opcode, VT);

}


bool X86TargetLowering::isCheapToSpeculateCttz(Type *Ty) const {

  // Speculate cttz only if we can directly use TZCNT/CMOV, can promote to

  // i32/i64 or can rely on BSF passthrough value.

  return Subtarget.hasBMI() || Subtarget.canUseCMOV() ||

         Subtarget.hasBitScanPassThrough() ||

         (!Ty->isVectorTy() &&

          Ty->getScalarSizeInBits() < (Subtarget.is64Bit() ? 64u : 32u));

}


bool X86TargetLowering::isCheapToSpeculateCtlz(Type *Ty) const {

  // Speculate ctlz only if we can directly use LZCNT/CMOV, or can rely on BSR

  // passthrough value.

  return Subtarget.hasLZCNT() || Subtarget.canUseCMOV() ||

         Subtarget.hasBitScanPassThrough();

}


bool X86TargetLowering::ShouldShrinkFPConstant(EVT VT) const {

  // Don't shrink FP constpool if SSE2 is available since cvtss2sd is more

  // expensive than a straight movsd. On the other hand, it's important to

  // shrink long double fp constant since fldt is very slow.

  return !Subtarget.hasSSE2() || VT == MVT::f80;

}


bool X86TargetLowering::isScalarFPTypeInSSEReg(EVT VT) const {

  return (VT == MVT::f64 && Subtarget.hasSSE2()) ||

         (VT == MVT::f32 && Subtarget.hasSSE1()) || VT == MVT::f16;

}


bool X86TargetLowering::isLoadBitCastBeneficial(EVT LoadVT, EVT BitcastVT,

                                                const SelectionDAG &DAG,

                                                const MachineMemOperand &MMO) const {

  if (!Subtarget.hasAVX512() && !LoadVT.isVector() && BitcastVT.isVector() &&

      BitcastVT.getVectorElementType() == MVT::i1)

    return false;


  if (!Subtarget.hasDQI() && BitcastVT == MVT::v8i1 && LoadVT == MVT::i8)

    return false;


  if (LoadVT.isVector() && BitcastVT.isVector()) {

    // If both types are legal vectors, it's always ok to convert them.

    // Don't convert to an illegal type.

    if (isTypeLegal(LoadVT))

      return isTypeLegal(BitcastVT);

  }


  // If we have a large vector type (even if illegal), don't bitcast to large

  // (illegal) scalar types. Better to load fewer vectors and extract.

  if (LoadVT.isVector() && !BitcastVT.isVector() && LoadVT.isInteger() &&

      BitcastVT.isInteger() && (LoadVT.getSizeInBits() % 128) == 0)

    return false;


  return TargetLowering::isLoadBitCastBeneficial(LoadVT, BitcastVT, DAG, MMO);

}


bool X86TargetLowering::canMergeStoresTo(unsigned AddressSpace, EVT MemVT,

                                         const MachineFunction &MF) const {

  // Do not merge to float value size (128 bytes) if no implicit

  // float attribute is set.

  bool NoFloat = MF.getFunction().hasFnAttribute(Attribute::NoImplicitFloat);


  if (NoFloat) {

    unsigned MaxIntSize = Subtarget.is64Bit() ? 64 : 32;

    return (MemVT.getSizeInBits() <= MaxIntSize);

  }

  // Make sure we don't merge greater than our preferred vector

  // width.

  if (MemVT.getSizeInBits() > Subtarget.getPreferVectorWidth())

    return false;


  return true;

}


bool X86TargetLowering::isCtlzFast() const {

  return Subtarget.hasFastLZCNT();

}


bool X86TargetLowering::isMaskAndCmp0FoldingBeneficial(

    const Instruction &AndI) const {

  return true;

}


bool X86TargetLowering::hasAndNotCompare(SDValue Y) const {

  // Scalar integer and-not compares are efficiently handled by NOT+TEST (or

  // BMI ANDN).

  return Y.getValueType().isScalarInteger();

}


bool X86TargetLowering::hasAndNot(SDValue Y) const {

  EVT VT = Y.getValueType();


  if (!VT.isVector()) {

    if (!Subtarget.hasBMI())

      return false;


    // There are only 32-bit and 64-bit forms for 'andn'.

    if (VT != MVT::i32 && VT != MVT::i64)

      return false;

    return !isa<ConstantSDNode>(Y) || cast<ConstantSDNode>(Y)->isOpaque();

  }


  // Vector.

  if (!Subtarget.hasSSE1() || VT.getSizeInBits() < 128)

    return false;


  if (VT == MVT::v4i32)

    return true;


  return Subtarget.hasSSE2();

}


bool X86TargetLowering::hasBitTest(SDValue X, SDValue Y) const {

  return X.getValueType().isScalarInteger(); // 'bt'

}


bool X86TargetLowering::

    shouldProduceAndByConstByHoistingConstFromShiftsLHSOfAnd(

        SDValue X, ConstantSDNode *XC, ConstantSDNode *CC, SDValue Y,

        unsigned OldShiftOpcode, unsigned NewShiftOpcode,

        SelectionDAG &DAG) const {

  // Does baseline recommend not to perform the fold by default?

  if (!TargetLowering::shouldProduceAndByConstByHoistingConstFromShiftsLHSOfAnd(

          X, XC, CC, Y, OldShiftOpcode, NewShiftOpcode, DAG))

    return false;

  // For scalars this transform is always beneficial.

  if (X.getValueType().isScalarInteger())

    return true;

  // If all the shift amounts are identical, then transform is beneficial even

  // with rudimentary SSE2 shifts.

  if (DAG.isSplatValue(Y, /*AllowUndefs=*/true))

    return true;

  // If we have AVX2 with it's powerful shift operations, then it's also good.

  if (Subtarget.hasAVX2())

    return true;

  // Pre-AVX2 vector codegen for this pattern is best for variant with 'shl'.

  return NewShiftOpcode == ISD::SHL;

}


unsigned X86TargetLowering::preferedOpcodeForCmpEqPiecesOfOperand(

    EVT VT, unsigned ShiftOpc, bool MayTransformRotate,

    const APInt &ShiftOrRotateAmt, const std::optional<APInt> &AndMask) const {

  if (!VT.isInteger())

    return ShiftOpc;


  bool PreferRotate = false;

  if (VT.isVector()) {

    // For vectors, if we have rotate instruction support, then its definetly

    // best. Otherwise its not clear what the best so just don't make changed.

    PreferRotate = Subtarget.hasAVX512() && (VT.getScalarType() == MVT::i32 ||

                                             VT.getScalarType() == MVT::i64);

  } else {

    // For scalar, if we have bmi prefer rotate for rorx. Otherwise prefer

    // rotate unless we have a zext mask+shr.

    PreferRotate = Subtarget.hasBMI2();

    if (!PreferRotate) {

      unsigned MaskBits =

          VT.getScalarSizeInBits() - ShiftOrRotateAmt.getZExtValue();

      PreferRotate = (MaskBits != 8) && (MaskBits != 16) && (MaskBits != 32);

    }

  }


  if (ShiftOpc == ISD::SHL || ShiftOpc == ISD::SRL) {

    assert(AndMask.has_value() && "Null andmask when querying about shift+and");


    if (PreferRotate && MayTransformRotate)

      return ISD::ROTL;


    // If vector we don't really get much benefit swapping around constants.

    // Maybe we could check if the DAG has the flipped node already in the

    // future.

    if (VT.isVector())

      return ShiftOpc;


    // See if the beneficial to swap shift type.

    if (ShiftOpc == ISD::SHL) {

      // If the current setup has imm64 mask, then inverse will have

      // at least imm32 mask (or be zext i32 -> i64).

      if (VT == MVT::i64)

        return AndMask->getSignificantBits() > 32 ? (unsigned)ISD::SRL

                                                  : ShiftOpc;


      // We can only benefit if req at least 7-bit for the mask. We

      // don't want to replace shl of 1,2,3 as they can be implemented

      // with lea/add.

      return ShiftOrRotateAmt.uge(7) ? (unsigned)ISD::SRL : ShiftOpc;

    }


    if (VT == MVT::i64)

      // Keep exactly 32-bit imm64, this is zext i32 -> i64 which is

      // extremely efficient.

      return AndMask->getSignificantBits() > 33 ? (unsigned)ISD::SHL : ShiftOpc;


    // Keep small shifts as shl so we can generate add/lea.

    return ShiftOrRotateAmt.ult(7) ? (unsigned)ISD::SHL : ShiftOpc;

  }


  // We prefer rotate for vectors of if we won't get a zext mask with SRL

  // (PreferRotate will be set in the latter case).

  if (PreferRotate || !MayTransformRotate || VT.isVector())

    return ShiftOpc;


  // Non-vector type and we have a zext mask with SRL.

  return ISD::SRL;

}


TargetLoweringBase::CondMergingParams


X86TargetLowering::getJumpConditionMergingParams(Instruction::BinaryOps Opc,

                                                 const Value *Lhs,

                                                 const Value *Rhs) const {

  using namespace llvm::PatternMatch;

  int BaseCost = BrMergingBaseCostThresh.getValue();

  // With CCMP, branches can be merged in a more efficient way.

  if (BaseCost >= 0 && Subtarget.hasCCMP())

    BaseCost += BrMergingCcmpBias;

  // a == b && a == c is a fast pattern on x86.

  if (BaseCost >= 0 && Opc == Instruction::And &&

      match(Lhs, m_SpecificICmp(ICmpInst::ICMP_EQ, m_Value(), m_Value())) &&

      match(Rhs, m_SpecificICmp(ICmpInst::ICMP_EQ, m_Value(), m_Value())))

    BaseCost += 1;


  // For OR conditions with EQ comparisons, prefer splitting into branches

  // (unless CCMP is available). OR+EQ cannot be optimized via bitwise ops,

  // unlike OR+NE which becomes (P|Q)!=0. Similarly, don't split signed

  // comparisons (SLT, SGT) that can be optimized.

  if (BaseCost >= 0 && !Subtarget.hasCCMP() && Opc == Instruction::Or &&

      match(Lhs, m_SpecificICmp(ICmpInst::ICMP_EQ, m_Value(), m_Value())) &&

      match(Rhs, m_SpecificICmp(ICmpInst::ICMP_EQ, m_Value(), m_Value())))

    return {-1, -1, -1};


  return {BaseCost, BrMergingLikelyBias.getValue(),

          BrMergingUnlikelyBias.getValue()};

}


bool X86TargetLowering::preferScalarizeSplat(SDNode *N) const {

  return N->getOpcode() != ISD::FP_EXTEND;

}


bool X86TargetLowering::shouldFoldConstantShiftPairToMask(

    const SDNode *N) const {

  assert(((N->getOpcode() == ISD::SHL &&

           N->getOperand(0).getOpcode() == ISD::SRL) ||

          (N->getOpcode() == ISD::SRL &&

           N->getOperand(0).getOpcode() == ISD::SHL)) &&

         "Expected shift-shift mask");

  // TODO: Should we always create i64 masks? Or only folded immediates?

  EVT VT = N->getValueType(0);

  if ((Subtarget.hasFastVectorShiftMasks() && VT.isVector()) ||

      (Subtarget.hasFastScalarShiftMasks() && !VT.isVector())) {

    // Only fold if the shift values are equal - so it folds to AND.

    // TODO - we should fold if either is a non-uniform vector but we don't do

    // the fold for non-splats yet.

    return N->getOperand(1) == N->getOperand(0).getOperand(1);

  }

  return TargetLoweringBase::shouldFoldConstantShiftPairToMask(N);

}


bool X86TargetLowering::shouldFoldMaskToVariableShiftPair(SDValue Y) const {

  EVT VT = Y.getValueType();


  // For vectors, we don't have a preference, but we probably want a mask.

  if (VT.isVector())

    return false;


  unsigned MaxWidth = Subtarget.is64Bit() ? 64 : 32;

  return VT.getScalarSizeInBits() <= MaxWidth;

}


TargetLowering::ShiftLegalizationStrategy


X86TargetLowering::preferredShiftLegalizationStrategy(

    SelectionDAG &DAG, SDNode *N, unsigned ExpansionFactor) const {

  if (DAG.getMachineFunction().getFunction().hasMinSize() &&

      !Subtarget.isOSWindows())

    return ShiftLegalizationStrategy::LowerToLibcall;

  return TargetLowering::preferredShiftLegalizationStrategy(DAG, N,

                                                            ExpansionFactor);

}


bool X86TargetLowering::shouldSplatInsEltVarIndex(EVT VT) const {

  // Any legal vector type can be splatted more efficiently than

  // loading/spilling from memory.

  return isTypeLegal(VT);

}


MVT X86TargetLowering::hasFastEqualityCompare(unsigned NumBits) const {

  MVT VT = MVT::getIntegerVT(NumBits);

  if (isTypeLegal(VT))

    return VT;


  // PMOVMSKB can handle this.

  if (NumBits == 128 && isTypeLegal(MVT::v16i8))

    return MVT::v16i8;


  // VPMOVMSKB can handle this.

  if (NumBits == 256 && isTypeLegal(MVT::v32i8))

    return MVT::v32i8;


  // TODO: Allow 64-bit type for 32-bit target.

  // TODO: 512-bit types should be allowed, but make sure that those

  // cases are handled in combineVectorSizedSetCCEquality().


  return MVT::INVALID_SIMPLE_VALUE_TYPE;

}


/// Val is the undef sentinel value or equal to the specified value.


static bool isUndefOrEqual(int Val, int CmpVal) {

  return ((Val == SM_SentinelUndef) || (Val == CmpVal));

}


/// Return true if every element in Mask is the undef sentinel value or equal to

/// the specified value.


static bool isUndefOrEqual(ArrayRef<int> Mask, int CmpVal) {

  return llvm::all_of(Mask, [CmpVal](int M) {

    return (M == SM_SentinelUndef) || (M == CmpVal);

  });

}


/// Return true if every element in Mask, beginning from position Pos and ending

/// in Pos+Size is the undef sentinel value or equal to the specified value.


static bool isUndefOrEqualInRange(ArrayRef<int> Mask, int CmpVal, unsigned Pos,

                                  unsigned Size) {

  return llvm::all_of(Mask.slice(Pos, Size),

                      [CmpVal](int M) { return isUndefOrEqual(M, CmpVal); });

}


/// Val is either the undef or zero sentinel value.


static bool isUndefOrZero(int Val) {

  return ((Val == SM_SentinelUndef) || (Val == SM_SentinelZero));

}


/// Return true if every element in Mask, beginning from position Pos and ending

/// in Pos+Size is the undef sentinel value.


static bool isUndefInRange(ArrayRef<int> Mask, unsigned Pos, unsigned Size) {

  return llvm::all_of(Mask.slice(Pos, Size), equal_to(SM_SentinelUndef));

}


/// Return true if the mask creates a vector whose lower half is undefined.


static bool isUndefLowerHalf(ArrayRef<int> Mask) {

  unsigned NumElts = Mask.size();

  return isUndefInRange(Mask, 0, NumElts / 2);

}


/// Return true if the mask creates a vector whose upper half is undefined.


static bool isUndefUpperHalf(ArrayRef<int> Mask) {

  unsigned NumElts = Mask.size();

  return isUndefInRange(Mask, NumElts / 2, NumElts / 2);

}


/// Return true if Val falls within the specified range (L, H].


static bool isInRange(int Val, int Low, int Hi) {

  return (Val >= Low && Val < Hi);

}


/// Return true if the value of any element in Mask falls within the specified

/// range (L, H].


static bool isAnyInRange(ArrayRef<int> Mask, int Low, int Hi) {

  return llvm::any_of(Mask, [Low, Hi](int M) { return isInRange(M, Low, Hi); });

}


/// Return true if the value of any element in Mask is the zero sentinel value.


static bool isAnyZero(ArrayRef<int> Mask) {

  return llvm::any_of(Mask, equal_to(SM_SentinelZero));

}


/// Return true if Val is undef or if its value falls within the

/// specified range (L, H].


static bool isUndefOrInRange(int Val, int Low, int Hi) {

  return (Val == SM_SentinelUndef) || isInRange(Val, Low, Hi);

}


/// Return true if every element in Mask is undef or if its value

/// falls within the specified range (L, H].


static bool isUndefOrInRange(ArrayRef<int> Mask, int Low, int Hi) {

  return llvm::all_of(

      Mask, [Low, Hi](int M) { return isUndefOrInRange(M, Low, Hi); });

}


/// Return true if Val is undef, zero or if its value falls within the

/// specified range (L, H].


static bool isUndefOrZeroOrInRange(int Val, int Low, int Hi) {

  return isUndefOrZero(Val) || isInRange(Val, Low, Hi);

}


/// Return true if every element in Mask is undef, zero or if its value

/// falls within the specified range (L, H].


static bool isUndefOrZeroOrInRange(ArrayRef<int> Mask, int Low, int Hi) {

  return llvm::all_of(

      Mask, [Low, Hi](int M) { return isUndefOrZeroOrInRange(M, Low, Hi); });

}


/// Return true if every element in Mask, is an in-place blend/select mask or is

/// undef.


[[maybe_unused]] static bool isBlendOrUndef(ArrayRef<int> Mask) {

  unsigned NumElts = Mask.size();

  for (auto [I, M] : enumerate(Mask))

    if (!isUndefOrEqual(M, I) && !isUndefOrEqual(M, I + NumElts))

      return false;

  return true;

}


/// Return true if every element in Mask, beginning

/// from position Pos and ending in Pos + Size, falls within the specified

/// sequence (Low, Low + Step, ..., Low + (Size - 1) * Step) or is undef.


static bool isSequentialOrUndefInRange(ArrayRef<int> Mask, unsigned Pos,

                                       unsigned Size, int Low, int Step = 1) {

  for (unsigned i = Pos, e = Pos + Size; i != e; ++i, Low += Step)

    if (!isUndefOrEqual(Mask[i], Low))

      return false;

  return true;

}


/// Return true if every element in Mask, beginning

/// from position Pos and ending in Pos+Size, falls within the specified

/// sequential range (Low, Low+Size], or is undef or is zero.


static bool isSequentialOrUndefOrZeroInRange(ArrayRef<int> Mask, unsigned Pos,

                                             unsigned Size, int Low,

                                             int Step = 1) {

  for (unsigned i = Pos, e = Pos + Size; i != e; ++i, Low += Step)

    if (!isUndefOrZero(Mask[i]) && Mask[i] != Low)

      return false;

  return true;

}


/// Return true if every element in Mask, beginning

/// from position Pos and ending in Pos+Size is undef or is zero.


static bool isUndefOrZeroInRange(ArrayRef<int> Mask, unsigned Pos,

                                 unsigned Size) {

  return llvm::all_of(Mask.slice(Pos, Size), isUndefOrZero);

}


/// Return true if every element of a single input is referenced by the shuffle

/// mask. i.e. it just permutes them all.


static bool isCompletePermute(ArrayRef<int> Mask) {

  unsigned NumElts = Mask.size();

  APInt DemandedElts = APInt::getZero(NumElts);

  for (int M : Mask)

    if (isInRange(M, 0, NumElts))

      DemandedElts.setBit(M);

  return DemandedElts.isAllOnes();

}


/// Helper function to test whether a shuffle mask could be

/// simplified by widening the elements being shuffled.

///

/// Appends the mask for wider elements in WidenedMask if valid. Otherwise

/// leaves it in an unspecified state.

///

/// NOTE: This must handle normal vector shuffle masks and *target* vector

/// shuffle masks. The latter have the special property of a '-2' representing

/// a zero-ed lane of a vector.


static bool canWidenShuffleElements(ArrayRef<int> Mask,

                                    SmallVectorImpl<int> &WidenedMask) {

  WidenedMask.assign(Mask.size() / 2, 0);

  for (int i = 0, Size = Mask.size(); i < Size; i += 2) {

    int M0 = Mask[i];

    int M1 = Mask[i + 1];


    // If both elements are undef, its trivial.

    if (M0 == SM_SentinelUndef && M1 == SM_SentinelUndef) {

      WidenedMask[i / 2] = SM_SentinelUndef;

      continue;

    }


    // Check for an undef mask and a mask value properly aligned to fit with

    // a pair of values. If we find such a case, use the non-undef mask's value.

    if (M0 == SM_SentinelUndef && M1 >= 0 && (M1 % 2) == 1) {

      WidenedMask[i / 2] = M1 / 2;

      continue;

    }

    if (M1 == SM_SentinelUndef && M0 >= 0 && (M0 % 2) == 0) {

      WidenedMask[i / 2] = M0 / 2;

      continue;

    }


    // When zeroing, we need to spread the zeroing across both lanes to widen.

    if (M0 == SM_SentinelZero || M1 == SM_SentinelZero) {

      if ((M0 == SM_SentinelZero || M0 == SM_SentinelUndef) &&

          (M1 == SM_SentinelZero || M1 == SM_SentinelUndef)) {

        WidenedMask[i / 2] = SM_SentinelZero;

        continue;

      }

      return false;

    }


    // Finally check if the two mask values are adjacent and aligned with

    // a pair.

    if (M0 != SM_SentinelUndef && (M0 % 2) == 0 && (M0 + 1) == M1) {

      WidenedMask[i / 2] = M0 / 2;

      continue;

    }


    // Otherwise we can't safely widen the elements used in this shuffle.

    return false;

  }

  assert(WidenedMask.size() == Mask.size() / 2 &&

         "Incorrect size of mask after widening the elements!");


  return true;

}


static bool canWidenShuffleElements(ArrayRef<int> Mask,

                                    const APInt &Zeroable,

                                    bool V2IsZero,

                                    SmallVectorImpl<int> &WidenedMask) {

  // Create an alternative mask with info about zeroable elements.

  // Here we do not set undef elements as zeroable.

  SmallVector<int, 64> ZeroableMask(Mask);

  if (V2IsZero) {

    assert(!Zeroable.isZero() && "V2's non-undef elements are used?!");

    for (int i = 0, Size = Mask.size(); i != Size; ++i)

      if (Mask[i] != SM_SentinelUndef && Zeroable[i])

        ZeroableMask[i] = SM_SentinelZero;

  }

  return canWidenShuffleElements(ZeroableMask, WidenedMask);

}


static bool canWidenShuffleElements(ArrayRef<int> Mask) {

  SmallVector<int, 32> WidenedMask;

  return canWidenShuffleElements(Mask, WidenedMask);

}


// Attempt to narrow/widen shuffle mask until it matches the target number of

// elements.


static bool scaleShuffleElements(ArrayRef<int> Mask, unsigned NumDstElts,

                                 SmallVectorImpl<int> &ScaledMask) {

  unsigned NumSrcElts = Mask.size();

  assert(((NumSrcElts % NumDstElts) == 0 || (NumDstElts % NumSrcElts) == 0) &&

         "Illegal shuffle scale factor");


  // Narrowing is guaranteed to work.

  if (NumDstElts >= NumSrcElts) {

    int Scale = NumDstElts / NumSrcElts;

    llvm::narrowShuffleMaskElts(Scale, Mask, ScaledMask);

    return true;

  }


  // We have to repeat the widening until we reach the target size, but we can

  // split out the first widening as it sets up ScaledMask for us.

  if (canWidenShuffleElements(Mask, ScaledMask)) {

    while (ScaledMask.size() > NumDstElts) {

      SmallVector<int, 16> WidenedMask;

      if (!canWidenShuffleElements(ScaledMask, WidenedMask))

        return false;

      ScaledMask = std::move(WidenedMask);

    }

    return true;

  }


  return false;

}


static bool canScaleShuffleElements(ArrayRef<int> Mask, unsigned NumDstElts) {

  SmallVector<int, 32> ScaledMask;

  return scaleShuffleElements(Mask, NumDstElts, ScaledMask);

}


// Helper to grow the shuffle mask for a larger value type.

// NOTE: This is different to scaleShuffleElements which is a same size type.


static void growShuffleMask(ArrayRef<int> SrcMask,

                            SmallVectorImpl<int> &DstMask,

                            unsigned SrcSizeInBits, unsigned DstSizeInBits) {

  assert(DstMask.empty() && "Expected an empty shuffle mas");

  assert((DstSizeInBits % SrcSizeInBits) == 0 && "Illegal shuffle scale");

  unsigned Scale = DstSizeInBits / SrcSizeInBits;

  unsigned NumSrcElts = SrcMask.size();

  DstMask.assign(SrcMask.begin(), SrcMask.end());

  for (int &M : DstMask) {

    if (M < 0)

      continue;

    M = (M % NumSrcElts) + ((M / NumSrcElts) * Scale * NumSrcElts);

  }

  DstMask.append((Scale - 1) * NumSrcElts, SM_SentinelUndef);

}


/// Returns true if Elt is a constant zero or a floating point constant +0.0.


bool X86::isZeroNode(SDValue Elt) {

  return isNullConstant(Elt) || isNullFPConstant(Elt);

}


// Build a vector of constants.

// Use an UNDEF node if MaskElt == -1.

// Split 64-bit constants in the 32-bit mode.


static SDValue getConstVector(ArrayRef<int> Values, MVT VT, SelectionDAG &DAG,

                              const SDLoc &dl, bool IsMask = false) {


  SmallVector<SDValue, 32>  Ops;

  bool Split = false;


  MVT ConstVecVT = VT;

  unsigned NumElts = VT.getVectorNumElements();

  bool In64BitMode = DAG.getTargetLoweringInfo().isTypeLegal(MVT::i64);

  if (!In64BitMode && VT.getVectorElementType() == MVT::i64) {

    ConstVecVT = MVT::getVectorVT(MVT::i32, NumElts * 2);

    Split = true;

  }


  MVT EltVT = ConstVecVT.getVectorElementType();

  for (unsigned i = 0; i < NumElts; ++i) {

    bool IsUndef = Values[i] < 0 && IsMask;

    SDValue OpNode = IsUndef ? DAG.getUNDEF(EltVT) :

      DAG.getConstant(Values[i], dl, EltVT);

    Ops.push_back(OpNode);

    if (Split)

      Ops.push_back(IsUndef ? DAG.getUNDEF(EltVT) :

                    DAG.getConstant(0, dl, EltVT));

  }

  SDValue ConstsNode = DAG.getBuildVector(ConstVecVT, dl, Ops);

  if (Split)

    ConstsNode = DAG.getBitcast(VT, ConstsNode);

  return ConstsNode;

}


static SDValue getConstVector(ArrayRef<APInt> Bits, const APInt &Undefs,

                              MVT VT, SelectionDAG &DAG, const SDLoc &dl) {

  assert(Bits.size() == Undefs.getBitWidth() &&

         "Unequal constant and undef arrays");

  SmallVector<SDValue, 32> Ops;

  bool Split = false;


  MVT ConstVecVT = VT;

  unsigned NumElts = VT.getVectorNumElements();

  bool In64BitMode = DAG.getTargetLoweringInfo().isTypeLegal(MVT::i64);

  if (!In64BitMode && VT.getVectorElementType() == MVT::i64) {

    ConstVecVT = MVT::getVectorVT(MVT::i32, NumElts * 2);

    Split = true;

  }


  MVT EltVT = ConstVecVT.getVectorElementType();

  MVT EltIntVT = EltVT.changeTypeToInteger();

  for (unsigned i = 0, e = Bits.size(); i != e; ++i) {

    if (Undefs[i]) {

      Ops.append(Split ? 2 : 1, DAG.getUNDEF(EltVT));

      continue;

    }

    const APInt &V = Bits[i];

    assert(V.getBitWidth() == VT.getScalarSizeInBits() && "Unexpected sizes");

    if (Split) {

      Ops.push_back(DAG.getConstant(V.extractBits(32, 0), dl, EltVT));

      Ops.push_back(DAG.getConstant(V.extractBits(32, 32), dl, EltVT));

    } else {

      Ops.push_back(DAG.getBitcast(EltVT, DAG.getConstant(V, dl, EltIntVT)));

    }

  }


  SDValue ConstsNode = DAG.getBuildVector(ConstVecVT, dl, Ops);

  return DAG.getBitcast(VT, ConstsNode);

}


static SDValue getConstVector(ArrayRef<APInt> Bits, MVT VT,

                              SelectionDAG &DAG, const SDLoc &dl) {

  APInt Undefs = APInt::getZero(Bits.size());

  return getConstVector(Bits, Undefs, VT, DAG, dl);

}


/// Returns a vector of specified type with all zero elements.


static SDValue getZeroVector(MVT VT, const X86Subtarget &Subtarget,

                             SelectionDAG &DAG, const SDLoc &dl) {

  assert((VT.is128BitVector() || VT.is256BitVector() || VT.is512BitVector() ||

          VT.getVectorElementType() == MVT::i1) &&

         "Unexpected vector type");


  // Try to build SSE/AVX zero vectors as <N x i32> bitcasted to their dest

  // type. This ensures they get CSE'd. But if the integer type is not

  // available, use a floating-point +0.0 instead.

  SDValue Vec;

  const TargetLowering &TLI = DAG.getTargetLoweringInfo();

  if (!Subtarget.hasSSE2() && VT.is128BitVector()) {

    Vec = DAG.getConstantFP(+0.0, dl, MVT::v4f32);

  } else if (VT.isFloatingPoint() &&

             TLI.isTypeLegal(VT.getVectorElementType())) {

    Vec = DAG.getConstantFP(+0.0, dl, VT);

  } else if (VT.getVectorElementType() == MVT::i1) {

    assert((Subtarget.hasBWI() || VT.getVectorNumElements() <= 16) &&

           "Unexpected vector type");

    Vec = DAG.getConstant(0, dl, VT);

  } else {

    unsigned Num32BitElts = VT.getSizeInBits() / 32;

    Vec = DAG.getConstant(0, dl, MVT::getVectorVT(MVT::i32, Num32BitElts));

  }

  return DAG.getBitcast(VT, Vec);

}


// Helper to determine if the ops are all the extracted subvectors come from a

// single source. If we allow commute they don't have to be in order (Lo/Hi).


static SDValue getSplitVectorSrc(SDValue LHS, SDValue RHS, bool AllowCommute) {

  if (LHS.getOpcode() != ISD::EXTRACT_SUBVECTOR ||

      RHS.getOpcode() != ISD::EXTRACT_SUBVECTOR ||

      LHS.getValueType() != RHS.getValueType() ||

      LHS.getOperand(0) != RHS.getOperand(0))

    return SDValue();


  SDValue Src = LHS.getOperand(0);

  if (Src.getValueSizeInBits() != (LHS.getValueSizeInBits() * 2))

    return SDValue();


  unsigned NumElts = LHS.getValueType().getVectorNumElements();

  if ((LHS.getConstantOperandAPInt(1) == 0 &&

       RHS.getConstantOperandAPInt(1) == NumElts) ||

      (AllowCommute && RHS.getConstantOperandAPInt(1) == 0 &&

       LHS.getConstantOperandAPInt(1) == NumElts))

    return Src;


  return SDValue();

}


static SDValue extractSubVector(SDValue Vec, unsigned IdxVal, SelectionDAG &DAG,

                                const SDLoc &dl, unsigned vectorWidth) {

  EVT VT = Vec.getValueType();

  EVT ElVT = VT.getVectorElementType();

  unsigned ResultNumElts =

      (VT.getVectorNumElements() * vectorWidth) / VT.getSizeInBits();

  EVT ResultVT = EVT::getVectorVT(*DAG.getContext(), ElVT, ResultNumElts);


  assert(ResultVT.getSizeInBits() == vectorWidth &&

         "Illegal subvector extraction");


  // Extract the relevant vectorWidth bits.  Generate an EXTRACT_SUBVECTOR

  unsigned ElemsPerChunk = vectorWidth / ElVT.getSizeInBits();

  assert(isPowerOf2_32(ElemsPerChunk) && "Elements per chunk not power of 2");


  // This is the index of the first element of the vectorWidth-bit chunk

  // we want. Since ElemsPerChunk is a power of 2 just need to clear bits.

  IdxVal &= ~(ElemsPerChunk - 1);


  // If the input is a buildvector just emit a smaller one.

  if (Vec.getOpcode() == ISD::BUILD_VECTOR)

    return DAG.getBuildVector(ResultVT, dl,

                              Vec->ops().slice(IdxVal, ElemsPerChunk));


  // Check if we're extracting the upper undef of a widening pattern.

  if (Vec.getOpcode() == ISD::INSERT_SUBVECTOR && Vec.getOperand(0).isUndef() &&

      Vec.getOperand(1).getValueType().getVectorNumElements() <= IdxVal &&

      isNullConstant(Vec.getOperand(2)))

    return DAG.getUNDEF(ResultVT);


  return DAG.getExtractSubvector(dl, ResultVT, Vec, IdxVal);

}


/// Generate a DAG to grab 128-bits from a vector > 128 bits.  This

/// sets things up to match to an AVX VEXTRACTF128 / VEXTRACTI128

/// or AVX-512 VEXTRACTF32x4 / VEXTRACTI32x4

/// instructions or a simple subregister reference. Idx is an index in the

/// 128 bits we want.  It need not be aligned to a 128-bit boundary.  That makes

/// lowering EXTRACT_VECTOR_ELT operations easier.


static SDValue extract128BitVector(SDValue Vec, unsigned IdxVal,

                                   SelectionDAG &DAG, const SDLoc &dl) {

  assert((Vec.getValueType().is256BitVector() ||

          Vec.getValueType().is512BitVector()) &&

         "Unexpected vector size!");

  return extractSubVector(Vec, IdxVal, DAG, dl, 128);

}


/// Generate a DAG to grab 256-bits from a 512-bit vector.


static SDValue extract256BitVector(SDValue Vec, unsigned IdxVal,

                                   SelectionDAG &DAG, const SDLoc &dl) {

  assert(Vec.getValueType().is512BitVector() && "Unexpected vector size!");

  return extractSubVector(Vec, IdxVal, DAG, dl, 256);

}


static SDValue insertSubVector(SDValue Result, SDValue Vec, unsigned IdxVal,

                               SelectionDAG &DAG, const SDLoc &dl,

                               unsigned vectorWidth) {

  assert((vectorWidth == 128 || vectorWidth == 256) &&

         "Unsupported vector width");

  // Inserting UNDEF is Result

  if (Vec.isUndef())

    return Result;


  // Insert the relevant vectorWidth bits.

  EVT VT = Vec.getValueType();

  unsigned ElemsPerChunk = vectorWidth / VT.getScalarSizeInBits();

  assert(isPowerOf2_32(ElemsPerChunk) && "Elements per chunk not power of 2");


  // This is the index of the first element of the vectorWidth-bit chunk

  // we want. Since ElemsPerChunk is a power of 2 just need to clear bits.

  IdxVal &= ~(ElemsPerChunk - 1);

  return DAG.getInsertSubvector(dl, Result, Vec, IdxVal);

}


/// Generate a DAG to put 128-bits into a vector > 128 bits.  This

/// sets things up to match to an AVX VINSERTF128/VINSERTI128 or

/// AVX-512 VINSERTF32x4/VINSERTI32x4 instructions or a

/// simple superregister reference.  Idx is an index in the 128 bits

/// we want.  It need not be aligned to a 128-bit boundary.  That makes

/// lowering INSERT_VECTOR_ELT operations easier.


static SDValue insert128BitVector(SDValue Result, SDValue Vec, unsigned IdxVal,

                                  SelectionDAG &DAG, const SDLoc &dl) {

  assert(Vec.getValueType().is128BitVector() && "Unexpected vector size!");

  return insertSubVector(Result, Vec, IdxVal, DAG, dl, 128);

}


/// Widen a vector to a larger size with the same scalar type, with the new

/// elements either zero or undef.


static SDValue widenSubVector(MVT VT, SDValue Vec, bool ZeroNewElements,

                              const X86Subtarget &Subtarget, SelectionDAG &DAG,

                              const SDLoc &dl) {

  EVT VecVT = Vec.getValueType();

  assert(VecVT.getFixedSizeInBits() <= VT.getFixedSizeInBits() &&

         VecVT.getScalarType() == VT.getScalarType() &&

         "Unsupported vector widening type");

  // If the upper 128-bits of a build vector are already undef/zero, then try to

  // widen from the lower 128-bits.

  if (Vec.getOpcode() == ISD::BUILD_VECTOR && VecVT.is256BitVector()) {

    unsigned NumSrcElts = VecVT.getVectorNumElements();

    ArrayRef<SDUse> Hi = Vec->ops().drop_front(NumSrcElts / 2);

    if (all_of(Hi, [&](SDValue V) {

          return V.isUndef() || (ZeroNewElements && X86::isZeroNode(V));

        }))

      Vec = extract128BitVector(Vec, 0, DAG, dl);

  }

  SDValue Res = ZeroNewElements ? getZeroVector(VT, Subtarget, DAG, dl)

                                : DAG.getUNDEF(VT);

  return DAG.getInsertSubvector(dl, Res, Vec, 0);

}


/// Widen a vector to a larger size with the same scalar type, with the new

/// elements either zero or undef.


static SDValue widenSubVector(SDValue Vec, bool ZeroNewElements,

                              const X86Subtarget &Subtarget, SelectionDAG &DAG,

                              const SDLoc &dl, unsigned WideSizeInBits) {

  assert(Vec.getValueSizeInBits() <= WideSizeInBits &&

         (WideSizeInBits % Vec.getScalarValueSizeInBits()) == 0 &&

         "Unsupported vector widening type");

  unsigned WideNumElts = WideSizeInBits / Vec.getScalarValueSizeInBits();

  MVT SVT = Vec.getSimpleValueType().getScalarType();

  MVT VT = MVT::getVectorVT(SVT, WideNumElts);

  return widenSubVector(VT, Vec, ZeroNewElements, Subtarget, DAG, dl);

}


/// Widen a mask vector type to a minimum of v8i1/v16i1 to allow use of KSHIFT

/// and bitcast with integer types.


static MVT widenMaskVectorType(MVT VT, const X86Subtarget &Subtarget) {

  assert(VT.getVectorElementType() == MVT::i1 && "Expected bool vector");

  unsigned NumElts = VT.getVectorNumElements();

  if ((!Subtarget.hasDQI() && NumElts == 8) || NumElts < 8)

    return Subtarget.hasDQI() ? MVT::v8i1 : MVT::v16i1;

  return VT;

}


/// Widen a mask vector to a minimum of v8i1/v16i1 to allow use of KSHIFT and

/// bitcast with integer types.


static SDValue widenMaskVector(SDValue Vec, bool ZeroNewElements,

                               const X86Subtarget &Subtarget, SelectionDAG &DAG,

                               const SDLoc &dl) {

  MVT VT = widenMaskVectorType(Vec.getSimpleValueType(), Subtarget);

  return widenSubVector(VT, Vec, ZeroNewElements, Subtarget, DAG, dl);

}


// Helper function to collect subvector ops that are concatenated together,

// either by ISD::CONCAT_VECTORS or a ISD::INSERT_SUBVECTOR series.

// The subvectors in Ops are guaranteed to be the same type.


static bool collectConcatOps(SDNode *N, SmallVectorImpl<SDValue> &Ops,

                             SelectionDAG &DAG) {

  assert(Ops.empty() && "Expected an empty ops vector");


  if (N->getOpcode() == ISD::CONCAT_VECTORS) {

    Ops.append(N->op_begin(), N->op_end());

    return true;

  }


  if (N->getOpcode() == ISD::INSERT_SUBVECTOR) {

    SDValue Src = N->getOperand(0);

    SDValue Sub = N->getOperand(1);

    const APInt &Idx = N->getConstantOperandAPInt(2);

    EVT VT = Src.getValueType();

    EVT SubVT = Sub.getValueType();


    if (VT.getSizeInBits() == (SubVT.getSizeInBits() * 2)) {

      // insert_subvector(undef, x, lo)

      if (Idx == 0 && Src.isUndef()) {

        Ops.push_back(Sub);

        Ops.push_back(DAG.getUNDEF(SubVT));

        return true;

      }

      if (Idx == (VT.getVectorNumElements() / 2)) {

        // insert_subvector(insert_subvector(undef, x, lo), y, hi)

        if (Src.getOpcode() == ISD::INSERT_SUBVECTOR &&

            Src.getOperand(1).getValueType() == SubVT &&

            isNullConstant(Src.getOperand(2))) {

          // Attempt to recurse into inner (matching) concats.

          SDValue Lo = Src.getOperand(1);

          SDValue Hi = Sub;

          SmallVector<SDValue, 2> LoOps, HiOps;

          if (collectConcatOps(Lo.getNode(), LoOps, DAG) &&

              collectConcatOps(Hi.getNode(), HiOps, DAG) &&

              LoOps.size() == HiOps.size()) {

            Ops.append(LoOps);

            Ops.append(HiOps);

            return true;

          }

          Ops.push_back(Lo);

          Ops.push_back(Hi);

          return true;

        }

        // insert_subvector(x, extract_subvector(x, lo), hi)

        if (Sub.getOpcode() == ISD::EXTRACT_SUBVECTOR &&

            Sub.getOperand(0) == Src && isNullConstant(Sub.getOperand(1))) {

          Ops.append(2, Sub);

          return true;

        }

        // insert_subvector(undef, x, hi)

        if (Src.isUndef()) {

          Ops.push_back(DAG.getUNDEF(SubVT));

          Ops.push_back(Sub);

          return true;

        }

      }

    }

  }


  if (N->getOpcode() == ISD::EXTRACT_SUBVECTOR) {

    EVT VT = N->getValueType(0);

    SDValue Src = N->getOperand(0);

    uint64_t Idx = N->getConstantOperandVal(1);


    // Collect all the subvectors from the source vector and slice off the

    // extraction.

    SmallVector<SDValue, 4> SrcOps;

    if (collectConcatOps(Src.getNode(), SrcOps, DAG) &&

        VT.getSizeInBits() > SrcOps[0].getValueSizeInBits() &&

        (VT.getSizeInBits() % SrcOps[0].getValueSizeInBits()) == 0 &&

        (Idx % SrcOps[0].getValueType().getVectorNumElements()) == 0) {

      unsigned SubIdx = Idx / SrcOps[0].getValueType().getVectorNumElements();

      unsigned NumSubs = VT.getSizeInBits() / SrcOps[0].getValueSizeInBits();

      Ops.append(SrcOps.begin() + SubIdx, SrcOps.begin() + SubIdx + NumSubs);

      return true;

    }

  }


  assert(Ops.empty() && "Expected an empty ops vector");

  return false;

}


// Helper to check if \p V can be split into subvectors and the upper subvectors

// are all undef. In which case return the lower subvector.


static SDValue isUpperSubvectorUndef(SDValue V, const SDLoc &DL,

                                     SelectionDAG &DAG) {

  SmallVector<SDValue> SubOps;

  if (!collectConcatOps(V.getNode(), SubOps, DAG))

    return SDValue();


  unsigned NumSubOps = SubOps.size();

  unsigned HalfNumSubOps = NumSubOps / 2;

  assert((NumSubOps % 2) == 0 && "Unexpected number of subvectors");


  ArrayRef<SDValue> UpperOps(SubOps.begin() + HalfNumSubOps, SubOps.end());

  if (any_of(UpperOps, [](SDValue Op) { return !Op.isUndef(); }))

    return SDValue();


  EVT HalfVT = V.getValueType().getHalfNumVectorElementsVT(*DAG.getContext());

  ArrayRef<SDValue> LowerOps(SubOps.begin(), SubOps.begin() + HalfNumSubOps);

  return DAG.getNode(ISD::CONCAT_VECTORS, DL, HalfVT, LowerOps);

}


// Helper to check if we can access all the constituent subvectors without any

// extract ops.


static bool isFreeToSplitVector(SDValue V, SelectionDAG &DAG) {

  SmallVector<SDValue> Ops;

  return collectConcatOps(V.getNode(), Ops, DAG);

}


static std::pair<SDValue, SDValue> splitVector(SDValue Op, SelectionDAG &DAG,

                                               const SDLoc &dl) {

  EVT VT = Op.getValueType();

  unsigned NumElems = VT.getVectorNumElements();

  unsigned SizeInBits = VT.getSizeInBits();

  assert((NumElems % 2) == 0 && (SizeInBits % 2) == 0 &&

         "Can't split odd sized vector");


  SmallVector<SDValue, 4> SubOps;

  if (collectConcatOps(Op.getNode(), SubOps, DAG)) {

    assert((SubOps.size() % 2) == 0 && "Can't split odd sized vector concat");

    unsigned HalfOps = SubOps.size() / 2;

    EVT HalfVT = VT.getHalfNumVectorElementsVT(*DAG.getContext());

    SmallVector<SDValue, 2> LoOps(SubOps.begin(), SubOps.begin() + HalfOps);

    SmallVector<SDValue, 2> HiOps(SubOps.begin() + HalfOps, SubOps.end());

    SDValue Lo = DAG.getNode(ISD::CONCAT_VECTORS, dl, HalfVT, LoOps);

    SDValue Hi = DAG.getNode(ISD::CONCAT_VECTORS, dl, HalfVT, HiOps);

    return std::make_pair(Lo, Hi);

  }


  // If this is a splat value (with no-undefs) then use the lower subvector,

  // which should be a free extraction.

  SDValue Lo = extractSubVector(Op, 0, DAG, dl, SizeInBits / 2);

  if (DAG.isSplatValue(Op, /*AllowUndefs*/ false))

    return std::make_pair(Lo, Lo);


  SDValue Hi = extractSubVector(Op, NumElems / 2, DAG, dl, SizeInBits / 2);

  return std::make_pair(Lo, Hi);

}


/// Break an operation into 2 half sized ops and then concatenate the results.


static SDValue splitVectorOp(SDValue Op, SelectionDAG &DAG, const SDLoc &dl) {

  unsigned NumOps = Op.getNumOperands();

  EVT VT = Op.getValueType();


  // Extract the LHS Lo/Hi vectors

  SmallVector<SDValue> LoOps(NumOps, SDValue());

  SmallVector<SDValue> HiOps(NumOps, SDValue());

  for (unsigned I = 0; I != NumOps; ++I) {

    SDValue SrcOp = Op.getOperand(I);

    if (!SrcOp.getValueType().isVector()) {

      LoOps[I] = HiOps[I] = SrcOp;

      continue;

    }

    std::tie(LoOps[I], HiOps[I]) = splitVector(SrcOp, DAG, dl);

  }


  EVT LoVT, HiVT;

  std::tie(LoVT, HiVT) = DAG.GetSplitDestVTs(VT);

  return DAG.getNode(ISD::CONCAT_VECTORS, dl, VT,

                     DAG.getNode(Op.getOpcode(), dl, LoVT, LoOps),

                     DAG.getNode(Op.getOpcode(), dl, HiVT, HiOps));

}


/// Break an unary integer operation into 2 half sized ops and then

/// concatenate the result back.


static SDValue splitVectorIntUnary(SDValue Op, SelectionDAG &DAG,

                                   const SDLoc &dl) {

  // Make sure we only try to split 256/512-bit types to avoid creating

  // narrow vectors.

  [[maybe_unused]] EVT VT = Op.getValueType();

  assert((Op.getOperand(0).getValueType().is256BitVector() ||

          Op.getOperand(0).getValueType().is512BitVector()) &&

         (VT.is256BitVector() || VT.is512BitVector()) && "Unsupported VT!");

  assert(Op.getOperand(0).getValueType().getVectorNumElements() ==

             VT.getVectorNumElements() &&

         "Unexpected VTs!");

  return splitVectorOp(Op, DAG, dl);

}


/// Break a binary integer operation into 2 half sized ops and then

/// concatenate the result back.


static SDValue splitVectorIntBinary(SDValue Op, SelectionDAG &DAG,

                                    const SDLoc &dl) {

  // Assert that all the types match.

  [[maybe_unused]] EVT VT = Op.getValueType();

  assert(Op.getOperand(0).getValueType() == VT &&

         Op.getOperand(1).getValueType() == VT && "Unexpected VTs!");

  assert((VT.is256BitVector() || VT.is512BitVector()) && "Unsupported VT!");

  return splitVectorOp(Op, DAG, dl);

}


// Helper for splitting operands of an operation to legal target size and

// apply a function on each part.

// Useful for operations that are available on SSE2 in 128-bit, on AVX2 in

// 256-bit and on AVX512BW in 512-bit. The argument VT is the type used for

// deciding if/how to split Ops. Ops elements do *not* have to be of type VT.

// The argument Builder is a function that will be applied on each split part:

// SDValue Builder(SelectionDAG&G, SDLoc, ArrayRef<SDValue>)

template <typename F>


SDValue SplitOpsAndApply(SelectionDAG &DAG, const X86Subtarget &Subtarget,

                         const SDLoc &DL, EVT VT, ArrayRef<SDValue> Ops,

                         F Builder, bool CheckBWI = true,

                         bool AllowAVX512 = true) {

  assert(Subtarget.hasSSE2() && "Target assumed to support at least SSE2");

  unsigned NumSubs = 1;

  if (AllowAVX512 && ((CheckBWI && Subtarget.useBWIRegs()) ||

                      (!CheckBWI && Subtarget.useAVX512Regs()))) {

    if (VT.getSizeInBits() > 512) {

      NumSubs = VT.getSizeInBits() / 512;

      assert((VT.getSizeInBits() % 512) == 0 && "Illegal vector size");

    }

  } else if (Subtarget.hasAVX2()) {

    if (VT.getSizeInBits() > 256) {

      NumSubs = VT.getSizeInBits() / 256;

      assert((VT.getSizeInBits() % 256) == 0 && "Illegal vector size");

    }

  } else {

    if (VT.getSizeInBits() > 128) {

      NumSubs = VT.getSizeInBits() / 128;

      assert((VT.getSizeInBits() % 128) == 0 && "Illegal vector size");

    }

  }


  if (NumSubs == 1)

    return Builder(DAG, DL, Ops);


  SmallVector<SDValue, 4> Subs;

  for (unsigned i = 0; i != NumSubs; ++i) {

    SmallVector<SDValue, 2> SubOps;

    for (SDValue Op : Ops) {

      EVT OpVT = Op.getValueType();

      unsigned NumSubElts = OpVT.getVectorNumElements() / NumSubs;

      unsigned SizeSub = OpVT.getSizeInBits() / NumSubs;

      SubOps.push_back(extractSubVector(Op, i * NumSubElts, DAG, DL, SizeSub));

    }

    Subs.push_back(Builder(DAG, DL, SubOps));

  }

  return DAG.getNode(ISD::CONCAT_VECTORS, DL, VT, Subs);

}


// Helper function that extends a non-512-bit vector op to 512-bits on non-VLX

// targets.


static SDValue getAVX512Node(unsigned Opcode, const SDLoc &DL, MVT VT,

                             ArrayRef<SDValue> Ops, SelectionDAG &DAG,

                             const X86Subtarget &Subtarget) {

  assert(Subtarget.hasAVX512() && "AVX512 target expected");

  MVT SVT = VT.getScalarType();


  // If we have a 32/64 splatted constant, splat it to DstTy to

  // encourage a foldable broadcast'd operand.

  auto MakeBroadcastOp = [&](SDValue Op, MVT OpVT, MVT DstVT) {

    unsigned OpEltSizeInBits = OpVT.getScalarSizeInBits();

    // AVX512 broadcasts 32/64-bit operands.

    // TODO: Support float once getAVX512Node is used by fp-ops.

    if (!OpVT.isInteger() || OpEltSizeInBits < 32 ||

        !DAG.getTargetLoweringInfo().isTypeLegal(SVT))

      return SDValue();

    // If we're not widening, don't bother if we're not bitcasting.

    if (OpVT == DstVT && Op.getOpcode() != ISD::BITCAST)

      return SDValue();

    if (auto *BV = dyn_cast<BuildVectorSDNode>(peekThroughBitcasts(Op))) {

      APInt SplatValue, SplatUndef;

      unsigned SplatBitSize;

      bool HasAnyUndefs;

      if (BV->isConstantSplat(SplatValue, SplatUndef, SplatBitSize,

                              HasAnyUndefs, OpEltSizeInBits) &&

          !HasAnyUndefs && SplatValue.getBitWidth() == OpEltSizeInBits)

        return DAG.getConstant(SplatValue, DL, DstVT);

    }

    return SDValue();

  };


  bool Widen = !(Subtarget.hasVLX() || VT.is512BitVector());


  MVT DstVT = VT;

  if (Widen)

    DstVT = MVT::getVectorVT(SVT, 512 / SVT.getSizeInBits());


  // Canonicalize src operands.

  SmallVector<SDValue> SrcOps(Ops);

  for (SDValue &Op : SrcOps) {

    MVT OpVT = Op.getSimpleValueType();

    // Just pass through scalar operands.

    if (!OpVT.isVector())

      continue;

    assert(OpVT == VT && "Vector type mismatch");


    if (SDValue BroadcastOp = MakeBroadcastOp(Op, OpVT, DstVT)) {

      Op = BroadcastOp;

      continue;

    }


    // Just widen the subvector by inserting into an undef wide vector.

    if (Widen)

      Op = widenSubVector(Op, false, Subtarget, DAG, DL, 512);

  }


  SDValue Res = DAG.getNode(Opcode, DL, DstVT, SrcOps);


  // Perform the 512-bit op then extract the bottom subvector.

  if (Widen)

    Res = extractSubVector(Res, 0, DAG, DL, VT.getSizeInBits());

  return Res;

}


/// Insert i1-subvector to i1-vector.


static SDValue insert1BitVector(SDValue Op, SelectionDAG &DAG,

                                const X86Subtarget &Subtarget) {


  SDLoc dl(Op);

  SDValue Vec = Op.getOperand(0);

  SDValue SubVec = Op.getOperand(1);

  SDValue Idx = Op.getOperand(2);

  unsigned IdxVal = Op.getConstantOperandVal(2);


  // Inserting undef is a nop. We can just return the original vector.

  if (SubVec.isUndef())

    return Vec;


  if (IdxVal == 0 && Vec.isUndef()) // the operation is legal

    return Op;


  MVT OpVT = Op.getSimpleValueType();

  unsigned NumElems = OpVT.getVectorNumElements();

  SDValue ZeroIdx = DAG.getVectorIdxConstant(0, dl);


  // Extend to natively supported kshift.

  MVT WideOpVT = widenMaskVectorType(OpVT, Subtarget);


  // Inserting into the lsbs of a zero vector is legal. ISel will insert shifts

  // if necessary.

  if (IdxVal == 0 && ISD::isBuildVectorAllZeros(Vec.getNode())) {

    // May need to promote to a legal type.

    Op = DAG.getNode(ISD::INSERT_SUBVECTOR, dl, WideOpVT,

                     DAG.getConstant(0, dl, WideOpVT),

                     SubVec, Idx);

    return DAG.getNode(ISD::EXTRACT_SUBVECTOR, dl, OpVT, Op, ZeroIdx);

  }


  MVT SubVecVT = SubVec.getSimpleValueType();

  unsigned SubVecNumElems = SubVecVT.getVectorNumElements();

  assert(IdxVal + SubVecNumElems <= NumElems &&

         IdxVal % SubVecVT.getSizeInBits() == 0 &&

         "Unexpected index value in INSERT_SUBVECTOR");


  SDValue Undef = DAG.getUNDEF(WideOpVT);


  if (IdxVal == 0) {

    // Zero lower bits of the Vec

    SDValue ShiftBits = DAG.getTargetConstant(SubVecNumElems, dl, MVT::i8);

    Vec = DAG.getNode(ISD::INSERT_SUBVECTOR, dl, WideOpVT, Undef, Vec,

                      ZeroIdx);

    Vec = DAG.getNode(X86ISD::KSHIFTR, dl, WideOpVT, Vec, ShiftBits);

    Vec = DAG.getNode(X86ISD::KSHIFTL, dl, WideOpVT, Vec, ShiftBits);

    // Merge them together, SubVec should be zero extended.

    SubVec = DAG.getNode(ISD::INSERT_SUBVECTOR, dl, WideOpVT,

                         DAG.getConstant(0, dl, WideOpVT),

                         SubVec, ZeroIdx);

    Op = DAG.getNode(ISD::OR, dl, WideOpVT, Vec, SubVec);

    return DAG.getNode(ISD::EXTRACT_SUBVECTOR, dl, OpVT, Op, ZeroIdx);

  }


  SubVec = DAG.getNode(ISD::INSERT_SUBVECTOR, dl, WideOpVT,

                       Undef, SubVec, ZeroIdx);


  if (Vec.isUndef()) {

    assert(IdxVal != 0 && "Unexpected index");

    SubVec = DAG.getNode(X86ISD::KSHIFTL, dl, WideOpVT, SubVec,

                         DAG.getTargetConstant(IdxVal, dl, MVT::i8));

    return DAG.getNode(ISD::EXTRACT_SUBVECTOR, dl, OpVT, SubVec, ZeroIdx);

  }


  if (ISD::isBuildVectorAllZeros(Vec.getNode())) {

    assert(IdxVal != 0 && "Unexpected index");

    // If upper elements of Vec are known undef, then just shift into place.

    if (llvm::all_of(Vec->ops().slice(IdxVal + SubVecNumElems),

                     [](SDValue V) { return V.isUndef(); })) {

      SubVec = DAG.getNode(X86ISD::KSHIFTL, dl, WideOpVT, SubVec,

                           DAG.getTargetConstant(IdxVal, dl, MVT::i8));

    } else {

      NumElems = WideOpVT.getVectorNumElements();

      unsigned ShiftLeft = NumElems - SubVecNumElems;

      unsigned ShiftRight = NumElems - SubVecNumElems - IdxVal;

      SubVec = DAG.getNode(X86ISD::KSHIFTL, dl, WideOpVT, SubVec,

                           DAG.getTargetConstant(ShiftLeft, dl, MVT::i8));

      if (ShiftRight != 0)

        SubVec = DAG.getNode(X86ISD::KSHIFTR, dl, WideOpVT, SubVec,

                             DAG.getTargetConstant(ShiftRight, dl, MVT::i8));

    }

    return DAG.getNode(ISD::EXTRACT_SUBVECTOR, dl, OpVT, SubVec, ZeroIdx);

  }


  // Simple case when we put subvector in the upper part

  if (IdxVal + SubVecNumElems == NumElems) {

    SubVec = DAG.getNode(X86ISD::KSHIFTL, dl, WideOpVT, SubVec,

                         DAG.getTargetConstant(IdxVal, dl, MVT::i8));

    if (SubVecNumElems * 2 == NumElems) {

      // Special case, use legal zero extending insert_subvector. This allows

      // isel to optimize when bits are known zero.

      Vec = DAG.getNode(ISD::EXTRACT_SUBVECTOR, dl, SubVecVT, Vec, ZeroIdx);

      Vec = DAG.getNode(ISD::INSERT_SUBVECTOR, dl, WideOpVT,

                        DAG.getConstant(0, dl, WideOpVT),

                        Vec, ZeroIdx);

    } else {

      // Otherwise use explicit shifts to zero the bits.

      Vec = DAG.getNode(ISD::INSERT_SUBVECTOR, dl, WideOpVT,

                        Undef, Vec, ZeroIdx);

      NumElems = WideOpVT.getVectorNumElements();

      SDValue ShiftBits = DAG.getTargetConstant(NumElems - IdxVal, dl, MVT::i8);

      Vec = DAG.getNode(X86ISD::KSHIFTL, dl, WideOpVT, Vec, ShiftBits);

      Vec = DAG.getNode(X86ISD::KSHIFTR, dl, WideOpVT, Vec, ShiftBits);

    }

    Op = DAG.getNode(ISD::OR, dl, WideOpVT, Vec, SubVec);

    return DAG.getNode(ISD::EXTRACT_SUBVECTOR, dl, OpVT, Op, ZeroIdx);

  }


  // Inserting into the middle is more complicated.


  NumElems = WideOpVT.getVectorNumElements();


  // Widen the vector if needed.

  Vec = DAG.getNode(ISD::INSERT_SUBVECTOR, dl, WideOpVT, Undef, Vec, ZeroIdx);


  unsigned ShiftLeft = NumElems - SubVecNumElems;

  unsigned ShiftRight = NumElems - SubVecNumElems - IdxVal;


  // Do an optimization for the most frequently used types.

  if (WideOpVT != MVT::v64i1 || Subtarget.is64Bit()) {

    APInt Mask0 = APInt::getBitsSet(NumElems, IdxVal, IdxVal + SubVecNumElems);

    Mask0.flipAllBits();

    SDValue CMask0 = DAG.getConstant(Mask0, dl, MVT::getIntegerVT(NumElems));

    SDValue VMask0 = DAG.getNode(ISD::BITCAST, dl, WideOpVT, CMask0);

    Vec = DAG.getNode(ISD::AND, dl, WideOpVT, Vec, VMask0);

    SubVec = DAG.getNode(X86ISD::KSHIFTL, dl, WideOpVT, SubVec,

                         DAG.getTargetConstant(ShiftLeft, dl, MVT::i8));

    SubVec = DAG.getNode(X86ISD::KSHIFTR, dl, WideOpVT, SubVec,

                         DAG.getTargetConstant(ShiftRight, dl, MVT::i8));

    Op = DAG.getNode(ISD::OR, dl, WideOpVT, Vec, SubVec);


    // Reduce to original width if needed.

    return DAG.getNode(ISD::EXTRACT_SUBVECTOR, dl, OpVT, Op, ZeroIdx);

  }


  // Clear the upper bits of the subvector and move it to its insert position.

  SubVec = DAG.getNode(X86ISD::KSHIFTL, dl, WideOpVT, SubVec,

                       DAG.getTargetConstant(ShiftLeft, dl, MVT::i8));

  SubVec = DAG.getNode(X86ISD::KSHIFTR, dl, WideOpVT, SubVec,

                       DAG.getTargetConstant(ShiftRight, dl, MVT::i8));


  // Isolate the bits below the insertion point.

  unsigned LowShift = NumElems - IdxVal;

  SDValue Low = DAG.getNode(X86ISD::KSHIFTL, dl, WideOpVT, Vec,

                            DAG.getTargetConstant(LowShift, dl, MVT::i8));

  Low = DAG.getNode(X86ISD::KSHIFTR, dl, WideOpVT, Low,

                    DAG.getTargetConstant(LowShift, dl, MVT::i8));


  // Isolate the bits after the last inserted bit.

  unsigned HighShift = IdxVal + SubVecNumElems;

  SDValue High = DAG.getNode(X86ISD::KSHIFTR, dl, WideOpVT, Vec,

                            DAG.getTargetConstant(HighShift, dl, MVT::i8));

  High = DAG.getNode(X86ISD::KSHIFTL, dl, WideOpVT, High,

                    DAG.getTargetConstant(HighShift, dl, MVT::i8));


  // Now OR all 3 pieces together.

  Vec = DAG.getNode(ISD::OR, dl, WideOpVT, Low, High);

  SubVec = DAG.getNode(ISD::OR, dl, WideOpVT, SubVec, Vec);


  // Reduce to original width if needed.

  return DAG.getNode(ISD::EXTRACT_SUBVECTOR, dl, OpVT, SubVec, ZeroIdx);

}


static SDValue concatSubVectors(SDValue V1, SDValue V2, SelectionDAG &DAG,

                                const SDLoc &dl) {

  assert(V1.getValueType() == V2.getValueType() && "subvector type mismatch");

  EVT SubVT = V1.getValueType();

  EVT SubSVT = SubVT.getScalarType();

  unsigned SubNumElts = SubVT.getVectorNumElements();

  unsigned SubVectorWidth = SubVT.getSizeInBits();

  EVT VT = EVT::getVectorVT(*DAG.getContext(), SubSVT, 2 * SubNumElts);

  SDValue V = insertSubVector(DAG.getUNDEF(VT), V1, 0, DAG, dl, SubVectorWidth);

  return insertSubVector(V, V2, SubNumElts, DAG, dl, SubVectorWidth);

}


/// Returns a vector of specified type with all bits set.

/// Always build ones vectors as <4 x i32>, <8 x i32> or <16 x i32>.

/// Then bitcast to their original type, ensuring they get CSE'd.


static SDValue getOnesVector(EVT VT, SelectionDAG &DAG, const SDLoc &dl) {

  assert((VT.is128BitVector() || VT.is256BitVector() || VT.is512BitVector()) &&

         "Expected a 128/256/512-bit vector type");

  unsigned NumElts = VT.getSizeInBits() / 32;

  SDValue Vec = DAG.getAllOnesConstant(dl, MVT::getVectorVT(MVT::i32, NumElts));

  return DAG.getBitcast(VT, Vec);

}


// Helper to get immediate/variable SSE shift opcode from other shift opcodes.


static unsigned getTargetVShiftUniformOpcode(unsigned Opc, bool IsVariable) {

  switch (Opc) {

  case ISD::SHL:

  case X86ISD::VSHL:

  case X86ISD::VSHLI:

    return IsVariable ? X86ISD::VSHL : X86ISD::VSHLI;

  case ISD::SRL:

  case X86ISD::VSRL:

  case X86ISD::VSRLI:

    return IsVariable ? X86ISD::VSRL : X86ISD::VSRLI;

  case ISD::SRA:

  case X86ISD::VSRA:

  case X86ISD::VSRAI:

    return IsVariable ? X86ISD::VSRA : X86ISD::VSRAI;

  }

  llvm_unreachable("Unknown target vector shift node");

}


/// Handle vector element shifts where the shift amount is a constant.

/// Takes immediate version of shift as input.


static SDValue getTargetVShiftByConstNode(unsigned Opc, const SDLoc &dl, MVT VT,

                                          SDValue SrcOp, uint64_t ShiftAmt,

                                          SelectionDAG &DAG) {

  MVT ElementType = VT.getVectorElementType();


  // Bitcast the source vector to the output type, this is mainly necessary for

  // vXi8/vXi64 shifts.

  if (VT != SrcOp.getSimpleValueType())

    SrcOp = DAG.getBitcast(VT, SrcOp);


  // Fold this packed shift into its first operand if ShiftAmt is 0.

  if (ShiftAmt == 0)

    return SrcOp;


  // Check for ShiftAmt >= element width

  if (ShiftAmt >= ElementType.getSizeInBits()) {

    if (Opc == X86ISD::VSRAI)

      ShiftAmt = ElementType.getSizeInBits() - 1;

    else

      return DAG.getConstant(0, dl, VT);

  }


  assert(

      (Opc == X86ISD::VSHLI || Opc == X86ISD::VSRLI || Opc == X86ISD::VSRAI) &&

      "Unknown target vector shift-by-constant node");


  // Fold this packed vector shift into a build vector if SrcOp is a

  // vector of Constants or UNDEFs.

  if (ISD::isBuildVectorOfConstantSDNodes(SrcOp.getNode())) {

    unsigned ShiftOpc;

    switch (Opc) {

    default:

      llvm_unreachable("Unknown opcode!");

    case X86ISD::VSHLI:

      ShiftOpc = ISD::SHL;

      break;

    case X86ISD::VSRLI:

      ShiftOpc = ISD::SRL;

      break;

    case X86ISD::VSRAI:

      ShiftOpc = ISD::SRA;

      break;

    }


    SDValue Amt = DAG.getConstant(ShiftAmt, dl, VT);

    if (SDValue C = DAG.FoldConstantArithmetic(ShiftOpc, dl, VT, {SrcOp, Amt}))

      return C;

  }


  return DAG.getNode(Opc, dl, VT, SrcOp,

                     DAG.getTargetConstant(ShiftAmt, dl, MVT::i8));

}


/// Handle vector element shifts by a splat shift amount


static SDValue getTargetVShiftNode(unsigned Opc, const SDLoc &dl, MVT VT,

                                   SDValue SrcOp, SDValue ShAmt, int ShAmtIdx,

                                   const X86Subtarget &Subtarget,

                                   SelectionDAG &DAG) {

  MVT AmtVT = ShAmt.getSimpleValueType();

  assert(AmtVT.isVector() && "Vector shift type mismatch");

  assert(0 <= ShAmtIdx && ShAmtIdx < (int)AmtVT.getVectorNumElements() &&

         "Illegal vector splat index");


  // Move the splat element to the bottom element.

  if (ShAmtIdx != 0) {

    SmallVector<int> Mask(AmtVT.getVectorNumElements(), -1);

    Mask[0] = ShAmtIdx;

    ShAmt = DAG.getVectorShuffle(AmtVT, dl, ShAmt, DAG.getUNDEF(AmtVT), Mask);

  }


  // Peek through any zext node if we can get back to a 128-bit source.

  if (AmtVT.getScalarSizeInBits() == 64 &&

      (ShAmt.getOpcode() == ISD::ZERO_EXTEND ||

       ShAmt.getOpcode() == ISD::ZERO_EXTEND_VECTOR_INREG) &&

      ShAmt.getOperand(0).getValueType().isSimple() &&

      ShAmt.getOperand(0).getValueType().is128BitVector()) {

    ShAmt = ShAmt.getOperand(0);

    AmtVT = ShAmt.getSimpleValueType();

  }


  // See if we can mask off the upper elements using the existing source node.

  // The shift uses the entire lower 64-bits of the amount vector, so no need to

  // do this for vXi64 types.

  bool IsMasked = false;

  if (AmtVT.getScalarSizeInBits() < 64) {

    if (ShAmt.getOpcode() == ISD::BUILD_VECTOR ||

        ShAmt.getOpcode() == ISD::SCALAR_TO_VECTOR) {

      // If the shift amount has come from a scalar, then zero-extend the scalar

      // before moving to the vector.

      ShAmt = DAG.getZExtOrTrunc(ShAmt.getOperand(0), dl, MVT::i32);

      ShAmt = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, MVT::v4i32, ShAmt);

      ShAmt = DAG.getNode(X86ISD::VZEXT_MOVL, dl, MVT::v4i32, ShAmt);

      AmtVT = MVT::v4i32;

      IsMasked = true;

    } else if (ShAmt.getOpcode() == ISD::AND) {

      // See if the shift amount is already masked (e.g. for rotation modulo),

      // then we can zero-extend it by setting all the other mask elements to

      // zero.

      SmallVector<SDValue> MaskElts(

          AmtVT.getVectorNumElements(),

          DAG.getConstant(0, dl, AmtVT.getScalarType()));

      MaskElts[0] = DAG.getAllOnesConstant(dl, AmtVT.getScalarType());

      SDValue Mask = DAG.getBuildVector(AmtVT, dl, MaskElts);

      if ((Mask = DAG.FoldConstantArithmetic(ISD::AND, dl, AmtVT,

                                             {ShAmt.getOperand(1), Mask}))) {

        ShAmt = DAG.getNode(ISD::AND, dl, AmtVT, ShAmt.getOperand(0), Mask);

        IsMasked = true;

      }

    }

  }


  // Extract if the shift amount vector is larger than 128-bits.

  if (AmtVT.getSizeInBits() > 128) {

    ShAmt = extract128BitVector(ShAmt, 0, DAG, dl);

    AmtVT = ShAmt.getSimpleValueType();

  }


  // Zero-extend bottom element to v2i64 vector type, either by extension or

  // shuffle masking.

  if (!IsMasked && AmtVT.getScalarSizeInBits() < 64) {

    if (AmtVT == MVT::v4i32 && (ShAmt.getOpcode() == X86ISD::VBROADCAST ||

                                ShAmt.getOpcode() == X86ISD::VBROADCAST_LOAD)) {

      ShAmt = DAG.getNode(X86ISD::VZEXT_MOVL, SDLoc(ShAmt), MVT::v4i32, ShAmt);

    } else if (Subtarget.hasSSE41()) {

      ShAmt = DAG.getNode(ISD::ZERO_EXTEND_VECTOR_INREG, SDLoc(ShAmt),

                          MVT::v2i64, ShAmt);

    } else {

      SDValue ByteShift = DAG.getTargetConstant(

          (128 - AmtVT.getScalarSizeInBits()) / 8, SDLoc(ShAmt), MVT::i8);

      ShAmt = DAG.getBitcast(MVT::v16i8, ShAmt);

      ShAmt = DAG.getNode(X86ISD::VSHLDQ, SDLoc(ShAmt), MVT::v16i8, ShAmt,

                          ByteShift);

      ShAmt = DAG.getNode(X86ISD::VSRLDQ, SDLoc(ShAmt), MVT::v16i8, ShAmt,

                          ByteShift);

    }

  }


  // Change opcode to non-immediate version.

  Opc = getTargetVShiftUniformOpcode(Opc, true);


  // The return type has to be a 128-bit type with the same element

  // type as the input type.

  MVT EltVT = VT.getVectorElementType();

  MVT ShVT = MVT::getVectorVT(EltVT, 128 / EltVT.getSizeInBits());


  ShAmt = DAG.getBitcast(ShVT, ShAmt);

  return DAG.getNode(Opc, dl, VT, SrcOp, ShAmt);

}


static SDValue getEXTEND_VECTOR_INREG(unsigned Opcode, const SDLoc &DL, EVT VT,

                                      SDValue In, SelectionDAG &DAG) {

  EVT InVT = In.getValueType();

  assert(VT.isVector() && InVT.isVector() && "Expected vector VTs.");


  // Canonicalize Opcode to general extension version.

  switch (Opcode) {

  case ISD::ANY_EXTEND:

  case ISD::ANY_EXTEND_VECTOR_INREG:

    Opcode = ISD::ANY_EXTEND;

    break;

  case ISD::SIGN_EXTEND:

  case ISD::SIGN_EXTEND_VECTOR_INREG:

    Opcode = ISD::SIGN_EXTEND;

    break;

  case ISD::ZERO_EXTEND:

  case ISD::ZERO_EXTEND_VECTOR_INREG:

    Opcode = ISD::ZERO_EXTEND;

    break;

  default:

    llvm_unreachable("Unknown extension opcode");

  }


  // For 256-bit vectors, we only need the lower (128-bit) input half.

  // For 512-bit vectors, we only need the lower input half or quarter.

  if (InVT.getSizeInBits() > 128) {

    assert(VT.getSizeInBits() == InVT.getSizeInBits() &&

           "Expected VTs to be the same size!");

    unsigned Scale = VT.getScalarSizeInBits() / InVT.getScalarSizeInBits();

    In = extractSubVector(In, 0, DAG, DL,

                          std::max(128U, (unsigned)VT.getSizeInBits() / Scale));

    InVT = In.getValueType();

  }


  if (VT.getVectorNumElements() != InVT.getVectorNumElements())

    Opcode = DAG.getOpcode_EXTEND_VECTOR_INREG(Opcode);


  return DAG.getNode(Opcode, DL, VT, In);

}


// Create OR(AND(LHS,MASK),AND(RHS,~MASK)) bit select pattern


static SDValue getBitSelect(const SDLoc &DL, MVT VT, SDValue LHS, SDValue RHS,

                            SDValue Mask, SelectionDAG &DAG) {

  LHS = DAG.getNode(ISD::AND, DL, VT, LHS, Mask);

  RHS = DAG.getNode(X86ISD::ANDNP, DL, VT, Mask, RHS);

  return DAG.getNode(ISD::OR, DL, VT, LHS, RHS);

}


void llvm::createUnpackShuffleMask(EVT VT, SmallVectorImpl<int> &Mask,

                                   bool Lo, bool Unary) {

  assert(VT.getScalarType().isSimple() && (VT.getSizeInBits() % 128) == 0 &&

         "Illegal vector type to unpack");

  assert(Mask.empty() && "Expected an empty shuffle mask vector");

  int NumElts = VT.getVectorNumElements();

  int NumEltsInLane = 128 / VT.getScalarSizeInBits();

  for (int i = 0; i < NumElts; ++i) {

    unsigned LaneStart = (i / NumEltsInLane) * NumEltsInLane;

    int Pos = (i % NumEltsInLane) / 2 + LaneStart;

    Pos += (Unary ? 0 : NumElts * (i % 2));

    Pos += (Lo ? 0 : NumEltsInLane / 2);

    Mask.push_back(Pos);

  }

}


/// Similar to unpacklo/unpackhi, but without the 128-bit lane limitation

/// imposed by AVX and specific to the unary pattern. Example:

/// v8iX Lo --> <0, 0, 1, 1, 2, 2, 3, 3>

/// v8iX Hi --> <4, 4, 5, 5, 6, 6, 7, 7>


void llvm::createSplat2ShuffleMask(MVT VT, SmallVectorImpl<int> &Mask,

                                   bool Lo) {

  assert(Mask.empty() && "Expected an empty shuffle mask vector");

  int NumElts = VT.getVectorNumElements();

  for (int i = 0; i < NumElts; ++i) {

    int Pos = i / 2;

    Pos += (Lo ? 0 : NumElts / 2);

    Mask.push_back(Pos);

  }

}


// Attempt to constant fold, else just create a VECTOR_SHUFFLE.


static SDValue getVectorShuffle(SelectionDAG &DAG, EVT VT, const SDLoc &dl,

                                SDValue V1, SDValue V2, ArrayRef<int> Mask) {

  if ((ISD::isBuildVectorOfConstantSDNodes(V1.getNode()) || V1.isUndef()) &&

      (ISD::isBuildVectorOfConstantSDNodes(V2.getNode()) || V2.isUndef())) {

    SmallVector<SDValue> Ops(Mask.size(), DAG.getUNDEF(VT.getScalarType()));

    for (int I = 0, NumElts = Mask.size(); I != NumElts; ++I) {

      int M = Mask[I];

      if (M < 0)

        continue;

      SDValue V = (M < NumElts) ? V1 : V2;

      if (V.isUndef())

        continue;

      Ops[I] = V.getOperand(M % NumElts);

    }

    return DAG.getBuildVector(VT, dl, Ops);

  }


  return DAG.getVectorShuffle(VT, dl, V1, V2, Mask);

}


/// Returns a vector_shuffle node for an unpackl operation.


static SDValue getUnpackl(SelectionDAG &DAG, const SDLoc &dl, EVT VT,

                          SDValue V1, SDValue V2) {

  SmallVector<int, 8> Mask;

  createUnpackShuffleMask(VT, Mask, /* Lo = */ true, /* Unary = */ false);

  return getVectorShuffle(DAG, VT, dl, V1, V2, Mask);

}


/// Returns a vector_shuffle node for an unpackh operation.


static SDValue getUnpackh(SelectionDAG &DAG, const SDLoc &dl, EVT VT,

                          SDValue V1, SDValue V2) {

  SmallVector<int, 8> Mask;

  createUnpackShuffleMask(VT, Mask, /* Lo = */ false, /* Unary = */ false);

  return getVectorShuffle(DAG, VT, dl, V1, V2, Mask);

}


/// Returns a node that packs the LHS + RHS nodes together at half width.

/// May return X86ISD::PACKSS/PACKUS, packing the top/bottom half.

/// TODO: Add subvector splitting if/when we have a need for it.


static SDValue getPack(SelectionDAG &DAG, const X86Subtarget &Subtarget,

                       const SDLoc &dl, MVT VT, SDValue LHS, SDValue RHS,

                       bool PackHiHalf = false) {

  MVT OpVT = LHS.getSimpleValueType();

  unsigned EltSizeInBits = VT.getScalarSizeInBits();

  bool UsePackUS = Subtarget.hasSSE41() || EltSizeInBits == 8;

  assert(OpVT == RHS.getSimpleValueType() &&

         VT.getSizeInBits() == OpVT.getSizeInBits() &&

         (EltSizeInBits * 2) == OpVT.getScalarSizeInBits() &&

         "Unexpected PACK operand types");

  assert((EltSizeInBits == 8 || EltSizeInBits == 16 || EltSizeInBits == 32) &&

         "Unexpected PACK result type");


  // Rely on vector shuffles for vXi64 -> vXi32 packing.

  if (EltSizeInBits == 32) {

    SmallVector<int> PackMask;

    int Offset = PackHiHalf ? 1 : 0;

    int NumElts = VT.getVectorNumElements();

    for (int I = 0; I != NumElts; I += 4) {

      PackMask.push_back(I + Offset);

      PackMask.push_back(I + Offset + 2);

      PackMask.push_back(I + Offset + NumElts);

      PackMask.push_back(I + Offset + NumElts + 2);

    }

    return DAG.getVectorShuffle(VT, dl, DAG.getBitcast(VT, LHS),

                                DAG.getBitcast(VT, RHS), PackMask);

  }


  // See if we already have sufficient leading bits for PACKSS/PACKUS.

  if (!PackHiHalf) {

    if (UsePackUS &&

        DAG.computeKnownBits(LHS).countMaxActiveBits() <= EltSizeInBits &&

        DAG.computeKnownBits(RHS).countMaxActiveBits() <= EltSizeInBits)

      return DAG.getNode(X86ISD::PACKUS, dl, VT, LHS, RHS);


    if (DAG.ComputeMaxSignificantBits(LHS) <= EltSizeInBits &&

        DAG.ComputeMaxSignificantBits(RHS) <= EltSizeInBits)

      return DAG.getNode(X86ISD::PACKSS, dl, VT, LHS, RHS);

  }


  // Fallback to sign/zero extending the requested half and pack.

  SDValue Amt = DAG.getTargetConstant(EltSizeInBits, dl, MVT::i8);

  if (UsePackUS) {

    if (PackHiHalf) {

      LHS = DAG.getNode(X86ISD::VSRLI, dl, OpVT, LHS, Amt);

      RHS = DAG.getNode(X86ISD::VSRLI, dl, OpVT, RHS, Amt);

    } else {

      SDValue Mask = DAG.getConstant((1ULL << EltSizeInBits) - 1, dl, OpVT);

      LHS = DAG.getNode(ISD::AND, dl, OpVT, LHS, Mask);

      RHS = DAG.getNode(ISD::AND, dl, OpVT, RHS, Mask);

    };

    return DAG.getNode(X86ISD::PACKUS, dl, VT, LHS, RHS);

  };


  if (!PackHiHalf) {

    LHS = DAG.getNode(X86ISD::VSHLI, dl, OpVT, LHS, Amt);

    RHS = DAG.getNode(X86ISD::VSHLI, dl, OpVT, RHS, Amt);

  }

  LHS = DAG.getNode(X86ISD::VSRAI, dl, OpVT, LHS, Amt);

  RHS = DAG.getNode(X86ISD::VSRAI, dl, OpVT, RHS, Amt);

  return DAG.getNode(X86ISD::PACKSS, dl, VT, LHS, RHS);

}


/// Return a vector_shuffle of the specified vector of zero or undef vector.

/// This produces a shuffle where the low element of V2 is swizzled into the

/// zero/undef vector, landing at element Idx.

/// This produces a shuffle mask like 4,1,2,3 (idx=0) or  0,1,2,4 (idx=3).


static SDValue getShuffleVectorZeroOrUndef(SDValue V2, int Idx,

                                           bool IsZero,

                                           const X86Subtarget &Subtarget,

                                           SelectionDAG &DAG) {

  MVT VT = V2.getSimpleValueType();

  SDValue V1 = IsZero

    ? getZeroVector(VT, Subtarget, DAG, SDLoc(V2)) : DAG.getUNDEF(VT);

  int NumElems = VT.getVectorNumElements();

  SmallVector<int, 16> MaskVec(NumElems);

  for (int i = 0; i != NumElems; ++i)

    // If this is the insertion idx, put the low elt of V2 here.

    MaskVec[i] = (i == Idx) ? NumElems : i;

  return DAG.getVectorShuffle(VT, SDLoc(V2), V1, V2, MaskVec);

}


static ConstantPoolSDNode *getTargetConstantPoolFromBasePtr(SDValue Ptr) {

  if (Ptr.getOpcode() == X86ISD::Wrapper ||

      Ptr.getOpcode() == X86ISD::WrapperRIP)

    Ptr = Ptr.getOperand(0);

  return dyn_cast<ConstantPoolSDNode>(Ptr);

}


// TODO: Add support for non-zero offsets.


static const Constant *getTargetConstantFromBasePtr(SDValue Ptr) {

  ConstantPoolSDNode *CNode = getTargetConstantPoolFromBasePtr(Ptr);

  if (!CNode || CNode->isMachineConstantPoolEntry() || CNode->getOffset() != 0)

    return nullptr;

  return CNode->getConstVal();

}


static const Constant *getTargetConstantFromNode(LoadSDNode *Load) {

  if (!Load || !ISD::isNormalLoad(Load))

    return nullptr;

  return getTargetConstantFromBasePtr(Load->getBasePtr());

}


static const Constant *getTargetConstantFromNode(SDValue Op) {

  Op = peekThroughBitcasts(Op);

  return getTargetConstantFromNode(dyn_cast<LoadSDNode>(Op));

}


const Constant *


X86TargetLowering::getTargetConstantFromLoad(LoadSDNode *LD) const {

  assert(LD && "Unexpected null LoadSDNode");

  return getTargetConstantFromNode(LD);

}


bool X86TargetLowering::isTargetCanonicalSelect(SDNode *N) const {

  // Do not fold (vselect not(C), X, 0s) to (vselect C, Os, X)

  SDValue Cond = N->getOperand(0);

  SDValue RHS = N->getOperand(2);

  EVT CondVT = Cond.getValueType();

  return N->getOpcode() == ISD::VSELECT && Subtarget.hasAVX512() &&

         CondVT.getVectorElementType() == MVT::i1 &&

         ISD::isBuildVectorAllZeros(RHS.getNode());

}


// Extract raw constant bits from constant pools.


static bool getTargetConstantBitsFromNode(SDValue Op, unsigned EltSizeInBits,

                                          APInt &UndefElts,

                                          SmallVectorImpl<APInt> &EltBits,

                                          bool AllowWholeUndefs = true,

                                          bool AllowPartialUndefs = false) {

  assert(EltBits.empty() && "Expected an empty EltBits vector");


  Op = peekThroughBitcasts(Op);


  EVT VT = Op.getValueType();

  unsigned SizeInBits = VT.getSizeInBits();

  unsigned NumElts = SizeInBits / EltSizeInBits;


  // Can't split constant.

  if ((SizeInBits % EltSizeInBits) != 0)

    return false;


  // Bitcast a source array of element bits to the target size.

  auto CastBitData = [&](APInt &UndefSrcElts, ArrayRef<APInt> SrcEltBits) {

    unsigned NumSrcElts = UndefSrcElts.getBitWidth();

    unsigned SrcEltSizeInBits = SrcEltBits[0].getBitWidth();

    assert((NumSrcElts * SrcEltSizeInBits) == SizeInBits &&

           "Constant bit sizes don't match");


    // Don't split if we don't allow undef bits.

    bool AllowUndefs = AllowWholeUndefs || AllowPartialUndefs;

    if (UndefSrcElts.getBoolValue() && !AllowUndefs)

      return false;


    // If we're already the right size, don't bother bitcasting.

    if (NumSrcElts == NumElts) {

      UndefElts = UndefSrcElts;

      EltBits.assign(SrcEltBits.begin(), SrcEltBits.end());

      return true;

    }


    // Extract all the undef/constant element data and pack into single bitsets.

    APInt UndefBits(SizeInBits, 0);

    APInt MaskBits(SizeInBits, 0);


    for (unsigned i = 0; i != NumSrcElts; ++i) {

      unsigned BitOffset = i * SrcEltSizeInBits;

      if (UndefSrcElts[i])

        UndefBits.setBits(BitOffset, BitOffset + SrcEltSizeInBits);

      MaskBits.insertBits(SrcEltBits[i], BitOffset);

    }


    // Split the undef/constant single bitset data into the target elements.

    UndefElts = APInt(NumElts, 0);

    EltBits.resize(NumElts, APInt(EltSizeInBits, 0));


    for (unsigned i = 0; i != NumElts; ++i) {

      unsigned BitOffset = i * EltSizeInBits;

      APInt UndefEltBits = UndefBits.extractBits(EltSizeInBits, BitOffset);


      // Only treat an element as UNDEF if all bits are UNDEF.

      if (UndefEltBits.isAllOnes()) {

        if (!AllowWholeUndefs)

          return false;

        UndefElts.setBit(i);

        continue;

      }


      // If only some bits are UNDEF then treat them as zero (or bail if not

      // supported).

      if (UndefEltBits.getBoolValue() && !AllowPartialUndefs)

        return false;


      EltBits[i] = MaskBits.extractBits(EltSizeInBits, BitOffset);

    }

    return true;

  };


  // Collect constant bits and insert into mask/undef bit masks.

  auto CollectConstantBits = [](const Constant *Cst, APInt &Mask, APInt &Undefs,

                                unsigned UndefBitIndex) {

    if (!Cst)

      return false;

    if (isa<UndefValue>(Cst)) {

      Undefs.setBit(UndefBitIndex);

      return true;

    }

    if (auto *CInt = dyn_cast<ConstantInt>(Cst)) {

      Mask = CInt->getValue();

      return true;

    }

    if (auto *CFP = dyn_cast<ConstantFP>(Cst)) {

      Mask = CFP->getValueAPF().bitcastToAPInt();

      return true;

    }

    if (auto *CDS = dyn_cast<ConstantDataSequential>(Cst)) {

      Type *Ty = CDS->getType();

      Mask = APInt::getZero(Ty->getPrimitiveSizeInBits());

      Type *EltTy = CDS->getElementType();

      bool IsInteger = EltTy->isIntegerTy();

      bool IsFP =

          EltTy->isHalfTy() || EltTy->isFloatTy() || EltTy->isDoubleTy();

      if (!IsInteger && !IsFP)

        return false;

      unsigned EltBits = EltTy->getPrimitiveSizeInBits();

      for (unsigned I = 0, E = CDS->getNumElements(); I != E; ++I)

        if (IsInteger)

          Mask.insertBits(CDS->getElementAsAPInt(I), I * EltBits);

        else

          Mask.insertBits(CDS->getElementAsAPFloat(I).bitcastToAPInt(),

                          I * EltBits);

      return true;

    }

    return false;

  };


  // Handle UNDEFs.

  if (Op.isUndef()) {

    APInt UndefSrcElts = APInt::getAllOnes(NumElts);

    SmallVector<APInt, 64> SrcEltBits(NumElts, APInt(EltSizeInBits, 0));

    return CastBitData(UndefSrcElts, SrcEltBits);

  }


  // Extract scalar constant bits.

  if (auto *Cst = dyn_cast<ConstantSDNode>(Op)) {

    APInt UndefSrcElts = APInt::getZero(1);

    SmallVector<APInt, 64> SrcEltBits(1, Cst->getAPIntValue());

    return CastBitData(UndefSrcElts, SrcEltBits);

  }

  if (auto *Cst = dyn_cast<ConstantFPSDNode>(Op)) {

    APInt UndefSrcElts = APInt::getZero(1);

    APInt RawBits = Cst->getValueAPF().bitcastToAPInt();

    SmallVector<APInt, 64> SrcEltBits(1, RawBits);

    return CastBitData(UndefSrcElts, SrcEltBits);

  }


  // Extract constant bits from build vector.

  if (auto *BV = dyn_cast<BuildVectorSDNode>(Op)) {

    BitVector Undefs;

    SmallVector<APInt> SrcEltBits;

    unsigned SrcEltSizeInBits = VT.getScalarSizeInBits();

    if (BV->getConstantRawBits(true, SrcEltSizeInBits, SrcEltBits, Undefs)) {

      APInt UndefSrcElts = APInt::getZero(SrcEltBits.size());

      for (unsigned I = 0, E = SrcEltBits.size(); I != E; ++I)

        if (Undefs[I])

          UndefSrcElts.setBit(I);

      return CastBitData(UndefSrcElts, SrcEltBits);

    }

  }


  // Extract constant bits from constant pool vector.

  if (auto *Cst = getTargetConstantFromNode(Op)) {

    Type *CstTy = Cst->getType();

    unsigned CstSizeInBits = CstTy->getPrimitiveSizeInBits();

    if (!CstTy->isVectorTy() || (CstSizeInBits % SizeInBits) != 0)

      return false;


    unsigned SrcEltSizeInBits = CstTy->getScalarSizeInBits();

    unsigned NumSrcElts = SizeInBits / SrcEltSizeInBits;

    if ((SizeInBits % SrcEltSizeInBits) != 0)

      return false;


    APInt UndefSrcElts(NumSrcElts, 0);

    SmallVector<APInt, 64> SrcEltBits(NumSrcElts, APInt(SrcEltSizeInBits, 0));

    for (unsigned i = 0; i != NumSrcElts; ++i)

      if (!CollectConstantBits(Cst->getAggregateElement(i), SrcEltBits[i],

                               UndefSrcElts, i))

        return false;


    return CastBitData(UndefSrcElts, SrcEltBits);

  }


  // Extract constant bits from a broadcasted constant pool scalar.

  if (Op.getOpcode() == X86ISD::VBROADCAST_LOAD &&

      EltSizeInBits <= VT.getScalarSizeInBits()) {

    auto *MemIntr = cast<MemIntrinsicSDNode>(Op);

    if (MemIntr->getMemoryVT().getStoreSizeInBits() != VT.getScalarSizeInBits())

      return false;


    SDValue Ptr = MemIntr->getBasePtr();

    if (const Constant *C = getTargetConstantFromBasePtr(Ptr)) {

      unsigned SrcEltSizeInBits = VT.getScalarSizeInBits();

      unsigned NumSrcElts = SizeInBits / SrcEltSizeInBits;


      APInt UndefSrcElts(NumSrcElts, 0);

      SmallVector<APInt, 64> SrcEltBits(1, APInt(SrcEltSizeInBits, 0));

      if (CollectConstantBits(C, SrcEltBits[0], UndefSrcElts, 0)) {

        if (UndefSrcElts[0])

          UndefSrcElts.setBits(0, NumSrcElts);

        if (SrcEltBits[0].getBitWidth() != SrcEltSizeInBits)

          SrcEltBits[0] = SrcEltBits[0].trunc(SrcEltSizeInBits);

        SrcEltBits.append(NumSrcElts - 1, SrcEltBits[0]);

        return CastBitData(UndefSrcElts, SrcEltBits);

      }

    }

  }


  // Extract constant bits from a subvector broadcast.

  if (Op.getOpcode() == X86ISD::SUBV_BROADCAST_LOAD) {

    auto *MemIntr = cast<MemIntrinsicSDNode>(Op);

    SDValue Ptr = MemIntr->getBasePtr();

    // The source constant may be larger than the subvector broadcast,

    // ensure we extract the correct subvector constants.

    if (const Constant *Cst = getTargetConstantFromBasePtr(Ptr)) {

      Type *CstTy = Cst->getType();

      unsigned CstSizeInBits = CstTy->getPrimitiveSizeInBits();

      unsigned SubVecSizeInBits = MemIntr->getMemoryVT().getStoreSizeInBits();

      if (!CstTy->isVectorTy() || (CstSizeInBits % SubVecSizeInBits) != 0 ||

          (SizeInBits % SubVecSizeInBits) != 0)

        return false;

      unsigned CstEltSizeInBits = CstTy->getScalarSizeInBits();

      unsigned NumSubElts = SubVecSizeInBits / CstEltSizeInBits;

      unsigned NumSubVecs = SizeInBits / SubVecSizeInBits;

      APInt UndefSubElts(NumSubElts, 0);

      SmallVector<APInt, 64> SubEltBits(NumSubElts * NumSubVecs,

                                        APInt(CstEltSizeInBits, 0));

      for (unsigned i = 0; i != NumSubElts; ++i) {

        if (!CollectConstantBits(Cst->getAggregateElement(i), SubEltBits[i],

                                 UndefSubElts, i))

          return false;

        for (unsigned j = 1; j != NumSubVecs; ++j)

          SubEltBits[i + (j * NumSubElts)] = SubEltBits[i];

      }

      UndefSubElts = APInt::getSplat(NumSubVecs * UndefSubElts.getBitWidth(),

                                     UndefSubElts);

      return CastBitData(UndefSubElts, SubEltBits);

    }

  }


  // Extract a rematerialized scalar constant insertion.

  if (Op.getOpcode() == X86ISD::VZEXT_MOVL &&

      Op.getOperand(0).getOpcode() == ISD::SCALAR_TO_VECTOR &&

      isa<ConstantSDNode>(Op.getOperand(0).getOperand(0))) {

    unsigned SrcEltSizeInBits = VT.getScalarSizeInBits();

    unsigned NumSrcElts = SizeInBits / SrcEltSizeInBits;


    APInt UndefSrcElts(NumSrcElts, 0);

    SmallVector<APInt, 64> SrcEltBits;

    const APInt &C = Op.getOperand(0).getConstantOperandAPInt(0);

    SrcEltBits.push_back(C.zextOrTrunc(SrcEltSizeInBits));

    SrcEltBits.append(NumSrcElts - 1, APInt(SrcEltSizeInBits, 0));

    return CastBitData(UndefSrcElts, SrcEltBits);

  }


  // Insert constant bits from a base and sub vector sources.

  if (Op.getOpcode() == ISD::INSERT_SUBVECTOR) {

    // If bitcasts to larger elements we might lose track of undefs - don't

    // allow any to be safe.

    unsigned SrcEltSizeInBits = VT.getScalarSizeInBits();

    bool AllowUndefs = EltSizeInBits >= SrcEltSizeInBits;


    APInt UndefSrcElts, UndefSubElts;

    SmallVector<APInt, 32> EltSrcBits, EltSubBits;

    if (getTargetConstantBitsFromNode(Op.getOperand(1), SrcEltSizeInBits,

                                      UndefSubElts, EltSubBits,

                                      AllowWholeUndefs && AllowUndefs,

                                      AllowPartialUndefs && AllowUndefs) &&

        getTargetConstantBitsFromNode(Op.getOperand(0), SrcEltSizeInBits,

                                      UndefSrcElts, EltSrcBits,

                                      AllowWholeUndefs && AllowUndefs,

                                      AllowPartialUndefs && AllowUndefs)) {

      unsigned BaseIdx = Op.getConstantOperandVal(2);

      UndefSrcElts.insertBits(UndefSubElts, BaseIdx);

      for (unsigned i = 0, e = EltSubBits.size(); i != e; ++i)

        EltSrcBits[BaseIdx + i] = EltSubBits[i];

      return CastBitData(UndefSrcElts, EltSrcBits);

    }

  }


  // Extract constant bits from a subvector's source.

  if (Op.getOpcode() == ISD::EXTRACT_SUBVECTOR &&

      getTargetConstantBitsFromNode(Op.getOperand(0), EltSizeInBits, UndefElts,

                                    EltBits, AllowWholeUndefs,

                                    AllowPartialUndefs)) {

    EVT SrcVT = Op.getOperand(0).getValueType();

    unsigned NumSrcElts = SrcVT.getSizeInBits() / EltSizeInBits;

    unsigned NumSubElts = VT.getSizeInBits() / EltSizeInBits;

    unsigned BaseOfs = Op.getConstantOperandVal(1) * VT.getScalarSizeInBits();

    unsigned BaseIdx = BaseOfs / EltSizeInBits;

    assert((SrcVT.getSizeInBits() % EltSizeInBits) == 0 &&

           (VT.getSizeInBits() % EltSizeInBits) == 0 &&

           (BaseOfs % EltSizeInBits) == 0 && "Bad subvector index");


    UndefElts = UndefElts.extractBits(NumSubElts, BaseIdx);

    if ((BaseIdx + NumSubElts) != NumSrcElts)

      EltBits.erase(EltBits.begin() + BaseIdx + NumSubElts, EltBits.end());

    if (BaseIdx != 0)

      EltBits.erase(EltBits.begin(), EltBits.begin() + BaseIdx);

    return true;

  }


  // Extract constant bits from shuffle node sources.

  if (auto *SVN = dyn_cast<ShuffleVectorSDNode>(Op)) {

    // TODO - support shuffle through bitcasts.

    if (EltSizeInBits != VT.getScalarSizeInBits())

      return false;


    ArrayRef<int> Mask = SVN->getMask();

    if ((!AllowWholeUndefs || !AllowPartialUndefs) &&

        llvm::any_of(Mask, [](int M) { return M < 0; }))

      return false;


    APInt UndefElts0, UndefElts1;

    SmallVector<APInt, 32> EltBits0, EltBits1;

    if (isAnyInRange(Mask, 0, NumElts) &&

        !getTargetConstantBitsFromNode(Op.getOperand(0), EltSizeInBits,

                                       UndefElts0, EltBits0, AllowWholeUndefs,

                                       AllowPartialUndefs))

      return false;

    if (isAnyInRange(Mask, NumElts, 2 * NumElts) &&

        !getTargetConstantBitsFromNode(Op.getOperand(1), EltSizeInBits,

                                       UndefElts1, EltBits1, AllowWholeUndefs,

                                       AllowPartialUndefs))

      return false;


    UndefElts = APInt::getZero(NumElts);

    for (int i = 0; i != (int)NumElts; ++i) {

      int M = Mask[i];

      if (M < 0) {

        UndefElts.setBit(i);

        EltBits.push_back(APInt::getZero(EltSizeInBits));

      } else if (M < (int)NumElts) {

        if (UndefElts0[M])

          UndefElts.setBit(i);

        EltBits.push_back(EltBits0[M]);

      } else {

        if (UndefElts1[M - NumElts])

          UndefElts.setBit(i);

        EltBits.push_back(EltBits1[M - NumElts]);

      }

    }

    return true;

  }


  return false;

}


namespace llvm {

namespace X86 {


bool isConstantSplat(SDValue Op, APInt &SplatVal, bool AllowPartialUndefs) {

  APInt UndefElts;

  SmallVector<APInt, 16> EltBits;

  if (getTargetConstantBitsFromNode(

          Op, Op.getScalarValueSizeInBits(), UndefElts, EltBits,

          /*AllowWholeUndefs*/ true, AllowPartialUndefs)) {

    int SplatIndex = -1;

    for (int i = 0, e = EltBits.size(); i != e; ++i) {

      if (UndefElts[i])

        continue;

      if (0 <= SplatIndex && EltBits[i] != EltBits[SplatIndex]) {

        SplatIndex = -1;

        break;

      }

      SplatIndex = i;

    }

    if (0 <= SplatIndex) {

      SplatVal = EltBits[SplatIndex];

      return true;

    }

  }


  return false;

}


int getRoundingModeX86(unsigned RM) {

  switch (static_cast<::llvm::RoundingMode>(RM)) {

    // clang-format off

  case ::llvm::RoundingMode::NearestTiesToEven: return X86::rmToNearest;

  case ::llvm::RoundingMode::TowardNegative:    return X86::rmDownward;

  case ::llvm::RoundingMode::TowardPositive:    return X86::rmUpward;

  case ::llvm::RoundingMode::TowardZero:        return X86::rmTowardZero;

  default:                                      return X86::rmInvalid;

    // clang-format on

  }

}


} // namespace X86

} // namespace llvm


static bool getTargetShuffleMaskIndices(SDValue MaskNode,

                                        unsigned MaskEltSizeInBits,

                                        SmallVectorImpl<uint64_t> &RawMask,

                                        APInt &UndefElts) {

  // Extract the raw target constant bits.

  SmallVector<APInt, 64> EltBits;

  if (!getTargetConstantBitsFromNode(MaskNode, MaskEltSizeInBits, UndefElts,

                                     EltBits, /* AllowWholeUndefs */ true,

                                     /* AllowPartialUndefs */ false))

    return false;


  // Insert the extracted elements into the mask.

  for (const APInt &Elt : EltBits)

    RawMask.push_back(Elt.getZExtValue());


  return true;

}


static bool isConstantPowerOf2(SDValue V, unsigned EltSizeInBIts,

                               bool AllowUndefs) {

  APInt UndefElts;

  SmallVector<APInt, 64> EltBits;

  if (!getTargetConstantBitsFromNode(V, EltSizeInBIts, UndefElts, EltBits,

                                     /*AllowWholeUndefs*/ AllowUndefs,

                                     /*AllowPartialUndefs*/ false))

    return false;


  bool IsPow2OrUndef = true;

  for (unsigned I = 0, E = EltBits.size(); I != E; ++I)

    IsPow2OrUndef &= UndefElts[I] || EltBits[I].isPowerOf2();

  return IsPow2OrUndef;

}


// Helper to attempt to return a cheaper, bit-inverted version of \p V.


static SDValue IsNOT(SDValue V, SelectionDAG &DAG) {

  // TODO: don't always ignore oneuse constraints.

  V = peekThroughBitcasts(V);

  EVT VT = V.getValueType();


  // Match not(xor X, -1) -> X.

  if (V.getOpcode() == ISD::XOR &&

      (ISD::isBuildVectorAllOnes(V.getOperand(1).getNode()) ||

       isAllOnesConstant(V.getOperand(1))))

    return V.getOperand(0);


  // Match not(extract_subvector(not(X)) -> extract_subvector(X).

  if (V.getOpcode() == ISD::EXTRACT_SUBVECTOR &&

      (isNullConstant(V.getOperand(1)) || V.getOperand(0).hasOneUse())) {

    if (SDValue Not = IsNOT(V.getOperand(0), DAG)) {

      Not = DAG.getBitcast(V.getOperand(0).getValueType(), Not);

      return DAG.getNode(ISD::EXTRACT_SUBVECTOR, SDLoc(Not), VT, Not,

                         V.getOperand(1));

    }

  }


  // Match not(pcmpgt(C, X)) -> pcmpgt(X, C - 1).

  if (V.getOpcode() == X86ISD::PCMPGT &&

      !ISD::isBuildVectorAllZeros(V.getOperand(0).getNode()) &&

      !ISD::isBuildVectorAllOnes(V.getOperand(0).getNode()) &&

      V.getOperand(0).hasOneUse()) {

    APInt UndefElts;

    SmallVector<APInt> EltBits;

    if (getTargetConstantBitsFromNode(V.getOperand(0),

                                      V.getScalarValueSizeInBits(), UndefElts,

                                      EltBits) &&

        !ISD::isBuildVectorOfConstantSDNodes(V.getOperand(1).getNode())) {

      // Don't fold min_signed_value -> (min_signed_value - 1)

      bool MinSigned = false;

      for (APInt &Elt : EltBits) {

        MinSigned |= Elt.isMinSignedValue();

        Elt -= 1;

      }

      if (!MinSigned) {

        SDLoc DL(V);

        MVT VT = V.getSimpleValueType();

        return DAG.getNode(X86ISD::PCMPGT, DL, VT, V.getOperand(1),

                           getConstVector(EltBits, UndefElts, VT, DAG, DL));

      }

    }

  }


  // Match not(concat_vectors(not(X), not(Y))) -> concat_vectors(X, Y).

  SmallVector<SDValue, 2> CatOps;

  if (collectConcatOps(V.getNode(), CatOps, DAG)) {

    for (SDValue &CatOp : CatOps) {

      SDValue NotCat = IsNOT(CatOp, DAG);

      if (!NotCat)

        return SDValue();

      CatOp = DAG.getBitcast(CatOp.getValueType(), NotCat);

    }

    return DAG.getNode(ISD::CONCAT_VECTORS, SDLoc(V), VT, CatOps);

  }


  // Match not(or(not(X),not(Y))) -> and(X, Y).

  if (V.getOpcode() == ISD::OR && DAG.getTargetLoweringInfo().isTypeLegal(VT) &&

      V.getOperand(0).hasOneUse() && V.getOperand(1).hasOneUse()) {

    // TODO: Handle cases with single NOT operand -> ANDNP

    if (SDValue Op1 = IsNOT(V.getOperand(1), DAG))

      if (SDValue Op0 = IsNOT(V.getOperand(0), DAG))

        return DAG.getNode(ISD::AND, SDLoc(V), VT, DAG.getBitcast(VT, Op0),

                           DAG.getBitcast(VT, Op1));

  }


  return SDValue();

}


/// Create a shuffle mask that matches the PACKSS/PACKUS truncation.

/// A multi-stage pack shuffle mask is created by specifying NumStages > 1.

/// Note: This ignores saturation, so inputs must be checked first.


static void createPackShuffleMask(MVT VT, SmallVectorImpl<int> &Mask,

                                  bool Unary, unsigned NumStages = 1) {

  assert(Mask.empty() && "Expected an empty shuffle mask vector");

  unsigned NumElts = VT.getVectorNumElements();

  unsigned NumLanes = VT.getSizeInBits() / 128;

  unsigned NumEltsPerLane = 128 / VT.getScalarSizeInBits();

  unsigned Offset = Unary ? 0 : NumElts;

  unsigned Repetitions = 1u << (NumStages - 1);

  unsigned Increment = 1u << NumStages;

  assert((NumEltsPerLane >> NumStages) > 0 && "Illegal packing compaction");


  for (unsigned Lane = 0; Lane != NumLanes; ++Lane) {

    for (unsigned Stage = 0; Stage != Repetitions; ++Stage) {

      for (unsigned Elt = 0; Elt != NumEltsPerLane; Elt += Increment)

        Mask.push_back(Elt + (Lane * NumEltsPerLane));

      for (unsigned Elt = 0; Elt != NumEltsPerLane; Elt += Increment)

        Mask.push_back(Elt + (Lane * NumEltsPerLane) + Offset);

    }

  }

}


// Split the demanded elts of a PACKSS/PACKUS node between its operands.


static void getPackDemandedElts(EVT VT, const APInt &DemandedElts,

                                APInt &DemandedLHS, APInt &DemandedRHS) {

  int NumLanes = VT.getSizeInBits() / 128;

  int NumElts = DemandedElts.getBitWidth();

  int NumInnerElts = NumElts / 2;

  int NumEltsPerLane = NumElts / NumLanes;

  int NumInnerEltsPerLane = NumInnerElts / NumLanes;


  DemandedLHS = APInt::getZero(NumInnerElts);

  DemandedRHS = APInt::getZero(NumInnerElts);


  // Map DemandedElts to the packed operands.

  for (int Lane = 0; Lane != NumLanes; ++Lane) {

    for (int Elt = 0; Elt != NumInnerEltsPerLane; ++Elt) {

      int OuterIdx = (Lane * NumEltsPerLane) + Elt;

      int InnerIdx = (Lane * NumInnerEltsPerLane) + Elt;

      if (DemandedElts[OuterIdx])

        DemandedLHS.setBit(InnerIdx);

      if (DemandedElts[OuterIdx + NumInnerEltsPerLane])

        DemandedRHS.setBit(InnerIdx);

    }

  }

}


// Split the demanded elts of a HADD/HSUB node between its operands.


static void getHorizDemandedElts(EVT VT, const APInt &DemandedElts,

                                 APInt &DemandedLHS, APInt &DemandedRHS) {

  getHorizDemandedEltsForFirstOperand(VT.getSizeInBits(), DemandedElts,

                                      DemandedLHS, DemandedRHS);

  DemandedLHS |= DemandedLHS << 1;

  DemandedRHS |= DemandedRHS << 1;

}


/// Calculates the shuffle mask corresponding to the target-specific opcode.

/// If the mask could be calculated, returns it in \p Mask, returns the shuffle

/// operands in \p Ops, and returns true.

/// Sets \p IsUnary to true if only one source is used. Note that this will set

/// IsUnary for shuffles which use a single input multiple times, and in those

/// cases it will adjust the mask to only have indices within that single input.

/// It is an error to call this with non-empty Mask/Ops vectors.


static bool getTargetShuffleMask(SDValue N, bool AllowSentinelZero,

                                 SmallVectorImpl<SDValue> &Ops,

                                 SmallVectorImpl<int> &Mask, bool &IsUnary) {

  if (!isTargetShuffle(N.getOpcode()))

    return false;


  MVT VT = N.getSimpleValueType();

  unsigned NumElems = VT.getVectorNumElements();

  unsigned MaskEltSize = VT.getScalarSizeInBits();

  SmallVector<uint64_t, 32> RawMask;

  APInt RawUndefs;

  uint64_t ImmN;


  assert(Mask.empty() && "getTargetShuffleMask expects an empty Mask vector");

  assert(Ops.empty() && "getTargetShuffleMask expects an empty Ops vector");


  IsUnary = false;

  bool IsFakeUnary = false;

  switch (N.getOpcode()) {

  case X86ISD::BLENDI:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    ImmN = N.getConstantOperandVal(N.getNumOperands() - 1);

    DecodeBLENDMask(NumElems, ImmN, Mask);

    IsUnary = IsFakeUnary = N.getOperand(0) == N.getOperand(1);

    break;

  case X86ISD::SHUFP:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    ImmN = N.getConstantOperandVal(N.getNumOperands() - 1);

    DecodeSHUFPMask(NumElems, MaskEltSize, ImmN, Mask);

    IsUnary = IsFakeUnary = N.getOperand(0) == N.getOperand(1);

    break;

  case X86ISD::INSERTPS:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    ImmN = N.getConstantOperandVal(N.getNumOperands() - 1);

    DecodeINSERTPSMask(ImmN, Mask, /*SrcIsMem=*/false);

    IsUnary = IsFakeUnary = N.getOperand(0) == N.getOperand(1);

    break;

  case X86ISD::EXTRQI:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    if (isa<ConstantSDNode>(N.getOperand(1)) &&

        isa<ConstantSDNode>(N.getOperand(2))) {

      int BitLen = N.getConstantOperandVal(1);

      int BitIdx = N.getConstantOperandVal(2);

      DecodeEXTRQIMask(NumElems, MaskEltSize, BitLen, BitIdx, Mask);

      IsUnary = true;

    }

    break;

  case X86ISD::INSERTQI:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    if (isa<ConstantSDNode>(N.getOperand(2)) &&

        isa<ConstantSDNode>(N.getOperand(3))) {

      int BitLen = N.getConstantOperandVal(2);

      int BitIdx = N.getConstantOperandVal(3);

      DecodeINSERTQIMask(NumElems, MaskEltSize, BitLen, BitIdx, Mask);

      IsUnary = IsFakeUnary = N.getOperand(0) == N.getOperand(1);

    }

    break;

  case X86ISD::UNPCKH:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    DecodeUNPCKHMask(NumElems, MaskEltSize, Mask);

    IsUnary = IsFakeUnary = N.getOperand(0) == N.getOperand(1);

    break;

  case X86ISD::UNPCKL:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    DecodeUNPCKLMask(NumElems, MaskEltSize, Mask);

    IsUnary = IsFakeUnary = N.getOperand(0) == N.getOperand(1);

    break;

  case X86ISD::MOVHLPS:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    DecodeMOVHLPSMask(NumElems, Mask);

    IsUnary = IsFakeUnary = N.getOperand(0) == N.getOperand(1);

    break;

  case X86ISD::MOVLHPS:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    DecodeMOVLHPSMask(NumElems, Mask);

    IsUnary = IsFakeUnary = N.getOperand(0) == N.getOperand(1);

    break;

  case X86ISD::VALIGN:

    assert((VT.getScalarType() == MVT::i32 || VT.getScalarType() == MVT::i64) &&

           "Only 32-bit and 64-bit elements are supported!");

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    ImmN = N.getConstantOperandVal(N.getNumOperands() - 1);

    DecodeVALIGNMask(NumElems, ImmN, Mask);

    IsUnary = IsFakeUnary = N.getOperand(0) == N.getOperand(1);

    Ops.push_back(N.getOperand(1));

    Ops.push_back(N.getOperand(0));

    break;

  case X86ISD::PALIGNR:

    assert(VT.getScalarType() == MVT::i8 && "Byte vector expected");

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    ImmN = N.getConstantOperandVal(N.getNumOperands() - 1);

    DecodePALIGNRMask(NumElems, ImmN, Mask);

    IsUnary = IsFakeUnary = N.getOperand(0) == N.getOperand(1);

    Ops.push_back(N.getOperand(1));

    Ops.push_back(N.getOperand(0));

    break;

  case X86ISD::VSHLDQ:

    assert(VT.getScalarType() == MVT::i8 && "Byte vector expected");

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    ImmN = N.getConstantOperandVal(N.getNumOperands() - 1);

    DecodePSLLDQMask(NumElems, ImmN, Mask);

    IsUnary = true;

    break;

  case X86ISD::VSRLDQ:

    assert(VT.getScalarType() == MVT::i8 && "Byte vector expected");

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    ImmN = N.getConstantOperandVal(N.getNumOperands() - 1);

    DecodePSRLDQMask(NumElems, ImmN, Mask);

    IsUnary = true;

    break;

  case X86ISD::PSHUFD:

  case X86ISD::VPERMILPI:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    ImmN = N.getConstantOperandVal(N.getNumOperands() - 1);

    DecodePSHUFMask(NumElems, MaskEltSize, ImmN, Mask);

    IsUnary = true;

    break;

  case X86ISD::PSHUFHW:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    ImmN = N.getConstantOperandVal(N.getNumOperands() - 1);

    DecodePSHUFHWMask(NumElems, ImmN, Mask);

    IsUnary = true;

    break;

  case X86ISD::PSHUFLW:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    ImmN = N.getConstantOperandVal(N.getNumOperands() - 1);

    DecodePSHUFLWMask(NumElems, ImmN, Mask);

    IsUnary = true;

    break;

  case X86ISD::VZEXT_MOVL:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    DecodeZeroMoveLowMask(NumElems, Mask);

    IsUnary = true;

    break;

  case X86ISD::VBROADCAST:

    // We only decode broadcasts of same-sized vectors, peeking through to

    // extracted subvectors is likely to cause hasOneUse issues with

    // SimplifyDemandedBits etc.

    if (N.getOperand(0).getValueType() == VT) {

      DecodeVectorBroadcast(NumElems, Mask);

      IsUnary = true;

      break;

    }

    return false;

  case X86ISD::VPERMILPV: {

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    IsUnary = true;

    SDValue MaskNode = N.getOperand(1);

    if (getTargetShuffleMaskIndices(MaskNode, MaskEltSize, RawMask,

                                    RawUndefs)) {

      DecodeVPERMILPMask(NumElems, MaskEltSize, RawMask, RawUndefs, Mask);

      break;

    }

    return false;

  }

  case X86ISD::PSHUFB: {

    assert(VT.getScalarType() == MVT::i8 && "Byte vector expected");

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    IsUnary = true;

    SDValue MaskNode = N.getOperand(1);

    if (getTargetShuffleMaskIndices(MaskNode, 8, RawMask, RawUndefs)) {

      DecodePSHUFBMask(RawMask, RawUndefs, Mask);

      break;

    }

    return false;

  }

  case X86ISD::VPERMI:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    ImmN = N.getConstantOperandVal(N.getNumOperands() - 1);

    DecodeVPERMMask(NumElems, ImmN, Mask);

    IsUnary = true;

    break;

  case X86ISD::MOVSS:

  case X86ISD::MOVSD:

  case X86ISD::MOVSH:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    DecodeScalarMoveMask(NumElems, /* IsLoad */ false, Mask);

    break;

  case X86ISD::VPERM2X128:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    ImmN = N.getConstantOperandVal(N.getNumOperands() - 1);

    DecodeVPERM2X128Mask(NumElems, ImmN, Mask);

    IsUnary = IsFakeUnary = N.getOperand(0) == N.getOperand(1);

    break;

  case X86ISD::SHUF128:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    ImmN = N.getConstantOperandVal(N.getNumOperands() - 1);

    decodeVSHUF64x2FamilyMask(NumElems, MaskEltSize, ImmN, Mask);

    IsUnary = IsFakeUnary = N.getOperand(0) == N.getOperand(1);

    break;

  case X86ISD::MOVSLDUP:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    DecodeMOVSLDUPMask(NumElems, Mask);

    IsUnary = true;

    break;

  case X86ISD::MOVSHDUP:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    DecodeMOVSHDUPMask(NumElems, Mask);

    IsUnary = true;

    break;

  case X86ISD::MOVDDUP:

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    DecodeMOVDDUPMask(NumElems, Mask);

    IsUnary = true;

    break;

  case X86ISD::VPERMIL2: {

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    IsUnary = IsFakeUnary = N.getOperand(0) == N.getOperand(1);

    SDValue MaskNode = N.getOperand(2);

    SDValue CtrlNode = N.getOperand(3);

    if (ConstantSDNode *CtrlOp = dyn_cast<ConstantSDNode>(CtrlNode)) {

      unsigned CtrlImm = CtrlOp->getZExtValue();

      if (getTargetShuffleMaskIndices(MaskNode, MaskEltSize, RawMask,

                                      RawUndefs)) {

        DecodeVPERMIL2PMask(NumElems, MaskEltSize, CtrlImm, RawMask, RawUndefs,

                            Mask);

        break;

      }

    }

    return false;

  }

  case X86ISD::VPPERM: {

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    IsUnary = IsFakeUnary = N.getOperand(0) == N.getOperand(1);

    SDValue MaskNode = N.getOperand(2);

    if (getTargetShuffleMaskIndices(MaskNode, 8, RawMask, RawUndefs)) {

      DecodeVPPERMMask(RawMask, RawUndefs, Mask);

      break;

    }

    return false;

  }

  case X86ISD::VPERMV: {

    assert(N.getOperand(1).getValueType() == VT && "Unexpected value type");

    IsUnary = true;

    // Unlike most shuffle nodes, VPERMV's mask operand is operand 0.

    Ops.push_back(N.getOperand(1));

    SDValue MaskNode = N.getOperand(0);

    if (getTargetShuffleMaskIndices(MaskNode, MaskEltSize, RawMask,

                                    RawUndefs)) {

      DecodeVPERMVMask(RawMask, RawUndefs, Mask);

      break;

    }

    return false;

  }

  case X86ISD::VPERMV3: {

    assert(N.getOperand(0).getValueType() == VT && "Unexpected value type");

    assert(N.getOperand(2).getValueType() == VT && "Unexpected value type");

    IsUnary = IsFakeUnary = N.getOperand(0) == N.getOperand(2);

    // Unlike most shuffle nodes, VPERMV3's mask operand is the middle one.

    Ops.push_back(N.getOperand(0));

    Ops.push_back(N.getOperand(2));

    SDValue MaskNode = N.getOperand(1);

    if (getTargetShuffleMaskIndices(MaskNode, MaskEltSize, RawMask,

                                    RawUndefs)) {

      DecodeVPERMV3Mask(RawMask, RawUndefs, Mask);

      break;

    }

    return false;

  }

  case X86ISD::COMPRESS: {

    SDValue CmpVec = N.getOperand(0);

    SDValue PassThru = N.getOperand(1);

    SDValue CmpMask = N.getOperand(2);

    APInt UndefElts;

    SmallVector<APInt> EltBits;

    if (!getTargetConstantBitsFromNode(CmpMask, 1, UndefElts, EltBits))

      return false;

    assert(UndefElts.getBitWidth() == NumElems && EltBits.size() == NumElems &&

           "Illegal compression mask");

    for (unsigned I = 0; I != NumElems; ++I) {

      if (!EltBits[I].isZero())

        Mask.push_back(I);

    }

    while (Mask.size() != NumElems) {

      Mask.push_back(NumElems + Mask.size());

    }

    Ops.push_back(CmpVec);

    Ops.push_back(PassThru);

    return true;

  }

  case X86ISD::EXPAND: {

    SDValue ExpVec = N.getOperand(0);

    SDValue PassThru = N.getOperand(1);

    SDValue ExpMask = N.getOperand(2);

    APInt UndefElts;

    SmallVector<APInt> EltBits;

    if (!getTargetConstantBitsFromNode(ExpMask, 1, UndefElts, EltBits))

      return false;

    assert(UndefElts.getBitWidth() == NumElems && EltBits.size() == NumElems &&

           "Illegal expansion mask");

    unsigned ExpIndex = 0;

    for (unsigned I = 0; I != NumElems; ++I) {

      if (EltBits[I].isZero())

        Mask.push_back(I + NumElems);

      else

        Mask.push_back(ExpIndex++);

    }

    Ops.push_back(ExpVec);

    Ops.push_back(PassThru);

    return true;

  }

  default:

    llvm_unreachable("unknown target shuffle node");

  }


  // Empty mask indicates the decode failed.

  if (Mask.empty())

    return false;


  // Check if we're getting a shuffle mask with zero'd elements.

  if (!AllowSentinelZero && isAnyZero(Mask))

    return false;


  // If we have a fake unary shuffle, the shuffle mask is spread across two

  // inputs that are actually the same node. Re-map the mask to always point

  // into the first input.

  if (IsFakeUnary)

    for (int &M : Mask)

      if (M >= (int)Mask.size())

        M -= Mask.size();


  // If we didn't already add operands in the opcode-specific code, default to

  // adding 1 or 2 operands starting at 0.

  if (Ops.empty()) {

    Ops.push_back(N.getOperand(0));

    if (!IsUnary || IsFakeUnary)

      Ops.push_back(N.getOperand(1));

  }


  return true;

}


// Wrapper for getTargetShuffleMask with InUnary;


static bool getTargetShuffleMask(SDValue N, bool AllowSentinelZero,

                                 SmallVectorImpl<SDValue> &Ops,

                                 SmallVectorImpl<int> &Mask) {

  bool IsUnary;

  return getTargetShuffleMask(N, AllowSentinelZero, Ops, Mask, IsUnary);

}


/// Compute whether each element of a shuffle is zeroable.

///

/// A "zeroable" vector shuffle element is one which can be lowered to zero.

/// Either it is an undef element in the shuffle mask, the element of the input

/// referenced is undef, or the element of the input referenced is known to be

/// zero. Many x86 shuffles can zero lanes cheaply and we often want to handle

/// as many lanes with this technique as possible to simplify the remaining

/// shuffle.


static void computeZeroableShuffleElements(ArrayRef<int> Mask,

                                           SDValue V1, SDValue V2,

                                           APInt &KnownUndef, APInt &KnownZero) {

  int Size = Mask.size();

  KnownUndef = KnownZero = APInt::getZero(Size);


  V1 = peekThroughBitcasts(V1);

  V2 = peekThroughBitcasts(V2);


  bool V1IsZero = ISD::isBuildVectorAllZeros(V1.getNode());

  bool V2IsZero = ISD::isBuildVectorAllZeros(V2.getNode());


  int VectorSizeInBits = V1.getValueSizeInBits();

  int ScalarSizeInBits = VectorSizeInBits / Size;

  assert(!(VectorSizeInBits % ScalarSizeInBits) && "Illegal shuffle mask size");


  for (int i = 0; i < Size; ++i) {

    int M = Mask[i];

    // Handle the easy cases.

    if (M < 0) {

      KnownUndef.setBit(i);

      continue;

    }

    if ((M >= 0 && M < Size && V1IsZero) || (M >= Size && V2IsZero)) {

      KnownZero.setBit(i);

      continue;

    }


    // Determine shuffle input and normalize the mask.

    SDValue V = M < Size ? V1 : V2;

    M %= Size;


    // Currently we can only search BUILD_VECTOR for UNDEF/ZERO elements.

    if (V.getOpcode() != ISD::BUILD_VECTOR)

      continue;


    // If the BUILD_VECTOR has fewer elements then the bitcasted portion of

    // the (larger) source element must be UNDEF/ZERO.

    if ((Size % V.getNumOperands()) == 0) {

      int Scale = Size / V->getNumOperands();

      SDValue Op = V.getOperand(M / Scale);

      if (Op.isUndef())

        KnownUndef.setBit(i);

      if (X86::isZeroNode(Op))

        KnownZero.setBit(i);

      else if (ConstantSDNode *Cst = dyn_cast<ConstantSDNode>(Op)) {

        APInt Val = Cst->getAPIntValue();

        Val = Val.extractBits(ScalarSizeInBits, (M % Scale) * ScalarSizeInBits);

        if (Val == 0)

          KnownZero.setBit(i);

      } else if (ConstantFPSDNode *Cst = dyn_cast<ConstantFPSDNode>(Op)) {

        APInt Val = Cst->getValueAPF().bitcastToAPInt();

        Val = Val.extractBits(ScalarSizeInBits, (M % Scale) * ScalarSizeInBits);

        if (Val == 0)

          KnownZero.setBit(i);

      }

      continue;

    }


    // If the BUILD_VECTOR has more elements then all the (smaller) source

    // elements must be UNDEF or ZERO.

    if ((V.getNumOperands() % Size) == 0) {

      int Scale = V->getNumOperands() / Size;

      bool AllUndef = true;

      bool AllZero = true;

      for (int j = 0; j < Scale; ++j) {

        SDValue Op = V.getOperand((M * Scale) + j);

        AllUndef &= Op.isUndef();

        AllZero &= X86::isZeroNode(Op);

      }

      if (AllUndef)

        KnownUndef.setBit(i);

      if (AllZero)

        KnownZero.setBit(i);

      continue;

    }

  }

}


/// Decode a target shuffle mask and inputs and see if any values are

/// known to be undef or zero from their inputs.

/// Returns true if the target shuffle mask was decoded.

/// FIXME: Merge this with computeZeroableShuffleElements?


static bool getTargetShuffleAndZeroables(SDValue N, SmallVectorImpl<int> &Mask,

                                         SmallVectorImpl<SDValue> &Ops,

                                         APInt &KnownUndef, APInt &KnownZero) {

  bool IsUnary;

  if (!isTargetShuffle(N.getOpcode()))

    return false;


  MVT VT = N.getSimpleValueType();

  if (!getTargetShuffleMask(N, true, Ops, Mask, IsUnary))

    return false;


  int Size = Mask.size();

  SDValue V1 = Ops[0];

  SDValue V2 = IsUnary ? V1 : Ops[1];

  KnownUndef = KnownZero = APInt::getZero(Size);


  V1 = peekThroughBitcasts(V1);

  V2 = peekThroughBitcasts(V2);


  assert((VT.getSizeInBits() % Size) == 0 &&

         "Illegal split of shuffle value type");

  unsigned EltSizeInBits = VT.getSizeInBits() / Size;


  // Extract known constant input data.

  APInt UndefSrcElts[2];

  SmallVector<APInt, 32> SrcEltBits[2];

  bool IsSrcConstant[2] = {

      getTargetConstantBitsFromNode(V1, EltSizeInBits, UndefSrcElts[0],

                                    SrcEltBits[0], /*AllowWholeUndefs*/ true,

                                    /*AllowPartialUndefs*/ false),

      getTargetConstantBitsFromNode(V2, EltSizeInBits, UndefSrcElts[1],

                                    SrcEltBits[1], /*AllowWholeUndefs*/ true,

                                    /*AllowPartialUndefs*/ false)};


  for (int i = 0; i < Size; ++i) {

    int M = Mask[i];


    // Already decoded as SM_SentinelZero / SM_SentinelUndef.

    if (M < 0) {

      assert(isUndefOrZero(M) && "Unknown shuffle sentinel value!");

      if (SM_SentinelUndef == M)

        KnownUndef.setBit(i);

      if (SM_SentinelZero == M)

        KnownZero.setBit(i);

      continue;

    }


    // Determine shuffle input and normalize the mask.

    unsigned SrcIdx = M / Size;

    SDValue V = M < Size ? V1 : V2;

    M %= Size;


    // We are referencing an UNDEF input.

    if (V.isUndef()) {

      KnownUndef.setBit(i);

      continue;

    }


    // SCALAR_TO_VECTOR - only the first element is defined, and the rest UNDEF.

    // TODO: We currently only set UNDEF for integer types - floats use the same

    // registers as vectors and many of the scalar folded loads rely on the

    // SCALAR_TO_VECTOR pattern.

    if (V.getOpcode() == ISD::SCALAR_TO_VECTOR &&

        (Size % V.getValueType().getVectorNumElements()) == 0) {

      int Scale = Size / V.getValueType().getVectorNumElements();

      int Idx = M / Scale;

      if (Idx != 0 && !VT.isFloatingPoint())

        KnownUndef.setBit(i);

      else if (Idx == 0 && X86::isZeroNode(V.getOperand(0)))

        KnownZero.setBit(i);

      continue;

    }


    // INSERT_SUBVECTOR - to widen vectors we often insert them into UNDEF

    // base vectors.

    if (V.getOpcode() == ISD::INSERT_SUBVECTOR) {

      SDValue Vec = V.getOperand(0);

      int NumVecElts = Vec.getValueType().getVectorNumElements();

      if (Vec.isUndef() && Size == NumVecElts) {

        int Idx = V.getConstantOperandVal(2);

        int NumSubElts = V.getOperand(1).getValueType().getVectorNumElements();

        if (M < Idx || (Idx + NumSubElts) <= M)

          KnownUndef.setBit(i);

      }

      continue;

    }


    // Attempt to extract from the source's constant bits.

    if (IsSrcConstant[SrcIdx]) {

      if (UndefSrcElts[SrcIdx][M])

        KnownUndef.setBit(i);

      else if (SrcEltBits[SrcIdx][M] == 0)

        KnownZero.setBit(i);

    }

  }


  assert(VT.getVectorNumElements() == (unsigned)Size &&

         "Different mask size from vector size!");

  return true;

}


// Replace target shuffle mask elements with known undef/zero sentinels.


static void resolveTargetShuffleFromZeroables(SmallVectorImpl<int> &Mask,

                                              const APInt &KnownUndef,

                                              const APInt &KnownZero,

                                              bool ResolveKnownZeros= true) {

  unsigned NumElts = Mask.size();

  assert(KnownUndef.getBitWidth() == NumElts &&

         KnownZero.getBitWidth() == NumElts && "Shuffle mask size mismatch");


  for (unsigned i = 0; i != NumElts; ++i) {

    if (KnownUndef[i])

      Mask[i] = SM_SentinelUndef;

    else if (ResolveKnownZeros && KnownZero[i])

      Mask[i] = SM_SentinelZero;

  }

}


// Extract target shuffle mask sentinel elements to known undef/zero bitmasks.


static void resolveZeroablesFromTargetShuffle(const SmallVectorImpl<int> &Mask,

                                              APInt &KnownUndef,

                                              APInt &KnownZero) {

  unsigned NumElts = Mask.size();

  KnownUndef = KnownZero = APInt::getZero(NumElts);


  for (unsigned i = 0; i != NumElts; ++i) {

    int M = Mask[i];

    if (SM_SentinelUndef == M)

      KnownUndef.setBit(i);

    if (SM_SentinelZero == M)

      KnownZero.setBit(i);

  }

}


// Attempt to create a shuffle mask from a VSELECT/BLENDV condition mask.


static bool createShuffleMaskFromVSELECT(SmallVectorImpl<int> &Mask,

                                         SDValue Cond, bool IsBLENDV = false) {

  EVT CondVT = Cond.getValueType();

  unsigned EltSizeInBits = CondVT.getScalarSizeInBits();

  unsigned NumElts = CondVT.getVectorNumElements();


  APInt UndefElts;

  SmallVector<APInt, 32> EltBits;

  if (!getTargetConstantBitsFromNode(Cond, EltSizeInBits, UndefElts, EltBits,

                                     /*AllowWholeUndefs*/ true,

                                     /*AllowPartialUndefs*/ false))

    return false;


  Mask.resize(NumElts, SM_SentinelUndef);


  for (int i = 0; i != (int)NumElts; ++i) {

    Mask[i] = i;

    // Arbitrarily choose from the 2nd operand if the select condition element

    // is undef.

    // TODO: Can we do better by matching patterns such as even/odd?

    if (UndefElts[i] || (!IsBLENDV && EltBits[i].isZero()) ||

        (IsBLENDV && EltBits[i].isNonNegative()))

      Mask[i] += NumElts;

  }


  return true;

}


// Forward declaration (for getFauxShuffleMask recursive check).

static bool getTargetShuffleInputs(SDValue Op, const APInt &DemandedElts,

                                   SmallVectorImpl<SDValue> &Inputs,

                                   SmallVectorImpl<int> &Mask,

                                   const SelectionDAG &DAG, unsigned Depth,

                                   bool ResolveKnownElts);


// Attempt to decode ops that could be represented as a shuffle mask.

// The decoded shuffle mask may contain a different number of elements to the

// destination value type.

// TODO: Merge into getTargetShuffleInputs()


static bool getFauxShuffleMask(SDValue N, const APInt &DemandedElts,

                               SmallVectorImpl<int> &Mask,

                               SmallVectorImpl<SDValue> &Ops,

                               const SelectionDAG &DAG, unsigned Depth,

                               bool ResolveKnownElts) {

  Mask.clear();

  Ops.clear();


  MVT VT = N.getSimpleValueType();

  unsigned NumElts = VT.getVectorNumElements();

  unsigned NumSizeInBits = VT.getSizeInBits();

  unsigned NumBitsPerElt = VT.getScalarSizeInBits();

  if ((NumBitsPerElt % 8) != 0 || (NumSizeInBits % 8) != 0)

    return false;

  assert(NumElts == DemandedElts.getBitWidth() && "Unexpected vector size");

  unsigned NumSizeInBytes = NumSizeInBits / 8;

  unsigned NumBytesPerElt = NumBitsPerElt / 8;


  unsigned Opcode = N.getOpcode();

  switch (Opcode) {

  case ISD::VECTOR_SHUFFLE: {

    // Don't treat ISD::VECTOR_SHUFFLE as a target shuffle so decode it here.

    ArrayRef<int> ShuffleMask = cast<ShuffleVectorSDNode>(N)->getMask();

    if (isUndefOrInRange(ShuffleMask, 0, 2 * NumElts)) {

      Mask.append(ShuffleMask.begin(), ShuffleMask.end());

      Ops.push_back(N.getOperand(0));

      Ops.push_back(N.getOperand(1));

      return true;

    }

    return false;

  }

  case ISD::AND:

  case X86ISD::ANDNP: {

    // Attempt to decode as a per-byte mask.

    APInt UndefElts;

    SmallVector<APInt, 32> EltBits;

    SDValue N0 = N.getOperand(0);

    SDValue N1 = N.getOperand(1);

    bool IsAndN = (X86ISD::ANDNP == Opcode);

    uint64_t ZeroMask = IsAndN ? 255 : 0;

    if (!getTargetConstantBitsFromNode(IsAndN ? N0 : N1, 8, UndefElts, EltBits,

                                       /*AllowWholeUndefs*/ false,

                                       /*AllowPartialUndefs*/ false))

      return false;

    // We can't assume an undef src element gives an undef dst - the other src

    // might be zero.

    assert(UndefElts.isZero() && "Unexpected UNDEF element in AND/ANDNP mask");

    for (int i = 0, e = (int)EltBits.size(); i != e; ++i) {

      const APInt &ByteBits = EltBits[i];

      if (ByteBits != 0 && ByteBits != 255)

        return false;

      Mask.push_back(ByteBits == ZeroMask ? SM_SentinelZero : i);

    }

    Ops.push_back(IsAndN ? N1 : N0);

    return true;

  }

  case ISD::OR: {

    // Handle OR(SHUFFLE,SHUFFLE) case where one source is zero and the other

    // is a valid shuffle index.

    SDValue N0 = peekThroughBitcasts(N.getOperand(0));

    SDValue N1 = peekThroughBitcasts(N.getOperand(1));

    if (!N0.getValueType().isVector() || !N1.getValueType().isVector())

      return false;


    SmallVector<int, 64> SrcMask0, SrcMask1;

    SmallVector<SDValue, 2> SrcInputs0, SrcInputs1;

    APInt Demand0 = APInt::getAllOnes(N0.getValueType().getVectorNumElements());

    APInt Demand1 = APInt::getAllOnes(N1.getValueType().getVectorNumElements());

    if (!getTargetShuffleInputs(N0, Demand0, SrcInputs0, SrcMask0, DAG,

                                Depth + 1, true) ||

        !getTargetShuffleInputs(N1, Demand1, SrcInputs1, SrcMask1, DAG,

                                Depth + 1, true))

      return false;


    size_t MaskSize = std::max(SrcMask0.size(), SrcMask1.size());

    SmallVector<int, 64> Mask0, Mask1;

    narrowShuffleMaskElts(MaskSize / SrcMask0.size(), SrcMask0, Mask0);

    narrowShuffleMaskElts(MaskSize / SrcMask1.size(), SrcMask1, Mask1);

    for (int i = 0; i != (int)MaskSize; ++i) {

      // NOTE: Don't handle demanded SM_SentinelUndef, as we can end up in

      // infinite loops converting between OR and BLEND shuffles due to

      // canWidenShuffleElements merging away undef elements, meaning we

      // fail to recognise the OR as the undef element isn't known zero.

      if (Mask0[i] == SM_SentinelZero && Mask1[i] == SM_SentinelZero)

        Mask.push_back(SM_SentinelZero);

      else if (Mask1[i] == SM_SentinelZero)

        Mask.push_back(i);

      else if (Mask0[i] == SM_SentinelZero)

        Mask.push_back(i + MaskSize);

      else if (MaskSize == NumElts && !DemandedElts[i])

        Mask.push_back(SM_SentinelUndef);

      else

        return false;

    }

    Ops.push_back(N.getOperand(0));

    Ops.push_back(N.getOperand(1));

    return true;

  }

  case ISD::CONCAT_VECTORS: {

    // Limit this to vXi64 vector cases to make the most of cross lane shuffles.

    unsigned NumSubElts = N.getOperand(0).getValueType().getVectorNumElements();

    if (NumBitsPerElt == 64) {

      for (unsigned I = 0, E = N.getNumOperands(); I != E; ++I) {

        for (unsigned M = 0; M != NumSubElts; ++M)

          Mask.push_back((I * NumElts) + M);

        Ops.push_back(N.getOperand(I));

      }

      return true;

    }

    return false;

  }

  case ISD::INSERT_SUBVECTOR: {

    SDValue Src = N.getOperand(0);

    SDValue Sub = N.getOperand(1);

    EVT SubVT = Sub.getValueType();

    unsigned NumSubElts = SubVT.getVectorNumElements();

    uint64_t InsertIdx = N.getConstantOperandVal(2);

    // Subvector isn't demanded - just return the base vector.

    if (DemandedElts.extractBits(NumSubElts, InsertIdx) == 0) {

      Mask.resize(NumElts);

      std::iota(Mask.begin(), Mask.end(), 0);

      Ops.push_back(Src);

      return true;

    }

    // Handle CONCAT(SUB0, SUB1).

    // Limit to vXi64/splat cases to make the most of cross lane shuffles.

    if (Depth > 0 && InsertIdx == NumSubElts && NumElts == (2 * NumSubElts) &&

        Src.getOpcode() == ISD::INSERT_SUBVECTOR &&

        Src.getOperand(0).isUndef() &&

        Src.getOperand(1).getValueType() == SubVT &&

        Src.getConstantOperandVal(2) == 0 &&

        (NumBitsPerElt == 64 || Src.getOperand(1) == Sub) &&

        SDNode::areOnlyUsersOf({N.getNode(), Src.getNode()}, Sub.getNode())) {

      Mask.resize(NumElts);

      std::iota(Mask.begin(), Mask.begin() + NumSubElts, 0);

      std::iota(Mask.begin() + NumSubElts, Mask.end(), NumElts);

      Ops.push_back(Src.getOperand(1));

      Ops.push_back(Sub);

      return true;

    }

    // Handle INSERT_SUBVECTOR(UNDEF, SUB, IDX) iff IDX != 0

    if (InsertIdx != 0 && Src.isUndef() &&

        peekThroughBitcasts(Sub).getOpcode() != ISD::EXTRACT_SUBVECTOR) {

      Mask.assign(NumElts, SM_SentinelUndef);

      std::iota(Mask.begin() + InsertIdx, Mask.begin() + InsertIdx + NumSubElts,

                0);

      Ops.push_back(Sub);

      return true;

    }

    if (!N->isOnlyUserOf(Sub.getNode()))

      return false;


    SmallVector<int, 64> SubMask;

    SmallVector<SDValue, 2> SubInputs;

    SDValue SubSrc = peekThroughOneUseBitcasts(Sub);

    EVT SubSrcVT = SubSrc.getValueType();

    if (!SubSrcVT.isVector())

      return false;


    // Handle INSERT_SUBVECTOR(SRC0, EXTRACT_SUBVECTOR(SRC1)).

    if (SubSrc.getOpcode() == ISD::EXTRACT_SUBVECTOR &&

        SubSrc.getOperand(0).getValueSizeInBits() == NumSizeInBits) {

      uint64_t ExtractIdx = SubSrc.getConstantOperandVal(1);

      SDValue SubSrcSrc = SubSrc.getOperand(0);

      unsigned NumSubSrcSrcElts =

          SubSrcSrc.getValueType().getVectorNumElements();

      unsigned MaxElts = std::max(NumElts, NumSubSrcSrcElts);

      assert((MaxElts % NumElts) == 0 && (MaxElts % NumSubSrcSrcElts) == 0 &&

             "Subvector valuetype mismatch");

      InsertIdx *= (MaxElts / NumElts);

      ExtractIdx *= (MaxElts / NumSubSrcSrcElts);

      NumSubElts *= (MaxElts / NumElts);

      bool SrcIsUndef = Src.isUndef();

      for (int i = 0; i != (int)MaxElts; ++i)

        Mask.push_back(SrcIsUndef ? SM_SentinelUndef : i);

      for (int i = 0; i != (int)NumSubElts; ++i)

        Mask[InsertIdx + i] = (SrcIsUndef ? 0 : MaxElts) + ExtractIdx + i;

      if (!SrcIsUndef)

        Ops.push_back(Src);

      Ops.push_back(SubSrcSrc);

      return true;

    }


    // Handle INSERT_SUBVECTOR(SRC0, SHUFFLE(SRC1)).

    APInt SubDemand = APInt::getAllOnes(SubSrcVT.getVectorNumElements());

    if (!getTargetShuffleInputs(SubSrc, SubDemand, SubInputs, SubMask, DAG,

                                Depth + 1, ResolveKnownElts))

      return false;


    // Subvector shuffle inputs must not be larger than the subvector.

    if (llvm::any_of(SubInputs, [SubVT](SDValue SubInput) {

          return SubVT.getFixedSizeInBits() <

                 SubInput.getValueSizeInBits().getFixedValue();

        }))

      return false;


    if (SubMask.size() != NumSubElts) {

      assert(((SubMask.size() % NumSubElts) == 0 ||

              (NumSubElts % SubMask.size()) == 0) &&

             "Illegal submask scale");

      if ((NumSubElts % SubMask.size()) == 0) {

        int Scale = NumSubElts / SubMask.size();

        SmallVector<int, 64> ScaledSubMask;

        narrowShuffleMaskElts(Scale, SubMask, ScaledSubMask);

        SubMask = ScaledSubMask;

      } else {

        int Scale = SubMask.size() / NumSubElts;

        NumSubElts = SubMask.size();

        NumElts *= Scale;

        InsertIdx *= Scale;

      }

    }

    Ops.push_back(Src);

    Ops.append(SubInputs.begin(), SubInputs.end());

    if (ISD::isBuildVectorAllZeros(Src.getNode()))

      Mask.append(NumElts, SM_SentinelZero);

    else

      for (int i = 0; i != (int)NumElts; ++i)

        Mask.push_back(i);

    for (int i = 0; i != (int)NumSubElts; ++i) {

      int M = SubMask[i];

      if (0 <= M) {

        int InputIdx = M / NumSubElts;

        M = (NumElts * (1 + InputIdx)) + (M % NumSubElts);

      }

      Mask[i + InsertIdx] = M;

    }

    return true;

  }

  case X86ISD::PINSRB:

  case X86ISD::PINSRW:

  case ISD::SCALAR_TO_VECTOR:

  case ISD::INSERT_VECTOR_ELT: {

    // Match against a insert_vector_elt/scalar_to_vector of an extract from a

    // vector, for matching src/dst vector types.

    SDValue Scl = N.getOperand(Opcode == ISD::SCALAR_TO_VECTOR ? 0 : 1);


    unsigned DstIdx = 0;

    if (Opcode != ISD::SCALAR_TO_VECTOR) {

      // Check we have an in-range constant insertion index.

      if (!isa<ConstantSDNode>(N.getOperand(2)) ||

          N.getConstantOperandAPInt(2).uge(NumElts))

        return false;

      DstIdx = N.getConstantOperandVal(2);


      // Attempt to recognise an INSERT*(VEC, 0, DstIdx) shuffle pattern.

      if (X86::isZeroNode(Scl)) {

        Ops.push_back(N.getOperand(0));

        for (unsigned i = 0; i != NumElts; ++i)

          Mask.push_back(i == DstIdx ? SM_SentinelZero : (int)i);

        return true;

      }

    }


    // Peek through trunc/aext/zext/bitcast.

    // TODO: aext shouldn't require SM_SentinelZero padding.

    // TODO: handle shift of scalars.

    unsigned MinBitsPerElt = Scl.getScalarValueSizeInBits();

    while (Scl.getOpcode() == ISD::TRUNCATE ||

           Scl.getOpcode() == ISD::ANY_EXTEND ||

           Scl.getOpcode() == ISD::ZERO_EXTEND ||

           (Scl.getOpcode() == ISD::BITCAST &&

            Scl.getScalarValueSizeInBits() ==

                Scl.getOperand(0).getScalarValueSizeInBits())) {

      Scl = Scl.getOperand(0);

      MinBitsPerElt =

          std::min<unsigned>(MinBitsPerElt, Scl.getScalarValueSizeInBits());

    }

    if ((MinBitsPerElt % 8) != 0)

      return false;


    // Attempt to find the source vector the scalar was extracted from.

    SDValue SrcExtract;

    if ((Scl.getOpcode() == ISD::EXTRACT_VECTOR_ELT ||

         Scl.getOpcode() == X86ISD::PEXTRW ||

         Scl.getOpcode() == X86ISD::PEXTRB) &&

        Scl.getOperand(0).getValueSizeInBits() == NumSizeInBits) {

      SrcExtract = Scl;

    }

    if (!SrcExtract || !isa<ConstantSDNode>(SrcExtract.getOperand(1)))

      return false;


    SDValue SrcVec = SrcExtract.getOperand(0);

    EVT SrcVT = SrcVec.getValueType();

    if (!SrcVT.getScalarType().isByteSized())

      return false;

    unsigned SrcIdx = SrcExtract.getConstantOperandVal(1);

    unsigned SrcByte = SrcIdx * (SrcVT.getScalarSizeInBits() / 8);

    unsigned DstByte = DstIdx * NumBytesPerElt;

    MinBitsPerElt =

        std::min<unsigned>(MinBitsPerElt, SrcVT.getScalarSizeInBits());


    // Create 'identity' byte level shuffle mask and then add inserted bytes.

    if (Opcode == ISD::SCALAR_TO_VECTOR) {

      Ops.push_back(SrcVec);

      Mask.append(NumSizeInBytes, SM_SentinelUndef);

    } else {

      Ops.push_back(SrcVec);

      Ops.push_back(N.getOperand(0));

      for (int i = 0; i != (int)NumSizeInBytes; ++i)

        Mask.push_back(NumSizeInBytes + i);

    }


    unsigned MinBytesPerElts = MinBitsPerElt / 8;

    MinBytesPerElts = std::min(MinBytesPerElts, NumBytesPerElt);

    for (unsigned i = 0; i != MinBytesPerElts; ++i)

      Mask[DstByte + i] = SrcByte + i;

    for (unsigned i = MinBytesPerElts; i < NumBytesPerElt; ++i)

      Mask[DstByte + i] = SM_SentinelZero;

    return true;

  }

  case X86ISD::PACKSS:

  case X86ISD::PACKUS: {

    SDValue N0 = N.getOperand(0);

    SDValue N1 = N.getOperand(1);

    assert(N0.getValueType().getVectorNumElements() == (NumElts / 2) &&

           N1.getValueType().getVectorNumElements() == (NumElts / 2) &&

           "Unexpected input value type");


    APInt EltsLHS, EltsRHS;

    getPackDemandedElts(VT, DemandedElts, EltsLHS, EltsRHS);


    // If we know input saturation won't happen (or we don't care for particular

    // lanes), we can treat this as a truncation shuffle.

    bool Offset0 = false, Offset1 = false;

    if (Opcode == X86ISD::PACKSS) {

      if ((!(N0.isUndef() || EltsLHS.isZero()) &&

           DAG.ComputeNumSignBits(N0, EltsLHS, Depth + 1) <= NumBitsPerElt) ||

          (!(N1.isUndef() || EltsRHS.isZero()) &&

           DAG.ComputeNumSignBits(N1, EltsRHS, Depth + 1) <= NumBitsPerElt))

        return false;

      // We can't easily fold ASHR into a shuffle, but if it was feeding a

      // PACKSS then it was likely being used for sign-extension for a

      // truncation, so just peek through and adjust the mask accordingly.

      if (N0.getOpcode() == X86ISD::VSRAI && N->isOnlyUserOf(N0.getNode()) &&

          N0.getConstantOperandAPInt(1) == NumBitsPerElt) {

        Offset0 = true;

        N0 = N0.getOperand(0);

      }

      if (N1.getOpcode() == X86ISD::VSRAI && N->isOnlyUserOf(N1.getNode()) &&

          N1.getConstantOperandAPInt(1) == NumBitsPerElt) {

        Offset1 = true;

        N1 = N1.getOperand(0);

      }

    } else {

      APInt ZeroMask = APInt::getHighBitsSet(2 * NumBitsPerElt, NumBitsPerElt);

      if ((!(N0.isUndef() || EltsLHS.isZero()) &&

           !DAG.MaskedValueIsZero(N0, ZeroMask, EltsLHS, Depth + 1)) ||

          (!(N1.isUndef() || EltsRHS.isZero()) &&

           !DAG.MaskedValueIsZero(N1, ZeroMask, EltsRHS, Depth + 1)))

        return false;

    }


    bool IsUnary = (N0 == N1);


    Ops.push_back(N0);

    if (!IsUnary)

      Ops.push_back(N1);


    createPackShuffleMask(VT, Mask, IsUnary);


    if (Offset0 || Offset1) {

      for (int &M : Mask)

        if ((Offset0 && isInRange(M, 0, NumElts)) ||

            (Offset1 && isInRange(M, NumElts, 2 * NumElts)))

          ++M;

    }

    return true;

  }

  case ISD::VSELECT:

  case X86ISD::BLENDV: {

    SDValue Cond = N.getOperand(0);

    if (createShuffleMaskFromVSELECT(Mask, Cond, Opcode == X86ISD::BLENDV)) {

      Ops.push_back(N.getOperand(1));

      Ops.push_back(N.getOperand(2));

      return true;

    }

    return false;

  }

  case X86ISD::VTRUNC: {

    SDValue Src = N.getOperand(0);

    EVT SrcVT = Src.getValueType();

    if (SrcVT.getSizeInBits() != NumSizeInBits)

      return false;

    unsigned NumSrcElts = SrcVT.getVectorNumElements();

    unsigned NumBitsPerSrcElt = SrcVT.getScalarSizeInBits();

    unsigned Scale = NumBitsPerSrcElt / NumBitsPerElt;

    assert((NumBitsPerSrcElt % NumBitsPerElt) == 0 && "Illegal truncation");

    for (unsigned i = 0; i != NumSrcElts; ++i)

      Mask.push_back(i * Scale);

    Mask.append(NumElts - NumSrcElts, SM_SentinelZero);

    Ops.push_back(Src);

    return true;

  }

  case ISD::SHL:

  case ISD::SRL: {

    APInt UndefElts;

    SmallVector<APInt, 32> EltBits;

    if (!getTargetConstantBitsFromNode(N.getOperand(1), NumBitsPerElt,

                                       UndefElts, EltBits,

                                       /*AllowWholeUndefs*/ true,

                                       /*AllowPartialUndefs*/ false))

      return false;


    // We can only decode 'whole byte' bit shifts as shuffles.

    for (unsigned I = 0; I != NumElts; ++I)

      if (DemandedElts[I] && !UndefElts[I] &&

          (EltBits[I].urem(8) != 0 || EltBits[I].uge(NumBitsPerElt)))

        return false;


    Mask.append(NumSizeInBytes, SM_SentinelUndef);

    Ops.push_back(N.getOperand(0));


    for (unsigned I = 0; I != NumElts; ++I) {

      if (!DemandedElts[I] || UndefElts[I])

        continue;

      unsigned ByteShift = EltBits[I].getZExtValue() / 8;

      unsigned Lo = I * NumBytesPerElt;

      unsigned Hi = Lo + NumBytesPerElt;

      // Clear mask to all zeros and insert the shifted byte indices.

      std::fill(Mask.begin() + Lo, Mask.begin() + Hi, SM_SentinelZero);

      if (ISD::SHL == Opcode)

        std::iota(Mask.begin() + Lo + ByteShift, Mask.begin() + Hi, Lo);

      else

        std::iota(Mask.begin() + Lo, Mask.begin() + Hi - ByteShift,

                  Lo + ByteShift);

    }

    return true;

  }

  case X86ISD::VSHLI:

  case X86ISD::VSRLI: {

    uint64_t ShiftVal = N.getConstantOperandVal(1);

    // Out of range bit shifts are guaranteed to be zero.

    if (NumBitsPerElt <= ShiftVal) {

      Mask.append(NumElts, SM_SentinelZero);

      return true;

    }


    // We can only decode 'whole byte' bit shifts as shuffles.

    if ((ShiftVal % 8) != 0)

      break;


    uint64_t ByteShift = ShiftVal / 8;

    Ops.push_back(N.getOperand(0));


    // Clear mask to all zeros and insert the shifted byte indices.

    Mask.append(NumSizeInBytes, SM_SentinelZero);


    if (X86ISD::VSHLI == Opcode) {

      for (unsigned i = 0; i != NumSizeInBytes; i += NumBytesPerElt)

        for (unsigned j = ByteShift; j != NumBytesPerElt; ++j)

          Mask[i + j] = i + j - ByteShift;

    } else {

      for (unsigned i = 0; i != NumSizeInBytes; i += NumBytesPerElt)

        for (unsigned j = ByteShift; j != NumBytesPerElt; ++j)

          Mask[i + j - ByteShift] = i + j;

    }

    return true;

  }

  case ISD::ROTL:

  case ISD::ROTR: {

    APInt UndefElts;

    SmallVector<APInt, 32> EltBits;

    if (!getTargetConstantBitsFromNode(N.getOperand(1), NumBitsPerElt,

                                       UndefElts, EltBits,

                                       /*AllowWholeUndefs*/ true,

                                       /*AllowPartialUndefs*/ false))

      return false;


    // We can only decode 'whole byte' bit rotates as shuffles.

    for (unsigned I = 0; I != NumElts; ++I)

      if (DemandedElts[I] && !UndefElts[I] &&

          (EltBits[I].urem(NumBitsPerElt) % 8) != 0)

        return false;


    Ops.push_back(N.getOperand(0));

    for (unsigned I = 0; I != NumElts; ++I) {

      if (!DemandedElts[I] || UndefElts[I]) {

        Mask.append(NumBytesPerElt, SM_SentinelUndef);

        continue;

      }

      int Offset = EltBits[I].urem(NumBitsPerElt) / 8;

      Offset = (ISD::ROTL == Opcode ? NumBytesPerElt - Offset : Offset);

      int BaseIdx = I * NumBytesPerElt;

      for (int J = 0; J != (int)NumBytesPerElt; ++J) {

        Mask.push_back(BaseIdx + ((Offset + J) % NumBytesPerElt));

      }

    }

    return true;

  }

  case X86ISD::VROTLI:

  case X86ISD::VROTRI: {

    // We can only decode 'whole byte' bit rotates as shuffles.

    uint64_t RotateVal = N.getConstantOperandAPInt(1).urem(NumBitsPerElt);

    if ((RotateVal % 8) != 0)

      return false;

    Ops.push_back(N.getOperand(0));

    int Offset = RotateVal / 8;

    Offset = (X86ISD::VROTLI == Opcode ? NumBytesPerElt - Offset : Offset);

    for (int i = 0; i != (int)NumElts; ++i) {

      int BaseIdx = i * NumBytesPerElt;

      for (int j = 0; j != (int)NumBytesPerElt; ++j) {

        Mask.push_back(BaseIdx + ((Offset + j) % NumBytesPerElt));

      }

    }

    return true;

  }

  case X86ISD::VBROADCAST: {

    SDValue Src = N.getOperand(0);

    if (!Src.getSimpleValueType().isVector()) {

      if (Src.getOpcode() != ISD::EXTRACT_VECTOR_ELT ||

          !isNullConstant(Src.getOperand(1)) ||

          Src.getOperand(0).getValueType().getScalarType() !=

              VT.getScalarType())

        return false;

      Src = Src.getOperand(0);

    }

    Ops.push_back(Src);

    Mask.append(NumElts, 0);

    return true;

  }

  case ISD::SIGN_EXTEND_VECTOR_INREG: {

    SDValue Src = N.getOperand(0);

    EVT SrcVT = Src.getValueType();

    unsigned NumBitsPerSrcElt = SrcVT.getScalarSizeInBits();


    // Extended source must be a simple vector.

    if (!SrcVT.isSimple() || (SrcVT.getSizeInBits() % 128) != 0 ||

        (NumBitsPerSrcElt % 8) != 0)

      return false;


    // We can only handle all-signbits extensions.

    APInt DemandedSrcElts =

        DemandedElts.zextOrTrunc(SrcVT.getVectorNumElements());

    if (DAG.ComputeNumSignBits(Src, DemandedSrcElts) != NumBitsPerSrcElt)

      return false;


    assert((NumBitsPerElt % NumBitsPerSrcElt) == 0 && "Unexpected extension");

    unsigned Scale = NumBitsPerElt / NumBitsPerSrcElt;

    for (unsigned I = 0; I != NumElts; ++I)

      Mask.append(Scale, I);

    Ops.push_back(Src);

    return true;

  }

  case ISD::ZERO_EXTEND:

  case ISD::ANY_EXTEND:

  case ISD::ZERO_EXTEND_VECTOR_INREG:

  case ISD::ANY_EXTEND_VECTOR_INREG: {

    SDValue Src = N.getOperand(0);

    EVT SrcVT = Src.getValueType();


    // Extended source must be a simple vector.

    if (!SrcVT.isSimple() || (SrcVT.getSizeInBits() % 128) != 0 ||

        (SrcVT.getScalarSizeInBits() % 8) != 0)

      return false;


    bool IsAnyExtend =

        (ISD::ANY_EXTEND == Opcode || ISD::ANY_EXTEND_VECTOR_INREG == Opcode);

    DecodeZeroExtendMask(SrcVT.getScalarSizeInBits(), NumBitsPerElt, NumElts,

                         IsAnyExtend, Mask);

    Ops.push_back(Src);

    return true;

  }

  }


  return false;

}


/// Removes unused/repeated shuffle source inputs and adjusts the shuffle mask.


static void resolveTargetShuffleInputsAndMask(SmallVectorImpl<SDValue> &Inputs,

                                              SmallVectorImpl<int> &Mask) {

  int MaskWidth = Mask.size();

  SmallVector<SDValue, 16> UsedInputs;

  for (int i = 0, e = Inputs.size(); i < e; ++i) {

    int lo = UsedInputs.size() * MaskWidth;

    int hi = lo + MaskWidth;


    // Strip UNDEF input usage.

    if (Inputs[i].isUndef())

      for (int &M : Mask)

        if ((lo <= M) && (M < hi))

          M = SM_SentinelUndef;


    // Check for unused inputs.

    if (none_of(Mask, [lo, hi](int i) { return (lo <= i) && (i < hi); })) {

      for (int &M : Mask)

        if (lo <= M)

          M -= MaskWidth;

      continue;

    }


    // Check for repeated inputs.

    bool IsRepeat = false;

    for (int j = 0, ue = UsedInputs.size(); j != ue; ++j) {

      if (UsedInputs[j] != Inputs[i])

        continue;

      for (int &M : Mask)

        if (lo <= M)

          M = (M < hi) ? ((M - lo) + (j * MaskWidth)) : (M - MaskWidth);

      IsRepeat = true;

      break;

    }

    if (IsRepeat)

      continue;


    UsedInputs.push_back(Inputs[i]);

  }

  Inputs = std::move(UsedInputs);

}


/// Calls getTargetShuffleAndZeroables to resolve a target shuffle mask's inputs

/// and then sets the SM_SentinelUndef and SM_SentinelZero values.

/// Returns true if the target shuffle mask was decoded.


static bool getTargetShuffleInputs(SDValue Op, const APInt &DemandedElts,

                                   SmallVectorImpl<SDValue> &Inputs,

                                   SmallVectorImpl<int> &Mask,

                                   APInt &KnownUndef, APInt &KnownZero,

                                   const SelectionDAG &DAG, unsigned Depth,

                                   bool ResolveKnownElts) {

  if (Depth >= SelectionDAG::MaxRecursionDepth)

    return false; // Limit search depth.


  EVT VT = Op.getValueType();

  if (!VT.isSimple() || !VT.isVector())

    return false;


  if (getTargetShuffleAndZeroables(Op, Mask, Inputs, KnownUndef, KnownZero)) {

    if (ResolveKnownElts)

      resolveTargetShuffleFromZeroables(Mask, KnownUndef, KnownZero);

    return true;

  }

  if (getFauxShuffleMask(Op, DemandedElts, Mask, Inputs, DAG, Depth,

                         ResolveKnownElts)) {

    resolveZeroablesFromTargetShuffle(Mask, KnownUndef, KnownZero);

    return true;

  }

  return false;

}


static bool getTargetShuffleInputs(SDValue Op, const APInt &DemandedElts,

                                   SmallVectorImpl<SDValue> &Inputs,

                                   SmallVectorImpl<int> &Mask,

                                   const SelectionDAG &DAG, unsigned Depth,

                                   bool ResolveKnownElts) {

  APInt KnownUndef, KnownZero;

  return getTargetShuffleInputs(Op, DemandedElts, Inputs, Mask, KnownUndef,

                                KnownZero, DAG, Depth, ResolveKnownElts);

}


static bool getTargetShuffleInputs(SDValue Op, SmallVectorImpl<SDValue> &Inputs,

                                   SmallVectorImpl<int> &Mask,

                                   const SelectionDAG &DAG, unsigned Depth = 0,

                                   bool ResolveKnownElts = true) {

  EVT VT = Op.getValueType();

  if (!VT.isSimple() || !VT.isVector())

    return false;


  unsigned NumElts = Op.getValueType().getVectorNumElements();

  APInt DemandedElts = APInt::getAllOnes(NumElts);

  return getTargetShuffleInputs(Op, DemandedElts, Inputs, Mask, DAG, Depth,

                                ResolveKnownElts);

}


// Attempt to create a scalar/subvector broadcast from the base MemSDNode.


static SDValue getBROADCAST_LOAD(unsigned Opcode, const SDLoc &DL, EVT VT,

                                 EVT MemVT, MemSDNode *Mem, unsigned Offset,

                                 SelectionDAG &DAG) {

  assert((Opcode == X86ISD::VBROADCAST_LOAD ||

          Opcode == X86ISD::SUBV_BROADCAST_LOAD) &&

         "Unknown broadcast load type");


  // Ensure this is a simple (non-atomic, non-voltile), temporal read memop.

  if (!Mem || !Mem->readMem() || !Mem->isSimple() || Mem->isNonTemporal())

    return SDValue();


  SDValue Ptr = DAG.getMemBasePlusOffset(Mem->getBasePtr(),

                                         TypeSize::getFixed(Offset), DL);

  SDVTList Tys = DAG.getVTList(VT, MVT::Other);

  SDValue Ops[] = {Mem->getChain(), Ptr};

  SDValue BcstLd = DAG.getMemIntrinsicNode(

      Opcode, DL, Tys, Ops, MemVT,

      DAG.getMachineFunction().getMachineMemOperand(

          Mem->getMemOperand(), Offset, MemVT.getStoreSize()));

  DAG.makeEquivalentMemoryOrdering(SDValue(Mem, 1), BcstLd.getValue(1));

  return BcstLd;

}


/// Returns the scalar element that will make up the i'th

/// element of the result of the vector shuffle.


static SDValue getShuffleScalarElt(SDValue Op, unsigned Index,

                                   SelectionDAG &DAG, unsigned Depth) {

  if (Depth >= SelectionDAG::MaxRecursionDepth)

    return SDValue(); // Limit search depth.


  EVT VT = Op.getValueType();

  unsigned Opcode = Op.getOpcode();

  unsigned NumElems = VT.getVectorNumElements();


  // Recurse into ISD::VECTOR_SHUFFLE node to find scalars.

  if (auto *SV = dyn_cast<ShuffleVectorSDNode>(Op)) {

    int Elt = SV->getMaskElt(Index);


    if (Elt < 0)

      return DAG.getUNDEF(VT.getVectorElementType());


    SDValue Src = (Elt < (int)NumElems) ? SV->getOperand(0) : SV->getOperand(1);

    return getShuffleScalarElt(Src, Elt % NumElems, DAG, Depth + 1);

  }


  // Recurse into target specific vector shuffles to find scalars.

  if (isTargetShuffle(Opcode)) {

    MVT ShufVT = VT.getSimpleVT();

    MVT ShufSVT = ShufVT.getVectorElementType();

    int NumElems = (int)ShufVT.getVectorNumElements();

    SmallVector<int, 16> ShuffleMask;

    SmallVector<SDValue, 16> ShuffleOps;

    if (!getTargetShuffleMask(Op, true, ShuffleOps, ShuffleMask))

      return SDValue();


    int Elt = ShuffleMask[Index];

    if (Elt == SM_SentinelZero)

      return ShufSVT.isInteger() ? DAG.getConstant(0, SDLoc(Op), ShufSVT)

                                 : DAG.getConstantFP(+0.0, SDLoc(Op), ShufSVT);

    if (Elt == SM_SentinelUndef)

      return DAG.getUNDEF(ShufSVT);


    assert(0 <= Elt && Elt < (2 * NumElems) && "Shuffle index out of range");

    SDValue Src = (Elt < NumElems) ? ShuffleOps[0] : ShuffleOps[1];

    return getShuffleScalarElt(Src, Elt % NumElems, DAG, Depth + 1);

  }


  // Recurse into insert_subvector base/sub vector to find scalars.

  if (Opcode == ISD::INSERT_SUBVECTOR) {

    SDValue Vec = Op.getOperand(0);

    SDValue Sub = Op.getOperand(1);

    uint64_t SubIdx = Op.getConstantOperandVal(2);

    unsigned NumSubElts = Sub.getValueType().getVectorNumElements();


    if (SubIdx <= Index && Index < (SubIdx + NumSubElts))

      return getShuffleScalarElt(Sub, Index - SubIdx, DAG, Depth + 1);

    return getShuffleScalarElt(Vec, Index, DAG, Depth + 1);

  }


  // Recurse into concat_vectors sub vector to find scalars.

  if (Opcode == ISD::CONCAT_VECTORS) {

    EVT SubVT = Op.getOperand(0).getValueType();

    unsigned NumSubElts = SubVT.getVectorNumElements();

    uint64_t SubIdx = Index / NumSubElts;

    uint64_t SubElt = Index % NumSubElts;

    return getShuffleScalarElt(Op.getOperand(SubIdx), SubElt, DAG, Depth + 1);

  }


  // Recurse into extract_subvector src vector to find scalars.

  if (Opcode == ISD::EXTRACT_SUBVECTOR) {

    SDValue Src = Op.getOperand(0);

    uint64_t SrcIdx = Op.getConstantOperandVal(1);

    return getShuffleScalarElt(Src, Index + SrcIdx, DAG, Depth + 1);

  }


  // We only peek through bitcasts of the same vector width.

  if (Opcode == ISD::BITCAST) {

    SDValue Src = Op.getOperand(0);

    EVT SrcVT = Src.getValueType();

    if (SrcVT.isVector() && SrcVT.getVectorNumElements() == NumElems)

      return getShuffleScalarElt(Src, Index, DAG, Depth + 1);

    return SDValue();

  }


  // Actual nodes that may contain scalar elements


  // For insert_vector_elt - either return the index matching scalar or recurse

  // into the base vector.

  if (Opcode == ISD::INSERT_VECTOR_ELT &&

      isa<ConstantSDNode>(Op.getOperand(2))) {

    if (Op.getConstantOperandAPInt(2) == Index)

      return Op.getOperand(1);

    return getShuffleScalarElt(Op.getOperand(0), Index, DAG, Depth + 1);

  }


  if (Opcode == ISD::SCALAR_TO_VECTOR)

    return (Index == 0) ? Op.getOperand(0)

                        : DAG.getUNDEF(VT.getVectorElementType());


  if (Opcode == ISD::BUILD_VECTOR)

    return Op.getOperand(Index);


  return SDValue();

}


// Use PINSRB/PINSRW/PINSRD to create a build vector.


static SDValue LowerBuildVectorAsInsert(SDValue Op, const SDLoc &DL,

                                        const APInt &NonZeroMask,

                                        unsigned NumNonZero, unsigned NumZero,

                                        SelectionDAG &DAG,

                                        const X86Subtarget &Subtarget) {

  MVT VT = Op.getSimpleValueType();

  unsigned NumElts = VT.getVectorNumElements();

  assert(((VT == MVT::v8i16 && Subtarget.hasSSE2()) ||

          ((VT == MVT::v16i8 || VT == MVT::v4i32) && Subtarget.hasSSE41())) &&

         "Illegal vector insertion");


  SDValue V;

  bool First = true;


  for (unsigned i = 0; i < NumElts; ++i) {

    bool IsNonZero = NonZeroMask[i];

    if (!IsNonZero)

      continue;


    // If the build vector contains zeros or our first insertion is not the

    // first index then insert into zero vector to break any register

    // dependency else use SCALAR_TO_VECTOR.

    if (First) {

      First = false;

      if (NumZero || 0 != i)

        V = getZeroVector(VT, Subtarget, DAG, DL);

      else {

        assert(0 == i && "Expected insertion into zero-index");

        V = DAG.getAnyExtOrTrunc(Op.getOperand(i), DL, MVT::i32);

        V = DAG.getNode(ISD::SCALAR_TO_VECTOR, DL, MVT::v4i32, V);

        V = DAG.getBitcast(VT, V);

        continue;

      }

    }

    V = DAG.getNode(ISD::INSERT_VECTOR_ELT, DL, VT, V, Op.getOperand(i),

                    DAG.getVectorIdxConstant(i, DL));

  }


  return V;

}


/// Custom lower build_vector of v16i8.


static SDValue LowerBuildVectorv16i8(SDValue Op, const SDLoc &DL,

                                     const APInt &NonZeroMask,

                                     unsigned NumNonZero, unsigned NumZero,

                                     SelectionDAG &DAG,

                                     const X86Subtarget &Subtarget) {

  if (NumNonZero > 8 && !Subtarget.hasSSE41())

    return SDValue();


  // SSE4.1 - use PINSRB to insert each byte directly.

  if (Subtarget.hasSSE41())

    return LowerBuildVectorAsInsert(Op, DL, NonZeroMask, NumNonZero, NumZero,

                                    DAG, Subtarget);


  SDValue V;


  // Pre-SSE4.1 - merge byte pairs and insert with PINSRW.

  // If both the lowest 16-bits are non-zero, then convert to MOVD.

  if (!NonZeroMask.extractBits(2, 0).isZero() &&

      !NonZeroMask.extractBits(2, 2).isZero()) {

    for (unsigned I = 0; I != 4; ++I) {

      if (!NonZeroMask[I])

        continue;

      SDValue Elt = DAG.getZExtOrTrunc(Op.getOperand(I), DL, MVT::i32);

      if (I != 0)

        Elt = DAG.getNode(ISD::SHL, DL, MVT::i32, Elt,

                          DAG.getConstant(I * 8, DL, MVT::i8));

      V = V ? DAG.getNode(ISD::OR, DL, MVT::i32, V, Elt) : Elt;

    }

    assert(V && "Failed to fold v16i8 vector to zero");

    V = DAG.getNode(ISD::SCALAR_TO_VECTOR, DL, MVT::v4i32, V);

    V = DAG.getNode(X86ISD::VZEXT_MOVL, DL, MVT::v4i32, V);

    V = DAG.getBitcast(MVT::v8i16, V);

  }

  for (unsigned i = V ? 4 : 0; i < 16; i += 2) {

    bool ThisIsNonZero = NonZeroMask[i];

    bool NextIsNonZero = NonZeroMask[i + 1];

    if (!ThisIsNonZero && !NextIsNonZero)

      continue;


    SDValue Elt;

    if (ThisIsNonZero) {

      if (NumZero || NextIsNonZero)

        Elt = DAG.getZExtOrTrunc(Op.getOperand(i), DL, MVT::i32);

      else

        Elt = DAG.getAnyExtOrTrunc(Op.getOperand(i), DL, MVT::i32);

    }


    if (NextIsNonZero) {

      SDValue NextElt = Op.getOperand(i + 1);

      if (i == 0 && NumZero)

        NextElt = DAG.getZExtOrTrunc(NextElt, DL, MVT::i32);

      else

        NextElt = DAG.getAnyExtOrTrunc(NextElt, DL, MVT::i32);

      NextElt = DAG.getNode(ISD::SHL, DL, MVT::i32, NextElt,

                            DAG.getConstant(8, DL, MVT::i8));

      if (ThisIsNonZero)

        Elt = DAG.getNode(ISD::OR, DL, MVT::i32, NextElt, Elt);

      else

        Elt = NextElt;

    }


    // If our first insertion is not the first index or zeros are needed, then

    // insert into zero vector. Otherwise, use SCALAR_TO_VECTOR (leaves high

    // elements undefined).

    if (!V) {

      if (i != 0 || NumZero)

        V = getZeroVector(MVT::v8i16, Subtarget, DAG, DL);

      else {

        V = DAG.getNode(ISD::SCALAR_TO_VECTOR, DL, MVT::v4i32, Elt);

        V = DAG.getBitcast(MVT::v8i16, V);

        continue;

      }

    }

    Elt = DAG.getNode(ISD::TRUNCATE, DL, MVT::i16, Elt);

    V = DAG.getNode(ISD::INSERT_VECTOR_ELT, DL, MVT::v8i16, V, Elt,

                    DAG.getVectorIdxConstant(i / 2, DL));

  }


  return DAG.getBitcast(MVT::v16i8, V);

}


/// Custom lower build_vector of v8i16.


static SDValue LowerBuildVectorv8i16(SDValue Op, const SDLoc &DL,

                                     const APInt &NonZeroMask,

                                     unsigned NumNonZero, unsigned NumZero,

                                     SelectionDAG &DAG,

                                     const X86Subtarget &Subtarget) {

  if (NumNonZero > 4 && !Subtarget.hasSSE41())

    return SDValue();


  // Use PINSRW to insert each byte directly.

  return LowerBuildVectorAsInsert(Op, DL, NonZeroMask, NumNonZero, NumZero, DAG,

                                  Subtarget);

}


/// Custom lower build_vector of v4i32 or v4f32.


static SDValue LowerBuildVectorv4x32(SDValue Op, const SDLoc &DL,

                                     SelectionDAG &DAG,

                                     const X86Subtarget &Subtarget) {

  // If this is a splat of a pair of elements, use MOVDDUP (unless the target

  // has XOP; in that case defer lowering to potentially use VPERMIL2PS).

  // Because we're creating a less complicated build vector here, we may enable

  // further folding of the MOVDDUP via shuffle transforms.

  if (Subtarget.hasSSE3() && !Subtarget.hasXOP() &&

      Op.getOperand(0) == Op.getOperand(2) &&

      Op.getOperand(1) == Op.getOperand(3) &&

      Op.getOperand(0) != Op.getOperand(1)) {

    MVT VT = Op.getSimpleValueType();

    MVT EltVT = VT.getVectorElementType();

    // Create a new build vector with the first 2 elements followed by undef

    // padding, bitcast to v2f64, duplicate, and bitcast back.

    SDValue Ops[4] = { Op.getOperand(0), Op.getOperand(1),

                       DAG.getUNDEF(EltVT), DAG.getUNDEF(EltVT) };

    SDValue NewBV = DAG.getBitcast(MVT::v2f64, DAG.getBuildVector(VT, DL, Ops));

    SDValue Dup = DAG.getNode(X86ISD::MOVDDUP, DL, MVT::v2f64, NewBV);

    return DAG.getBitcast(VT, Dup);

  }


  // Find all zeroable elements.

  std::bitset<4> Zeroable, Undefs;

  for (int i = 0; i < 4; ++i) {

    SDValue Elt = Op.getOperand(i);

    Undefs[i] = Elt.isUndef();

    Zeroable[i] = (Elt.isUndef() || X86::isZeroNode(Elt));

  }

  assert(Zeroable.size() - Zeroable.count() > 1 &&

         "We expect at least two non-zero elements!");


  // We only know how to deal with build_vector nodes where elements are either

  // zeroable or extract_vector_elt with constant index.

  SDValue FirstNonZero;

  unsigned FirstNonZeroIdx;

  for (unsigned i = 0; i < 4; ++i) {

    if (Zeroable[i])

      continue;

    SDValue Elt = Op.getOperand(i);

    if (Elt.getOpcode() != ISD::EXTRACT_VECTOR_ELT ||

        !isa<ConstantSDNode>(Elt.getOperand(1)))

      return SDValue();

    // Make sure that this node is extracting from a 128-bit vector.

    MVT VT = Elt.getOperand(0).getSimpleValueType();

    if (!VT.is128BitVector())

      return SDValue();

    if (!FirstNonZero.getNode()) {

      FirstNonZero = Elt;

      FirstNonZeroIdx = i;

    }

  }


  assert(FirstNonZero.getNode() && "Unexpected build vector of all zeros!");

  SDValue V1 = FirstNonZero.getOperand(0);

  MVT VT = V1.getSimpleValueType();


  // See if this build_vector can be lowered as a blend with zero.

  SDValue Elt;

  unsigned EltMaskIdx, EltIdx;

  int Mask[4];

  for (EltIdx = 0; EltIdx < 4; ++EltIdx) {

    if (Zeroable[EltIdx]) {

      // The zero vector will be on the right hand side.

      Mask[EltIdx] = EltIdx+4;

      continue;

    }


    Elt = Op->getOperand(EltIdx);

    // By construction, Elt is a EXTRACT_VECTOR_ELT with constant index.

    EltMaskIdx = Elt.getConstantOperandVal(1);

    if (Elt.getOperand(0) != V1 || EltMaskIdx != EltIdx)

      break;

    Mask[EltIdx] = EltIdx;

  }


  if (EltIdx == 4) {

    // Let the shuffle legalizer deal with blend operations.

    SDValue VZeroOrUndef = (Zeroable == Undefs)

                               ? DAG.getUNDEF(VT)

                               : getZeroVector(VT, Subtarget, DAG, DL);

    if (V1.getSimpleValueType() != VT)

      V1 = DAG.getBitcast(VT, V1);

    return DAG.getVectorShuffle(VT, SDLoc(V1), V1, VZeroOrUndef, Mask);

  }


  // See if we can lower this build_vector to a INSERTPS.

  if (!Subtarget.hasSSE41())

    return SDValue();


  SDValue V2 = Elt.getOperand(0);

  if (Elt == FirstNonZero && EltIdx == FirstNonZeroIdx)

    V1 = SDValue();


  bool CanFold = true;

  for (unsigned i = EltIdx + 1; i < 4 && CanFold; ++i) {

    if (Zeroable[i])

      continue;


    SDValue Current = Op->getOperand(i);

    SDValue SrcVector = Current->getOperand(0);

    if (!V1.getNode())

      V1 = SrcVector;

    CanFold = (SrcVector == V1) && (Current.getConstantOperandAPInt(1) == i);

  }


  if (!CanFold)

    return SDValue();


  assert(V1.getNode() && "Expected at least two non-zero elements!");

  if (V1.getSimpleValueType() != MVT::v4f32)

    V1 = DAG.getBitcast(MVT::v4f32, V1);

  if (V2.getSimpleValueType() != MVT::v4f32)

    V2 = DAG.getBitcast(MVT::v4f32, V2);


  // Ok, we can emit an INSERTPS instruction.

  unsigned ZMask = Zeroable.to_ulong();


  unsigned InsertPSMask = EltMaskIdx << 6 | EltIdx << 4 | ZMask;

  assert((InsertPSMask & ~0xFFu) == 0 && "Invalid mask!");

  SDValue Result =

      DAG.getNode(X86ISD::INSERTPS, DL, MVT::v4f32, V1, V2,

                  DAG.getTargetConstant(InsertPSMask, DL, MVT::i8));

  return DAG.getBitcast(VT, Result);

}


/// Return a vector logical shift node.


static SDValue getVShift(bool isLeft, EVT VT, SDValue SrcOp, unsigned NumBits,

                         SelectionDAG &DAG, const TargetLowering &TLI,

                         const SDLoc &dl) {

  assert(VT.is128BitVector() && "Unknown type for VShift");

  MVT ShVT = MVT::v16i8;

  unsigned Opc = isLeft ? X86ISD::VSHLDQ : X86ISD::VSRLDQ;

  SrcOp = DAG.getBitcast(ShVT, SrcOp);

  assert(NumBits % 8 == 0 && "Only support byte sized shifts");

  SDValue ShiftVal = DAG.getTargetConstant(NumBits / 8, dl, MVT::i8);

  return DAG.getBitcast(VT, DAG.getNode(Opc, dl, ShVT, SrcOp, ShiftVal));

}


static SDValue LowerAsSplatVectorLoad(SDValue SrcOp, MVT VT, const SDLoc &dl,

                                      SelectionDAG &DAG) {


  // Check if the scalar load can be widened into a vector load. And if

  // the address is "base + cst" see if the cst can be "absorbed" into

  // the shuffle mask.

  if (LoadSDNode *LD = dyn_cast<LoadSDNode>(SrcOp)) {

    SDValue Ptr = LD->getBasePtr();

    if (!ISD::isNormalLoad(LD) || !LD->isSimple())

      return SDValue();

    EVT PVT = LD->getValueType(0);

    if (PVT != MVT::i32 && PVT != MVT::f32)

      return SDValue();


    int FI = -1;

    int64_t Offset = 0;

    if (FrameIndexSDNode *FINode = dyn_cast<FrameIndexSDNode>(Ptr)) {

      FI = FINode->getIndex();

      Offset = 0;

    } else if (DAG.isBaseWithConstantOffset(Ptr) &&

               isa<FrameIndexSDNode>(Ptr.getOperand(0))) {

      FI = cast<FrameIndexSDNode>(Ptr.getOperand(0))->getIndex();

      Offset = Ptr.getConstantOperandVal(1);

      Ptr = Ptr.getOperand(0);

    } else {

      return SDValue();

    }


    // FIXME: 256-bit vector instructions don't require a strict alignment,

    // improve this code to support it better.

    Align RequiredAlign(VT.getSizeInBits() / 8);

    SDValue Chain = LD->getChain();

    // Make sure the stack object alignment is at least 16 or 32.

    MachineFrameInfo &MFI = DAG.getMachineFunction().getFrameInfo();

    MaybeAlign InferredAlign = DAG.InferPtrAlign(Ptr);

    if (!InferredAlign || *InferredAlign < RequiredAlign) {

      if (MFI.isFixedObjectIndex(FI)) {

        // Can't change the alignment. FIXME: It's possible to compute

        // the exact stack offset and reference FI + adjust offset instead.

        // If someone *really* cares about this. That's the way to implement it.

        return SDValue();

      } else {

        MFI.setObjectAlignment(FI, RequiredAlign);

      }

    }


    // (Offset % 16 or 32) must be multiple of 4. Then address is then

    // Ptr + (Offset & ~15).

    if (Offset < 0)

      return SDValue();

    if ((Offset % RequiredAlign.value()) & 3)

      return SDValue();

    int64_t StartOffset = Offset & ~int64_t(RequiredAlign.value() - 1);

    if (StartOffset) {

      SDLoc DL(Ptr);

      Ptr = DAG.getNode(ISD::ADD, DL, Ptr.getValueType(), Ptr,

                        DAG.getConstant(StartOffset, DL, Ptr.getValueType()));

    }


    int EltNo = (Offset - StartOffset) >> 2;

    unsigned NumElems = VT.getVectorNumElements();


    EVT NVT = EVT::getVectorVT(*DAG.getContext(), PVT, NumElems);

    SDValue V1 = DAG.getLoad(NVT, dl, Chain, Ptr,

                             LD->getPointerInfo().getWithOffset(StartOffset));


    SmallVector<int, 8> Mask(NumElems, EltNo);


    return DAG.getVectorShuffle(NVT, dl, V1, DAG.getUNDEF(NVT), Mask);

  }


  return SDValue();

}


// Recurse to find a LoadSDNode source and the accumulated ByteOffest.


static bool findEltLoadSrc(SDValue Elt, LoadSDNode *&Ld, int64_t &ByteOffset) {

  if (ISD::isNON_EXTLoad(Elt.getNode())) {

    auto *BaseLd = cast<LoadSDNode>(Elt);

    if (!BaseLd->isSimple())

      return false;

    Ld = BaseLd;

    ByteOffset = 0;

    return true;

  }


  switch (Elt.getOpcode()) {

  case ISD::BITCAST:

  case ISD::TRUNCATE:

  case ISD::SCALAR_TO_VECTOR:

    return findEltLoadSrc(Elt.getOperand(0), Ld, ByteOffset);

  case ISD::SRL:

    if (auto *AmtC = dyn_cast<ConstantSDNode>(Elt.getOperand(1))) {

      uint64_t Amt = AmtC->getZExtValue();

      if ((Amt % 8) == 0 && findEltLoadSrc(Elt.getOperand(0), Ld, ByteOffset)) {

        ByteOffset += Amt / 8;

        return true;

      }

    }

    break;

  case ISD::EXTRACT_VECTOR_ELT:

    if (auto *IdxC = dyn_cast<ConstantSDNode>(Elt.getOperand(1))) {

      SDValue Src = Elt.getOperand(0);

      unsigned SrcSizeInBits = Src.getScalarValueSizeInBits();

      unsigned DstSizeInBits = Elt.getScalarValueSizeInBits();

      if (DstSizeInBits == SrcSizeInBits && (SrcSizeInBits % 8) == 0 &&

          findEltLoadSrc(Src, Ld, ByteOffset)) {

        uint64_t Idx = IdxC->getZExtValue();

        ByteOffset += Idx * (SrcSizeInBits / 8);

        return true;

      }

    }

    break;

  }


  return false;

}


/// Given the initializing elements 'Elts' of a vector of type 'VT', see if the

/// elements can be replaced by a single large load which has the same value as

/// a build_vector or insert_subvector whose loaded operands are 'Elts'.

///

/// Example: <load i32 *a, load i32 *a+4, zero, undef> -> zextload a


static SDValue EltsFromConsecutiveLoads(EVT VT, ArrayRef<SDValue> Elts,

                                        const SDLoc &DL, SelectionDAG &DAG,

                                        const X86Subtarget &Subtarget,

                                        bool IsAfterLegalize,

                                        unsigned Depth = 0) {

  if (Depth >= SelectionDAG::MaxRecursionDepth)

    return SDValue(); // Limit search depth.

  if ((VT.getScalarSizeInBits() % 8) != 0)

    return SDValue();


  unsigned NumElems = Elts.size();


  int LastLoadedElt = -1;

  APInt LoadMask = APInt::getZero(NumElems);

  APInt ZeroMask = APInt::getZero(NumElems);

  APInt UndefMask = APInt::getZero(NumElems);


  SmallVector<LoadSDNode*, 8> Loads(NumElems, nullptr);

  SmallVector<int64_t, 8> ByteOffsets(NumElems, 0);


  // For each element in the initializer, see if we've found a load, zero or an

  // undef.

  for (unsigned i = 0; i < NumElems; ++i) {

    SDValue Elt = peekThroughBitcasts(Elts[i]);

    if (!Elt.getNode())

      return SDValue();

    if (Elt.isUndef()) {

      UndefMask.setBit(i);

      continue;

    }

    if (X86::isZeroNode(Elt) || ISD::isBuildVectorAllZeros(Elt.getNode())) {

      ZeroMask.setBit(i);

      continue;

    }


    // Each loaded element must be the correct fractional portion of the

    // requested vector load.

    unsigned EltSizeInBits = Elt.getValueSizeInBits();

    if ((NumElems * EltSizeInBits) != VT.getSizeInBits())

      return SDValue();


    if (!findEltLoadSrc(Elt, Loads[i], ByteOffsets[i]) || ByteOffsets[i] < 0)

      return SDValue();

    unsigned LoadSizeInBits = Loads[i]->getValueSizeInBits(0);

    if (((ByteOffsets[i] * 8) + EltSizeInBits) > LoadSizeInBits)

      return SDValue();


    LoadMask.setBit(i);

    LastLoadedElt = i;

  }

  assert((ZeroMask.popcount() + UndefMask.popcount() + LoadMask.popcount()) ==

             NumElems &&

         "Incomplete element masks");


  // Handle Special Cases - all undef or undef/zero.

  if (UndefMask.popcount() == NumElems)

    return DAG.getUNDEF(VT);

  if ((ZeroMask.popcount() + UndefMask.popcount()) == NumElems)

    return VT.isInteger() ? DAG.getConstant(0, DL, VT)

                          : DAG.getConstantFP(0.0, DL, VT);


  const TargetLowering &TLI = DAG.getTargetLoweringInfo();

  int FirstLoadedElt = LoadMask.countr_zero();

  SDValue EltBase = peekThroughBitcasts(Elts[FirstLoadedElt]);

  EVT EltBaseVT = EltBase.getValueType();

  assert(EltBaseVT.getSizeInBits() == EltBaseVT.getStoreSizeInBits() &&

         "Register/Memory size mismatch");

  LoadSDNode *LDBase = Loads[FirstLoadedElt];

  assert(LDBase && "Did not find base load for merging consecutive loads");

  unsigned BaseSizeInBits = EltBaseVT.getStoreSizeInBits();

  unsigned BaseSizeInBytes = BaseSizeInBits / 8;

  int NumLoadedElts = (1 + LastLoadedElt - FirstLoadedElt);

  int LoadSizeInBits = NumLoadedElts * BaseSizeInBits;

  assert((BaseSizeInBits % 8) == 0 && "Sub-byte element loads detected");


  // TODO: Support offsetting the base load.

  if (ByteOffsets[FirstLoadedElt] != 0)

    return SDValue();


  // Check to see if the element's load is consecutive to the base load

  // or offset from a previous (already checked) load.

  auto CheckConsecutiveLoad = [&](LoadSDNode *Base, int EltIdx) {

    LoadSDNode *Ld = Loads[EltIdx];

    int64_t ByteOffset = ByteOffsets[EltIdx];

    if (ByteOffset && (ByteOffset % BaseSizeInBytes) == 0) {

      int64_t BaseIdx = EltIdx - (ByteOffset / BaseSizeInBytes);

      return (0 <= BaseIdx && BaseIdx < (int)NumElems && LoadMask[BaseIdx] &&

              Loads[BaseIdx] == Ld && ByteOffsets[BaseIdx] == 0);

    }

    int Stride = EltIdx - FirstLoadedElt;

    if (DAG.areNonVolatileConsecutiveLoads(Ld, Base, BaseSizeInBytes, Stride))

      return true;

    // Try again using the memory load size (we might have broken a large load

    // into smaller elements), ensure the stride is the full memory load size

    // apart and a whole number of elements fit in each memory load.

    unsigned BaseMemSizeInBits = Base->getMemoryVT().getSizeInBits();

    if (((Stride * BaseSizeInBits) % BaseMemSizeInBits) == 0 &&

        (BaseMemSizeInBits % BaseSizeInBits) == 0) {

      unsigned Scale = BaseMemSizeInBits / BaseSizeInBits;

      return DAG.areNonVolatileConsecutiveLoads(Ld, Base, BaseMemSizeInBits / 8,

                                                Stride / Scale);

    }

    return false;

  };


  // Consecutive loads can contain UNDEFS but not ZERO elements.

  // Consecutive loads with UNDEFs and ZEROs elements require a

  // an additional shuffle stage to clear the ZERO elements.

  bool IsConsecutiveLoad = true;

  bool IsConsecutiveLoadWithZeros = true;

  for (int i = FirstLoadedElt + 1; i <= LastLoadedElt; ++i) {

    if (LoadMask[i]) {

      if (!CheckConsecutiveLoad(LDBase, i)) {

        IsConsecutiveLoad = false;

        IsConsecutiveLoadWithZeros = false;

        break;

      }

    } else if (ZeroMask[i]) {

      IsConsecutiveLoad = false;

    }

  }


  auto CreateLoad = [&DAG, &DL, &Loads](EVT VT, LoadSDNode *LDBase) {

    auto MMOFlags = LDBase->getMemOperand()->getFlags();

    assert(LDBase->isSimple() &&

           "Cannot merge volatile or atomic loads.");

    SDValue NewLd =

        DAG.getLoad(VT, DL, LDBase->getChain(), LDBase->getBasePtr(),

                    LDBase->getPointerInfo(), LDBase->getBaseAlign(), MMOFlags);

    for (auto *LD : Loads)

      if (LD)

        DAG.makeEquivalentMemoryOrdering(LD, NewLd);

    return NewLd;

  };


  // Check if the base load is entirely dereferenceable.

  bool IsDereferenceable = LDBase->getPointerInfo().isDereferenceable(

      VT.getSizeInBits() / 8, *DAG.getContext(), DAG.getDataLayout());


  // LOAD - all consecutive load/undefs (must start/end with a load or be

  // entirely dereferenceable). If we have found an entire vector of loads and

  // undefs, then return a large load of the entire vector width starting at the

  // base pointer. If the vector contains zeros, then attempt to shuffle those

  // elements.

  if (FirstLoadedElt == 0 &&

      (NumLoadedElts == (int)NumElems || IsDereferenceable) &&

      (IsConsecutiveLoad || IsConsecutiveLoadWithZeros)) {

    if (IsAfterLegalize && !TLI.isOperationLegal(ISD::LOAD, VT))

      return SDValue();


    // Don't create 256-bit non-temporal aligned loads without AVX2 as these

    // will lower to regular temporal loads and use the cache.

    if (LDBase->isNonTemporal() && LDBase->getAlign() >= Align(32) &&

        VT.is256BitVector() && !Subtarget.hasInt256())

      return SDValue();


    if (NumElems == 1)

      return DAG.getBitcast(VT, Elts[FirstLoadedElt]);


    if (!ZeroMask)

      return CreateLoad(VT, LDBase);


    // IsConsecutiveLoadWithZeros - we need to create a shuffle of the loaded

    // vector and a zero vector to clear out the zero elements.

    if (!IsAfterLegalize && VT.isVector()) {

      unsigned NumMaskElts = VT.getVectorNumElements();

      if ((NumMaskElts % NumElems) == 0) {

        unsigned Scale = NumMaskElts / NumElems;

        SmallVector<int, 4> ClearMask(NumMaskElts, -1);

        for (unsigned i = 0; i < NumElems; ++i) {

          if (UndefMask[i])

            continue;

          int Offset = ZeroMask[i] ? NumMaskElts : 0;

          for (unsigned j = 0; j != Scale; ++j)

            ClearMask[(i * Scale) + j] = (i * Scale) + j + Offset;

        }

        SDValue V = CreateLoad(VT, LDBase);

        SDValue Z = VT.isInteger() ? DAG.getConstant(0, DL, VT)

                                   : DAG.getConstantFP(0.0, DL, VT);

        return DAG.getVectorShuffle(VT, DL, V, Z, ClearMask);

      }

    }

  }


  // If the upper half of a ymm/zmm load is undef then just load the lower half.

  if (VT.is256BitVector() || VT.is512BitVector()) {

    unsigned HalfNumElems = NumElems / 2;

    if (UndefMask.extractBits(HalfNumElems, HalfNumElems).isAllOnes()) {

      EVT HalfVT =

          EVT::getVectorVT(*DAG.getContext(), VT.getScalarType(), HalfNumElems);

      SDValue HalfLD =

          EltsFromConsecutiveLoads(HalfVT, Elts.drop_back(HalfNumElems), DL,

                                   DAG, Subtarget, IsAfterLegalize, Depth + 1);

      if (HalfLD)

        return DAG.getNode(ISD::INSERT_SUBVECTOR, DL, VT, DAG.getUNDEF(VT),

                           HalfLD, DAG.getVectorIdxConstant(0, DL));

    }

  }


  // VZEXT_LOAD - consecutive 32/64-bit load/undefs followed by zeros/undefs.

  if (IsConsecutiveLoad && FirstLoadedElt == 0 &&

      ((LoadSizeInBits == 16 && Subtarget.hasFP16()) || LoadSizeInBits == 32 ||

       LoadSizeInBits == 64) &&

      ((VT.is128BitVector() || VT.is256BitVector() || VT.is512BitVector()))) {

    MVT VecSVT = VT.isFloatingPoint() ? MVT::getFloatingPointVT(LoadSizeInBits)

                                      : MVT::getIntegerVT(LoadSizeInBits);

    MVT VecVT = MVT::getVectorVT(VecSVT, VT.getSizeInBits() / LoadSizeInBits);

    // Allow v4f32 on SSE1 only targets.

    // FIXME: Add more isel patterns so we can just use VT directly.

    if (!Subtarget.hasSSE2() && VT == MVT::v4f32)

      VecVT = MVT::v4f32;

    if (TLI.isTypeLegal(VecVT)) {

      SDVTList Tys = DAG.getVTList(VecVT, MVT::Other);

      SDValue Ops[] = { LDBase->getChain(), LDBase->getBasePtr() };

      SDValue ResNode = DAG.getMemIntrinsicNode(

          X86ISD::VZEXT_LOAD, DL, Tys, Ops, VecSVT, LDBase->getPointerInfo(),

          LDBase->getBaseAlign(), MachineMemOperand::MOLoad);

      for (auto *LD : Loads)

        if (LD)

          DAG.makeEquivalentMemoryOrdering(LD, ResNode);

      return DAG.getBitcast(VT, ResNode);

    }

  }


  // BROADCAST - match the smallest possible repetition pattern, load that

  // scalar/subvector element and then broadcast to the entire vector.

  if (ZeroMask.isZero() && isPowerOf2_32(NumElems) && Subtarget.hasAVX() &&

      (VT.is128BitVector() || VT.is256BitVector() || VT.is512BitVector())) {

    for (unsigned SubElems = 1; SubElems < NumElems; SubElems *= 2) {

      unsigned RepeatSize = SubElems * BaseSizeInBits;

      unsigned ScalarSize = std::min(RepeatSize, 64u);

      if (!Subtarget.hasAVX2() && ScalarSize < 32)

        continue;


      // Don't attempt a 1:N subvector broadcast - it should be caught by

      // combineConcatVectorOps, else will cause infinite loops.

      if (RepeatSize > ScalarSize && SubElems == 1)

        continue;


      bool Match = true;

      SmallVector<SDValue, 8> RepeatedLoads(SubElems, DAG.getUNDEF(EltBaseVT));

      for (unsigned i = 0; i != NumElems && Match; ++i) {

        if (!LoadMask[i])

          continue;

        SDValue Elt = peekThroughBitcasts(Elts[i]);

        if (RepeatedLoads[i % SubElems].isUndef())

          RepeatedLoads[i % SubElems] = Elt;

        else

          Match &= (RepeatedLoads[i % SubElems] == Elt);

      }


      // We must have loads at both ends of the repetition.

      Match &= !RepeatedLoads.front().isUndef();

      Match &= !RepeatedLoads.back().isUndef();

      if (!Match)

        continue;


      EVT RepeatVT =

          VT.isInteger() && (RepeatSize != 64 || TLI.isTypeLegal(MVT::i64))

              ? EVT::getIntegerVT(*DAG.getContext(), ScalarSize)

              : EVT::getFloatingPointVT(ScalarSize);

      if (RepeatSize > ScalarSize)

        RepeatVT = EVT::getVectorVT(*DAG.getContext(), RepeatVT,

                                    RepeatSize / ScalarSize);

      EVT BroadcastVT =

          EVT::getVectorVT(*DAG.getContext(), RepeatVT.getScalarType(),

                           VT.getSizeInBits() / ScalarSize);

      if (TLI.isTypeLegal(BroadcastVT)) {

        if (SDValue RepeatLoad = EltsFromConsecutiveLoads(

                RepeatVT, RepeatedLoads, DL, DAG, Subtarget, IsAfterLegalize,

                Depth + 1)) {

          SDValue Broadcast = RepeatLoad;

          if (RepeatSize > ScalarSize) {

            while (Broadcast.getValueSizeInBits() < VT.getSizeInBits())

              Broadcast = concatSubVectors(Broadcast, Broadcast, DAG, DL);

          } else {

            if (!Subtarget.hasAVX2() &&

                !X86::mayFoldLoadIntoBroadcastFromMem(

                    RepeatLoad, RepeatVT.getScalarType().getSimpleVT(),

                    Subtarget,

                    /*AssumeSingleUse=*/true))

              return SDValue();

            Broadcast =

                DAG.getNode(X86ISD::VBROADCAST, DL, BroadcastVT, RepeatLoad);

          }

          return DAG.getBitcast(VT, Broadcast);

        }

      }

    }

  }


  // REVERSE - attempt to match the loads in reverse and then shuffle back.

  // TODO: Do this for any permute or mismatching element counts.

  if (Depth == 0 && ZeroMask.isZero() && UndefMask.isZero() &&

      TLI.isTypeLegal(VT) && VT.isVector() &&

      NumElems == VT.getVectorNumElements()) {

    SmallVector<SDValue, 16> ReverseElts(Elts.rbegin(), Elts.rend());

    if (SDValue RevLd = EltsFromConsecutiveLoads(

            VT, ReverseElts, DL, DAG, Subtarget, IsAfterLegalize, Depth + 1)) {

      SmallVector<int, 16> ReverseMask(NumElems);

      std::iota(ReverseMask.rbegin(), ReverseMask.rend(), 0);

      return DAG.getVectorShuffle(VT, DL, RevLd, DAG.getUNDEF(VT), ReverseMask);

    }

  }


  return SDValue();

}


// Combine a vector ops (shuffles etc.) that is equal to build_vector load1,

// load2, load3, load4, <0, 1, 2, 3> into a vector load if the load addresses

// are consecutive, non-overlapping, and in the right order.


static SDValue combineToConsecutiveLoads(EVT VT, SDValue Op, const SDLoc &DL,

                                         SelectionDAG &DAG,

                                         const X86Subtarget &Subtarget,

                                         bool IsAfterLegalize) {

  SmallVector<SDValue, 64> Elts;

  for (unsigned i = 0, e = VT.getVectorNumElements(); i != e; ++i) {

    if (SDValue Elt = getShuffleScalarElt(Op, i, DAG, 0)) {

      Elts.push_back(Elt);

      continue;

    }

    return SDValue();

  }

  assert(Elts.size() == VT.getVectorNumElements());

  return EltsFromConsecutiveLoads(VT, Elts, DL, DAG, Subtarget,

                                  IsAfterLegalize);

}


static Constant *getConstantVector(MVT VT, ArrayRef<APInt> Bits,

                                   const APInt &Undefs, LLVMContext &C) {

  unsigned ScalarSize = VT.getScalarSizeInBits();

  Type *Ty = EVT(VT.getScalarType()).getTypeForEVT(C);


  auto getConstantScalar = [&](const APInt &Val) -> Constant * {

    if (VT.isFloatingPoint()) {

      if (ScalarSize == 16)

        return ConstantFP::get(C, APFloat(APFloat::IEEEhalf(), Val));

      if (ScalarSize == 32)

        return ConstantFP::get(C, APFloat(APFloat::IEEEsingle(), Val));

      assert(ScalarSize == 64 && "Unsupported floating point scalar size");

      return ConstantFP::get(C, APFloat(APFloat::IEEEdouble(), Val));

    }

    return Constant::getIntegerValue(Ty, Val);

  };


  SmallVector<Constant *, 32> ConstantVec;

  for (unsigned I = 0, E = Bits.size(); I != E; ++I)

    ConstantVec.push_back(Undefs[I] ? UndefValue::get(Ty)

                                    : getConstantScalar(Bits[I]));


  return ConstantVector::get(ArrayRef<Constant *>(ConstantVec));

}


static Constant *getConstantVector(MVT VT, const APInt &SplatValue,

                                   unsigned SplatBitSize, LLVMContext &C) {

  unsigned ScalarSize = VT.getScalarSizeInBits();


  auto getConstantScalar = [&](const APInt &Val) -> Constant * {

    if (VT.isFloatingPoint()) {

      if (ScalarSize == 16)

        return ConstantFP::get(C, APFloat(APFloat::IEEEhalf(), Val));

      if (ScalarSize == 32)

        return ConstantFP::get(C, APFloat(APFloat::IEEEsingle(), Val));

      assert(ScalarSize == 64 && "Unsupported floating point scalar size");

      return ConstantFP::get(C, APFloat(APFloat::IEEEdouble(), Val));

    }

    return Constant::getIntegerValue(Type::getIntNTy(C, ScalarSize), Val);

  };


  if (ScalarSize == SplatBitSize)

    return getConstantScalar(SplatValue);


  unsigned NumElm = SplatBitSize / ScalarSize;

  SmallVector<Constant *, 32> ConstantVec;

  for (unsigned I = 0; I != NumElm; ++I) {

    APInt Val = SplatValue.extractBits(ScalarSize, ScalarSize * I);

    ConstantVec.push_back(getConstantScalar(Val));

  }

  return ConstantVector::get(ArrayRef<Constant *>(ConstantVec));

}


static bool isFoldableUseOfShuffle(SDNode *N) {

  for (auto *U : N->users()) {

    unsigned Opc = U->getOpcode();

    // VPERMV/VPERMV3 shuffles can never fold their index operands.

    if (Opc == X86ISD::VPERMV && U->getOperand(0).getNode() == N)

      return false;

    if (Opc == X86ISD::VPERMV3 && U->getOperand(1).getNode() == N)

      return false;

    if (isTargetShuffle(Opc))

      return true;

    if (Opc == ISD::BITCAST) // Ignore bitcasts

      return isFoldableUseOfShuffle(U);

    if (N->hasOneUse()) {

      // TODO, there may be some general way to know if a SDNode can

      // be folded. We now only know whether an MI is foldable.

      if (Opc == X86ISD::VPDPBUSD && U->getOperand(2).getNode() != N)

        return false;

      return true;

    }

  }

  return false;

}


// If the node has a single use by a VSELECT then AVX512 targets may be able to

// fold as a predicated instruction.


static bool isMaskableNode(SDValue V, const X86Subtarget &Subtarget) {

  unsigned SizeInBits = V.getValueSizeInBits();

  if ((SizeInBits == 512 && Subtarget.hasAVX512()) ||

      (SizeInBits >= 128 && Subtarget.hasVLX())) {

    if (V.hasOneUse() && V->user_begin()->getOpcode() == ISD::VSELECT &&

        V->user_begin()->getOperand(0).getScalarValueSizeInBits() == 1) {

      return true;

    }

  }

  return false;

}


/// Attempt to use the vbroadcast instruction to generate a splat value

/// from a splat BUILD_VECTOR which uses:

///  a. A single scalar load, or a constant.

///  b. Repeated pattern of constants (e.g. <0,1,0,1> or <0,1,2,3,0,1,2,3>).

///

/// The VBROADCAST node is returned when a pattern is found,

/// or SDValue() otherwise.


static SDValue lowerBuildVectorAsBroadcast(BuildVectorSDNode *BVOp,

                                           const SDLoc &dl,

                                           const X86Subtarget &Subtarget,

                                           SelectionDAG &DAG) {

  // VBROADCAST requires AVX.

  // TODO: Splats could be generated for non-AVX CPUs using SSE

  // instructions, but there's less potential gain for only 128-bit vectors.

  if (!Subtarget.hasAVX())

    return SDValue();


  MVT VT = BVOp->getSimpleValueType(0);

  unsigned NumElts = VT.getVectorNumElements();

  const TargetLowering &TLI = DAG.getTargetLoweringInfo();

  assert((VT.is128BitVector() || VT.is256BitVector() || VT.is512BitVector()) &&

         "Unsupported vector type for broadcast.");


  // See if the build vector is a repeating sequence of scalars (inc. splat).

  SDValue Ld;

  BitVector UndefElements;

  SmallVector<SDValue, 16> Sequence;

  if (BVOp->getRepeatedSequence(Sequence, &UndefElements)) {

    assert((NumElts % Sequence.size()) == 0 && "Sequence doesn't fit.");

    if (Sequence.size() == 1)

      Ld = Sequence[0];

  }


  // Attempt to use VBROADCASTM

  // From this pattern:

  // a. t0 = (zext_i64 (bitcast_i8 v2i1 X))

  // b. t1 = (build_vector t0 t0)

  //

  // Create (VBROADCASTM v2i1 X)

  if (!Sequence.empty() && Subtarget.hasCDI()) {

    // If not a splat, are the upper sequence values zeroable?

    unsigned SeqLen = Sequence.size();

    bool UpperZeroOrUndef =

        SeqLen == 1 ||

        llvm::all_of(ArrayRef(Sequence).drop_front(),

                     [](SDValue V) { return !V || isNullConstantOrUndef(V); });

    SDValue Op0 = Sequence[0];

    if (UpperZeroOrUndef && ((Op0.getOpcode() == ISD::BITCAST) ||

                             (Op0.getOpcode() == ISD::ZERO_EXTEND &&

                              Op0.getOperand(0).getOpcode() == ISD::BITCAST))) {

      SDValue BOperand = Op0.getOpcode() == ISD::BITCAST

                             ? Op0.getOperand(0)

                             : Op0.getOperand(0).getOperand(0);

      MVT MaskVT = BOperand.getSimpleValueType();

      MVT EltType = MVT::getIntegerVT(VT.getScalarSizeInBits() * SeqLen);

      if ((EltType == MVT::i64 && MaskVT == MVT::v8i1) ||  // for broadcastmb2q

          (EltType == MVT::i32 && MaskVT == MVT::v16i1)) { // for broadcastmw2d

        MVT BcstVT = MVT::getVectorVT(EltType, NumElts / SeqLen);

        if (!VT.is512BitVector() && !Subtarget.hasVLX()) {

          unsigned Scale = 512 / VT.getSizeInBits();

          BcstVT = MVT::getVectorVT(EltType, Scale * (NumElts / SeqLen));

        }

        SDValue Bcst = DAG.getNode(X86ISD::VBROADCASTM, dl, BcstVT, BOperand);

        if (BcstVT.getSizeInBits() != VT.getSizeInBits())

          Bcst = extractSubVector(Bcst, 0, DAG, dl, VT.getSizeInBits());

        return DAG.getBitcast(VT, Bcst);

      }

    }

  }


  unsigned NumUndefElts = UndefElements.count();

  if (!Ld || (NumElts - NumUndefElts) <= 1) {

    APInt SplatValue, Undef;

    unsigned SplatBitSize;

    bool HasUndef;

    // Check if this is a repeated constant pattern suitable for broadcasting.

    if (BVOp->isConstantSplat(SplatValue, Undef, SplatBitSize, HasUndef) &&

        SplatBitSize > VT.getScalarSizeInBits() &&

        SplatBitSize < VT.getSizeInBits()) {

      // Avoid replacing with broadcast when it's a use of a shuffle

      // instruction to preserve the present custom lowering of shuffles.

      if (isFoldableUseOfShuffle(BVOp))

        return SDValue();

      // replace BUILD_VECTOR with broadcast of the repeated constants.

      LLVMContext *Ctx = DAG.getContext();

      MVT PVT = TLI.getPointerTy(DAG.getDataLayout());

      if (SplatBitSize == 32 || SplatBitSize == 64 ||

          (SplatBitSize < 32 && Subtarget.hasAVX2())) {

        // Load the constant scalar/subvector and broadcast it.

        MVT CVT = MVT::getIntegerVT(SplatBitSize);

        Constant *C = getConstantVector(VT, SplatValue, SplatBitSize, *Ctx);

        SDValue CP = DAG.getConstantPool(C, PVT);

        unsigned Repeat = VT.getSizeInBits() / SplatBitSize;


        Align Alignment = cast<ConstantPoolSDNode>(CP)->getAlign();

        SDVTList Tys = DAG.getVTList(MVT::getVectorVT(CVT, Repeat), MVT::Other);

        SDValue Ops[] = {DAG.getEntryNode(), CP};

        MachinePointerInfo MPI =

            MachinePointerInfo::getConstantPool(DAG.getMachineFunction());

        SDValue Brdcst =

            DAG.getMemIntrinsicNode(X86ISD::VBROADCAST_LOAD, dl, Tys, Ops, CVT,

                                    MPI, Alignment, MachineMemOperand::MOLoad);

        return DAG.getBitcast(VT, Brdcst);

      }

      if (SplatBitSize > 64) {

        // Load the vector of constants and broadcast it.

        Constant *VecC = getConstantVector(VT, SplatValue, SplatBitSize, *Ctx);

        SDValue VCP = DAG.getConstantPool(VecC, PVT);

        unsigned NumElm = SplatBitSize / VT.getScalarSizeInBits();

        MVT VVT = MVT::getVectorVT(VT.getScalarType(), NumElm);

        Align Alignment = cast<ConstantPoolSDNode>(VCP)->getAlign();

        SDVTList Tys = DAG.getVTList(VT, MVT::Other);

        SDValue Ops[] = {DAG.getEntryNode(), VCP};

        MachinePointerInfo MPI =

            MachinePointerInfo::getConstantPool(DAG.getMachineFunction());

        return DAG.getMemIntrinsicNode(X86ISD::SUBV_BROADCAST_LOAD, dl, Tys,

                                       Ops, VVT, MPI, Alignment,

                                       MachineMemOperand::MOLoad);

      }

    }


    // If we are moving a scalar into a vector (Ld must be set and all elements

    // but 1 are undef) and that operation is not obviously supported by

    // vmovd/vmovq/vmovss/vmovsd, then keep trying to form a broadcast.

    // That's better than general shuffling and may eliminate a load to GPR and

    // move from scalar to vector register.

    if (!Ld || NumElts - NumUndefElts != 1)

      return SDValue();

    unsigned ScalarSize = Ld.getValueSizeInBits();

    if (!(UndefElements[0] || (ScalarSize != 32 && ScalarSize != 64)))

      return SDValue();

  }


  bool ConstSplatVal =

      (Ld.getOpcode() == ISD::Constant || Ld.getOpcode() == ISD::ConstantFP);

  bool IsLoad = ISD::isNormalLoad(Ld.getNode());


  // TODO: Handle broadcasts of non-constant sequences.


  // Make sure that all of the users of a non-constant load are from the

  // BUILD_VECTOR node.

  // FIXME: Is the use count needed for non-constant, non-load case?

  if (!ConstSplatVal && !IsLoad && !BVOp->isOnlyUserOf(Ld.getNode()))

    return SDValue();


  unsigned ScalarSize = Ld.getValueSizeInBits();

  bool IsGE256 = (VT.getSizeInBits() >= 256);


  // When optimizing for size, generate up to 5 extra bytes for a broadcast

  // instruction to save 8 or more bytes of constant pool data.

  // TODO: If multiple splats are generated to load the same constant,

  // it may be detrimental to overall size. There needs to be a way to detect

  // that condition to know if this is truly a size win.

  bool OptForSize = DAG.shouldOptForSize();


  // Handle broadcasting a single constant scalar from the constant pool

  // into a vector.

  // On Sandybridge (no AVX2), it is still better to load a constant vector

  // from the constant pool and not to broadcast it from a scalar.

  // But override that restriction when optimizing for size.

  // TODO: Check if splatting is recommended for other AVX-capable CPUs.

  if (ConstSplatVal && (Subtarget.hasAVX2() || OptForSize)) {

    EVT CVT = Ld.getValueType();

    assert(!CVT.isVector() && "Must not broadcast a vector type");


    // Splat f16, f32, i32, v4f64, v4i64 in all cases with AVX2.

    // For size optimization, also splat v2f64 and v2i64, and for size opt

    // with AVX2, also splat i8 and i16.

    // With pattern matching, the VBROADCAST node may become a VMOVDDUP.

    if (ScalarSize == 32 ||

        (ScalarSize == 64 && (IsGE256 || Subtarget.hasVLX())) ||

        (CVT == MVT::f16 && Subtarget.hasAVX2()) ||

        (OptForSize && (ScalarSize == 64 || Subtarget.hasAVX2()))) {

      const Constant *C = nullptr;

      if (ConstantSDNode *CI = dyn_cast<ConstantSDNode>(Ld))

        C = CI->getConstantIntValue();

      else if (ConstantFPSDNode *CF = dyn_cast<ConstantFPSDNode>(Ld))

        C = CF->getConstantFPValue();


      assert(C && "Invalid constant type");


      SDValue CP =

          DAG.getConstantPool(C, TLI.getPointerTy(DAG.getDataLayout()));

      Align Alignment = cast<ConstantPoolSDNode>(CP)->getAlign();


      SDVTList Tys = DAG.getVTList(VT, MVT::Other);

      SDValue Ops[] = {DAG.getEntryNode(), CP};

      MachinePointerInfo MPI =

          MachinePointerInfo::getConstantPool(DAG.getMachineFunction());

      return DAG.getMemIntrinsicNode(X86ISD::VBROADCAST_LOAD, dl, Tys, Ops, CVT,

                                     MPI, Alignment, MachineMemOperand::MOLoad);

    }

  }


  // Handle AVX2 in-register broadcasts.

  if (!IsLoad && Subtarget.hasInt256() &&

      (ScalarSize == 32 || (IsGE256 && ScalarSize == 64)))

    return DAG.getNode(X86ISD::VBROADCAST, dl, VT, Ld);


  // The scalar source must be a normal load.

  if (!IsLoad)

    return SDValue();


  // Make sure the non-chain result is only used by this build vector.

  if (!Ld->hasNUsesOfValue(NumElts - NumUndefElts, 0))

    return SDValue();


  if (ScalarSize == 32 || (IsGE256 && ScalarSize == 64) ||

      (Subtarget.hasVLX() && ScalarSize == 64)) {

    auto *LN = cast<LoadSDNode>(Ld);

    SDVTList Tys = DAG.getVTList(VT, MVT::Other);

    SDValue Ops[] = {LN->getChain(), LN->getBasePtr()};

    SDValue BCast =

        DAG.getMemIntrinsicNode(X86ISD::VBROADCAST_LOAD, dl, Tys, Ops,

                                LN->getMemoryVT(), LN->getMemOperand());

    DAG.ReplaceAllUsesOfValueWith(SDValue(LN, 1), BCast.getValue(1));

    return BCast;

  }


  // The integer check is needed for the 64-bit into 128-bit so it doesn't match

  // double since there is no vbroadcastsd xmm

  if (Subtarget.hasInt256() && Ld.getValueType().isInteger() &&

      (ScalarSize == 8 || ScalarSize == 16 || ScalarSize == 64)) {

    auto *LN = cast<LoadSDNode>(Ld);

    SDVTList Tys = DAG.getVTList(VT, MVT::Other);

    SDValue Ops[] = {LN->getChain(), LN->getBasePtr()};

    SDValue BCast =

        DAG.getMemIntrinsicNode(X86ISD::VBROADCAST_LOAD, dl, Tys, Ops,

                                LN->getMemoryVT(), LN->getMemOperand());

    DAG.ReplaceAllUsesOfValueWith(SDValue(LN, 1), BCast.getValue(1));

    return BCast;

  }


  if (ScalarSize == 16 && Subtarget.hasFP16() && IsGE256)

    return DAG.getNode(X86ISD::VBROADCAST, dl, VT, Ld);


  // Unsupported broadcast.

  return SDValue();

}


/// For an EXTRACT_VECTOR_ELT with a constant index return the real

/// underlying vector and index.

///

/// Modifies \p ExtractedFromVec to the real vector and returns the real

/// index.


static int getUnderlyingExtractedFromVec(SDValue &ExtractedFromVec,

                                         SDValue ExtIdx) {

  int Idx = ExtIdx->getAsZExtVal();

  if (!isa<ShuffleVectorSDNode>(ExtractedFromVec))

    return Idx;


  // For 256-bit vectors, LowerEXTRACT_VECTOR_ELT_SSE4 may have already

  // lowered this:

  //   (extract_vector_elt (v8f32 %1), Constant<6>)

  // to:

  //   (extract_vector_elt (vector_shuffle<2,u,u,u>

  //                           (extract_subvector (v8f32 %0), Constant<4>),

  //                           undef)

  //                       Constant<0>)

  // In this case the vector is the extract_subvector expression and the index

  // is 2, as specified by the shuffle.

  ShuffleVectorSDNode *SVOp = cast<ShuffleVectorSDNode>(ExtractedFromVec);

  SDValue ShuffleVec = SVOp->getOperand(0);

  MVT ShuffleVecVT = ShuffleVec.getSimpleValueType();

  assert(ShuffleVecVT.getVectorElementType() ==

         ExtractedFromVec.getSimpleValueType().getVectorElementType());


  int ShuffleIdx = SVOp->getMaskElt(Idx);

  if (isUndefOrInRange(ShuffleIdx, 0, ShuffleVecVT.getVectorNumElements())) {

    ExtractedFromVec = ShuffleVec;

    return ShuffleIdx;

  }

  return Idx;

}


static SDValue buildFromShuffleMostly(SDValue Op, const SDLoc &DL,

                                      SelectionDAG &DAG) {

  MVT VT = Op.getSimpleValueType();


  // Skip if insert_vec_elt is not supported.

  const TargetLowering &TLI = DAG.getTargetLoweringInfo();

  if (!TLI.isOperationLegalOrCustom(ISD::INSERT_VECTOR_ELT, VT))

    return SDValue();


  unsigned NumElems = Op.getNumOperands();

  SDValue VecIn1;

  SDValue VecIn2;

  SmallVector<unsigned, 4> InsertIndices;

  SmallVector<int, 8> Mask(NumElems, -1);


  for (unsigned i = 0; i != NumElems; ++i) {

    unsigned Opc = Op.getOperand(i).getOpcode();


    if (Opc == ISD::POISON || Opc == ISD::UNDEF)

      continue;


    if (Opc != ISD::EXTRACT_VECTOR_ELT) {

      // Quit if more than 1 elements need inserting.

      if (InsertIndices.size() > 1)

        return SDValue();


      InsertIndices.push_back(i);

      continue;

    }


    SDValue ExtractedFromVec = Op.getOperand(i).getOperand(0);

    SDValue ExtIdx = Op.getOperand(i).getOperand(1);


    // Quit if non-constant index.

    if (!isa<ConstantSDNode>(ExtIdx))

      return SDValue();

    int Idx = getUnderlyingExtractedFromVec(ExtractedFromVec, ExtIdx);


    // Quit if extracted from vector of different type.

    if (ExtractedFromVec.getValueType() != VT)

      return SDValue();


    if (!VecIn1.getNode())

      VecIn1 = ExtractedFromVec;

    else if (VecIn1 != ExtractedFromVec) {

      if (!VecIn2.getNode())

        VecIn2 = ExtractedFromVec;

      else if (VecIn2 != ExtractedFromVec)

        // Quit if more than 2 vectors to shuffle

        return SDValue();

    }


    if (ExtractedFromVec == VecIn1)

      Mask[i] = Idx;

    else if (ExtractedFromVec == VecIn2)

      Mask[i] = Idx + NumElems;

  }


  if (!VecIn1.getNode())

    return SDValue();


  VecIn2 = VecIn2.getNode() ? VecIn2 : DAG.getPOISON(VT);

  SDValue NV = DAG.getVectorShuffle(VT, DL, VecIn1, VecIn2, Mask);


  for (unsigned Idx : InsertIndices)

    NV = DAG.getNode(ISD::INSERT_VECTOR_ELT, DL, VT, NV, Op.getOperand(Idx),

                     DAG.getVectorIdxConstant(Idx, DL));


  return NV;

}


// Lower BUILD_VECTOR operation for v8bf16, v16bf16 and v32bf16 types.


static SDValue LowerBUILD_VECTORvXbf16(SDValue Op, SelectionDAG &DAG,

                                       const X86Subtarget &Subtarget) {

  MVT VT = Op.getSimpleValueType();

  MVT SVT = Subtarget.hasFP16() ? MVT::f16 : MVT::i16;

  MVT IVT = VT.changeVectorElementType(SVT);

  SmallVector<SDValue, 16> NewOps;

  for (unsigned I = 0, E = Op.getNumOperands(); I != E; ++I)

    NewOps.push_back(DAG.getBitcast(SVT, Op.getOperand(I)));

  SDValue Res = DAG.getNode(ISD::BUILD_VECTOR, SDLoc(), IVT, NewOps);

  return DAG.getBitcast(VT, Res);

}


// Lower BUILD_VECTOR operation for v8i1 and v16i1 types.


static SDValue LowerBUILD_VECTORvXi1(SDValue Op, const SDLoc &dl,

                                     SelectionDAG &DAG,

                                     const X86Subtarget &Subtarget) {


  MVT VT = Op.getSimpleValueType();

  assert((VT.getVectorElementType() == MVT::i1) &&

         "Unexpected type in LowerBUILD_VECTORvXi1!");

  if (ISD::isBuildVectorAllZeros(Op.getNode()) ||

      ISD::isBuildVectorAllOnes(Op.getNode()))

    return Op;


  uint64_t Immediate = 0;

  SmallVector<unsigned, 16> NonConstIdx;

  bool IsSplat = true;

  bool HasConstElts = false;

  int SplatIdx = -1;

  for (unsigned idx = 0, e = Op.getNumOperands(); idx < e; ++idx) {

    SDValue In = Op.getOperand(idx);

    if (In.isUndef())

      continue;

    if (auto *InC = dyn_cast<ConstantSDNode>(In)) {

      Immediate |= (InC->getZExtValue() & 0x1) << idx;

      HasConstElts = true;

    } else {

      NonConstIdx.push_back(idx);

    }

    if (SplatIdx < 0)

      SplatIdx = idx;

    else if (In != Op.getOperand(SplatIdx))

      IsSplat = false;

  }


  // for splat use " (select i1 splat_elt, all-ones, all-zeroes)"

  if (IsSplat) {

    // The build_vector allows the scalar element to be larger than the vector

    // element type. We need to mask it to use as a condition unless we know

    // the upper bits are zero.

    // FIXME: Use computeKnownBits instead of checking specific opcode?

    SDValue Cond = Op.getOperand(SplatIdx);

    assert(Cond.getValueType() == MVT::i8 && "Unexpected VT!");

    if (Cond.getOpcode() != ISD::SETCC)

      Cond = DAG.getNode(ISD::AND, dl, MVT::i8, Cond,

                         DAG.getConstant(1, dl, MVT::i8));


    // Perform the select in the scalar domain so we can use cmov.

    if (VT == MVT::v64i1 && !Subtarget.is64Bit()) {

      SDValue Select = DAG.getSelect(dl, MVT::i32, Cond,

                                     DAG.getAllOnesConstant(dl, MVT::i32),

                                     DAG.getConstant(0, dl, MVT::i32));

      Select = DAG.getBitcast(MVT::v32i1, Select);

      return DAG.getNode(ISD::CONCAT_VECTORS, dl, MVT::v64i1, Select, Select);

    } else {

      MVT ImmVT = MVT::getIntegerVT(std::max((unsigned)VT.getSizeInBits(), 8U));

      SDValue Select = DAG.getSelect(dl, ImmVT, Cond,

                                     DAG.getAllOnesConstant(dl, ImmVT),

                                     DAG.getConstant(0, dl, ImmVT));

      MVT VecVT = VT.getSizeInBits() >= 8 ? VT : MVT::v8i1;

      Select = DAG.getBitcast(VecVT, Select);

      return DAG.getNode(ISD::EXTRACT_SUBVECTOR, dl, VT, Select,

                         DAG.getVectorIdxConstant(0, dl));

    }

  }


  // insert elements one by one

  SDValue DstVec;

  if (HasConstElts) {

    if (VT == MVT::v64i1 && !Subtarget.is64Bit()) {

      SDValue ImmL = DAG.getConstant(Lo_32(Immediate), dl, MVT::i32);

      SDValue ImmH = DAG.getConstant(Hi_32(Immediate), dl, MVT::i32);

      ImmL = DAG.getBitcast(MVT::v32i1, ImmL);

      ImmH = DAG.getBitcast(MVT::v32i1, ImmH);

      DstVec = DAG.getNode(ISD::CONCAT_VECTORS, dl, MVT::v64i1, ImmL, ImmH);

    } else {

      MVT ImmVT = MVT::getIntegerVT(std::max((unsigned)VT.getSizeInBits(), 8U));

      SDValue Imm = DAG.getConstant(Immediate, dl, ImmVT);

      MVT VecVT = VT.getSizeInBits() >= 8 ? VT : MVT::v8i1;

      DstVec = DAG.getBitcast(VecVT, Imm);

      DstVec = DAG.getNode(ISD::EXTRACT_SUBVECTOR, dl, VT, DstVec,

                           DAG.getVectorIdxConstant(0, dl));

    }

  } else

    DstVec = DAG.getUNDEF(VT);


  for (unsigned InsertIdx : NonConstIdx) {

    DstVec = DAG.getNode(ISD::INSERT_VECTOR_ELT, dl, VT, DstVec,

                         Op.getOperand(InsertIdx),

                         DAG.getVectorIdxConstant(InsertIdx, dl));

  }

  return DstVec;

}


[[maybe_unused]] static bool isHorizOp(unsigned Opcode) {

  switch (Opcode) {

  case X86ISD::PACKSS:

  case X86ISD::PACKUS:

  case X86ISD::FHADD:

  case X86ISD::FHSUB:

  case X86ISD::HADD:

  case X86ISD::HSUB:

  case X86ISD::HADDS:

  case X86ISD::HSUBS:

    return true;

  }

  return false;

}


/// This is a helper function of LowerToHorizontalOp().

/// This function checks that the build_vector \p N in input implements a

/// 128-bit partial horizontal operation on a 256-bit vector, but that operation

/// may not match the layout of an x86 256-bit horizontal instruction.

/// In other words, if this returns true, then some extraction/insertion will

/// be required to produce a valid horizontal instruction.

///

/// Parameter \p Opcode defines the kind of horizontal operation to match.

/// For example, if \p Opcode is equal to ISD::ADD, then this function

/// checks if \p N implements a horizontal arithmetic add; if instead \p Opcode

/// is equal to ISD::SUB, then this function checks if this is a horizontal

/// arithmetic sub.

///

/// This function only analyzes elements of \p N whose indices are

/// in range [BaseIdx, LastIdx).

///

/// TODO: This function was originally used to match both real and fake partial

/// horizontal operations, but the index-matching logic is incorrect for that.

/// See the corrected implementation in isHopBuildVector(). Can we reduce this

/// code because it is only used for partial h-op matching now?


static bool isHorizontalBinOpPart(const BuildVectorSDNode *N, unsigned Opcode,

                                  const SDLoc &DL, SelectionDAG &DAG,

                                  unsigned BaseIdx, unsigned LastIdx,

                                  SDValue &V0, SDValue &V1) {

  EVT VT = N->getValueType(0);

  assert(VT.is256BitVector() && "Only use for matching partial 256-bit h-ops");

  assert(BaseIdx * 2 <= LastIdx && "Invalid Indices in input!");

  assert(VT.isVector() && VT.getVectorNumElements() >= LastIdx &&

         "Invalid Vector in input!");


  bool IsCommutable = (Opcode == ISD::ADD || Opcode == ISD::FADD);

  bool CanFold = true;

  unsigned ExpectedVExtractIdx = BaseIdx;

  unsigned NumElts = LastIdx - BaseIdx;

  V0 = DAG.getUNDEF(VT);

  V1 = DAG.getUNDEF(VT);


  // Check if N implements a horizontal binop.

  for (unsigned i = 0, e = NumElts; i != e && CanFold; ++i) {

    SDValue Op = N->getOperand(i + BaseIdx);


    // Skip UNDEFs.

    if (Op->isUndef()) {

      // Update the expected vector extract index.

      if (i * 2 == NumElts)

        ExpectedVExtractIdx = BaseIdx;

      ExpectedVExtractIdx += 2;

      continue;

    }


    CanFold = Op->getOpcode() == Opcode && Op->hasOneUse();


    if (!CanFold)

      break;


    SDValue Op0 = Op.getOperand(0);

    SDValue Op1 = Op.getOperand(1);


    // Try to match the following pattern:

    // (BINOP (extract_vector_elt A, I), (extract_vector_elt A, I+1))

    CanFold = (Op0.getOpcode() == ISD::EXTRACT_VECTOR_ELT &&

        Op1.getOpcode() == ISD::EXTRACT_VECTOR_ELT &&

        Op0.getOperand(0) == Op1.getOperand(0) &&

        isa<ConstantSDNode>(Op0.getOperand(1)) &&

        isa<ConstantSDNode>(Op1.getOperand(1)));

    if (!CanFold)

      break;


    unsigned I0 = Op0.getConstantOperandVal(1);

    unsigned I1 = Op1.getConstantOperandVal(1);


    if (i * 2 < NumElts) {

      if (V0.isUndef()) {

        V0 = Op0.getOperand(0);

        if (V0.getValueType() != VT)

          return false;

      }

    } else {

      if (V1.isUndef()) {

        V1 = Op0.getOperand(0);

        if (V1.getValueType() != VT)

          return false;

      }

      if (i * 2 == NumElts)

        ExpectedVExtractIdx = BaseIdx;

    }


    SDValue Expected = (i * 2 < NumElts) ? V0 : V1;

    if (I0 == ExpectedVExtractIdx)

      CanFold = I1 == I0 + 1 && Op0.getOperand(0) == Expected;

    else if (IsCommutable && I1 == ExpectedVExtractIdx) {

      // Try to match the following dag sequence:

      // (BINOP (extract_vector_elt A, I+1), (extract_vector_elt A, I))

      CanFold = I0 == I1 + 1 && Op1.getOperand(0) == Expected;

    } else

      CanFold = false;


    ExpectedVExtractIdx += 2;

  }


  return CanFold;

}


/// Emit a sequence of two 128-bit horizontal add/sub followed by

/// a concat_vector.

///

/// This is a helper function of LowerToHorizontalOp().

/// This function expects two 256-bit vectors called V0 and V1.

/// At first, each vector is split into two separate 128-bit vectors.

/// Then, the resulting 128-bit vectors are used to implement two

/// horizontal binary operations.

///

/// The kind of horizontal binary operation is defined by \p X86Opcode.

///

/// \p Mode specifies how the 128-bit parts of V0 and V1 are passed in input to

/// the two new horizontal binop.

/// When Mode is set, the first horizontal binop dag node would take as input

/// the lower 128-bit of V0 and the upper 128-bit of V0. The second

/// horizontal binop dag node would take as input the lower 128-bit of V1

/// and the upper 128-bit of V1.

///   Example:

///     HADD V0_LO, V0_HI

///     HADD V1_LO, V1_HI

///

/// Otherwise, the first horizontal binop dag node takes as input the lower

/// 128-bit of V0 and the lower 128-bit of V1, and the second horizontal binop

/// dag node takes the upper 128-bit of V0 and the upper 128-bit of V1.

///   Example:

///     HADD V0_LO, V1_LO

///     HADD V0_HI, V1_HI

///

/// If \p isUndefLO is set, then the algorithm propagates UNDEF to the lower

/// 128-bits of the result. If \p isUndefHI is set, then UNDEF is propagated to

/// the upper 128-bits of the result.


static SDValue ExpandHorizontalBinOp(const SDValue &V0, const SDValue &V1,

                                     const SDLoc &DL, SelectionDAG &DAG,

                                     unsigned X86Opcode, bool Mode,

                                     bool isUndefLO, bool isUndefHI) {

  MVT VT = V0.getSimpleValueType();

  assert(VT.is256BitVector() && VT == V1.getSimpleValueType() &&

         "Invalid nodes in input!");


  unsigned NumElts = VT.getVectorNumElements();

  SDValue V0_LO = extract128BitVector(V0, 0, DAG, DL);

  SDValue V0_HI = extract128BitVector(V0, NumElts/2, DAG, DL);

  SDValue V1_LO = extract128BitVector(V1, 0, DAG, DL);

  SDValue V1_HI = extract128BitVector(V1, NumElts/2, DAG, DL);

  MVT NewVT = V0_LO.getSimpleValueType();


  SDValue LO = DAG.getUNDEF(NewVT);

  SDValue HI = DAG.getUNDEF(NewVT);


  if (Mode) {

    // Don't emit a horizontal binop if the result is expected to be UNDEF.

    if (!isUndefLO && !V0->isUndef())

      LO = DAG.getNode(X86Opcode, DL, NewVT, V0_LO, V0_HI);

    if (!isUndefHI && !V1->isUndef())

      HI = DAG.getNode(X86Opcode, DL, NewVT, V1_LO, V1_HI);

  } else {

    // Don't emit a horizontal binop if the result is expected to be UNDEF.

    if (!isUndefLO && (!V0_LO->isUndef() || !V1_LO->isUndef()))

      LO = DAG.getNode(X86Opcode, DL, NewVT, V0_LO, V1_LO);


    if (!isUndefHI && (!V0_HI->isUndef() || !V1_HI->isUndef()))

      HI = DAG.getNode(X86Opcode, DL, NewVT, V0_HI, V1_HI);

  }


  return DAG.getNode(ISD::CONCAT_VECTORS, DL, VT, LO, HI);

}


/// Returns true iff \p BV builds a vector with the result equivalent to

/// the result of ADDSUB/SUBADD operation.

/// If true is returned then the operands of ADDSUB = Opnd0 +- Opnd1

/// (SUBADD = Opnd0 -+ Opnd1) operation are written to the parameters

/// \p Opnd0 and \p Opnd1.


static bool isAddSubOrSubAdd(const BuildVectorSDNode *BV,

                             const X86Subtarget &Subtarget, SelectionDAG &DAG,

                             SDValue &Opnd0, SDValue &Opnd1,

                             unsigned &NumExtracts, bool &IsSubAdd,

                             bool &HasAllowContract) {

  using namespace SDPatternMatch;


  MVT VT = BV->getSimpleValueType(0);

  if (!Subtarget.hasSSE3() || !VT.isFloatingPoint())

    return false;


  unsigned NumElts = VT.getVectorNumElements();

  SDValue InVec0 = DAG.getUNDEF(VT);

  SDValue InVec1 = DAG.getUNDEF(VT);


  NumExtracts = 0;

  HasAllowContract = NumElts != 0;


  // Odd-numbered elements in the input build vector are obtained from

  // adding/subtracting two integer/float elements.

  // Even-numbered elements in the input build vector are obtained from

  // subtracting/adding two integer/float elements.

  unsigned Opc[2] = {0, 0};

  for (unsigned i = 0, e = NumElts; i != e; ++i) {

    SDValue Op = BV->getOperand(i);


    // Skip 'undef' values.

    unsigned Opcode = Op.getOpcode();

    if (Opcode == ISD::UNDEF)

      continue;


    // Early exit if we found an unexpected opcode.

    if (Opcode != ISD::FADD && Opcode != ISD::FSUB)

      return false;


    SDValue Op0 = Op.getOperand(0);

    SDValue Op1 = Op.getOperand(1);


    // Try to match the following pattern:

    // (BINOP (extract_vector_elt A, i), (extract_vector_elt B, i))

    // Early exit if we cannot match that sequence.

    if (!sd_match(Op0, m_ExtractElt(m_SpecificVT(VT), m_SpecificInt(i))) ||

        !sd_match(Op1, m_ExtractElt(m_SpecificVT(VT), m_SpecificInt(i))))

      return false;


    // We found a valid add/sub node, make sure its the same opcode as previous

    // elements for this parity.

    if (Opc[i % 2] != 0 && Opc[i % 2] != Opcode)

      return false;

    Opc[i % 2] = Opcode;


    // Update InVec0 and InVec1.

    if (InVec0.isUndef())

      InVec0 = Op0.getOperand(0);

    if (InVec1.isUndef())

      InVec1 = Op1.getOperand(0);


    // Make sure that operands in input to each add/sub node always

    // come from a same pair of vectors.

    if (InVec0 != Op0.getOperand(0)) {

      if (Opcode == ISD::FSUB)

        return false;


      // FADD is commutable. Try to commute the operands

      // and then test again.

      std::swap(Op0, Op1);

      if (InVec0 != Op0.getOperand(0))

        return false;

    }


    if (InVec1 != Op1.getOperand(0))

      return false;


    // Increment the number of extractions done.

    ++NumExtracts;

    HasAllowContract &= Op->getFlags().hasAllowContract();

  }


  // Ensure we have found an opcode for both parities and that they are

  // different. Don't try to fold this build_vector into an ADDSUB/SUBADD if the

  // inputs are undef.

  if (!Opc[0] || !Opc[1] || Opc[0] == Opc[1] ||

      InVec0.isUndef() || InVec1.isUndef())

    return false;


  IsSubAdd = Opc[0] == ISD::FADD;


  Opnd0 = InVec0;

  Opnd1 = InVec1;

  return true;

}


/// Returns true if is possible to fold MUL and an idiom that has already been

/// recognized as ADDSUB/SUBADD(\p Opnd0, \p Opnd1) into

/// FMADDSUB/FMSUBADD(x, y, \p Opnd1). If (and only if) true is returned, the

/// operands of FMADDSUB/FMSUBADD are written to parameters \p Opnd0, \p Opnd1, \p Opnd2.

///

/// Prior to calling this function it should be known that there is some

/// SDNode that potentially can be replaced with an X86ISD::ADDSUB operation

/// using \p Opnd0 and \p Opnd1 as operands. Also, this method is called

/// before replacement of such SDNode with ADDSUB operation. Thus the number

/// of \p Opnd0 uses is expected to be equal to 2.

/// For example, this function may be called for the following IR:

///    %AB = fmul fast <2 x double> %A, %B

///    %Sub = fsub fast <2 x double> %AB, %C

///    %Add = fadd fast <2 x double> %AB, %C

///    %Addsub = shufflevector <2 x double> %Sub, <2 x double> %Add,

///                            <2 x i32> <i32 0, i32 3>

/// There is a def for %Addsub here, which potentially can be replaced by

/// X86ISD::ADDSUB operation:

///    %Addsub = X86ISD::ADDSUB %AB, %C

/// and such ADDSUB can further be replaced with FMADDSUB:

///    %Addsub = FMADDSUB %A, %B, %C.

///

/// The main reason why this method is called before the replacement of the

/// recognized ADDSUB idiom with ADDSUB operation is that such replacement

/// is illegal sometimes. E.g. 512-bit ADDSUB is not available, while 512-bit

/// FMADDSUB is.


static bool isFMAddSubOrFMSubAdd(const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG, SDValue &Opnd0,

                                 SDValue &Opnd1, SDValue &Opnd2,

                                 unsigned ExpectedUses,

                                 bool AllowSubAddOrAddSubContract) {

  if (Opnd0.getOpcode() != ISD::FMUL ||

      !Opnd0->hasNUsesOfValue(ExpectedUses, 0) || !Subtarget.hasAnyFMA())

    return false;


  // FIXME: These checks must match the similar ones in

  // DAGCombiner::visitFADDForFMACombine. It would be good to have one

  // function that would answer if it is Ok to fuse MUL + ADD to FMADD

  // or MUL + ADDSUB to FMADDSUB.

  bool AllowFusion =

      (AllowSubAddOrAddSubContract && Opnd0->getFlags().hasAllowContract());

  if (!AllowFusion)

    return false;


  Opnd2 = Opnd1;

  Opnd1 = Opnd0.getOperand(1);

  Opnd0 = Opnd0.getOperand(0);


  return true;

}


/// Try to fold a build_vector that performs an 'addsub' or 'fmaddsub' or

/// 'fsubadd' operation accordingly to X86ISD::ADDSUB or X86ISD::FMADDSUB or

/// X86ISD::FMSUBADD node.


static SDValue lowerToAddSubOrFMAddSub(const BuildVectorSDNode *BV,

                                       const SDLoc &DL,

                                       const X86Subtarget &Subtarget,

                                       SelectionDAG &DAG) {

  SDValue Opnd0, Opnd1;

  unsigned NumExtracts;

  bool IsSubAdd;

  bool HasAllowContract;

  if (!isAddSubOrSubAdd(BV, Subtarget, DAG, Opnd0, Opnd1, NumExtracts, IsSubAdd,

                        HasAllowContract))

    return SDValue();


  MVT VT = BV->getSimpleValueType(0);


  // Try to generate X86ISD::FMADDSUB node here.

  SDValue Opnd2;

  if (isFMAddSubOrFMSubAdd(Subtarget, DAG, Opnd0, Opnd1, Opnd2, NumExtracts,

                           HasAllowContract)) {

    unsigned Opc = IsSubAdd ? X86ISD::FMSUBADD : X86ISD::FMADDSUB;

    return DAG.getNode(Opc, DL, VT, Opnd0, Opnd1, Opnd2);

  }


  // We only support ADDSUB.

  if (IsSubAdd)

    return SDValue();


  // There are no known X86 targets with 512-bit ADDSUB instructions!

  // Convert to blend(fsub,fadd).

  if (VT.is512BitVector()) {

    SmallVector<int> Mask;

    for (int I = 0, E = VT.getVectorNumElements(); I != E; I += 2) {

        Mask.push_back(I);

        Mask.push_back(I + E + 1);

    }

    SDValue Sub = DAG.getNode(ISD::FSUB, DL, VT, Opnd0, Opnd1);

    SDValue Add = DAG.getNode(ISD::FADD, DL, VT, Opnd0, Opnd1);

    return DAG.getVectorShuffle(VT, DL, Sub, Add, Mask);

  }


  return DAG.getNode(X86ISD::ADDSUB, DL, VT, Opnd0, Opnd1);

}


static bool isHopBuildVector(const BuildVectorSDNode *BV, SelectionDAG &DAG,

                             unsigned &HOpcode, SDValue &V0, SDValue &V1) {

  // Initialize outputs to known values.

  MVT VT = BV->getSimpleValueType(0);

  HOpcode = ISD::DELETED_NODE;

  V0 = DAG.getUNDEF(VT);

  V1 = DAG.getUNDEF(VT);


  // x86 256-bit horizontal ops are defined in a non-obvious way. Each 128-bit

  // half of the result is calculated independently from the 128-bit halves of

  // the inputs, so that makes the index-checking logic below more complicated.

  unsigned NumElts = VT.getVectorNumElements();

  unsigned GenericOpcode = ISD::DELETED_NODE;

  unsigned Num128BitChunks = VT.is256BitVector() ? 2 : 1;

  unsigned NumEltsIn128Bits = NumElts / Num128BitChunks;

  unsigned NumEltsIn64Bits = NumEltsIn128Bits / 2;

  for (unsigned i = 0; i != Num128BitChunks; ++i) {

    for (unsigned j = 0; j != NumEltsIn128Bits; ++j) {

      // Ignore undef elements.

      SDValue Op = BV->getOperand(i * NumEltsIn128Bits + j);

      if (Op.isUndef())

        continue;


      // If there's an opcode mismatch, we're done.

      if (HOpcode != ISD::DELETED_NODE && Op.getOpcode() != GenericOpcode)

        return false;


      // Initialize horizontal opcode.

      if (HOpcode == ISD::DELETED_NODE) {

        GenericOpcode = Op.getOpcode();

        switch (GenericOpcode) {

        // clang-format off

        case ISD::ADD: HOpcode = X86ISD::HADD; break;

        case ISD::SUB: HOpcode = X86ISD::HSUB; break;

        case ISD::FADD: HOpcode = X86ISD::FHADD; break;

        case ISD::FSUB: HOpcode = X86ISD::FHSUB; break;

        default: return false;

        // clang-format on

        }

      }


      SDValue Op0 = Op.getOperand(0);

      SDValue Op1 = Op.getOperand(1);

      if (Op0.getOpcode() != ISD::EXTRACT_VECTOR_ELT ||

          Op1.getOpcode() != ISD::EXTRACT_VECTOR_ELT ||

          Op0.getOperand(0) != Op1.getOperand(0) ||

          !isa<ConstantSDNode>(Op0.getOperand(1)) ||

          !isa<ConstantSDNode>(Op1.getOperand(1)) || !Op.hasOneUse())

        return false;


      // The source vector is chosen based on which 64-bit half of the

      // destination vector is being calculated.

      if (j < NumEltsIn64Bits) {

        if (V0.isUndef())

          V0 = Op0.getOperand(0);

      } else {

        if (V1.isUndef())

          V1 = Op0.getOperand(0);

      }


      SDValue SourceVec = (j < NumEltsIn64Bits) ? V0 : V1;

      if (SourceVec != Op0.getOperand(0))

        return false;


      // op (extract_vector_elt A, I), (extract_vector_elt A, I+1)

      unsigned ExtIndex0 = Op0.getConstantOperandVal(1);

      unsigned ExtIndex1 = Op1.getConstantOperandVal(1);

      unsigned ExpectedIndex = i * NumEltsIn128Bits +

                               (j % NumEltsIn64Bits) * 2;

      if (ExpectedIndex == ExtIndex0 && ExtIndex1 == ExtIndex0 + 1)

        continue;


      // If this is not a commutative op, this does not match.

      if (GenericOpcode != ISD::ADD && GenericOpcode != ISD::FADD)

        return false;


      // Addition is commutative, so try swapping the extract indexes.

      // op (extract_vector_elt A, I+1), (extract_vector_elt A, I)

      if (ExpectedIndex == ExtIndex1 && ExtIndex0 == ExtIndex1 + 1)

        continue;


      // Extract indexes do not match horizontal requirement.

      return false;

    }

  }

  // We matched. Opcode and operands are returned by reference as arguments.

  return true;

}


static SDValue getHopForBuildVector(const BuildVectorSDNode *BV,

                                    const SDLoc &DL, SelectionDAG &DAG,

                                    unsigned HOpcode, SDValue V0, SDValue V1) {

  // If either input vector is not the same size as the build vector,

  // extract/insert the low bits to the correct size.

  // This is free (examples: zmm --> xmm, xmm --> ymm).

  MVT VT = BV->getSimpleValueType(0);

  unsigned Width = VT.getSizeInBits();

  if (V0.getValueSizeInBits() > Width)

    V0 = extractSubVector(V0, 0, DAG, DL, Width);

  else if (V0.getValueSizeInBits() < Width)

    V0 = insertSubVector(DAG.getUNDEF(VT), V0, 0, DAG, DL, Width);


  if (V1.getValueSizeInBits() > Width)

    V1 = extractSubVector(V1, 0, DAG, DL, Width);

  else if (V1.getValueSizeInBits() < Width)

    V1 = insertSubVector(DAG.getUNDEF(VT), V1, 0, DAG, DL, Width);


  unsigned NumElts = VT.getVectorNumElements();

  APInt DemandedElts = APInt::getAllOnes(NumElts);

  for (unsigned i = 0; i != NumElts; ++i)

    if (BV->getOperand(i).isUndef())

      DemandedElts.clearBit(i);


  // If we don't need the upper xmm, then perform as a xmm hop.

  unsigned HalfNumElts = NumElts / 2;

  if (VT.is256BitVector() && DemandedElts.lshr(HalfNumElts) == 0) {

    MVT HalfVT = VT.getHalfNumVectorElementsVT();

    V0 = extractSubVector(V0, 0, DAG, DL, 128);

    V1 = extractSubVector(V1, 0, DAG, DL, 128);

    SDValue Half = DAG.getNode(HOpcode, DL, HalfVT, V0, V1);

    return insertSubVector(DAG.getUNDEF(VT), Half, 0, DAG, DL, 256);

  }


  return DAG.getNode(HOpcode, DL, VT, V0, V1);

}


/// Lower BUILD_VECTOR to a horizontal add/sub operation if possible.


static SDValue LowerToHorizontalOp(const BuildVectorSDNode *BV, const SDLoc &DL,

                                   const X86Subtarget &Subtarget,

                                   SelectionDAG &DAG) {

  // We need at least 2 non-undef elements to make this worthwhile by default.

  unsigned NumNonUndefs =

      count_if(BV->op_values(), [](SDValue V) { return !V.isUndef(); });

  if (NumNonUndefs < 2)

    return SDValue();


  // There are 4 sets of horizontal math operations distinguished by type:

  // int/FP at 128-bit/256-bit. Each type was introduced with a different

  // subtarget feature. Try to match those "native" patterns first.

  MVT VT = BV->getSimpleValueType(0);

  if (((VT == MVT::v4f32 || VT == MVT::v2f64) && Subtarget.hasSSE3()) ||

      ((VT == MVT::v8i16 || VT == MVT::v4i32) && Subtarget.hasSSSE3()) ||

      ((VT == MVT::v8f32 || VT == MVT::v4f64) && Subtarget.hasAVX()) ||

      ((VT == MVT::v16i16 || VT == MVT::v8i32) && Subtarget.hasAVX2())) {

    unsigned HOpcode;

    SDValue V0, V1;

    if (isHopBuildVector(BV, DAG, HOpcode, V0, V1))

      return getHopForBuildVector(BV, DL, DAG, HOpcode, V0, V1);

  }


  // Try harder to match 256-bit ops by using extract/concat.

  if (!Subtarget.hasAVX() || !VT.is256BitVector())

    return SDValue();


  // Count the number of UNDEF operands in the build_vector in input.

  unsigned NumElts = VT.getVectorNumElements();

  unsigned Half = NumElts / 2;

  unsigned NumUndefsLO = 0;

  unsigned NumUndefsHI = 0;

  for (unsigned i = 0, e = Half; i != e; ++i)

    if (BV->getOperand(i)->isUndef())

      NumUndefsLO++;


  for (unsigned i = Half, e = NumElts; i != e; ++i)

    if (BV->getOperand(i)->isUndef())

      NumUndefsHI++;


  SDValue InVec0, InVec1;

  if (VT == MVT::v8i32 || VT == MVT::v16i16) {

    SDValue InVec2, InVec3;

    unsigned X86Opcode;

    bool CanFold = true;


    if (isHorizontalBinOpPart(BV, ISD::ADD, DL, DAG, 0, Half, InVec0, InVec1) &&

        isHorizontalBinOpPart(BV, ISD::ADD, DL, DAG, Half, NumElts, InVec2,

                              InVec3) &&

        ((InVec0.isUndef() || InVec2.isUndef()) || InVec0 == InVec2) &&

        ((InVec1.isUndef() || InVec3.isUndef()) || InVec1 == InVec3))

      X86Opcode = X86ISD::HADD;

    else if (isHorizontalBinOpPart(BV, ISD::SUB, DL, DAG, 0, Half, InVec0,

                                   InVec1) &&

             isHorizontalBinOpPart(BV, ISD::SUB, DL, DAG, Half, NumElts, InVec2,

                                   InVec3) &&

             ((InVec0.isUndef() || InVec2.isUndef()) || InVec0 == InVec2) &&

             ((InVec1.isUndef() || InVec3.isUndef()) || InVec1 == InVec3))

      X86Opcode = X86ISD::HSUB;

    else

      CanFold = false;


    if (CanFold) {

      // Do not try to expand this build_vector into a pair of horizontal

      // add/sub if we can emit a pair of scalar add/sub.

      if (NumUndefsLO + 1 == Half || NumUndefsHI + 1 == Half)

        return SDValue();


      // Convert this build_vector into a pair of horizontal binops followed by

      // a concat vector. We must adjust the outputs from the partial horizontal

      // matching calls above to account for undefined vector halves.

      SDValue V0 = InVec0.isUndef() ? InVec2 : InVec0;

      SDValue V1 = InVec1.isUndef() ? InVec3 : InVec1;

      assert((!V0.isUndef() || !V1.isUndef()) && "Horizontal-op of undefs?");

      bool isUndefLO = NumUndefsLO == Half;

      bool isUndefHI = NumUndefsHI == Half;

      return ExpandHorizontalBinOp(V0, V1, DL, DAG, X86Opcode, false, isUndefLO,

                                   isUndefHI);

    }

  }


  if (VT == MVT::v8f32 || VT == MVT::v4f64 || VT == MVT::v8i32 ||

      VT == MVT::v16i16) {

    unsigned X86Opcode;

    if (isHorizontalBinOpPart(BV, ISD::ADD, DL, DAG, 0, NumElts, InVec0,

                              InVec1))

      X86Opcode = X86ISD::HADD;

    else if (isHorizontalBinOpPart(BV, ISD::SUB, DL, DAG, 0, NumElts, InVec0,

                                   InVec1))

      X86Opcode = X86ISD::HSUB;

    else if (isHorizontalBinOpPart(BV, ISD::FADD, DL, DAG, 0, NumElts, InVec0,

                                   InVec1))

      X86Opcode = X86ISD::FHADD;

    else if (isHorizontalBinOpPart(BV, ISD::FSUB, DL, DAG, 0, NumElts, InVec0,

                                   InVec1))

      X86Opcode = X86ISD::FHSUB;

    else

      return SDValue();


    // Don't try to expand this build_vector into a pair of horizontal add/sub

    // if we can simply emit a pair of scalar add/sub.

    if (NumUndefsLO + 1 == Half || NumUndefsHI + 1 == Half)

      return SDValue();


    // Convert this build_vector into two horizontal add/sub followed by

    // a concat vector.

    bool isUndefLO = NumUndefsLO == Half;

    bool isUndefHI = NumUndefsHI == Half;

    return ExpandHorizontalBinOp(InVec0, InVec1, DL, DAG, X86Opcode, true,

                                 isUndefLO, isUndefHI);

  }


  return SDValue();

}


static SDValue LowerShift(SDValue Op, const X86Subtarget &Subtarget,

                          SelectionDAG &DAG);


/// If a BUILD_VECTOR's source elements all apply the same bit operation and

/// one of their operands is constant, lower to a pair of BUILD_VECTOR and

/// just apply the bit to the vectors.

/// NOTE: Its not in our interest to start make a general purpose vectorizer

/// from this, but enough scalar bit operations are created from the later

/// legalization + scalarization stages to need basic support.


static SDValue lowerBuildVectorToBitOp(BuildVectorSDNode *Op, const SDLoc &DL,

                                       const X86Subtarget &Subtarget,

                                       SelectionDAG &DAG) {

  MVT VT = Op->getSimpleValueType(0);

  unsigned NumElems = VT.getVectorNumElements();

  unsigned ElemSize = VT.getScalarSizeInBits();

  const TargetLowering &TLI = DAG.getTargetLoweringInfo();


  // Check that all elements have the same opcode.

  // TODO: Should we allow UNDEFS and if so how many?

  unsigned Opcode = Op->getOperand(0).getOpcode();

  for (unsigned i = 1; i < NumElems; ++i)

    if (Opcode != Op->getOperand(i).getOpcode())

      return SDValue();


  // TODO: We may be able to add support for other Ops (e.g. ADD/SUB).

  bool IsShift = false;

  switch (Opcode) {

  default:

    return SDValue();

  case ISD::SHL:

  case ISD::SRL:

  case ISD::SRA:

    IsShift = true;

    break;

  case ISD::AND:

  case ISD::XOR:

  case ISD::OR:

    // Don't do this if the buildvector is a splat - we'd replace one

    // constant with an entire vector.

    if (Op->getSplatValue())

      return SDValue();

    if (!TLI.isOperationLegalOrPromote(Opcode, VT))

      return SDValue();

    break;

  }


  // Collect elements.

  bool RHSAllConst = true;

  SmallVector<SDValue, 4> LHSElts, RHSElts;

  for (SDValue Elt : Op->ops()) {

    SDValue LHS = Elt.getOperand(0);

    SDValue RHS = Elt.getOperand(1);

    RHSAllConst &= isa<ConstantSDNode>(RHS);

    LHSElts.push_back(LHS);

    RHSElts.push_back(RHS);

  }


  // Canonicalize shift amounts.

  if (IsShift) {

    // We expect the canonicalized RHS operand to be the constant.

    // TODO: Permit non-constant XOP/AVX2 cases?

    if (!RHSAllConst)

      return SDValue();


    // Extend shift amounts.

    for (SDValue &Op1 : RHSElts)

      if (Op1.getValueSizeInBits() != ElemSize)

        Op1 = DAG.getZExtOrTrunc(Op1, DL, VT.getScalarType());


    // Limit to shifts by uniform immediates.

    // TODO: Only accept vXi8/vXi64 special cases?

    // TODO: Permit non-uniform XOP/AVX2/MULLO cases?

    if (any_of(RHSElts, [&](SDValue V) { return RHSElts[0] != V; }))

      return SDValue();

  }

  assert(all_of(llvm::concat<SDValue>(LHSElts, RHSElts),

                [ElemSize](SDValue V) {

                  return V.getValueSizeInBits() == ElemSize;

                }) &&

         "Element size mismatch");


  // To avoid an increase in GPR->FPU instructions, LHS/RHS must be foldable as

  // a load or RHS must be constant.

  SDValue LHS = EltsFromConsecutiveLoads(VT, LHSElts, DL, DAG, Subtarget,

                                         /*IsAfterLegalize=*/true);

  SDValue RHS = EltsFromConsecutiveLoads(VT, RHSElts, DL, DAG, Subtarget,

                                         /*IsAfterLegalize=*/true);

  if (!LHS && !RHS && !RHSAllConst)

    return SDValue();


  if (!LHS)

    LHS = DAG.getBuildVector(VT, DL, LHSElts);

  if (!RHS)

    RHS = DAG.getBuildVector(VT, DL, RHSElts);

  SDValue Res = DAG.getNode(Opcode, DL, VT, LHS, RHS);


  if (!IsShift)

    return Res;


  // Immediately lower the shift to ensure the constant build vector doesn't

  // get converted to a constant pool before the shift is lowered.

  return LowerShift(Res, Subtarget, DAG);

}


static bool isShuffleFoldableLoad(SDValue);


/// Attempt to lower a BUILD_VECTOR of scalar values to a shuffle of splats

/// representing a blend.


static SDValue lowerBuildVectorAsBlend(BuildVectorSDNode *BVOp, SDLoc const &DL,

                                       X86Subtarget const &Subtarget,

                                       SelectionDAG &DAG) {

  MVT VT = BVOp->getSimpleValueType(0u);


  if (VT != MVT::v4f64)

    return SDValue();


  // Collect unique operands.

  auto UniqueOps = SmallSet<SDValue, 16u>();

  for (SDValue Op : BVOp->ops()) {

    if (isIntOrFPConstant(Op) || Op.isUndef())

      return SDValue();

    UniqueOps.insert(Op);

  }


  // Candidate BUILD_VECTOR must have 2 unique operands.

  if (UniqueOps.size() != 2u)

    return SDValue();


  SDValue Op0 = BVOp->getOperand(0u);

  UniqueOps.erase(Op0);

  SDValue Op1 = *UniqueOps.begin();


  if (Subtarget.hasAVX2() || isShuffleFoldableLoad(Op0) ||

      isShuffleFoldableLoad(Op1)) {

    // Create shuffle mask.

    auto const NumElems = VT.getVectorNumElements();

    SmallVector<int, 16u> Mask(NumElems);

    for (auto I = 0u; I < NumElems; ++I) {

      SDValue Op = BVOp->getOperand(I);

      Mask[I] = Op == Op0 ? I : I + NumElems;

    }

    // Create shuffle of splats.

    SDValue NewOp0 = DAG.getSplatBuildVector(VT, DL, Op0);

    SDValue NewOp1 = DAG.getSplatBuildVector(VT, DL, Op1);

    return DAG.getVectorShuffle(VT, DL, NewOp0, NewOp1, Mask);

  }


  return SDValue();

}


/// Widen a BUILD_VECTOR if the scalar operands are freely mergeable.


static SDValue widenBuildVector(BuildVectorSDNode *BVOp, SDLoc const &DL,

                                X86Subtarget const &Subtarget,

                                SelectionDAG &DAG) {

  using namespace SDPatternMatch;

  MVT VT = BVOp->getSimpleValueType(0);

  MVT SVT = VT.getScalarType();

  unsigned NumElts = VT.getVectorNumElements();

  unsigned EltBits = SVT.getSizeInBits();


  if (SVT != MVT::i8 && SVT != MVT::i16 && SVT != MVT::i32)

    return SDValue();


  unsigned WideBits = 2 * EltBits;

  MVT WideSVT = MVT::getIntegerVT(WideBits);

  MVT WideVT = MVT::getVectorVT(WideSVT, NumElts / 2);

  if (!DAG.getTargetLoweringInfo().isTypeLegal(WideSVT))

    return SDValue();


  SmallVector<SDValue, 8> WideOps;

  for (unsigned I = 0; I != NumElts; I += 2) {

    SDValue Op0 = BVOp->getOperand(I + 0);

    SDValue Op1 = BVOp->getOperand(I + 1);


    if (Op0.isUndef() && Op1.isUndef()) {

      WideOps.push_back(DAG.getUNDEF(WideSVT));

      continue;

    }


    // TODO: Constant repacking?


    // Merge scalars that have been split from the same source.

    SDValue X, Y;

    if (sd_match(Op0, m_Trunc(m_Value(X))) &&

        sd_match(Op1, m_Trunc(m_Srl(m_Value(Y), m_SpecificInt(EltBits)))) &&

        peekThroughTruncates(X) == peekThroughTruncates(Y) &&

        X.getValueType().bitsGE(WideSVT)) {

      if (X.getValueType().bitsGT(WideSVT))

        X = DAG.getNode(ISD::TRUNCATE, DL, WideSVT, X);

      WideOps.push_back(X);

      continue;

    }


    return SDValue();

  }


  assert(WideOps.size() == (NumElts / 2) && "Failed to widen build vector");

  return DAG.getBitcast(VT, DAG.getBuildVector(WideVT, DL, WideOps));

}


/// Create a vector constant without a load. SSE/AVX provide the bare minimum

/// functionality to do this, so it's all zeros, all ones, or some derivation

/// that is cheap to calculate.


static SDValue materializeVectorConstant(SDValue Op, const SDLoc &DL,

                                         SelectionDAG &DAG,

                                         const X86Subtarget &Subtarget) {

  MVT VT = Op.getSimpleValueType();


  // Vectors containing all zeros can be matched by pxor and xorps.

  if (ISD::isBuildVectorAllZeros(Op.getNode()))

    return Op;


  // Vectors containing all ones can be matched by pcmpeqd on 128-bit width

  // vectors or broken into v4i32 operations on 256-bit vectors. AVX2 can use

  // vpcmpeqd on 256-bit vectors.

  if (Subtarget.hasSSE2() && ISD::isBuildVectorAllOnes(Op.getNode())) {

    if (VT == MVT::v4i32 || VT == MVT::v8i32 || VT == MVT::v16i32)

      return Op;


    return getOnesVector(VT, DAG, DL);

  }


  return SDValue();

}


/// Look for opportunities to create a VPERMV/VPERMILPV/PSHUFB variable permute

/// from a vector of source values and a vector of extraction indices.

/// The vectors might be manipulated to match the type of the permute op.


static SDValue createVariablePermute(MVT VT, SDValue SrcVec, SDValue IndicesVec,

                                     const SDLoc &DL, SelectionDAG &DAG,

                                     const X86Subtarget &Subtarget) {

  MVT ShuffleVT = VT;

  EVT IndicesVT = EVT(VT).changeVectorElementTypeToInteger();

  unsigned NumElts = VT.getVectorNumElements();

  unsigned SizeInBits = VT.getSizeInBits();


  // Adjust IndicesVec to match VT size.

  assert(IndicesVec.getValueType().getVectorNumElements() >= NumElts &&

         "Illegal variable permute mask size");

  if (IndicesVec.getValueType().getVectorNumElements() > NumElts) {

    // Narrow/widen the indices vector to the correct size.

    if (IndicesVec.getValueSizeInBits() > SizeInBits)

      IndicesVec = extractSubVector(IndicesVec, 0, DAG, SDLoc(IndicesVec),

                                    NumElts * VT.getScalarSizeInBits());

    else if (IndicesVec.getValueSizeInBits() < SizeInBits)

      IndicesVec = widenSubVector(IndicesVec, false, Subtarget, DAG,

                                  SDLoc(IndicesVec), SizeInBits);

    // Zero-extend the index elements within the vector.

    if (IndicesVec.getValueType().getVectorNumElements() > NumElts)

      IndicesVec = DAG.getNode(ISD::ZERO_EXTEND_VECTOR_INREG, SDLoc(IndicesVec),

                               IndicesVT, IndicesVec);

  }

  IndicesVec = DAG.getZExtOrTrunc(IndicesVec, SDLoc(IndicesVec), IndicesVT);


  // Handle SrcVec that don't match VT type.

  if (SrcVec.getValueSizeInBits() != SizeInBits) {

    if ((SrcVec.getValueSizeInBits() % SizeInBits) == 0) {

      // Handle larger SrcVec by treating it as a larger permute.

      unsigned Scale = SrcVec.getValueSizeInBits() / SizeInBits;

      VT = MVT::getVectorVT(VT.getScalarType(), Scale * NumElts);

      IndicesVT = EVT(VT).changeVectorElementTypeToInteger();

      IndicesVec = widenSubVector(IndicesVT.getSimpleVT(), IndicesVec, false,

                                  Subtarget, DAG, SDLoc(IndicesVec));

      SDValue NewSrcVec =

          createVariablePermute(VT, SrcVec, IndicesVec, DL, DAG, Subtarget);

      if (NewSrcVec)

        return extractSubVector(NewSrcVec, 0, DAG, DL, SizeInBits);

      return SDValue();

    } else if (SrcVec.getValueSizeInBits() < SizeInBits) {

      // Widen smaller SrcVec to match VT.

      SrcVec = widenSubVector(VT, SrcVec, false, Subtarget, DAG, SDLoc(SrcVec));

    } else

      return SDValue();

  }


  auto ScaleIndices = [&DAG](SDValue Idx, uint64_t Scale) {

    assert(isPowerOf2_64(Scale) && "Illegal variable permute shuffle scale");

    EVT SrcVT = Idx.getValueType();

    unsigned NumDstBits = SrcVT.getScalarSizeInBits() / Scale;

    uint64_t IndexScale = 0;

    uint64_t IndexOffset = 0;


    // If we're scaling a smaller permute op, then we need to repeat the

    // indices, scaling and offsetting them as well.

    // e.g. v4i32 -> v16i8 (Scale = 4)

    // IndexScale = v4i32 Splat(4 << 24 | 4 << 16 | 4 << 8 | 4)

    // IndexOffset = v4i32 Splat(3 << 24 | 2 << 16 | 1 << 8 | 0)

    for (uint64_t i = 0; i != Scale; ++i) {

      IndexScale |= Scale << (i * NumDstBits);

      IndexOffset |= i << (i * NumDstBits);

    }


    Idx = DAG.getNode(ISD::MUL, SDLoc(Idx), SrcVT, Idx,

                      DAG.getConstant(IndexScale, SDLoc(Idx), SrcVT));

    Idx = DAG.getNode(ISD::ADD, SDLoc(Idx), SrcVT, Idx,

                      DAG.getConstant(IndexOffset, SDLoc(Idx), SrcVT));

    return Idx;

  };


  unsigned Opcode = 0;

  switch (VT.SimpleTy) {

  default:

    break;

  case MVT::v16i8:

    if (Subtarget.hasSSSE3())

      Opcode = X86ISD::PSHUFB;

    break;

  case MVT::v8i16:

    if (Subtarget.hasVLX() && Subtarget.hasBWI())

      Opcode = X86ISD::VPERMV;

    else if (Subtarget.hasSSSE3()) {

      Opcode = X86ISD::PSHUFB;

      ShuffleVT = MVT::v16i8;

    }

    break;

  case MVT::v4f32:

  case MVT::v4i32:

    if (Subtarget.hasAVX()) {

      Opcode = X86ISD::VPERMILPV;

      ShuffleVT = MVT::v4f32;

    } else if (Subtarget.hasSSSE3()) {

      Opcode = X86ISD::PSHUFB;

      ShuffleVT = MVT::v16i8;

    }

    break;

  case MVT::v2f64:

  case MVT::v2i64:

    if (Subtarget.hasAVX()) {

      // VPERMILPD selects using bit#1 of the index vector, so scale IndicesVec.

      IndicesVec = DAG.getNode(ISD::ADD, DL, IndicesVT, IndicesVec, IndicesVec);

      Opcode = X86ISD::VPERMILPV;

      ShuffleVT = MVT::v2f64;

    } else if (Subtarget.hasSSE41()) {

      // SSE41 can compare v2i64 - select between indices 0 and 1.

      return DAG.getSelectCC(

          DL, IndicesVec,

          getZeroVector(IndicesVT.getSimpleVT(), Subtarget, DAG, DL),

          DAG.getVectorShuffle(VT, DL, SrcVec, SrcVec, {0, 0}),

          DAG.getVectorShuffle(VT, DL, SrcVec, SrcVec, {1, 1}),

          ISD::CondCode::SETEQ);

    }

    break;

  case MVT::v32i8:

    if (Subtarget.hasVLX() && Subtarget.hasVBMI())

      Opcode = X86ISD::VPERMV;

    else if (Subtarget.hasXOP()) {

      SDValue LoSrc = extract128BitVector(SrcVec, 0, DAG, DL);

      SDValue HiSrc = extract128BitVector(SrcVec, 16, DAG, DL);

      SDValue LoIdx = extract128BitVector(IndicesVec, 0, DAG, DL);

      SDValue HiIdx = extract128BitVector(IndicesVec, 16, DAG, DL);

      return DAG.getNode(

          ISD::CONCAT_VECTORS, DL, VT,

          DAG.getNode(X86ISD::VPPERM, DL, MVT::v16i8, LoSrc, HiSrc, LoIdx),

          DAG.getNode(X86ISD::VPPERM, DL, MVT::v16i8, LoSrc, HiSrc, HiIdx));

    } else if (Subtarget.hasAVX()) {

      SDValue Lo = extract128BitVector(SrcVec, 0, DAG, DL);

      SDValue Hi = extract128BitVector(SrcVec, 16, DAG, DL);

      SDValue LoLo = DAG.getNode(ISD::CONCAT_VECTORS, DL, VT, Lo, Lo);

      SDValue HiHi = DAG.getNode(ISD::CONCAT_VECTORS, DL, VT, Hi, Hi);

      auto PSHUFBBuilder = [](SelectionDAG &DAG, const SDLoc &DL,

                              ArrayRef<SDValue> Ops) {

        // Permute Lo and Hi and then select based on index range.

        // This works as SHUFB uses bits[3:0] to permute elements and we don't

        // care about the bit[7] as its just an index vector.

        SDValue Idx = Ops[2];

        EVT VT = Idx.getValueType();

        return DAG.getSelectCC(DL, Idx, DAG.getConstant(15, DL, VT),

                               DAG.getNode(X86ISD::PSHUFB, DL, VT, Ops[1], Idx),

                               DAG.getNode(X86ISD::PSHUFB, DL, VT, Ops[0], Idx),

                               ISD::CondCode::SETGT);

      };

      SDValue Ops[] = {LoLo, HiHi, IndicesVec};

      return SplitOpsAndApply(DAG, Subtarget, DL, MVT::v32i8, Ops,

                              PSHUFBBuilder);

    }

    break;

  case MVT::v16i16:

    if (Subtarget.hasVLX() && Subtarget.hasBWI())

      Opcode = X86ISD::VPERMV;

    else if (Subtarget.hasAVX()) {

      // Scale to v32i8 and perform as v32i8.

      IndicesVec = ScaleIndices(IndicesVec, 2);

      return DAG.getBitcast(

          VT, createVariablePermute(

                  MVT::v32i8, DAG.getBitcast(MVT::v32i8, SrcVec),

                  DAG.getBitcast(MVT::v32i8, IndicesVec), DL, DAG, Subtarget));

    }

    break;

  case MVT::v8f32:

  case MVT::v8i32:

    if (Subtarget.hasAVX2())

      Opcode = X86ISD::VPERMV;

    else if (Subtarget.hasAVX()) {

      SrcVec = DAG.getBitcast(MVT::v8f32, SrcVec);

      SDValue LoLo = DAG.getVectorShuffle(MVT::v8f32, DL, SrcVec, SrcVec,

                                          {0, 1, 2, 3, 0, 1, 2, 3});

      SDValue HiHi = DAG.getVectorShuffle(MVT::v8f32, DL, SrcVec, SrcVec,

                                          {4, 5, 6, 7, 4, 5, 6, 7});

      if (Subtarget.hasXOP())

        return DAG.getBitcast(

            VT, DAG.getNode(X86ISD::VPERMIL2, DL, MVT::v8f32, LoLo, HiHi,

                            IndicesVec, DAG.getTargetConstant(0, DL, MVT::i8)));

      // Permute Lo and Hi and then select based on index range.

      // This works as VPERMILPS only uses index bits[0:1] to permute elements.

      SDValue Res = DAG.getSelectCC(

          DL, IndicesVec, DAG.getConstant(3, DL, MVT::v8i32),

          DAG.getNode(X86ISD::VPERMILPV, DL, MVT::v8f32, HiHi, IndicesVec),

          DAG.getNode(X86ISD::VPERMILPV, DL, MVT::v8f32, LoLo, IndicesVec),

          ISD::CondCode::SETGT);

      return DAG.getBitcast(VT, Res);

    }

    break;

  case MVT::v4i64:

  case MVT::v4f64:

    if (Subtarget.hasAVX512()) {

      if (!Subtarget.hasVLX()) {

        MVT WidenSrcVT = MVT::getVectorVT(VT.getScalarType(), 8);

        SrcVec = widenSubVector(WidenSrcVT, SrcVec, false, Subtarget, DAG,

                                SDLoc(SrcVec));

        IndicesVec = widenSubVector(MVT::v8i64, IndicesVec, false, Subtarget,

                                    DAG, SDLoc(IndicesVec));

        SDValue Res = createVariablePermute(WidenSrcVT, SrcVec, IndicesVec, DL,

                                            DAG, Subtarget);

        return extract256BitVector(Res, 0, DAG, DL);

      }

      Opcode = X86ISD::VPERMV;

    } else if (Subtarget.hasAVX()) {

      SrcVec = DAG.getBitcast(MVT::v4f64, SrcVec);

      SDValue LoLo =

          DAG.getVectorShuffle(MVT::v4f64, DL, SrcVec, SrcVec, {0, 1, 0, 1});

      SDValue HiHi =

          DAG.getVectorShuffle(MVT::v4f64, DL, SrcVec, SrcVec, {2, 3, 2, 3});

      // VPERMIL2PD selects with bit#1 of the index vector, so scale IndicesVec.

      IndicesVec = DAG.getNode(ISD::ADD, DL, IndicesVT, IndicesVec, IndicesVec);

      if (Subtarget.hasXOP())

        return DAG.getBitcast(

            VT, DAG.getNode(X86ISD::VPERMIL2, DL, MVT::v4f64, LoLo, HiHi,

                            IndicesVec, DAG.getTargetConstant(0, DL, MVT::i8)));

      // Permute Lo and Hi and then select based on index range.

      // This works as VPERMILPD only uses index bit[1] to permute elements.

      SDValue Res = DAG.getSelectCC(

          DL, IndicesVec, DAG.getConstant(2, DL, MVT::v4i64),

          DAG.getNode(X86ISD::VPERMILPV, DL, MVT::v4f64, HiHi, IndicesVec),

          DAG.getNode(X86ISD::VPERMILPV, DL, MVT::v4f64, LoLo, IndicesVec),

          ISD::CondCode::SETGT);

      return DAG.getBitcast(VT, Res);

    }

    break;

  case MVT::v64i8:

    if (Subtarget.hasVBMI())

      Opcode = X86ISD::VPERMV;

    break;

  case MVT::v32i16:

    if (Subtarget.hasBWI())

      Opcode = X86ISD::VPERMV;

    break;

  case MVT::v16f32:

  case MVT::v16i32:

  case MVT::v8f64:

  case MVT::v8i64:

    if (Subtarget.hasAVX512())

      Opcode = X86ISD::VPERMV;

    break;

  }

  if (!Opcode)

    return SDValue();


  assert((VT.getSizeInBits() == ShuffleVT.getSizeInBits()) &&

         (VT.getScalarSizeInBits() % ShuffleVT.getScalarSizeInBits()) == 0 &&

         "Illegal variable permute shuffle type");


  uint64_t Scale = VT.getScalarSizeInBits() / ShuffleVT.getScalarSizeInBits();

  if (Scale > 1)

    IndicesVec = ScaleIndices(IndicesVec, Scale);


  EVT ShuffleIdxVT = EVT(ShuffleVT).changeVectorElementTypeToInteger();

  IndicesVec = DAG.getBitcast(ShuffleIdxVT, IndicesVec);


  SrcVec = DAG.getBitcast(ShuffleVT, SrcVec);

  SDValue Res = Opcode == X86ISD::VPERMV

                    ? DAG.getNode(Opcode, DL, ShuffleVT, IndicesVec, SrcVec)

                    : DAG.getNode(Opcode, DL, ShuffleVT, SrcVec, IndicesVec);

  return DAG.getBitcast(VT, Res);

}


// Tries to lower a BUILD_VECTOR composed of extract-extract chains that can be

// reasoned to be a permutation of a vector by indices in a non-constant vector.

// (build_vector (extract_elt V, (extract_elt I, 0)),

//               (extract_elt V, (extract_elt I, 1)),

//                    ...

// ->

// (vpermv I, V)

//

// TODO: Handle undefs

// TODO: Utilize pshufb and zero mask blending to support more efficient

// construction of vectors with constant-0 elements.

static SDValue


LowerBUILD_VECTORAsVariablePermute(SDValue V, const SDLoc &DL,

                                   SelectionDAG &DAG,

                                   const X86Subtarget &Subtarget) {

  SDValue SrcVec, IndicesVec;


  auto PeekThroughFreeze = [](SDValue N) {

    if (N->getOpcode() == ISD::FREEZE && N.hasOneUse())

      return N->getOperand(0);

    return N;

  };

  // Check for a match of the permute source vector and permute index elements.

  // This is done by checking that the i-th build_vector operand is of the form:

  // (extract_elt SrcVec, (extract_elt IndicesVec, i)).

  for (unsigned Idx = 0, E = V.getNumOperands(); Idx != E; ++Idx) {

    SDValue Op = PeekThroughFreeze(V.getOperand(Idx));

    if (Op.getOpcode() != ISD::EXTRACT_VECTOR_ELT)

      return SDValue();


    // If this is the first extract encountered in V, set the source vector,

    // otherwise verify the extract is from the previously defined source

    // vector.

    if (!SrcVec)

      SrcVec = Op.getOperand(0);

    else if (SrcVec != Op.getOperand(0))

      return SDValue();

    SDValue ExtractedIndex = Op->getOperand(1);

    // Peek through extends.

    if (ExtractedIndex.getOpcode() == ISD::ZERO_EXTEND ||

        ExtractedIndex.getOpcode() == ISD::SIGN_EXTEND)

      ExtractedIndex = ExtractedIndex.getOperand(0);

    if (ExtractedIndex.getOpcode() != ISD::EXTRACT_VECTOR_ELT)

      return SDValue();


    // If this is the first extract from the index vector candidate, set the

    // indices vector, otherwise verify the extract is from the previously

    // defined indices vector.

    if (!IndicesVec)

      IndicesVec = ExtractedIndex.getOperand(0);

    else if (IndicesVec != ExtractedIndex.getOperand(0))

      return SDValue();


    auto *PermIdx = dyn_cast<ConstantSDNode>(ExtractedIndex.getOperand(1));

    if (!PermIdx || PermIdx->getAPIntValue() != Idx)

      return SDValue();

  }


  MVT VT = V.getSimpleValueType();

  return createVariablePermute(VT, SrcVec, IndicesVec, DL, DAG, Subtarget);

}


SDValue

X86TargetLowering::LowerBUILD_VECTOR(SDValue Op, SelectionDAG &DAG) const {

  SDLoc dl(Op);


  MVT VT = Op.getSimpleValueType();

  MVT EltVT = VT.getVectorElementType();

  MVT OpEltVT = Op.getOperand(0).getSimpleValueType();

  unsigned NumElems = Op.getNumOperands();


  // Generate vectors for predicate vectors.

  if (VT.getVectorElementType() == MVT::i1 && Subtarget.hasAVX512())

    return LowerBUILD_VECTORvXi1(Op, dl, DAG, Subtarget);


  if (VT.getVectorElementType() == MVT::bf16 &&

      (Subtarget.hasAVXNECONVERT() || Subtarget.hasBF16()))

    return LowerBUILD_VECTORvXbf16(Op, DAG, Subtarget);


  if (SDValue VectorCst = materializeVectorConstant(Op, dl, DAG, Subtarget))

    return VectorCst;


  unsigned EVTBits = EltVT.getSizeInBits();

  APInt UndefMask = APInt::getZero(NumElems);

  APInt FrozenUndefMask = APInt::getZero(NumElems);

  APInt ZeroMask = APInt::getZero(NumElems);

  APInt NonZeroMask = APInt::getZero(NumElems);

  bool IsAllConstants = true;

  bool OneUseFrozenUndefs = true;

  SmallSet<SDValue, 8> Values;

  unsigned NumConstants = NumElems;

  for (unsigned i = 0; i < NumElems; ++i) {

    SDValue Elt = Op.getOperand(i);

    if (Elt.isUndef()) {

      UndefMask.setBit(i);

      continue;

    }

    if (ISD::isFreezeUndef(Elt.getNode())) {

      OneUseFrozenUndefs = OneUseFrozenUndefs && Elt->hasOneUse();

      FrozenUndefMask.setBit(i);

      continue;

    }

    Values.insert(Elt);

    if (!isIntOrFPConstant(Elt)) {

      IsAllConstants = false;

      NumConstants--;

    }

    if (X86::isZeroNode(Elt)) {

      ZeroMask.setBit(i);

    } else {

      NonZeroMask.setBit(i);

    }

  }


  // All undef vector. Return an UNDEF.

  if (UndefMask.isAllOnes())

    return DAG.getUNDEF(VT);


  // All undef/freeze(undef) vector. Return a FREEZE UNDEF.

  if (OneUseFrozenUndefs && (UndefMask | FrozenUndefMask).isAllOnes())

    return DAG.getFreeze(DAG.getUNDEF(VT));


  // All undef/freeze(undef)/zero vector. Return a zero vector.

  if ((UndefMask | FrozenUndefMask | ZeroMask).isAllOnes())

    return getZeroVector(VT, Subtarget, DAG, dl);


  // If we have multiple FREEZE-UNDEF operands, we are likely going to end up

  // lowering into a suboptimal insertion sequence. Instead, thaw the UNDEF in

  // our source BUILD_VECTOR, create another FREEZE-UNDEF splat BUILD_VECTOR,

  // and blend the FREEZE-UNDEF operands back in.

  // FIXME: is this worthwhile even for a single FREEZE-UNDEF operand?

  if (unsigned NumFrozenUndefElts = FrozenUndefMask.popcount();

      NumFrozenUndefElts >= 2 && NumFrozenUndefElts < NumElems) {

    SmallVector<int, 16> BlendMask(NumElems, -1);

    SmallVector<SDValue, 16> Elts(NumElems, DAG.getUNDEF(OpEltVT));

    for (unsigned i = 0; i < NumElems; ++i) {

      if (UndefMask[i]) {

        BlendMask[i] = -1;

        continue;

      }

      BlendMask[i] = i;

      if (!FrozenUndefMask[i])

        Elts[i] = Op.getOperand(i);

      else

        BlendMask[i] += NumElems;

    }

    SDValue EltsBV = DAG.getBuildVector(VT, dl, Elts);

    SDValue FrozenUndefElt = DAG.getFreeze(DAG.getUNDEF(OpEltVT));

    SDValue FrozenUndefBV = DAG.getSplatBuildVector(VT, dl, FrozenUndefElt);

    return DAG.getVectorShuffle(VT, dl, EltsBV, FrozenUndefBV, BlendMask);

  }


  BuildVectorSDNode *BV = cast<BuildVectorSDNode>(Op.getNode());


  // If the upper elts of a ymm/zmm are undef/freeze(undef)/zero then we might

  // be better off lowering to a smaller build vector and padding with

  // undef/zero.

  if ((VT.is256BitVector() || VT.is512BitVector()) &&

      !isFoldableUseOfShuffle(BV)) {

    unsigned UpperElems = NumElems / 2;

    APInt UndefOrZeroMask = FrozenUndefMask | UndefMask | ZeroMask;

    unsigned NumUpperUndefsOrZeros = UndefOrZeroMask.countl_one();

    if (NumUpperUndefsOrZeros >= UpperElems) {

      if (VT.is512BitVector() &&

          NumUpperUndefsOrZeros >= (NumElems - (NumElems / 4)))

        UpperElems = NumElems - (NumElems / 4);

      // If freeze(undef) is in any upper elements, force to zero.

      bool UndefUpper = UndefMask.countl_one() >= UpperElems;

      MVT LowerVT = MVT::getVectorVT(EltVT, NumElems - UpperElems);

      SDValue NewBV =

          DAG.getBuildVector(LowerVT, dl, Op->ops().drop_back(UpperElems));

      return widenSubVector(VT, NewBV, !UndefUpper, Subtarget, DAG, dl);

    }

  }


  if (SDValue AddSub = lowerToAddSubOrFMAddSub(BV, dl, Subtarget, DAG))

    return AddSub;

  if (SDValue HorizontalOp = LowerToHorizontalOp(BV, dl, Subtarget, DAG))

    return HorizontalOp;

  if (SDValue Broadcast = lowerBuildVectorAsBroadcast(BV, dl, Subtarget, DAG))

    return Broadcast;

  if (SDValue BitOp = lowerBuildVectorToBitOp(BV, dl, Subtarget, DAG))

    return BitOp;

  if (SDValue Blend = lowerBuildVectorAsBlend(BV, dl, Subtarget, DAG))

    return Blend;

  if (SDValue WideBV = widenBuildVector(BV, dl, Subtarget, DAG))

    return WideBV;


  unsigned NumZero = ZeroMask.popcount();

  unsigned NumNonZero = NonZeroMask.popcount();


  // If we are inserting one variable into a vector of non-zero constants, try

  // to avoid loading each constant element as a scalar. Load the constants as a

  // vector and then insert the variable scalar element. If insertion is not

  // supported, fall back to a shuffle to get the scalar blended with the

  // constants. Insertion into a zero vector is handled as a special-case

  // somewhere below here.

  if (NumConstants == NumElems - 1 && NumNonZero != 1 &&

      FrozenUndefMask.isZero() &&

      (isOperationLegalOrCustom(ISD::INSERT_VECTOR_ELT, VT) ||

       isOperationLegalOrCustom(ISD::VECTOR_SHUFFLE, VT))) {

    // Create an all-constant vector. The variable element in the old

    // build vector is replaced by undef in the constant vector. Save the

    // variable scalar element and its index for use in the insertelement.

    LLVMContext &Context = *DAG.getContext();

    Type *EltType = Op.getValueType().getScalarType().getTypeForEVT(Context);

    SmallVector<Constant *, 16> ConstVecOps(NumElems, UndefValue::get(EltType));

    SDValue VarElt;

    SDValue InsIndex;

    for (unsigned i = 0; i != NumElems; ++i) {

      SDValue Elt = Op.getOperand(i);

      if (auto *C = dyn_cast<ConstantSDNode>(Elt))

        ConstVecOps[i] = ConstantInt::get(Context, C->getAPIntValue());

      else if (auto *C = dyn_cast<ConstantFPSDNode>(Elt))

        ConstVecOps[i] = ConstantFP::get(Context, C->getValueAPF());

      else if (!Elt.isUndef()) {

        assert(!VarElt.getNode() && !InsIndex.getNode() &&

               "Expected one variable element in this vector");

        VarElt = Elt;

        InsIndex = DAG.getVectorIdxConstant(i, dl);

      }

    }

    Constant *CV = ConstantVector::get(ConstVecOps);

    SDValue DAGConstVec = DAG.getConstantPool(CV, VT);


    // The constants we just created may not be legal (eg, floating point). We

    // must lower the vector right here because we can not guarantee that we'll

    // legalize it before loading it. This is also why we could not just create

    // a new build vector here. If the build vector contains illegal constants,

    // it could get split back up into a series of insert elements.

    // TODO: Improve this by using shorter loads with broadcast/VZEXT_LOAD.

    SDValue LegalDAGConstVec = LowerConstantPool(DAGConstVec, DAG);

    MachineFunction &MF = DAG.getMachineFunction();

    MachinePointerInfo MPI = MachinePointerInfo::getConstantPool(MF);

    SDValue Ld = DAG.getLoad(VT, dl, DAG.getEntryNode(), LegalDAGConstVec, MPI);

    unsigned InsertC = InsIndex->getAsZExtVal();

    unsigned NumEltsInLow128Bits = 128 / VT.getScalarSizeInBits();

    if (InsertC < NumEltsInLow128Bits)

      return DAG.getNode(ISD::INSERT_VECTOR_ELT, dl, VT, Ld, VarElt, InsIndex);


    // There's no good way to insert into the high elements of a >128-bit

    // vector, so use shuffles to avoid an extract/insert sequence.

    assert(VT.getSizeInBits() > 128 && "Invalid insertion index?");

    assert(Subtarget.hasAVX() && "Must have AVX with >16-byte vector");

    SmallVector<int, 8> ShuffleMask;

    unsigned NumElts = VT.getVectorNumElements();

    for (unsigned i = 0; i != NumElts; ++i)

      ShuffleMask.push_back(i == InsertC ? NumElts : i);

    SDValue S2V = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, VT, VarElt);

    return DAG.getVectorShuffle(VT, dl, Ld, S2V, ShuffleMask);

  }


  // Special case for single non-zero, non-undef, element.

  if (NumNonZero == 1) {

    unsigned Idx = NonZeroMask.countr_zero();

    SDValue Item = Op.getOperand(Idx);


    // If we have a constant or non-constant insertion into the low element of

    // a vector, we can do this with SCALAR_TO_VECTOR + shuffle of zero into

    // the rest of the elements.  This will be matched as movd/movq/movss/movsd

    // depending on what the source datatype is.

    if (Idx == 0) {

      if (NumZero == 0)

        return DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, VT, Item);


      if (EltVT == MVT::i32 || EltVT == MVT::f16 || EltVT == MVT::f32 ||

          EltVT == MVT::f64 || (EltVT == MVT::i64 && Subtarget.is64Bit()) ||

          (EltVT == MVT::i16 && Subtarget.hasFP16())) {

        assert((VT.is128BitVector() || VT.is256BitVector() ||

                VT.is512BitVector()) &&

               "Expected an SSE value type!");

        Item = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, VT, Item);

        // Turn it into a MOVL (i.e. movsh, movss, movsd, movw or movd) to a

        // zero vector.

        return getShuffleVectorZeroOrUndef(Item, 0, true, Subtarget, DAG);

      }


      // We can't directly insert an i8 or i16 into a vector, so zero extend

      // it to i32 first.

      if (EltVT == MVT::i16 || EltVT == MVT::i8) {

        Item = DAG.getNode(ISD::ZERO_EXTEND, dl, MVT::i32, Item);

        MVT ShufVT = MVT::getVectorVT(MVT::i32, VT.getSizeInBits() / 32);

        Item = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, ShufVT, Item);

        Item = getShuffleVectorZeroOrUndef(Item, 0, true, Subtarget, DAG);

        return DAG.getBitcast(VT, Item);

      }

    }


    // Is it a vector logical left shift?

    if (NumElems == 2 && Idx == 1 &&

        X86::isZeroNode(Op.getOperand(0)) &&

        !X86::isZeroNode(Op.getOperand(1))) {

      unsigned NumBits = VT.getSizeInBits();

      return getVShift(true, VT,

                       DAG.getNode(ISD::SCALAR_TO_VECTOR, dl,

                                   VT, Op.getOperand(1)),

                       NumBits/2, DAG, *this, dl);

    }


    if (IsAllConstants) // Otherwise, it's better to do a constpool load.

      return SDValue();


    // Otherwise, if this is a vector with i32 or f32 elements, and the element

    // is a non-constant being inserted into an element other than the low one,

    // we can't use a constant pool load.  Instead, use SCALAR_TO_VECTOR (aka

    // movd/movss) to move this into the low element, then shuffle it into

    // place.

    if (EVTBits == 32) {

      Item = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, VT, Item);

      return getShuffleVectorZeroOrUndef(Item, Idx, NumZero > 0, Subtarget, DAG);

    }

  }


  // Splat is obviously ok. Let legalizer expand it to a shuffle.

  if (Values.size() == 1) {

    if (EVTBits == 32) {

      // Instead of a shuffle like this:

      // shuffle (scalar_to_vector (load (ptr + 4))), undef, <0, 0, 0, 0>

      // Check if it's possible to issue this instead.

      // shuffle (vload ptr)), undef, <1, 1, 1, 1>

      unsigned Idx = NonZeroMask.countr_zero();

      SDValue Item = Op.getOperand(Idx);

      if (Op.getNode()->isOnlyUserOf(Item.getNode()))

        return LowerAsSplatVectorLoad(Item, VT, dl, DAG);

    }

    return SDValue();

  }


  // A vector full of immediates; various special cases are already

  // handled, so this is best done with a single constant-pool load.

  if (IsAllConstants)

    return SDValue();


  if (SDValue V = LowerBUILD_VECTORAsVariablePermute(Op, dl, DAG, Subtarget))

    return V;


  // See if we can use a vector load to get all of the elements.

  {

    SmallVector<SDValue, 64> Ops(Op->ops().take_front(NumElems));

    if (SDValue LD =

            EltsFromConsecutiveLoads(VT, Ops, dl, DAG, Subtarget, false))

      return LD;

  }


  // If this is a splat of pairs of 32-bit elements, we can use a narrower

  // build_vector and broadcast it.

  // TODO: We could probably generalize this more.

  if (Subtarget.hasAVX2() && EVTBits == 32 && Values.size() == 2) {

    SDValue Ops[4] = { Op.getOperand(0), Op.getOperand(1),

                       DAG.getUNDEF(EltVT), DAG.getUNDEF(EltVT) };

    auto CanSplat = [](SDValue Op, unsigned NumElems, ArrayRef<SDValue> Ops) {

      // Make sure all the even/odd operands match.

      for (unsigned i = 2; i != NumElems; ++i)

        if (Ops[i % 2] != Op.getOperand(i))

          return false;

      return true;

    };

    if (CanSplat(Op, NumElems, Ops)) {

      MVT WideEltVT = VT.isFloatingPoint() ? MVT::f64 : MVT::i64;

      MVT NarrowVT = MVT::getVectorVT(EltVT, 4);

      // Create a new build vector and cast to v2i64/v2f64.

      SDValue NewBV = DAG.getBitcast(MVT::getVectorVT(WideEltVT, 2),

                                     DAG.getBuildVector(NarrowVT, dl, Ops));

      // Broadcast from v2i64/v2f64 and cast to final VT.

      MVT BcastVT = MVT::getVectorVT(WideEltVT, NumElems / 2);

      return DAG.getBitcast(VT, DAG.getNode(X86ISD::VBROADCAST, dl, BcastVT,

                                            NewBV));

    }

  }


  // For AVX-length vectors, build the individual 128-bit pieces and use

  // shuffles to put them in place.

  if (VT.getSizeInBits() > 128) {

    MVT HVT = MVT::getVectorVT(EltVT, NumElems / 2);


    // Build both the lower and upper subvector.

    SDValue Lower =

        DAG.getBuildVector(HVT, dl, Op->ops().slice(0, NumElems / 2));

    SDValue Upper = DAG.getBuildVector(

        HVT, dl, Op->ops().slice(NumElems / 2, NumElems /2));


    // Recreate the wider vector with the lower and upper part.

    return concatSubVectors(Lower, Upper, DAG, dl);

  }


  // Let legalizer expand 2-wide build_vectors.

  if (EVTBits == 64) {

    if (NumNonZero == 1) {

      // One half is zero or undef.

      unsigned Idx = NonZeroMask.countr_zero();

      SDValue V2 = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, VT,

                               Op.getOperand(Idx));

      return getShuffleVectorZeroOrUndef(V2, Idx, true, Subtarget, DAG);

    }

    return SDValue();

  }


  // If element VT is < 32 bits, convert it to inserts into a zero vector.

  if (EVTBits == 8 && NumElems == 16)

    if (SDValue V = LowerBuildVectorv16i8(Op, dl, NonZeroMask, NumNonZero,

                                          NumZero, DAG, Subtarget))

      return V;


  if (EltVT == MVT::i16 && NumElems == 8)

    if (SDValue V = LowerBuildVectorv8i16(Op, dl, NonZeroMask, NumNonZero,

                                          NumZero, DAG, Subtarget))

      return V;


  // If element VT is == 32 bits and has 4 elems, try to generate an INSERTPS

  if (EVTBits == 32 && NumElems == 4)

    if (SDValue V = LowerBuildVectorv4x32(Op, dl, DAG, Subtarget))

      return V;


  // If element VT is == 32 bits, turn it into a number of shuffles.

  if (NumElems == 4 && NumZero > 0) {

    SmallVector<SDValue, 8> Ops(NumElems);

    for (unsigned i = 0; i < 4; ++i) {

      bool isZero = !NonZeroMask[i];

      if (isZero)

        Ops[i] = getZeroVector(VT, Subtarget, DAG, dl);

      else

        Ops[i] = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, VT, Op.getOperand(i));

    }


    for (unsigned i = 0; i < 2; ++i) {

      switch (NonZeroMask.extractBitsAsZExtValue(2, i * 2)) {

        default: llvm_unreachable("Unexpected NonZero count");

        case 0:

          Ops[i] = Ops[i*2];  // Must be a zero vector.

          break;

        case 1:

          Ops[i] = getMOVL(DAG, dl, VT, Ops[i*2+1], Ops[i*2]);

          break;

        case 2:

          Ops[i] = getMOVL(DAG, dl, VT, Ops[i*2], Ops[i*2+1]);

          break;

        case 3:

          Ops[i] = getUnpackl(DAG, dl, VT, Ops[i*2], Ops[i*2+1]);

          break;

      }

    }


    bool Reverse1 = NonZeroMask.extractBitsAsZExtValue(2, 0) == 2;

    bool Reverse2 = NonZeroMask.extractBitsAsZExtValue(2, 2) == 2;

    int MaskVec[] = {

      Reverse1 ? 1 : 0,

      Reverse1 ? 0 : 1,

      static_cast<int>(Reverse2 ? NumElems+1 : NumElems),

      static_cast<int>(Reverse2 ? NumElems   : NumElems+1)

    };

    return DAG.getVectorShuffle(VT, dl, Ops[0], Ops[1], MaskVec);

  }


  assert(Values.size() > 1 && "Expected non-undef and non-splat vector");


  // Check for a build vector from mostly shuffle plus few inserting.

  if (SDValue Sh = buildFromShuffleMostly(Op, dl, DAG))

    return Sh;


  // For SSE 4.1, use insertps to put the high elements into the low element.

  if (Subtarget.hasSSE41() && EltVT != MVT::f16) {

    SDValue Result;

    if (!Op.getOperand(0).isUndef())

      Result = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, VT, Op.getOperand(0));

    else

      Result = DAG.getUNDEF(VT);


    for (unsigned i = 1; i < NumElems; ++i) {

      if (Op.getOperand(i).isUndef()) continue;

      Result = DAG.getNode(ISD::INSERT_VECTOR_ELT, dl, VT, Result,

                           Op.getOperand(i), DAG.getVectorIdxConstant(i, dl));

    }

    return Result;

  }


  // Otherwise, expand into a number of unpckl*, start by extending each of

  // our (non-undef) elements to the full vector width with the element in the

  // bottom slot of the vector (which generates no code for SSE).

  SmallVector<SDValue, 8> Ops(NumElems);

  for (unsigned i = 0; i < NumElems; ++i) {

    if (!Op.getOperand(i).isUndef())

      Ops[i] = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, VT, Op.getOperand(i));

    else

      Ops[i] = DAG.getUNDEF(VT);

  }


  // Next, we iteratively mix elements, e.g. for v4f32:

  //   Step 1: unpcklps 0, 1 ==> X: <?, ?, 1, 0>

  //         : unpcklps 2, 3 ==> Y: <?, ?, 3, 2>

  //   Step 2: unpcklpd X, Y ==>    <3, 2, 1, 0>

  for (unsigned Scale = 1; Scale < NumElems; Scale *= 2) {

    // Generate scaled UNPCKL shuffle mask.

    SmallVector<int, 16> Mask;

    for(unsigned i = 0; i != Scale; ++i)

      Mask.push_back(i);

    for (unsigned i = 0; i != Scale; ++i)

      Mask.push_back(NumElems+i);

    Mask.append(NumElems - Mask.size(), SM_SentinelUndef);


    for (unsigned i = 0, e = NumElems / (2 * Scale); i != e; ++i)

      Ops[i] = DAG.getVectorShuffle(VT, dl, Ops[2*i], Ops[(2*i)+1], Mask);

  }

  return Ops[0];

}


// 256-bit AVX can use the vinsertf128 instruction

// to create 256-bit vectors from two other 128-bit ones.

// TODO: Detect subvector broadcast here instead of DAG combine?


static SDValue LowerAVXCONCAT_VECTORS(SDValue Op, const SDLoc &dl,

                                      SelectionDAG &DAG,

                                      const X86Subtarget &Subtarget) {

  MVT ResVT = Op.getSimpleValueType();

  assert((ResVT.is256BitVector() || ResVT.is512BitVector()) &&

         "Value type must be 256-/512-bit wide");


  unsigned NumOperands = Op.getNumOperands();

  unsigned NumFreezeUndef = 0;

  unsigned NumZero = 0;

  unsigned NumNonZero = 0;

  unsigned NonZeros = 0;

  SmallSet<SDValue, 4> Undefs;

  for (unsigned i = 0; i != NumOperands; ++i) {

    SDValue SubVec = Op.getOperand(i);

    if (SubVec.isUndef())

      continue;

    if (ISD::isFreezeUndef(SubVec.getNode())) {

        // If the freeze(undef) has multiple uses then we must fold to zero.

        if (SubVec.hasOneUse()) {

          ++NumFreezeUndef;

        } else {

          ++NumZero;

          Undefs.insert(SubVec);

        }

    }

    else if (ISD::isBuildVectorAllZeros(SubVec.getNode()))

      ++NumZero;

    else {

      assert(i < sizeof(NonZeros) * CHAR_BIT); // Ensure the shift is in range.

      NonZeros |= 1 << i;

      ++NumNonZero;

    }

  }


  // If we have more than 2 non-zeros, build each half separately.

  if (NumNonZero > 2) {

    MVT HalfVT = ResVT.getHalfNumVectorElementsVT();

    ArrayRef<SDUse> Ops = Op->ops();

    SDValue Lo = DAG.getNode(ISD::CONCAT_VECTORS, dl, HalfVT,

                             Ops.slice(0, NumOperands/2));

    SDValue Hi = DAG.getNode(ISD::CONCAT_VECTORS, dl, HalfVT,

                             Ops.slice(NumOperands/2));

    return DAG.getNode(ISD::CONCAT_VECTORS, dl, ResVT, Lo, Hi);

  }


  // Otherwise, build it up through insert_subvectors.

  SDValue Vec = NumZero ? getZeroVector(ResVT, Subtarget, DAG, dl)

                        : (NumFreezeUndef ? DAG.getFreeze(DAG.getUNDEF(ResVT))

                                          : DAG.getUNDEF(ResVT));


  // Replace Undef operands with ZeroVector.

  for (SDValue U : Undefs)

    DAG.ReplaceAllUsesWith(

        U, getZeroVector(U.getSimpleValueType(), Subtarget, DAG, dl));


  MVT SubVT = Op.getOperand(0).getSimpleValueType();

  unsigned NumSubElems = SubVT.getVectorNumElements();

  for (unsigned i = 0; i != NumOperands; ++i) {

    if ((NonZeros & (1 << i)) == 0)

      continue;


    Vec = DAG.getNode(ISD::INSERT_SUBVECTOR, dl, ResVT, Vec, Op.getOperand(i),

                      DAG.getVectorIdxConstant(i * NumSubElems, dl));

  }


  return Vec;

}


// Returns true if the given node is a type promotion (by concatenating i1

// zeros) of the result of a node that already zeros all upper bits of

// k-register.

// TODO: Merge this with LowerAVXCONCAT_VECTORS?


static SDValue LowerCONCAT_VECTORSvXi1(SDValue Op, const SDLoc &dl,

                                       const X86Subtarget &Subtarget,

                                       SelectionDAG & DAG) {

  MVT ResVT = Op.getSimpleValueType();

  unsigned NumOperands = Op.getNumOperands();

  assert(NumOperands > 1 && isPowerOf2_32(NumOperands) &&

         "Unexpected number of operands in CONCAT_VECTORS");


  uint64_t Zeros = 0;

  uint64_t NonZeros = 0;

  for (unsigned i = 0; i != NumOperands; ++i) {

    SDValue SubVec = Op.getOperand(i);

    if (SubVec.isUndef())

      continue;

    assert(i < sizeof(NonZeros) * CHAR_BIT); // Ensure the shift is in range.

    if (ISD::isBuildVectorAllZeros(SubVec.getNode()))

      Zeros |= (uint64_t)1 << i;

    else

      NonZeros |= (uint64_t)1 << i;

  }


  unsigned NumElems = ResVT.getVectorNumElements();


  // If we are inserting non-zero vector and there are zeros in LSBs and undef

  // in the MSBs we need to emit a KSHIFTL. The generic lowering to

  // insert_subvector will give us two kshifts.

  if (isPowerOf2_64(NonZeros) && Zeros != 0 && NonZeros > Zeros &&

      Log2_64(NonZeros) != NumOperands - 1) {

    unsigned Idx = Log2_64(NonZeros);

    SDValue SubVec = Op.getOperand(Idx);

    unsigned SubVecNumElts = SubVec.getSimpleValueType().getVectorNumElements();

    MVT ShiftVT = widenMaskVectorType(ResVT, Subtarget);

    Op = widenSubVector(ShiftVT, SubVec, false, Subtarget, DAG, dl);

    Op = DAG.getNode(X86ISD::KSHIFTL, dl, ShiftVT, Op,

                     DAG.getTargetConstant(Idx * SubVecNumElts, dl, MVT::i8));

    return DAG.getNode(ISD::EXTRACT_SUBVECTOR, dl, ResVT, Op,

                       DAG.getVectorIdxConstant(0, dl));

  }


  // If there are zero or one non-zeros we can handle this very simply.

  if (NonZeros == 0 || isPowerOf2_64(NonZeros)) {

    SDValue Vec = Zeros ? DAG.getConstant(0, dl, ResVT) : DAG.getUNDEF(ResVT);

    if (!NonZeros)

      return Vec;

    unsigned Idx = Log2_64(NonZeros);

    SDValue SubVec = Op.getOperand(Idx);

    unsigned SubVecNumElts = SubVec.getSimpleValueType().getVectorNumElements();

    return DAG.getNode(ISD::INSERT_SUBVECTOR, dl, ResVT, Vec, SubVec,

                       DAG.getVectorIdxConstant(Idx * SubVecNumElts, dl));

  }


  if (NumOperands > 2) {

    MVT HalfVT = ResVT.getHalfNumVectorElementsVT();

    ArrayRef<SDUse> Ops = Op->ops();

    SDValue Lo = DAG.getNode(ISD::CONCAT_VECTORS, dl, HalfVT,

                             Ops.slice(0, NumOperands / 2));

    SDValue Hi = DAG.getNode(ISD::CONCAT_VECTORS, dl, HalfVT,

                             Ops.slice(NumOperands / 2));

    return DAG.getNode(ISD::CONCAT_VECTORS, dl, ResVT, Lo, Hi);

  }


  assert(llvm::popcount(NonZeros) == 2 && "Simple cases not handled?");


  if (ResVT.getVectorNumElements() >= 16)

    return Op; // The operation is legal with KUNPCK


  SDValue Vec =

      DAG.getNode(ISD::INSERT_SUBVECTOR, dl, ResVT, DAG.getUNDEF(ResVT),

                  Op.getOperand(0), DAG.getVectorIdxConstant(0, dl));

  return DAG.getNode(ISD::INSERT_SUBVECTOR, dl, ResVT, Vec, Op.getOperand(1),

                     DAG.getVectorIdxConstant(NumElems / 2, dl));

}


static SDValue LowerCONCAT_VECTORS(SDValue Op,

                                   const X86Subtarget &Subtarget,

                                   SelectionDAG &DAG) {

  SDLoc DL(Op);

  MVT VT = Op.getSimpleValueType();

  if (VT.getVectorElementType() == MVT::i1)

    return LowerCONCAT_VECTORSvXi1(Op, DL, Subtarget, DAG);


  // AVX can use the vinsertf128 instruction to create 256-bit vectors

  // from two other 128-bit ones.

  // 512-bit vector may contain 2 256-bit vectors or 4 128-bit vectors

  assert((VT.is256BitVector() && Op.getNumOperands() == 2) ||

         (VT.is512BitVector() &&

          (Op.getNumOperands() == 2 || Op.getNumOperands() == 4)));

  return LowerAVXCONCAT_VECTORS(Op, DL, DAG, Subtarget);

}


//===----------------------------------------------------------------------===//

// Vector shuffle lowering

//

// This is an experimental code path for lowering vector shuffles on x86. It is

// designed to handle arbitrary vector shuffles and blends, gracefully

// degrading performance as necessary. It works hard to recognize idiomatic

// shuffles and lower them to optimal instruction patterns without leaving

// a framework that allows reasonably efficient handling of all vector shuffle

// patterns.

//===----------------------------------------------------------------------===//


/// Checks whether the vector elements referenced by two shuffle masks are

/// equivalent.


static bool IsElementEquivalent(int MaskSize, SDValue Op, SDValue ExpectedOp,

                                int Idx, int ExpectedIdx) {

  assert(0 <= Idx && Idx < MaskSize && 0 <= ExpectedIdx &&

         ExpectedIdx < MaskSize && "Out of range element index");

  if (!Op || !ExpectedOp || Op.getOpcode() != ExpectedOp.getOpcode())

    return false;


  EVT VT = Op.getValueType();

  EVT ExpectedVT = ExpectedOp.getValueType();


  // Sources must be vectors and match the mask's element count.

  if (!VT.isVector() || !ExpectedVT.isVector() ||

      (int)VT.getVectorNumElements() != MaskSize ||

      (int)ExpectedVT.getVectorNumElements() != MaskSize)

    return false;


  // Exact match.

  if (Idx == ExpectedIdx && Op == ExpectedOp)

    return true;


  switch (Op.getOpcode()) {

  case ISD::BUILD_VECTOR:

    // If the values are build vectors, we can look through them to find

    // equivalent inputs that make the shuffles equivalent.

    return Op.getOperand(Idx) == ExpectedOp.getOperand(ExpectedIdx);

  case ISD::BITCAST: {

    SDValue Src = peekThroughBitcasts(Op);

    EVT SrcVT = Src.getValueType();

    if (Op == ExpectedOp && SrcVT.isVector()) {

      if ((SrcVT.getScalarSizeInBits() % VT.getScalarSizeInBits()) == 0) {

        unsigned Scale = SrcVT.getScalarSizeInBits() / VT.getScalarSizeInBits();

        return (Idx % Scale) == (ExpectedIdx % Scale) &&

               IsElementEquivalent(SrcVT.getVectorNumElements(), Src, Src,

                                   Idx / Scale, ExpectedIdx / Scale);

      }

      if ((VT.getScalarSizeInBits() % SrcVT.getScalarSizeInBits()) == 0) {

        unsigned Scale = VT.getScalarSizeInBits() / SrcVT.getScalarSizeInBits();

        for (unsigned I = 0; I != Scale; ++I)

          if (!IsElementEquivalent(SrcVT.getVectorNumElements(), Src, Src,

                                   (Idx * Scale) + I,

                                   (ExpectedIdx * Scale) + I))

            return false;

        return true;

      }

    }

    break;

  }

  case ISD::VECTOR_SHUFFLE: {

    auto *SVN = cast<ShuffleVectorSDNode>(Op);

    return Op == ExpectedOp &&

           SVN->getMaskElt(Idx) == SVN->getMaskElt(ExpectedIdx);

  }

  case X86ISD::VBROADCAST:

  case X86ISD::VBROADCAST_LOAD:

    return Op == ExpectedOp;

  case X86ISD::SUBV_BROADCAST_LOAD:

    if (Op == ExpectedOp) {

      auto *MemOp = cast<MemSDNode>(Op);

      unsigned NumMemElts = MemOp->getMemoryVT().getVectorNumElements();

      return (Idx % NumMemElts) == (ExpectedIdx % NumMemElts);

    }

    break;

  case X86ISD::VPERMI: {

    if (Op == ExpectedOp) {

      SmallVector<int, 8> Mask;

      DecodeVPERMMask(MaskSize, Op.getConstantOperandVal(1), Mask);

      SDValue Src = Op.getOperand(0);

      return IsElementEquivalent(MaskSize, Src, Src, Mask[Idx],

                                 Mask[ExpectedIdx]);

    }

    break;

  }

  case X86ISD::HADD:

  case X86ISD::HSUB:

  case X86ISD::FHADD:

  case X86ISD::FHSUB:

  case X86ISD::PACKSS:

  case X86ISD::PACKUS:

    // HOP(X,X) can refer to the elt from the lower/upper half of a lane.

    // TODO: Handle HOP(X,Y) vs HOP(Y,X) equivalence cases.

    if (Op == ExpectedOp && Op.getOperand(0) == Op.getOperand(1)) {

      int NumElts = VT.getVectorNumElements();

      int NumLanes = VT.getSizeInBits() / 128;

      int NumEltsPerLane = NumElts / NumLanes;

      int NumHalfEltsPerLane = NumEltsPerLane / 2;

      bool SameLane = (Idx / NumEltsPerLane) == (ExpectedIdx / NumEltsPerLane);

      bool SameElt =

          (Idx % NumHalfEltsPerLane) == (ExpectedIdx % NumHalfEltsPerLane);

      return SameLane && SameElt;

    }

    break;

  }


  return false;

}


/// Tiny helper function to identify a no-op mask.

///

/// This is a somewhat boring predicate function. It checks whether the mask

/// array input, which is assumed to be a single-input shuffle mask of the kind

/// used by the X86 shuffle instructions (not a fully general

/// ShuffleVectorSDNode mask) requires any shuffles to occur. Both undef and an

/// in-place shuffle are 'no-op's.


static bool isNoopShuffleMask(ArrayRef<int> Mask) {

  for (int i = 0, Size = Mask.size(); i < Size; ++i) {

    assert(Mask[i] >= -1 && "Out of bound mask element!");

    if (Mask[i] >= 0 && Mask[i] != i)

      return false;

  }

  return true;

}


/// Test whether there are elements crossing LaneSizeInBits lanes in this

/// shuffle mask.

///

/// X86 divides up its shuffles into in-lane and cross-lane shuffle operations

/// and we routinely test for these.


static bool isLaneCrossingShuffleMask(unsigned LaneSizeInBits,

                                      unsigned ScalarSizeInBits,

                                      ArrayRef<int> Mask) {

  assert(LaneSizeInBits && ScalarSizeInBits &&

         (LaneSizeInBits % ScalarSizeInBits) == 0 &&

         "Illegal shuffle lane size");

  int LaneSize = LaneSizeInBits / ScalarSizeInBits;

  int Size = Mask.size();

  for (int i = 0; i < Size; ++i)

    if (Mask[i] >= 0 && (Mask[i] % Size) / LaneSize != i / LaneSize)

      return true;

  return false;

}


/// Test whether there are elements crossing 128-bit lanes in this

/// shuffle mask.


static bool is128BitLaneCrossingShuffleMask(MVT VT, ArrayRef<int> Mask) {

  return isLaneCrossingShuffleMask(128, VT.getScalarSizeInBits(), Mask);

}


/// Test whether elements in each LaneSizeInBits lane in this shuffle mask come

/// from multiple lanes - this is different to isLaneCrossingShuffleMask to

/// better support 'repeated mask + lane permute' style shuffles.


static bool isMultiLaneShuffleMask(unsigned LaneSizeInBits,

                                   unsigned ScalarSizeInBits,

                                   ArrayRef<int> Mask) {

  assert(LaneSizeInBits && ScalarSizeInBits &&

         (LaneSizeInBits % ScalarSizeInBits) == 0 &&

         "Illegal shuffle lane size");

  int NumElts = Mask.size();

  int NumEltsPerLane = LaneSizeInBits / ScalarSizeInBits;

  int NumLanes = NumElts / NumEltsPerLane;

  if (NumLanes > 1) {

    for (int i = 0; i != NumLanes; ++i) {

      int SrcLane = -1;

      for (int j = 0; j != NumEltsPerLane; ++j) {

        int M = Mask[(i * NumEltsPerLane) + j];

        if (M < 0)

          continue;

        int Lane = (M % NumElts) / NumEltsPerLane;

        if (SrcLane >= 0 && SrcLane != Lane)

          return true;

        SrcLane = Lane;

      }

    }

  }

  return false;

}


/// Test whether a shuffle mask is equivalent within each sub-lane.

///

/// This checks a shuffle mask to see if it is performing the same

/// lane-relative shuffle in each sub-lane. This trivially implies

/// that it is also not lane-crossing. It may however involve a blend from the

/// same lane of a second vector.

///

/// The specific repeated shuffle mask is populated in \p RepeatedMask, as it is

/// non-trivial to compute in the face of undef lanes. The representation is

/// suitable for use with existing 128-bit shuffles as entries from the second

/// vector have been remapped to [LaneSize, 2*LaneSize).


static bool isRepeatedShuffleMask(unsigned LaneSizeInBits, MVT VT,

                                  ArrayRef<int> Mask,

                                  SmallVectorImpl<int> &RepeatedMask) {

  auto LaneSize = LaneSizeInBits / VT.getScalarSizeInBits();

  RepeatedMask.assign(LaneSize, -1);

  int Size = Mask.size();

  for (int i = 0; i < Size; ++i) {

    assert(Mask[i] == SM_SentinelUndef || Mask[i] >= 0);

    if (Mask[i] < 0)

      continue;

    if ((Mask[i] % Size) / LaneSize != i / LaneSize)

      // This entry crosses lanes, so there is no way to model this shuffle.

      return false;


    // Ok, handle the in-lane shuffles by detecting if and when they repeat.

    // Adjust second vector indices to start at LaneSize instead of Size.

    int LocalM = Mask[i] < Size ? Mask[i] % LaneSize

                                : Mask[i] % LaneSize + LaneSize;

    if (RepeatedMask[i % LaneSize] < 0)

      // This is the first non-undef entry in this slot of a 128-bit lane.

      RepeatedMask[i % LaneSize] = LocalM;

    else if (RepeatedMask[i % LaneSize] != LocalM)

      // Found a mismatch with the repeated mask.

      return false;

  }

  return true;

}


/// Test whether a shuffle mask is equivalent within each 128-bit lane.

static bool


is128BitLaneRepeatedShuffleMask(MVT VT, ArrayRef<int> Mask,

                                SmallVectorImpl<int> &RepeatedMask) {

  return isRepeatedShuffleMask(128, VT, Mask, RepeatedMask);

}


static bool


is128BitLaneRepeatedShuffleMask(MVT VT, ArrayRef<int> Mask) {

  SmallVector<int, 32> RepeatedMask;

  return isRepeatedShuffleMask(128, VT, Mask, RepeatedMask);

}


/// Test whether a shuffle mask is equivalent within each 256-bit lane.

static bool


is256BitLaneRepeatedShuffleMask(MVT VT, ArrayRef<int> Mask,

                                SmallVectorImpl<int> &RepeatedMask) {

  return isRepeatedShuffleMask(256, VT, Mask, RepeatedMask);

}


/// Test whether a target shuffle mask is equivalent within each sub-lane.

/// Unlike isRepeatedShuffleMask we must respect SM_SentinelZero.


static bool isRepeatedTargetShuffleMask(unsigned LaneSizeInBits,

                                        unsigned EltSizeInBits,

                                        ArrayRef<int> Mask,

                                        SmallVectorImpl<int> &RepeatedMask) {

  int LaneSize = LaneSizeInBits / EltSizeInBits;

  RepeatedMask.assign(LaneSize, SM_SentinelUndef);

  int Size = Mask.size();

  for (int i = 0; i < Size; ++i) {

    assert(isUndefOrZero(Mask[i]) || (Mask[i] >= 0));

    if (Mask[i] == SM_SentinelUndef)

      continue;

    if (Mask[i] == SM_SentinelZero) {

      if (!isUndefOrZero(RepeatedMask[i % LaneSize]))

        return false;

      RepeatedMask[i % LaneSize] = SM_SentinelZero;

      continue;

    }

    if ((Mask[i] % Size) / LaneSize != i / LaneSize)

      // This entry crosses lanes, so there is no way to model this shuffle.

      return false;


    // Handle the in-lane shuffles by detecting if and when they repeat. Adjust

    // later vector indices to start at multiples of LaneSize instead of Size.

    int LaneM = Mask[i] / Size;

    int LocalM = (Mask[i] % LaneSize) + (LaneM * LaneSize);

    if (RepeatedMask[i % LaneSize] == SM_SentinelUndef)

      // This is the first non-undef entry in this slot of a 128-bit lane.

      RepeatedMask[i % LaneSize] = LocalM;

    else if (RepeatedMask[i % LaneSize] != LocalM)

      // Found a mismatch with the repeated mask.

      return false;

  }

  return true;

}


/// Test whether a target shuffle mask is equivalent within each sub-lane.

/// Unlike isRepeatedShuffleMask we must respect SM_SentinelZero.


static bool isRepeatedTargetShuffleMask(unsigned LaneSizeInBits, MVT VT,

                                        ArrayRef<int> Mask,

                                        SmallVectorImpl<int> &RepeatedMask) {

  return isRepeatedTargetShuffleMask(LaneSizeInBits, VT.getScalarSizeInBits(),

                                     Mask, RepeatedMask);

}


/// Checks whether a shuffle mask is equivalent to an explicit list of

/// arguments.

///

/// This is a fast way to test a shuffle mask against a fixed pattern:

///

///   if (isShuffleEquivalent(Mask, 3, 2, {1, 0})) { ... }

///

/// It returns true if the mask is exactly as wide as the argument list, and

/// each element of the mask is either -1 (signifying undef) or the value given

/// in the argument.


static bool isShuffleEquivalent(ArrayRef<int> Mask, ArrayRef<int> ExpectedMask,

                                SDValue V1 = SDValue(),

                                SDValue V2 = SDValue()) {

  int Size = Mask.size();

  if (Size != (int)ExpectedMask.size())

    return false;


  for (int i = 0; i < Size; ++i) {

    assert(Mask[i] >= -1 && "Out of bound mask element!");

    int MaskIdx = Mask[i];

    int ExpectedIdx = ExpectedMask[i];

    if (0 <= MaskIdx && MaskIdx != ExpectedIdx) {

      SDValue MaskV = MaskIdx < Size ? V1 : V2;

      SDValue ExpectedV = ExpectedIdx < Size ? V1 : V2;

      MaskIdx = MaskIdx < Size ? MaskIdx : (MaskIdx - Size);

      ExpectedIdx = ExpectedIdx < Size ? ExpectedIdx : (ExpectedIdx - Size);

      if (!IsElementEquivalent(Size, MaskV, ExpectedV, MaskIdx, ExpectedIdx))

        return false;

    }

  }

  return true;

}


/// Checks whether a target shuffle mask is equivalent to an explicit pattern.

///

/// The masks must be exactly the same width.

///

/// If an element in Mask matches SM_SentinelUndef (-1) then the corresponding

/// value in ExpectedMask is always accepted. Otherwise the indices must match.

///

/// SM_SentinelZero is accepted as a valid negative index but must match in

/// both, or via a known bits test.


static bool isTargetShuffleEquivalent(MVT VT, ArrayRef<int> Mask,

                                      ArrayRef<int> ExpectedMask,

                                      const SelectionDAG &DAG,

                                      SDValue V1 = SDValue(),

                                      SDValue V2 = SDValue()) {

  int Size = Mask.size();

  if (Size != (int)ExpectedMask.size())

    return false;

  assert(llvm::all_of(ExpectedMask,

                      [Size](int M) {

                        return M == SM_SentinelZero ||

                               isInRange(M, 0, 2 * Size);

                      }) &&

         "Illegal target shuffle mask");


  // Check for out-of-range target shuffle mask indices.

  if (!isUndefOrZeroOrInRange(Mask, 0, 2 * Size))

    return false;


  // Don't use V1/V2 if they're not the same size as the shuffle mask type.

  if (V1 && (V1.getValueSizeInBits() != VT.getSizeInBits() ||

             !V1.getValueType().isVector()))

    V1 = SDValue();

  if (V2 && (V2.getValueSizeInBits() != VT.getSizeInBits() ||

             !V2.getValueType().isVector()))

    V2 = SDValue();


  APInt ZeroV1 = APInt::getZero(Size);

  APInt ZeroV2 = APInt::getZero(Size);


  for (int i = 0; i < Size; ++i) {

    int MaskIdx = Mask[i];

    int ExpectedIdx = ExpectedMask[i];

    if (MaskIdx == SM_SentinelUndef || MaskIdx == ExpectedIdx)

      continue;

    // If we failed to match an expected SM_SentinelZero then early out.

    if (ExpectedIdx < 0)

      return false;

    if (MaskIdx == SM_SentinelZero) {

      // If we need this expected index to be a zero element, then update the

      // relevant zero mask and perform the known bits at the end to minimize

      // repeated computes.

      SDValue ExpectedV = ExpectedIdx < Size ? V1 : V2;

      if (ExpectedV &&

          Size == (int)ExpectedV.getValueType().getVectorNumElements()) {

        int BitIdx = ExpectedIdx < Size ? ExpectedIdx : (ExpectedIdx - Size);

        APInt &ZeroMask = ExpectedIdx < Size ? ZeroV1 : ZeroV2;

        ZeroMask.setBit(BitIdx);

        continue;

      }

    }

    if (MaskIdx >= 0) {

      SDValue MaskV = MaskIdx < Size ? V1 : V2;

      SDValue ExpectedV = ExpectedIdx < Size ? V1 : V2;

      MaskIdx = MaskIdx < Size ? MaskIdx : (MaskIdx - Size);

      ExpectedIdx = ExpectedIdx < Size ? ExpectedIdx : (ExpectedIdx - Size);

      if (IsElementEquivalent(Size, MaskV, ExpectedV, MaskIdx, ExpectedIdx))

        continue;

    }

    return false;

  }

  return (ZeroV1.isZero() || DAG.MaskedVectorIsZero(V1, ZeroV1)) &&

         (ZeroV2.isZero() || DAG.MaskedVectorIsZero(V2, ZeroV2));

}


// Check if the shuffle mask is suitable for the AVX vpunpcklwd or vpunpckhwd

// instructions.


static bool isUnpackWdShuffleMask(ArrayRef<int> Mask, MVT VT,

                                  const SelectionDAG &DAG) {

  if (VT != MVT::v8i32 && VT != MVT::v8f32)

    return false;


  SmallVector<int, 8> Unpcklwd;

  createUnpackShuffleMask(MVT::v8i16, Unpcklwd, /* Lo = */ true,

                          /* Unary = */ false);

  SmallVector<int, 8> Unpckhwd;

  createUnpackShuffleMask(MVT::v8i16, Unpckhwd, /* Lo = */ false,

                          /* Unary = */ false);

  bool IsUnpackwdMask = (isTargetShuffleEquivalent(VT, Mask, Unpcklwd, DAG) ||

                         isTargetShuffleEquivalent(VT, Mask, Unpckhwd, DAG));

  return IsUnpackwdMask;

}


static bool is128BitUnpackShuffleMask(ArrayRef<int> Mask,

                                      const SelectionDAG &DAG) {

  // Create 128-bit vector type based on mask size.

  MVT EltVT = MVT::getIntegerVT(128 / Mask.size());

  MVT VT = MVT::getVectorVT(EltVT, Mask.size());


  // We can't assume a canonical shuffle mask, so try the commuted version too.

  SmallVector<int, 4> CommutedMask(Mask);

  ShuffleVectorSDNode::commuteMask(CommutedMask);


  // Match any of unary/binary or low/high.

  for (unsigned i = 0; i != 4; ++i) {

    SmallVector<int, 16> UnpackMask;

    createUnpackShuffleMask(VT, UnpackMask, (i >> 1) % 2, i % 2);

    if (isTargetShuffleEquivalent(VT, Mask, UnpackMask, DAG) ||

        isTargetShuffleEquivalent(VT, CommutedMask, UnpackMask, DAG))

      return true;

  }

  return false;

}


/// Return true if a shuffle mask chooses elements identically in its top and

/// bottom halves. For example, any splat mask has the same top and bottom

/// halves. If an element is undefined in only one half of the mask, the halves

/// are not considered identical.


static bool hasIdenticalHalvesShuffleMask(ArrayRef<int> Mask) {

  assert(Mask.size() % 2 == 0 && "Expecting even number of elements in mask");

  unsigned HalfSize = Mask.size() / 2;

  for (unsigned i = 0; i != HalfSize; ++i) {

    if (Mask[i] != Mask[i + HalfSize])

      return false;

  }

  return true;

}


/// Get a 4-lane 8-bit shuffle immediate for a mask.

///

/// This helper function produces an 8-bit shuffle immediate corresponding to

/// the ubiquitous shuffle encoding scheme used in x86 instructions for

/// shuffling 4 lanes. It can be used with most of the PSHUF instructions for

/// example.

///

/// NB: We rely heavily on "undef" masks preserving the input lane.


static unsigned getV4X86ShuffleImm(ArrayRef<int> Mask) {

  assert(Mask.size() == 4 && "Only 4-lane shuffle masks");

  assert(Mask[0] >= -1 && Mask[0] < 4 && "Out of bound mask element!");

  assert(Mask[1] >= -1 && Mask[1] < 4 && "Out of bound mask element!");

  assert(Mask[2] >= -1 && Mask[2] < 4 && "Out of bound mask element!");

  assert(Mask[3] >= -1 && Mask[3] < 4 && "Out of bound mask element!");


  // If the mask only uses one non-undef element, then fully 'splat' it to

  // improve later broadcast matching.

  int FirstIndex = find_if(Mask, [](int M) { return M >= 0; }) - Mask.begin();

  assert(0 <= FirstIndex && FirstIndex < 4 && "All undef shuffle mask");


  int FirstElt = Mask[FirstIndex];

  if (all_of(Mask, [FirstElt](int M) { return M < 0 || M == FirstElt; }))

    return (FirstElt << 6) | (FirstElt << 4) | (FirstElt << 2) | FirstElt;


  unsigned Imm = 0;

  Imm |= (Mask[0] < 0 ? 0 : Mask[0]) << 0;

  Imm |= (Mask[1] < 0 ? 1 : Mask[1]) << 2;

  Imm |= (Mask[2] < 0 ? 2 : Mask[2]) << 4;

  Imm |= (Mask[3] < 0 ? 3 : Mask[3]) << 6;

  return Imm;

}


static SDValue getV4X86ShuffleImm8ForMask(ArrayRef<int> Mask, const SDLoc &DL,

                                          SelectionDAG &DAG) {

  return DAG.getTargetConstant(getV4X86ShuffleImm(Mask), DL, MVT::i8);

}


// Canonicalize SHUFPD mask to improve chances of further folding.

// Mask elements are assumed to be -1, 0 or 1 to match the SHUFPD lo/hi pattern.


static unsigned getSHUFPDImm(ArrayRef<int> Mask) {

  assert((Mask.size() == 2 || Mask.size() == 4 || Mask.size() == 8) &&

         "Unexpected SHUFPD mask size");

  assert(all_of(Mask, [](int M) { return -1 <= M && M <= 1; }) &&

         "Unexpected SHUFPD mask elements");


  // If the mask only uses one non-undef element, then fully 'splat' it to

  // improve later broadcast matching.

  int FirstIndex = find_if(Mask, [](int M) { return M >= 0; }) - Mask.begin();

  assert(0 <= FirstIndex && FirstIndex < (int)Mask.size() &&

         "All undef shuffle mask");


  int FirstElt = Mask[FirstIndex];

  if (all_of(Mask, [FirstElt](int M) { return M < 0 || M == FirstElt; }) &&

      count_if(Mask, [FirstElt](int M) { return M == FirstElt; }) > 1) {

    unsigned Imm = 0;

    for (unsigned I = 0, E = Mask.size(); I != E; ++I)

      Imm |= FirstElt << I;

    return Imm;

  }


  // Attempt to keep any undef elements in place to improve chances of the

  // shuffle becoming a (commutative) blend.

  unsigned Imm = 0;

  for (unsigned I = 0, E = Mask.size(); I != E; ++I)

    Imm |= (Mask[I] < 0 ? (I & 1) : Mask[I]) << I;


  return Imm;

}


static SDValue getSHUFPDImmForMask(ArrayRef<int> Mask, const SDLoc &DL,

                                   SelectionDAG &DAG) {

  return DAG.getTargetConstant(getSHUFPDImm(Mask), DL, MVT::i8);

}


// The Shuffle result is as follow:

// 0*a[0]0*a[1]...0*a[n] , n >=0 where a[] elements in a ascending order.

// Each Zeroable's element correspond to a particular Mask's element.

// As described in computeZeroableShuffleElements function.

//

// The function looks for a sub-mask that the nonzero elements are in

// increasing order. If such sub-mask exist. The function returns true.


static bool isNonZeroElementsInOrder(const APInt &Zeroable,

                                     ArrayRef<int> Mask, const EVT &VectorType,

                                     bool &IsZeroSideLeft) {

  int NextElement = -1;

  // Check if the Mask's nonzero elements are in increasing order.

  for (int i = 0, e = Mask.size(); i < e; i++) {

    // Checks if the mask's zeros elements are built from only zeros.

    assert(Mask[i] >= -1 && "Out of bound mask element!");

    if (Mask[i] < 0)

      return false;

    if (Zeroable[i])

      continue;

    // Find the lowest non zero element

    if (NextElement < 0) {

      NextElement = Mask[i] != 0 ? VectorType.getVectorNumElements() : 0;

      IsZeroSideLeft = NextElement != 0;

    }

    // Exit if the mask's non zero elements are not in increasing order.

    if (NextElement != Mask[i])

      return false;

    NextElement++;

  }

  return true;

}


static SDValue combineConcatVectorOps(const SDLoc &DL, MVT VT,

                                      ArrayRef<SDValue> Ops, SelectionDAG &DAG,

                                      const X86Subtarget &Subtarget,

                                      unsigned Depth = 0);


/// Try to lower a shuffle with a single PSHUFB of V1 or V2.


static SDValue lowerShuffleWithPSHUFB(const SDLoc &DL, MVT VT,

                                      ArrayRef<int> Mask, SDValue V1,

                                      SDValue V2, const APInt &Zeroable,

                                      const X86Subtarget &Subtarget,

                                      SelectionDAG &DAG) {

  int Size = Mask.size();

  int LaneSize = 128 / VT.getScalarSizeInBits();

  const int NumBytes = VT.getSizeInBits() / 8;

  const int NumEltBytes = VT.getScalarSizeInBits() / 8;


  assert((Subtarget.hasSSSE3() && VT.is128BitVector()) ||

         (Subtarget.hasAVX2() && VT.is256BitVector()) ||

         (Subtarget.hasBWI() && VT.is512BitVector()));


  SmallVector<SDValue, 64> PSHUFBMask(NumBytes);

  // Sign bit set in i8 mask means zero element.

  SDValue ZeroMask = DAG.getConstant(0x80, DL, MVT::i8);


  SDValue V;

  for (int i = 0; i < NumBytes; ++i) {

    int M = Mask[i / NumEltBytes];

    if (M < 0) {

      PSHUFBMask[i] = DAG.getUNDEF(MVT::i8);

      continue;

    }

    if (Zeroable[i / NumEltBytes]) {

      PSHUFBMask[i] = ZeroMask;

      continue;

    }


    // We can only use a single input of V1 or V2.

    SDValue SrcV = (M >= Size ? V2 : V1);

    if (V && V != SrcV)

      return SDValue();

    V = SrcV;

    M %= Size;


    // PSHUFB can't cross lanes, ensure this doesn't happen.

    if ((M / LaneSize) != ((i / NumEltBytes) / LaneSize))

      return SDValue();


    M = M % LaneSize;

    M = M * NumEltBytes + (i % NumEltBytes);

    PSHUFBMask[i] = DAG.getConstant(M, DL, MVT::i8);

  }

  assert(V && "Failed to find a source input");


  MVT I8VT = MVT::getVectorVT(MVT::i8, NumBytes);

  return DAG.getBitcast(

      VT, DAG.getNode(X86ISD::PSHUFB, DL, I8VT, DAG.getBitcast(I8VT, V),

                      DAG.getBuildVector(I8VT, DL, PSHUFBMask)));

}


/// Return Mask with the necessary casting or extending

/// for \p Mask according to \p MaskVT when lowering masking intrinsics


static SDValue getMaskNode(SDValue Mask, MVT MaskVT,

                           const X86Subtarget &Subtarget, SelectionDAG &DAG,

                           const SDLoc &dl) {

  MVT SrcVT = Mask.getSimpleValueType();

  assert(SrcVT.isScalarInteger() && "Expected scalar integer mask source!");

  assert(MaskVT.bitsLE(SrcVT) && "Unexpected mask size!");

  assert(MaskVT.getVectorElementType() == MVT::i1 && "Bool vector expected!");


  if (isAllOnesConstant(Mask))

    return DAG.getConstant(1, dl, MaskVT);

  if (X86::isZeroNode(Mask))

    return DAG.getConstant(0, dl, MaskVT);


  // Attempt to pre-truncate the mask source (to a minimum of i8).

  if (SrcVT.getSizeInBits() > MaskVT.getVectorNumElements()) {

    SrcVT = MVT::getIntegerVT(std::max((int)MaskVT.getVectorNumElements(), 8));

    Mask = DAG.getNode(ISD::TRUNCATE, dl, SrcVT, Mask);

  }


  if (SrcVT == MVT::i64 && Subtarget.is32Bit()) {

    assert(MaskVT == MVT::v64i1 && "Expected v64i1 mask!");

    assert(Subtarget.hasBWI() && "Expected AVX512BW target!");

    // In case 32bit mode, bitcast i64 is illegal, extend/split it.

    SDValue Lo, Hi;

    std::tie(Lo, Hi) = DAG.SplitScalar(Mask, dl, MVT::i32, MVT::i32);

    Lo = DAG.getBitcast(MVT::v32i1, Lo);

    Hi = DAG.getBitcast(MVT::v32i1, Hi);

    return DAG.getNode(ISD::CONCAT_VECTORS, dl, MVT::v64i1, Lo, Hi);

  }


  MVT BitcastVT = MVT::getVectorVT(MVT::i1, SrcVT.getSizeInBits());

  // In case when MaskVT equals v2i1 or v4i1, low 2 or 4 elements

  // are extracted by EXTRACT_SUBVECTOR.

  return DAG.getNode(ISD::EXTRACT_SUBVECTOR, dl, MaskVT,

                     DAG.getBitcast(BitcastVT, Mask),

                     DAG.getVectorIdxConstant(0, dl));

}


// X86 has dedicated shuffle that can be lowered to VEXPAND


static SDValue lowerShuffleWithEXPAND(const SDLoc &DL, MVT VT, SDValue V1,

                                      SDValue V2, ArrayRef<int> Mask,

                                      const APInt &Zeroable,

                                      const X86Subtarget &Subtarget,

                                      SelectionDAG &DAG) {

  bool IsLeftZeroSide = true;

  if (!isNonZeroElementsInOrder(Zeroable, Mask, V1.getValueType(),

                                IsLeftZeroSide))

    return SDValue();

  unsigned VEXPANDMask = (~Zeroable).getZExtValue();

  MVT IntegerType =

      MVT::getIntegerVT(std::max((int)VT.getVectorNumElements(), 8));

  SDValue MaskNode = DAG.getConstant(VEXPANDMask, DL, IntegerType);

  unsigned NumElts = VT.getVectorNumElements();

  assert((NumElts == 4 || NumElts == 8 || NumElts == 16) &&

         "Unexpected number of vector elements");

  SDValue VMask = getMaskNode(MaskNode, MVT::getVectorVT(MVT::i1, NumElts),

                              Subtarget, DAG, DL);

  SDValue ZeroVector = getZeroVector(VT, Subtarget, DAG, DL);

  SDValue ExpandedVector = IsLeftZeroSide ? V2 : V1;

  return DAG.getNode(X86ISD::EXPAND, DL, VT, ExpandedVector, ZeroVector, VMask);

}


static bool matchShuffleWithUNPCK(MVT VT, SDValue &V1, SDValue &V2,

                                  unsigned &UnpackOpcode, bool IsUnary,

                                  ArrayRef<int> TargetMask, const SDLoc &DL,

                                  SelectionDAG &DAG,

                                  const X86Subtarget &Subtarget) {

  int NumElts = VT.getVectorNumElements();


  bool Undef1 = true, Undef2 = true, Zero1 = true, Zero2 = true;

  for (int i = 0; i != NumElts; i += 2) {

    int M1 = TargetMask[i + 0];

    int M2 = TargetMask[i + 1];

    Undef1 &= (SM_SentinelUndef == M1);

    Undef2 &= (SM_SentinelUndef == M2);

    Zero1 &= isUndefOrZero(M1);

    Zero2 &= isUndefOrZero(M2);

  }

  assert(!((Undef1 || Zero1) && (Undef2 || Zero2)) &&

         "Zeroable shuffle detected");


  // Attempt to match the target mask against the unpack lo/hi mask patterns.

  SmallVector<int, 64> Unpckl, Unpckh;

  createUnpackShuffleMask(VT, Unpckl, /* Lo = */ true, IsUnary);

  if (isTargetShuffleEquivalent(VT, TargetMask, Unpckl, DAG, V1,

                                (IsUnary ? V1 : V2))) {

    UnpackOpcode = X86ISD::UNPCKL;

    V2 = (Undef2 ? DAG.getUNDEF(VT) : (IsUnary ? V1 : V2));

    V1 = (Undef1 ? DAG.getUNDEF(VT) : V1);

    return true;

  }


  createUnpackShuffleMask(VT, Unpckh, /* Lo = */ false, IsUnary);

  if (isTargetShuffleEquivalent(VT, TargetMask, Unpckh, DAG, V1,

                                (IsUnary ? V1 : V2))) {

    UnpackOpcode = X86ISD::UNPCKH;

    V2 = (Undef2 ? DAG.getUNDEF(VT) : (IsUnary ? V1 : V2));

    V1 = (Undef1 ? DAG.getUNDEF(VT) : V1);

    return true;

  }


  // If an unary shuffle, attempt to match as an unpack lo/hi with zero.

  if (IsUnary && (Zero1 || Zero2)) {

    // Don't bother if we can blend instead.

    if ((Subtarget.hasSSE41() || VT == MVT::v2i64 || VT == MVT::v2f64) &&

        isSequentialOrUndefOrZeroInRange(TargetMask, 0, NumElts, 0))

      return false;


    bool MatchLo = true, MatchHi = true;

    for (int i = 0; (i != NumElts) && (MatchLo || MatchHi); ++i) {

      int M = TargetMask[i];


      // Ignore if the input is known to be zero or the index is undef.

      if ((((i & 1) == 0) && Zero1) || (((i & 1) == 1) && Zero2) ||

          (M == SM_SentinelUndef))

        continue;


      MatchLo &= (M == Unpckl[i]);

      MatchHi &= (M == Unpckh[i]);

    }


    if (MatchLo || MatchHi) {

      UnpackOpcode = MatchLo ? X86ISD::UNPCKL : X86ISD::UNPCKH;

      V2 = Zero2 ? getZeroVector(VT, Subtarget, DAG, DL) : V1;

      V1 = Zero1 ? getZeroVector(VT, Subtarget, DAG, DL) : V1;

      return true;

    }

  }


  // If a binary shuffle, commute and try again.

  if (!IsUnary) {

    ShuffleVectorSDNode::commuteMask(Unpckl);

    if (isTargetShuffleEquivalent(VT, TargetMask, Unpckl, DAG)) {

      UnpackOpcode = X86ISD::UNPCKL;

      std::swap(V1, V2);

      return true;

    }


    ShuffleVectorSDNode::commuteMask(Unpckh);

    if (isTargetShuffleEquivalent(VT, TargetMask, Unpckh, DAG)) {

      UnpackOpcode = X86ISD::UNPCKH;

      std::swap(V1, V2);

      return true;

    }

  }


  return false;

}


// X86 has dedicated unpack instructions that can handle specific blend

// operations: UNPCKH and UNPCKL.


static SDValue lowerShuffleWithUNPCK(const SDLoc &DL, MVT VT, SDValue V1,

                                     SDValue V2, ArrayRef<int> Mask,

                                     SelectionDAG &DAG) {

  SmallVector<int, 8> Unpckl;

  createUnpackShuffleMask(VT, Unpckl, /* Lo = */ true, /* Unary = */ false);

  if (isShuffleEquivalent(Mask, Unpckl, V1, V2))

    return DAG.getNode(X86ISD::UNPCKL, DL, VT, V1, V2);


  SmallVector<int, 8> Unpckh;

  createUnpackShuffleMask(VT, Unpckh, /* Lo = */ false, /* Unary = */ false);

  if (isShuffleEquivalent(Mask, Unpckh, V1, V2))

    return DAG.getNode(X86ISD::UNPCKH, DL, VT, V1, V2);


  // Commute and try again.

  ShuffleVectorSDNode::commuteMask(Unpckl);

  if (isShuffleEquivalent(Mask, Unpckl, V1, V2))

    return DAG.getNode(X86ISD::UNPCKL, DL, VT, V2, V1);


  ShuffleVectorSDNode::commuteMask(Unpckh);

  if (isShuffleEquivalent(Mask, Unpckh, V1, V2))

    return DAG.getNode(X86ISD::UNPCKH, DL, VT, V2, V1);


  return SDValue();

}


/// Check if the mask can be mapped to a preliminary shuffle (vperm 64-bit)

/// followed by unpack 256-bit.


static SDValue lowerShuffleWithUNPCK256(const SDLoc &DL, MVT VT, SDValue V1,

                                        SDValue V2, ArrayRef<int> Mask,

                                        SelectionDAG &DAG) {

  SmallVector<int, 32> Unpckl, Unpckh;

  createSplat2ShuffleMask(VT, Unpckl, /* Lo */ true);

  createSplat2ShuffleMask(VT, Unpckh, /* Lo */ false);


  unsigned UnpackOpcode;

  if (isShuffleEquivalent(Mask, Unpckl, V1, V2))

    UnpackOpcode = X86ISD::UNPCKL;

  else if (isShuffleEquivalent(Mask, Unpckh, V1, V2))

    UnpackOpcode = X86ISD::UNPCKH;

  else

    return SDValue();


  // This is a "natural" unpack operation (rather than the 128-bit sectored

  // operation implemented by AVX). We need to rearrange 64-bit chunks of the

  // input in order to use the x86 instruction.

  V1 = DAG.getVectorShuffle(MVT::v4f64, DL, DAG.getBitcast(MVT::v4f64, V1),

                            DAG.getUNDEF(MVT::v4f64), {0, 2, 1, 3});

  V1 = DAG.getBitcast(VT, V1);

  return DAG.getNode(UnpackOpcode, DL, VT, V1, V1);

}


// Check if the mask can be mapped to a TRUNCATE or VTRUNC, truncating the

// source into the lower elements and zeroing the upper elements.


static bool matchShuffleAsVTRUNC(MVT &SrcVT, MVT &DstVT, MVT VT,

                                 ArrayRef<int> Mask, const APInt &Zeroable,

                                 const X86Subtarget &Subtarget) {

  if (!VT.is512BitVector() && !Subtarget.hasVLX())

    return false;


  unsigned NumElts = Mask.size();

  unsigned EltSizeInBits = VT.getScalarSizeInBits();

  unsigned MaxScale = 64 / EltSizeInBits;


  for (unsigned Scale = 2; Scale <= MaxScale; Scale += Scale) {

    unsigned SrcEltBits = EltSizeInBits * Scale;

    if (SrcEltBits < 32 && !Subtarget.hasBWI())

      continue;

    unsigned NumSrcElts = NumElts / Scale;

    if (!isSequentialOrUndefInRange(Mask, 0, NumSrcElts, 0, Scale))

      continue;

    unsigned UpperElts = NumElts - NumSrcElts;

    if (!Zeroable.extractBits(UpperElts, NumSrcElts).isAllOnes())

      continue;

    SrcVT = MVT::getIntegerVT(EltSizeInBits * Scale);

    SrcVT = MVT::getVectorVT(SrcVT, NumSrcElts);

    DstVT = MVT::getIntegerVT(EltSizeInBits);

    if ((NumSrcElts * EltSizeInBits) >= 128) {

      // ISD::TRUNCATE

      DstVT = MVT::getVectorVT(DstVT, NumSrcElts);

    } else {

      // X86ISD::VTRUNC

      DstVT = MVT::getVectorVT(DstVT, 128 / EltSizeInBits);

    }

    return true;

  }


  return false;

}


// Helper to create TRUNCATE/VTRUNC nodes, optionally with zero/undef upper

// element padding to the final DstVT.


static SDValue getAVX512TruncNode(const SDLoc &DL, MVT DstVT, SDValue Src,

                                  const X86Subtarget &Subtarget,

                                  SelectionDAG &DAG, bool ZeroUppers) {

  MVT SrcVT = Src.getSimpleValueType();

  MVT DstSVT = DstVT.getScalarType();

  unsigned NumDstElts = DstVT.getVectorNumElements();

  unsigned NumSrcElts = SrcVT.getVectorNumElements();

  unsigned DstEltSizeInBits = DstVT.getScalarSizeInBits();


  if (!DAG.getTargetLoweringInfo().isTypeLegal(SrcVT))

    return SDValue();


  // Perform a direct ISD::TRUNCATE if possible.

  if (NumSrcElts == NumDstElts)

    return DAG.getNode(ISD::TRUNCATE, DL, DstVT, Src);


  if (NumSrcElts > NumDstElts) {

    MVT TruncVT = MVT::getVectorVT(DstSVT, NumSrcElts);

    SDValue Trunc = DAG.getNode(ISD::TRUNCATE, DL, TruncVT, Src);

    return extractSubVector(Trunc, 0, DAG, DL, DstVT.getSizeInBits());

  }


  if ((NumSrcElts * DstEltSizeInBits) >= 128) {

    MVT TruncVT = MVT::getVectorVT(DstSVT, NumSrcElts);

    SDValue Trunc = DAG.getNode(ISD::TRUNCATE, DL, TruncVT, Src);

    return widenSubVector(Trunc, ZeroUppers, Subtarget, DAG, DL,

                          DstVT.getSizeInBits());

  }


  // Non-VLX targets must truncate from a 512-bit type, so we need to

  // widen, truncate and then possibly extract the original subvector.

  if (!Subtarget.hasVLX() && !SrcVT.is512BitVector()) {

    SDValue NewSrc = widenSubVector(Src, ZeroUppers, Subtarget, DAG, DL, 512);

    return getAVX512TruncNode(DL, DstVT, NewSrc, Subtarget, DAG, ZeroUppers);

  }


  // Fallback to a X86ISD::VTRUNC, padding if necessary.

  MVT TruncVT = MVT::getVectorVT(DstSVT, 128 / DstEltSizeInBits);

  SDValue Trunc = DAG.getNode(X86ISD::VTRUNC, DL, TruncVT, Src);

  if (DstVT != TruncVT)

    Trunc = widenSubVector(Trunc, ZeroUppers, Subtarget, DAG, DL,

                           DstVT.getSizeInBits());

  return Trunc;

}


// Try to lower trunc+vector_shuffle to a vpmovdb or a vpmovdw instruction.

//

// An example is the following:

//

// t0: ch = EntryToken

//           t2: v4i64,ch = CopyFromReg t0, Register:v4i64 %0

//         t25: v4i32 = truncate t2

//       t41: v8i16 = bitcast t25

//       t21: v8i16 = BUILD_VECTOR undef:i16, undef:i16, undef:i16, undef:i16,

//       Constant:i16<0>, Constant:i16<0>, Constant:i16<0>, Constant:i16<0>

//     t51: v8i16 = vector_shuffle<0,2,4,6,12,13,14,15> t41, t21

//   t18: v2i64 = bitcast t51

//

// One can just use a single vpmovdw instruction, without avx512vl we need to

// use the zmm variant and extract the lower subvector, padding with zeroes.

// TODO: Merge with lowerShuffleAsVTRUNC.


static SDValue lowerShuffleWithVPMOV(const SDLoc &DL, MVT VT, SDValue V1,

                                     SDValue V2, ArrayRef<int> Mask,

                                     const APInt &Zeroable,

                                     const X86Subtarget &Subtarget,

                                     SelectionDAG &DAG) {

  assert((VT == MVT::v16i8 || VT == MVT::v8i16) && "Unexpected VTRUNC type");

  if (!Subtarget.hasAVX512())

    return SDValue();


  unsigned NumElts = VT.getVectorNumElements();

  unsigned EltSizeInBits = VT.getScalarSizeInBits();

  unsigned MaxScale = 64 / EltSizeInBits;

  for (unsigned Scale = 2; Scale <= MaxScale; Scale += Scale) {

    unsigned SrcEltBits = EltSizeInBits * Scale;

    unsigned NumSrcElts = NumElts / Scale;

    unsigned UpperElts = NumElts - NumSrcElts;

    if (!isSequentialOrUndefInRange(Mask, 0, NumSrcElts, 0, Scale) ||

        !Zeroable.extractBits(UpperElts, NumSrcElts).isAllOnes())

      continue;


    // Attempt to find a matching source truncation, but as a fall back VLX

    // cases can use the VPMOV directly.

    SDValue Src = peekThroughBitcasts(V1);

    if (Src.getOpcode() == ISD::TRUNCATE &&

        Src.getScalarValueSizeInBits() == SrcEltBits) {

      Src = Src.getOperand(0);

    } else if (Subtarget.hasVLX()) {

      MVT SrcSVT = MVT::getIntegerVT(SrcEltBits);

      MVT SrcVT = MVT::getVectorVT(SrcSVT, NumSrcElts);

      Src = DAG.getBitcast(SrcVT, Src);

      // Don't do this if PACKSS/PACKUS could perform it cheaper.

      if (Scale == 2 &&

          ((DAG.ComputeNumSignBits(Src) > EltSizeInBits) ||

           (DAG.computeKnownBits(Src).countMinLeadingZeros() >= EltSizeInBits)))

        return SDValue();

    } else

      return SDValue();


    // VPMOVWB is only available with avx512bw.

    if (!Subtarget.hasBWI() && Src.getScalarValueSizeInBits() < 32)

      return SDValue();


    bool UndefUppers = isUndefInRange(Mask, NumSrcElts, UpperElts);

    return getAVX512TruncNode(DL, VT, Src, Subtarget, DAG, !UndefUppers);

  }


  return SDValue();

}


// Attempt to match binary shuffle patterns as a truncate.


static SDValue lowerShuffleAsVTRUNC(const SDLoc &DL, MVT VT, SDValue V1,

                                    SDValue V2, ArrayRef<int> Mask,

                                    const APInt &Zeroable,

                                    const X86Subtarget &Subtarget,

                                    SelectionDAG &DAG) {

  assert((VT.is128BitVector() || VT.is256BitVector()) &&

         "Unexpected VTRUNC type");

  if (!Subtarget.hasAVX512() ||

      (VT.is256BitVector() && !Subtarget.useAVX512Regs()))

    return SDValue();


  unsigned NumElts = VT.getVectorNumElements();

  unsigned EltSizeInBits = VT.getScalarSizeInBits();

  unsigned MaxScale = 64 / EltSizeInBits;

  for (unsigned Scale = 2; Scale <= MaxScale; Scale += Scale) {

    // TODO: Support non-BWI VPMOVWB truncations?

    unsigned SrcEltBits = EltSizeInBits * Scale;

    if (SrcEltBits < 32 && !Subtarget.hasBWI())

      continue;


    // Match shuffle <Ofs,Ofs+Scale,Ofs+2*Scale,..,undef_or_zero,undef_or_zero>

    // Bail if the V2 elements are undef.

    unsigned NumHalfSrcElts = NumElts / Scale;

    unsigned NumSrcElts = 2 * NumHalfSrcElts;

    for (unsigned Offset = 0; Offset != Scale; ++Offset) {

      if (!isSequentialOrUndefInRange(Mask, 0, NumSrcElts, Offset, Scale) ||

          isUndefInRange(Mask, NumHalfSrcElts, NumHalfSrcElts))

        continue;


      // The elements beyond the truncation must be undef/zero.

      unsigned UpperElts = NumElts - NumSrcElts;

      if (UpperElts > 0 &&

          !Zeroable.extractBits(UpperElts, NumSrcElts).isAllOnes())

        continue;

      bool UndefUppers =

          UpperElts > 0 && isUndefInRange(Mask, NumSrcElts, UpperElts);


      // As we're using both sources then we need to concat them together

      // and truncate from the double-sized src.

      MVT ConcatVT = VT.getDoubleNumVectorElementsVT();


      // For offset truncations, ensure that the concat is cheap.

      SDValue Src =

          combineConcatVectorOps(DL, ConcatVT, {V1, V2}, DAG, Subtarget);

      if (!Src) {

        if (Offset)

          continue;

        Src = DAG.getNode(ISD::CONCAT_VECTORS, DL, ConcatVT, V1, V2);

      }


      MVT SrcSVT = MVT::getIntegerVT(SrcEltBits);

      MVT SrcVT = MVT::getVectorVT(SrcSVT, NumSrcElts);

      Src = DAG.getBitcast(SrcVT, Src);


      // Shift the offset'd elements into place for the truncation.

      // TODO: Use getTargetVShiftByConstNode.

      if (Offset)

        Src = DAG.getNode(

            X86ISD::VSRLI, DL, SrcVT, Src,

            DAG.getTargetConstant(Offset * EltSizeInBits, DL, MVT::i8));


      return getAVX512TruncNode(DL, VT, Src, Subtarget, DAG, !UndefUppers);

    }

  }


  return SDValue();

}


/// Check whether a compaction lowering can be done by dropping even/odd

/// elements and compute how many times even/odd elements must be dropped.

///

/// This handles shuffles which take every Nth element where N is a power of

/// two. Example shuffle masks:

///

/// (even)

///  N = 1:  0,  2,  4,  6,  8, 10, 12, 14,  0,  2,  4,  6,  8, 10, 12, 14

///  N = 1:  0,  2,  4,  6,  8, 10, 12, 14, 16, 18, 20, 22, 24, 26, 28, 30

///  N = 2:  0,  4,  8, 12,  0,  4,  8, 12,  0,  4,  8, 12,  0,  4,  8, 12

///  N = 2:  0,  4,  8, 12, 16, 20, 24, 28,  0,  4,  8, 12, 16, 20, 24, 28

///  N = 3:  0,  8,  0,  8,  0,  8,  0,  8,  0,  8,  0,  8,  0,  8,  0,  8

///  N = 3:  0,  8, 16, 24,  0,  8, 16, 24,  0,  8, 16, 24,  0,  8, 16, 24

///

/// (odd)

///  N = 1:  1,  3,  5,  7,  9, 11, 13, 15,  0,  2,  4,  6,  8, 10, 12, 14

///  N = 1:  1,  3,  5,  7,  9, 11, 13, 15, 17, 19, 21, 23, 25, 27, 29, 31

///

/// Any of these lanes can of course be undef.

///

/// This routine only supports N <= 3.

/// FIXME: Evaluate whether either AVX or AVX-512 have any opportunities here

/// for larger N.

///

/// \returns N above, or the number of times even/odd elements must be dropped

/// if there is such a number. Otherwise returns zero.


static int canLowerByDroppingElements(ArrayRef<int> Mask, bool MatchEven,

                                      bool IsSingleInput) {

  // The modulus for the shuffle vector entries is based on whether this is

  // a single input or not.

  int ShuffleModulus = Mask.size() * (IsSingleInput ? 1 : 2);

  assert(isPowerOf2_32((uint32_t)ShuffleModulus) &&

         "We should only be called with masks with a power-of-2 size!");


  uint64_t ModMask = (uint64_t)ShuffleModulus - 1;

  int Offset = MatchEven ? 0 : 1;


  // We track whether the input is viable for all power-of-2 strides 2^1, 2^2,

  // and 2^3 simultaneously. This is because we may have ambiguity with

  // partially undef inputs.

  bool ViableForN[3] = {true, true, true};


  for (int i = 0, e = Mask.size(); i < e; ++i) {

    // Ignore undef lanes, we'll optimistically collapse them to the pattern we

    // want.

    if (Mask[i] < 0)

      continue;


    bool IsAnyViable = false;

    for (unsigned j = 0; j != std::size(ViableForN); ++j)

      if (ViableForN[j]) {

        uint64_t N = j + 1;


        // The shuffle mask must be equal to (i * 2^N) % M.

        if ((uint64_t)(Mask[i] - Offset) == (((uint64_t)i << N) & ModMask))

          IsAnyViable = true;

        else

          ViableForN[j] = false;

      }

    // Early exit if we exhaust the possible powers of two.

    if (!IsAnyViable)

      break;

  }


  for (unsigned j = 0; j != std::size(ViableForN); ++j)

    if (ViableForN[j])

      return j + 1;


  // Return 0 as there is no viable power of two.

  return 0;

}


// X86 has dedicated pack instructions that can handle specific truncation

// operations: PACKSS and PACKUS.

// Checks for compaction shuffle masks if MaxStages > 1.

// TODO: Add support for matching multiple PACKSS/PACKUS stages.


static bool matchShuffleWithPACK(MVT VT, MVT &SrcVT, SDValue &V1, SDValue &V2,

                                 unsigned &PackOpcode, ArrayRef<int> TargetMask,

                                 const SelectionDAG &DAG,

                                 const X86Subtarget &Subtarget,

                                 unsigned MaxStages = 1) {

  unsigned NumElts = VT.getVectorNumElements();

  unsigned BitSize = VT.getScalarSizeInBits();

  assert(0 < MaxStages && MaxStages <= 3 && (BitSize << MaxStages) <= 64 &&

         "Illegal maximum compaction");


  auto MatchPACK = [&](SDValue N1, SDValue N2, MVT PackVT) {

    unsigned NumSrcBits = PackVT.getScalarSizeInBits();

    unsigned NumPackedBits = NumSrcBits - BitSize;

    N1 = peekThroughBitcasts(N1);

    N2 = peekThroughBitcasts(N2);

    unsigned NumBits1 = N1.getScalarValueSizeInBits();

    unsigned NumBits2 = N2.getScalarValueSizeInBits();

    bool IsZero1 = llvm::isNullOrNullSplat(N1, /*AllowUndefs*/ false);

    bool IsZero2 = llvm::isNullOrNullSplat(N2, /*AllowUndefs*/ false);

    if ((!N1.isUndef() && !IsZero1 && NumBits1 != NumSrcBits) ||

        (!N2.isUndef() && !IsZero2 && NumBits2 != NumSrcBits))

      return false;

    if (Subtarget.hasSSE41() || BitSize == 8) {

      APInt ZeroMask = APInt::getHighBitsSet(NumSrcBits, NumPackedBits);

      if ((N1.isUndef() || IsZero1 || DAG.MaskedValueIsZero(N1, ZeroMask)) &&

          (N2.isUndef() || IsZero2 || DAG.MaskedValueIsZero(N2, ZeroMask))) {

        V1 = N1;

        V2 = N2;

        SrcVT = PackVT;

        PackOpcode = X86ISD::PACKUS;

        return true;

      }

    }

    bool IsAllOnes1 = llvm::isAllOnesOrAllOnesSplat(N1, /*AllowUndefs*/ false);

    bool IsAllOnes2 = llvm::isAllOnesOrAllOnesSplat(N2, /*AllowUndefs*/ false);

    if ((N1.isUndef() || IsZero1 || IsAllOnes1 ||

         DAG.ComputeNumSignBits(N1) > NumPackedBits) &&

        (N2.isUndef() || IsZero2 || IsAllOnes2 ||

         DAG.ComputeNumSignBits(N2) > NumPackedBits)) {

      V1 = N1;

      V2 = N2;

      SrcVT = PackVT;

      PackOpcode = X86ISD::PACKSS;

      return true;

    }

    return false;

  };


  // Attempt to match against wider and wider compaction patterns.

  for (unsigned NumStages = 1; NumStages <= MaxStages; ++NumStages) {

    MVT PackSVT = MVT::getIntegerVT(BitSize << NumStages);

    MVT PackVT = MVT::getVectorVT(PackSVT, NumElts >> NumStages);


    // Try binary shuffle.

    SmallVector<int, 32> BinaryMask;

    createPackShuffleMask(VT, BinaryMask, false, NumStages);

    if (isTargetShuffleEquivalent(VT, TargetMask, BinaryMask, DAG, V1, V2))

      if (MatchPACK(V1, V2, PackVT))

        return true;


    // Try unary shuffle.

    SmallVector<int, 32> UnaryMask;

    createPackShuffleMask(VT, UnaryMask, true, NumStages);

    if (isTargetShuffleEquivalent(VT, TargetMask, UnaryMask, DAG, V1))

      if (MatchPACK(V1, V1, PackVT))

        return true;

  }


  return false;

}


static SDValue lowerShuffleWithPACK(const SDLoc &DL, MVT VT, SDValue V1,

                                    SDValue V2, ArrayRef<int> Mask,

                                    const X86Subtarget &Subtarget,

                                    SelectionDAG &DAG) {

  MVT PackVT;

  unsigned PackOpcode;

  unsigned SizeBits = VT.getSizeInBits();

  unsigned EltBits = VT.getScalarSizeInBits();

  unsigned MaxStages = Log2_32(64 / EltBits);

  if (!matchShuffleWithPACK(VT, PackVT, V1, V2, PackOpcode, Mask, DAG,

                            Subtarget, MaxStages))

    return SDValue();


  unsigned CurrentEltBits = PackVT.getScalarSizeInBits();

  unsigned NumStages = Log2_32(CurrentEltBits / EltBits);


  // Don't lower multi-stage packs on AVX512, truncation is better.

  if (NumStages != 1 && SizeBits == 128 && Subtarget.hasVLX())

    return SDValue();


  // Pack to the largest type possible:

  // vXi64/vXi32 -> PACK*SDW and vXi16 -> PACK*SWB.

  unsigned MaxPackBits = 16;

  if (CurrentEltBits > 16 &&

      (PackOpcode == X86ISD::PACKSS || Subtarget.hasSSE41()))

    MaxPackBits = 32;


  // Repeatedly pack down to the target size.

  SDValue Res;

  for (unsigned i = 0; i != NumStages; ++i) {

    unsigned SrcEltBits = std::min(MaxPackBits, CurrentEltBits);

    unsigned NumSrcElts = SizeBits / SrcEltBits;

    MVT SrcSVT = MVT::getIntegerVT(SrcEltBits);

    MVT DstSVT = MVT::getIntegerVT(SrcEltBits / 2);

    MVT SrcVT = MVT::getVectorVT(SrcSVT, NumSrcElts);

    MVT DstVT = MVT::getVectorVT(DstSVT, NumSrcElts * 2);

    Res = DAG.getNode(PackOpcode, DL, DstVT, DAG.getBitcast(SrcVT, V1),

                      DAG.getBitcast(SrcVT, V2));

    V1 = V2 = Res;

    CurrentEltBits /= 2;

  }

  assert(Res && Res.getValueType() == VT &&

         "Failed to lower compaction shuffle");

  return Res;

}


/// Try to emit a bitmask instruction for a shuffle.

///

/// This handles cases where we can model a blend exactly as a bitmask due to

/// one of the inputs being zeroable.


static SDValue lowerShuffleAsBitMask(const SDLoc &DL, MVT VT, SDValue V1,

                                     SDValue V2, ArrayRef<int> Mask,

                                     const APInt &Zeroable,

                                     const X86Subtarget &Subtarget,

                                     SelectionDAG &DAG) {

  MVT MaskVT = VT;

  MVT EltVT = VT.getVectorElementType();

  SDValue Zero, AllOnes;

  // Use f64 if i64 isn't legal.

  if (EltVT == MVT::i64 && !Subtarget.is64Bit()) {

    EltVT = MVT::f64;

    MaskVT = MVT::getVectorVT(EltVT, Mask.size());

  }


  MVT LogicVT = VT;

  if (EltVT.isFloatingPoint()) {

    Zero = DAG.getConstantFP(0.0, DL, EltVT);

    APFloat AllOnesValue = APFloat::getAllOnesValue(EltVT.getFltSemantics());

    AllOnes = DAG.getConstantFP(AllOnesValue, DL, EltVT);

    LogicVT = MVT::getVectorVT(EltVT.changeTypeToInteger(), Mask.size());

  } else {

    Zero = DAG.getConstant(0, DL, EltVT);

    AllOnes = DAG.getAllOnesConstant(DL, EltVT);

  }


  SmallVector<SDValue, 16> VMaskOps(Mask.size(), Zero);

  SDValue V;

  for (int i = 0, Size = Mask.size(); i < Size; ++i) {

    if (Zeroable[i])

      continue;

    if (Mask[i] % Size != i)

      return SDValue(); // Not a blend.

    if (!V)

      V = Mask[i] < Size ? V1 : V2;

    else if (V != (Mask[i] < Size ? V1 : V2))

      return SDValue(); // Can only let one input through the mask.


    VMaskOps[i] = AllOnes;

  }

  if (!V)

    return SDValue(); // No non-zeroable elements!


  SDValue VMask = DAG.getBuildVector(MaskVT, DL, VMaskOps);

  VMask = DAG.getBitcast(LogicVT, VMask);

  V = DAG.getBitcast(LogicVT, V);

  SDValue And = DAG.getNode(ISD::AND, DL, LogicVT, V, VMask);

  return DAG.getBitcast(VT, And);

}


/// Try to emit a blend instruction for a shuffle using bit math.

///

/// This is used as a fallback approach when first class blend instructions are

/// unavailable. Currently it is only suitable for integer vectors, but could

/// be generalized for floating point vectors if desirable.


static SDValue lowerShuffleAsBitBlend(const SDLoc &DL, MVT VT, SDValue V1,

                                      SDValue V2, ArrayRef<int> Mask,

                                      SelectionDAG &DAG) {

  assert(VT.isInteger() && "Only supports integer vector types!");

  MVT EltVT = VT.getVectorElementType();

  SDValue Zero = DAG.getConstant(0, DL, EltVT);

  SDValue AllOnes = DAG.getAllOnesConstant(DL, EltVT);

  SmallVector<SDValue, 16> MaskOps;

  for (int i = 0, Size = Mask.size(); i < Size; ++i) {

    if (Mask[i] >= 0 && Mask[i] != i && Mask[i] != i + Size)

      return SDValue(); // Shuffled input!

    MaskOps.push_back(Mask[i] < Size ? AllOnes : Zero);

  }


  SDValue V1Mask = DAG.getBuildVector(VT, DL, MaskOps);

  return getBitSelect(DL, VT, V1, V2, V1Mask, DAG);

}


static SDValue getVectorMaskingNode(SDValue Op, SDValue Mask,

                                    SDValue PreservedSrc,

                                    const X86Subtarget &Subtarget,

                                    SelectionDAG &DAG);


static bool matchShuffleAsBlend(MVT VT, SDValue V1, SDValue V2,

                                MutableArrayRef<int> Mask,

                                const APInt &Zeroable, bool &ForceV1Zero,

                                bool &ForceV2Zero, uint64_t &BlendMask) {

  bool V1IsZeroOrUndef =

      V1.isUndef() || ISD::isBuildVectorAllZeros(V1.getNode());

  bool V2IsZeroOrUndef =

      V2.isUndef() || ISD::isBuildVectorAllZeros(V2.getNode());


  BlendMask = 0;

  ForceV1Zero = false, ForceV2Zero = false;

  assert(Mask.size() <= 64 && "Shuffle mask too big for blend mask");


  int NumElts = Mask.size();

  int NumLanes = VT.getSizeInBits() / 128;

  int NumEltsPerLane = NumElts / NumLanes;

  assert((NumLanes * NumEltsPerLane) == NumElts && "Value type mismatch");


  // For 32/64-bit elements, if we only reference one input (plus any undefs),

  // then ensure the blend mask part for that lane just references that input.

  bool ForceWholeLaneMasks =

      VT.is256BitVector() && VT.getScalarSizeInBits() >= 32;


  // Attempt to generate the binary blend mask. If an input is zero then

  // we can use any lane.

  for (int Lane = 0; Lane != NumLanes; ++Lane) {

    // Keep track of the inputs used per lane.

    bool LaneV1InUse = false;

    bool LaneV2InUse = false;

    uint64_t LaneBlendMask = 0;

    for (int LaneElt = 0; LaneElt != NumEltsPerLane; ++LaneElt) {

      int Elt = (Lane * NumEltsPerLane) + LaneElt;

      int M = Mask[Elt];

      if (M == SM_SentinelUndef)

        continue;

      if (M == Elt || (0 <= M && M < NumElts &&

                     IsElementEquivalent(NumElts, V1, V1, M, Elt))) {

        Mask[Elt] = Elt;

        LaneV1InUse = true;

        continue;

      }

      if (M == (Elt + NumElts) ||

          (NumElts <= M &&

           IsElementEquivalent(NumElts, V2, V2, M - NumElts, Elt))) {

        LaneBlendMask |= 1ull << LaneElt;

        Mask[Elt] = Elt + NumElts;

        LaneV2InUse = true;

        continue;

      }

      if (Zeroable[Elt]) {

        if (V1IsZeroOrUndef) {

          ForceV1Zero = true;

          Mask[Elt] = Elt;

          LaneV1InUse = true;

          continue;

        }

        if (V2IsZeroOrUndef) {

          ForceV2Zero = true;

          LaneBlendMask |= 1ull << LaneElt;

          Mask[Elt] = Elt + NumElts;

          LaneV2InUse = true;

          continue;

        }

      }

      return false;

    }


    // If we only used V2 then splat the lane blend mask to avoid any demanded

    // elts from V1 in this lane (the V1 equivalent is implicit with a zero

    // blend mask bit).

    if (ForceWholeLaneMasks && LaneV2InUse && !LaneV1InUse)

      LaneBlendMask = (1ull << NumEltsPerLane) - 1;


    BlendMask |= LaneBlendMask << (Lane * NumEltsPerLane);

  }

  return true;

}


/// Try to emit a blend instruction for a shuffle.

///

/// This doesn't do any checks for the availability of instructions for blending

/// these values. It relies on the availability of the X86ISD::BLENDI pattern to

/// be matched in the backend with the type given. What it does check for is

/// that the shuffle mask is a blend, or convertible into a blend with zero.


static SDValue lowerShuffleAsBlend(const SDLoc &DL, MVT VT, SDValue V1,

                                   SDValue V2, ArrayRef<int> Original,

                                   const APInt &Zeroable,

                                   const X86Subtarget &Subtarget,

                                   SelectionDAG &DAG) {

  uint64_t BlendMask = 0;

  bool ForceV1Zero = false, ForceV2Zero = false;

  SmallVector<int, 64> Mask(Original);

  if (!matchShuffleAsBlend(VT, V1, V2, Mask, Zeroable, ForceV1Zero, ForceV2Zero,

                           BlendMask))

    return SDValue();


  // Create a REAL zero vector - ISD::isBuildVectorAllZeros allows UNDEFs.

  if (ForceV1Zero)

    V1 = getZeroVector(VT, Subtarget, DAG, DL);

  if (ForceV2Zero)

    V2 = getZeroVector(VT, Subtarget, DAG, DL);


  unsigned NumElts = VT.getVectorNumElements();


  switch (VT.SimpleTy) {

  case MVT::v4i64:

  case MVT::v8i32:

    assert(Subtarget.hasAVX2() && "256-bit integer blends require AVX2!");

    [[fallthrough]];

  case MVT::v4f64:

  case MVT::v8f32:

    assert(Subtarget.hasAVX() && "256-bit float blends require AVX!");

    [[fallthrough]];

  case MVT::v2f64:

  case MVT::v2i64:

  case MVT::v4f32:

  case MVT::v4i32:

  case MVT::v8i16:

    assert(Subtarget.hasSSE41() && "128-bit blends require SSE41!");

    return DAG.getNode(X86ISD::BLENDI, DL, VT, V1, V2,

                       DAG.getTargetConstant(BlendMask, DL, MVT::i8));

  case MVT::v16i16: {

    assert(Subtarget.hasAVX2() && "v16i16 blends require AVX2!");

    SmallVector<int, 8> RepeatedMask;

    if (is128BitLaneRepeatedShuffleMask(MVT::v16i16, Mask, RepeatedMask)) {

      // We can lower these with PBLENDW which is mirrored across 128-bit lanes.

      assert(RepeatedMask.size() == 8 && "Repeated mask size doesn't match!");

      BlendMask = 0;

      for (int i = 0; i < 8; ++i)

        if (RepeatedMask[i] >= 8)

          BlendMask |= 1ull << i;

      return DAG.getNode(X86ISD::BLENDI, DL, MVT::v16i16, V1, V2,

                         DAG.getTargetConstant(BlendMask, DL, MVT::i8));

    }

    // Use PBLENDW for lower/upper lanes and then blend lanes.

    // TODO - we should allow 2 PBLENDW here and leave shuffle combine to

    // merge to VSELECT where useful.

    uint64_t LoMask = BlendMask & 0xFF;

    uint64_t HiMask = (BlendMask >> 8) & 0xFF;

    if (LoMask == 0 || LoMask == 255 || HiMask == 0 || HiMask == 255) {

      SDValue Lo = DAG.getNode(X86ISD::BLENDI, DL, MVT::v16i16, V1, V2,

                               DAG.getTargetConstant(LoMask, DL, MVT::i8));

      SDValue Hi = DAG.getNode(X86ISD::BLENDI, DL, MVT::v16i16, V1, V2,

                               DAG.getTargetConstant(HiMask, DL, MVT::i8));

      return DAG.getVectorShuffle(

          MVT::v16i16, DL, Lo, Hi,

          {0, 1, 2, 3, 4, 5, 6, 7, 24, 25, 26, 27, 28, 29, 30, 31});

    }

    [[fallthrough]];

  }

  case MVT::v32i8:

    assert(Subtarget.hasAVX2() && "256-bit byte-blends require AVX2!");

    [[fallthrough]];

  case MVT::v16i8: {

    assert(Subtarget.hasSSE41() && "128-bit byte-blends require SSE41!");


    // Attempt to lower to a bitmask if we can. VPAND is faster than VPBLENDVB.

    if (SDValue Masked = lowerShuffleAsBitMask(DL, VT, V1, V2, Mask, Zeroable,

                                               Subtarget, DAG))

      return Masked;


    if (Subtarget.hasBWI() && Subtarget.hasVLX()) {

      MVT IntegerType = MVT::getIntegerVT(std::max<unsigned>(NumElts, 8));

      SDValue MaskNode = DAG.getConstant(BlendMask, DL, IntegerType);

      return getVectorMaskingNode(V2, MaskNode, V1, Subtarget, DAG);

    }


    // If we have VPTERNLOG, we can use that as a bit blend.

    if (Subtarget.hasVLX())

      if (SDValue BitBlend =

              lowerShuffleAsBitBlend(DL, VT, V1, V2, Mask, DAG))

        return BitBlend;


    // Scale the blend by the number of bytes per element.

    int Scale = VT.getScalarSizeInBits() / 8;


    // This form of blend is always done on bytes. Compute the byte vector

    // type.

    MVT BlendVT = MVT::getVectorVT(MVT::i8, VT.getSizeInBits() / 8);


    // x86 allows load folding with blendvb from the 2nd source operand. But

    // we are still using LLVM select here (see comment below), so that's V1.

    // If V2 can be load-folded and V1 cannot be load-folded, then commute to

    // allow that load-folding possibility.

    if (!ISD::isNormalLoad(V1.getNode()) && ISD::isNormalLoad(V2.getNode())) {

      ShuffleVectorSDNode::commuteMask(Mask);

      std::swap(V1, V2);

    }


    // Compute the VSELECT mask. Note that VSELECT is really confusing in the

    // mix of LLVM's code generator and the x86 backend. We tell the code

    // generator that boolean values in the elements of an x86 vector register

    // are -1 for true and 0 for false. We then use the LLVM semantics of 'true'

    // mapping a select to operand #1, and 'false' mapping to operand #2. The

    // reality in x86 is that vector masks (pre-AVX-512) use only the high bit

    // of the element (the remaining are ignored) and 0 in that high bit would

    // mean operand #1 while 1 in the high bit would mean operand #2. So while

    // the LLVM model for boolean values in vector elements gets the relevant

    // bit set, it is set backwards and over constrained relative to x86's

    // actual model.

    SmallVector<SDValue, 32> VSELECTMask;

    for (int i = 0, Size = Mask.size(); i < Size; ++i)

      for (int j = 0; j < Scale; ++j)

        VSELECTMask.push_back(

            Mask[i] < 0

                ? DAG.getUNDEF(MVT::i8)

                : DAG.getSignedConstant(Mask[i] < Size ? -1 : 0, DL, MVT::i8));


    V1 = DAG.getBitcast(BlendVT, V1);

    V2 = DAG.getBitcast(BlendVT, V2);

    return DAG.getBitcast(

        VT,

        DAG.getSelect(DL, BlendVT, DAG.getBuildVector(BlendVT, DL, VSELECTMask),

                      V1, V2));

  }

  case MVT::v16f32:

  case MVT::v8f64:

  case MVT::v8i64:

  case MVT::v16i32:

  case MVT::v32i16:

  case MVT::v64i8: {

    // Attempt to lower to a bitmask if we can. Only if not optimizing for size.

    bool OptForSize = DAG.shouldOptForSize();

    if (!OptForSize) {

      if (SDValue Masked = lowerShuffleAsBitMask(DL, VT, V1, V2, Mask, Zeroable,

                                                 Subtarget, DAG))

        return Masked;

    }


    // Otherwise load an immediate into a GPR, cast to k-register, and use a

    // masked move.

    MVT IntegerType = MVT::getIntegerVT(std::max<unsigned>(NumElts, 8));

    SDValue MaskNode = DAG.getConstant(BlendMask, DL, IntegerType);

    return getVectorMaskingNode(V2, MaskNode, V1, Subtarget, DAG);

  }

  default:

    llvm_unreachable("Not a supported integer vector type!");

  }

}


/// Try to lower as a blend of elements from two inputs followed by

/// a single-input permutation.

///

/// This matches the pattern where we can blend elements from two inputs and

/// then reduce the shuffle to a single-input permutation.


static SDValue lowerShuffleAsBlendAndPermute(const SDLoc &DL, MVT VT,

                                             SDValue V1, SDValue V2,

                                             ArrayRef<int> Mask,

                                             SelectionDAG &DAG,

                                             bool ImmBlends = false) {

  // We build up the blend mask while checking whether a blend is a viable way

  // to reduce the shuffle.

  SmallVector<int, 32> BlendMask(Mask.size(), -1);

  SmallVector<int, 32> PermuteMask(Mask.size(), -1);


  for (int i = 0, Size = Mask.size(); i < Size; ++i) {

    if (Mask[i] < 0)

      continue;


    assert(Mask[i] < Size * 2 && "Shuffle input is out of bounds.");


    if (BlendMask[Mask[i] % Size] < 0)

      BlendMask[Mask[i] % Size] = Mask[i];

    else if (BlendMask[Mask[i] % Size] != Mask[i])

      return SDValue(); // Can't blend in the needed input!


    PermuteMask[i] = Mask[i] % Size;

  }


  // If only immediate blends, then bail if the blend mask can't be widened to

  // i16.

  unsigned EltSize = VT.getScalarSizeInBits();

  if (ImmBlends && EltSize == 8 && !canWidenShuffleElements(BlendMask))

    return SDValue();


  SDValue V = DAG.getVectorShuffle(VT, DL, V1, V2, BlendMask);

  return DAG.getVectorShuffle(VT, DL, V, DAG.getUNDEF(VT), PermuteMask);

}


/// Try to lower as an unpack of elements from two inputs followed by

/// a single-input permutation.

///

/// This matches the pattern where we can unpack elements from two inputs and

/// then reduce the shuffle to a single-input (wider) permutation.


static SDValue lowerShuffleAsUNPCKAndPermute(const SDLoc &DL, MVT VT,

                                             SDValue V1, SDValue V2,

                                             ArrayRef<int> Mask,

                                             SelectionDAG &DAG) {

  int NumElts = Mask.size();

  int NumLanes = VT.getSizeInBits() / 128;

  int NumLaneElts = NumElts / NumLanes;

  int NumHalfLaneElts = NumLaneElts / 2;


  bool MatchLo = true, MatchHi = true;

  SDValue Ops[2] = {DAG.getUNDEF(VT), DAG.getUNDEF(VT)};


  // Determine UNPCKL/UNPCKH type and operand order.

  for (int Elt = 0; Elt != NumElts; ++Elt) {

    int M = Mask[Elt];

    if (M < 0)

      continue;


    // Normalize the mask value depending on whether it's V1 or V2.

    int NormM = M;

    SDValue &Op = Ops[Elt & 1];

    if (M < NumElts && (Op.isUndef() || Op == V1))

      Op = V1;

    else if (NumElts <= M && (Op.isUndef() || Op == V2)) {

      Op = V2;

      NormM -= NumElts;

    } else

      return SDValue();


    bool MatchLoAnyLane = false, MatchHiAnyLane = false;

    for (int Lane = 0; Lane != NumElts; Lane += NumLaneElts) {

      int Lo = Lane, Mid = Lane + NumHalfLaneElts, Hi = Lane + NumLaneElts;

      MatchLoAnyLane |= isUndefOrInRange(NormM, Lo, Mid);

      MatchHiAnyLane |= isUndefOrInRange(NormM, Mid, Hi);

      if (MatchLoAnyLane || MatchHiAnyLane) {

        assert((MatchLoAnyLane ^ MatchHiAnyLane) &&

               "Failed to match UNPCKLO/UNPCKHI");

        break;

      }

    }

    MatchLo &= MatchLoAnyLane;

    MatchHi &= MatchHiAnyLane;

    if (!MatchLo && !MatchHi)

      return SDValue();

  }

  assert((MatchLo ^ MatchHi) && "Failed to match UNPCKLO/UNPCKHI");


  // Element indices have changed after unpacking. Calculate permute mask

  // so that they will be put back to the position as dictated by the

  // original shuffle mask indices.

  SmallVector<int, 32> PermuteMask(NumElts, -1);

  for (int Elt = 0; Elt != NumElts; ++Elt) {

    int M = Mask[Elt];

    if (M < 0)

      continue;

    int NormM = M;

    if (NumElts <= M)

      NormM -= NumElts;

    bool IsFirstOp = M < NumElts;

    int BaseMaskElt =

        NumLaneElts * (NormM / NumLaneElts) + (2 * (NormM % NumHalfLaneElts));

    if ((IsFirstOp && V1 == Ops[0]) || (!IsFirstOp && V2 == Ops[0]))

      PermuteMask[Elt] = BaseMaskElt;

    else if ((IsFirstOp && V1 == Ops[1]) || (!IsFirstOp && V2 == Ops[1]))

      PermuteMask[Elt] = BaseMaskElt + 1;

    assert(PermuteMask[Elt] != -1 &&

           "Input mask element is defined but failed to assign permute mask");

  }


  unsigned UnpckOp = MatchLo ? X86ISD::UNPCKL : X86ISD::UNPCKH;

  SDValue Unpck = DAG.getNode(UnpckOp, DL, VT, Ops);

  return DAG.getVectorShuffle(VT, DL, Unpck, DAG.getUNDEF(VT), PermuteMask);

}


/// Try to lower a shuffle as a permute of the inputs followed by an

/// UNPCK instruction.

///

/// This specifically targets cases where we end up with alternating between

/// the two inputs, and so can permute them into something that feeds a single

/// UNPCK instruction. Note that this routine only targets integer vectors

/// because for floating point vectors we have a generalized SHUFPS lowering

/// strategy that handles everything that doesn't *exactly* match an unpack,

/// making this clever lowering unnecessary.


static SDValue lowerShuffleAsPermuteAndUnpack(const SDLoc &DL, MVT VT,

                                              SDValue V1, SDValue V2,

                                              ArrayRef<int> Mask,

                                              const X86Subtarget &Subtarget,

                                              SelectionDAG &DAG) {

  int Size = Mask.size();

  assert(Mask.size() >= 2 && "Single element masks are invalid.");


  // This routine only supports 128-bit integer dual input vectors.

  if (VT.isFloatingPoint() || !VT.is128BitVector() || V2.isUndef())

    return SDValue();


  int NumLoInputs =

      count_if(Mask, [Size](int M) { return M >= 0 && M % Size < Size / 2; });

  int NumHiInputs =

      count_if(Mask, [Size](int M) { return M % Size >= Size / 2; });


  bool UnpackLo = NumLoInputs >= NumHiInputs;


  auto TryUnpack = [&](int ScalarSize, int Scale) {

    SmallVector<int, 16> V1Mask((unsigned)Size, -1);

    SmallVector<int, 16> V2Mask((unsigned)Size, -1);


    for (int i = 0; i < Size; ++i) {

      if (Mask[i] < 0)

        continue;


      // Each element of the unpack contains Scale elements from this mask.

      int UnpackIdx = i / Scale;


      // We only handle the case where V1 feeds the first slots of the unpack.

      // We rely on canonicalization to ensure this is the case.

      if ((UnpackIdx % 2 == 0) != (Mask[i] < Size))

        return SDValue();


      // Setup the mask for this input. The indexing is tricky as we have to

      // handle the unpack stride.

      SmallVectorImpl<int> &VMask = (UnpackIdx % 2 == 0) ? V1Mask : V2Mask;

      VMask[(UnpackIdx / 2) * Scale + i % Scale + (UnpackLo ? 0 : Size / 2)] =

          Mask[i] % Size;

    }


    // If we will have to shuffle both inputs to use the unpack, check whether

    // we can just unpack first and shuffle the result. If so, skip this unpack.

    if ((NumLoInputs == 0 || NumHiInputs == 0) && !isNoopShuffleMask(V1Mask) &&

        !isNoopShuffleMask(V2Mask))

      return SDValue();


    // Shuffle the inputs into place.

    V1 = DAG.getVectorShuffle(VT, DL, V1, DAG.getUNDEF(VT), V1Mask);

    V2 = DAG.getVectorShuffle(VT, DL, V2, DAG.getUNDEF(VT), V2Mask);


    // Cast the inputs to the type we will use to unpack them.

    MVT UnpackVT =

        MVT::getVectorVT(MVT::getIntegerVT(ScalarSize), Size / Scale);

    V1 = DAG.getBitcast(UnpackVT, V1);

    V2 = DAG.getBitcast(UnpackVT, V2);


    // Unpack the inputs and cast the result back to the desired type.

    return DAG.getBitcast(

        VT, DAG.getNode(UnpackLo ? X86ISD::UNPCKL : X86ISD::UNPCKH, DL,

                        UnpackVT, V1, V2));

  };


  // We try each unpack from the largest to the smallest to try and find one

  // that fits this mask.

  int OrigScalarSize = VT.getScalarSizeInBits();

  for (int ScalarSize = 64; ScalarSize >= OrigScalarSize; ScalarSize /= 2)

    if (SDValue Unpack = TryUnpack(ScalarSize, ScalarSize / OrigScalarSize))

      return Unpack;


  // If we're shuffling with a zero vector then we're better off not doing

  // VECTOR_SHUFFLE(UNPCK()) as we lose track of those zero elements.

  if (ISD::isBuildVectorAllZeros(V1.getNode()) ||

      ISD::isBuildVectorAllZeros(V2.getNode()))

    return SDValue();


  // If none of the unpack-rooted lowerings worked (or were profitable) try an

  // initial unpack.

  if (NumLoInputs == 0 || NumHiInputs == 0) {

    assert((NumLoInputs > 0 || NumHiInputs > 0) &&

           "We have to have *some* inputs!");

    int HalfOffset = NumLoInputs == 0 ? Size / 2 : 0;


    // FIXME: We could consider the total complexity of the permute of each

    // possible unpacking. Or at the least we should consider how many

    // half-crossings are created.

    // FIXME: We could consider commuting the unpacks.


    SmallVector<int, 32> PermMask((unsigned)Size, -1);

    for (int i = 0; i < Size; ++i) {

      if (Mask[i] < 0)

        continue;


      assert(Mask[i] % Size >= HalfOffset && "Found input from wrong half!");


      PermMask[i] =

          2 * ((Mask[i] % Size) - HalfOffset) + (Mask[i] < Size ? 0 : 1);

    }

    return DAG.getVectorShuffle(

        VT, DL,

        DAG.getNode(NumLoInputs == 0 ? X86ISD::UNPCKH : X86ISD::UNPCKL, DL, VT,

                    V1, V2),

        DAG.getUNDEF(VT), PermMask);

  }


  return SDValue();

}


/// Helper to form a PALIGNR-based rotate+permute, merging 2 inputs and then

/// permuting the elements of the result in place.


static SDValue lowerShuffleAsByteRotateAndPermute(

    const SDLoc &DL, MVT VT, SDValue V1, SDValue V2, ArrayRef<int> Mask,

    const X86Subtarget &Subtarget, SelectionDAG &DAG) {

  if ((VT.is128BitVector() && !Subtarget.hasSSSE3()) ||

      (VT.is256BitVector() && !Subtarget.hasAVX2()) ||

      (VT.is512BitVector() && !Subtarget.hasBWI()))

    return SDValue();


  // We don't currently support lane crossing permutes.

  if (is128BitLaneCrossingShuffleMask(VT, Mask))

    return SDValue();


  int Scale = VT.getScalarSizeInBits() / 8;

  int NumLanes = VT.getSizeInBits() / 128;

  int NumElts = VT.getVectorNumElements();

  int NumEltsPerLane = NumElts / NumLanes;


  // Determine range of mask elts.

  bool Blend1 = true;

  bool Blend2 = true;

  std::pair<int, int> Range1 = std::make_pair(INT_MAX, INT_MIN);

  std::pair<int, int> Range2 = std::make_pair(INT_MAX, INT_MIN);

  for (int Lane = 0; Lane != NumElts; Lane += NumEltsPerLane) {

    for (int Elt = 0; Elt != NumEltsPerLane; ++Elt) {

      int M = Mask[Lane + Elt];

      if (M < 0)

        continue;

      if (M < NumElts) {

        Blend1 &= (M == (Lane + Elt));

        assert(Lane <= M && M < (Lane + NumEltsPerLane) && "Out of range mask");

        M = M % NumEltsPerLane;

        Range1.first = std::min(Range1.first, M);

        Range1.second = std::max(Range1.second, M);

      } else {

        M -= NumElts;

        Blend2 &= (M == (Lane + Elt));

        assert(Lane <= M && M < (Lane + NumEltsPerLane) && "Out of range mask");

        M = M % NumEltsPerLane;

        Range2.first = std::min(Range2.first, M);

        Range2.second = std::max(Range2.second, M);

      }

    }

  }


  // Bail if we don't need both elements.

  // TODO - it might be worth doing this for unary shuffles if the permute

  // can be widened.

  if (!(0 <= Range1.first && Range1.second < NumEltsPerLane) ||

      !(0 <= Range2.first && Range2.second < NumEltsPerLane))

    return SDValue();


  if (VT.getSizeInBits() > 128 && (Blend1 || Blend2))

    return SDValue();


  // Rotate the 2 ops so we can access both ranges, then permute the result.

  auto RotateAndPermute = [&](SDValue Lo, SDValue Hi, int RotAmt, int Ofs) {

    MVT ByteVT = MVT::getVectorVT(MVT::i8, VT.getSizeInBits() / 8);

    SDValue Rotate = DAG.getBitcast(

        VT, DAG.getNode(X86ISD::PALIGNR, DL, ByteVT, DAG.getBitcast(ByteVT, Hi),

                        DAG.getBitcast(ByteVT, Lo),

                        DAG.getTargetConstant(Scale * RotAmt, DL, MVT::i8)));

    SmallVector<int, 64> PermMask(NumElts, SM_SentinelUndef);

    for (int Lane = 0; Lane != NumElts; Lane += NumEltsPerLane) {

      for (int Elt = 0; Elt != NumEltsPerLane; ++Elt) {

        int M = Mask[Lane + Elt];

        if (M < 0)

          continue;

        if (M < NumElts)

          PermMask[Lane + Elt] = Lane + ((M + Ofs - RotAmt) % NumEltsPerLane);

        else

          PermMask[Lane + Elt] = Lane + ((M - Ofs - RotAmt) % NumEltsPerLane);

      }

    }

    return DAG.getVectorShuffle(VT, DL, Rotate, DAG.getUNDEF(VT), PermMask);

  };


  // Check if the ranges are small enough to rotate from either direction.

  if (Range2.second < Range1.first)

    return RotateAndPermute(V1, V2, Range1.first, 0);

  if (Range1.second < Range2.first)

    return RotateAndPermute(V2, V1, Range2.first, NumElts);

  return SDValue();

}


static bool isBroadcastShuffleMask(ArrayRef<int> Mask) {

  return isUndefOrEqual(Mask, 0);

}


static bool isNoopOrBroadcastShuffleMask(ArrayRef<int> Mask) {

  return isNoopShuffleMask(Mask) || isBroadcastShuffleMask(Mask);

}


/// Check if the Mask consists of the same element repeated multiple times.


static bool isSingleElementRepeatedMask(ArrayRef<int> Mask) {

  size_t NumUndefs = 0;

  std::optional<int> UniqueElt;

  for (int Elt : Mask) {

    if (Elt == SM_SentinelUndef) {

      NumUndefs++;

      continue;

    }

    if (UniqueElt.has_value() && UniqueElt.value() != Elt)

      return false;

    UniqueElt = Elt;

  }

  // Make sure the element is repeated enough times by checking the number of

  // undefs is small.

  return NumUndefs <= Mask.size() / 2 && UniqueElt.has_value();

}


/// Generic routine to decompose a shuffle and blend into independent

/// blends and permutes.

///

/// This matches the extremely common pattern for handling combined

/// shuffle+blend operations on newer X86 ISAs where we have very fast blend

/// operations. It will try to pick the best arrangement of shuffles and

/// blends. For vXi8/vXi16 shuffles we may use unpack instead of blend.


static SDValue lowerShuffleAsDecomposedShuffleMerge(

    const SDLoc &DL, MVT VT, SDValue V1, SDValue V2, ArrayRef<int> Mask,

    const APInt &Zeroable, const X86Subtarget &Subtarget, SelectionDAG &DAG) {

  int NumElts = Mask.size();

  int NumLanes = VT.getSizeInBits() / 128;

  int NumEltsPerLane = NumElts / NumLanes;


  // Shuffle the input elements into the desired positions in V1 and V2 and

  // unpack/blend them together.

  bool IsAlternating = true;

  bool V1Zero = true, V2Zero = true;

  SmallVector<int, 32> V1Mask(NumElts, -1);

  SmallVector<int, 32> V2Mask(NumElts, -1);

  SmallVector<int, 32> FinalMask(NumElts, -1);

  for (int i = 0; i < NumElts; ++i) {

    int M = Mask[i];

    if (M >= 0 && M < NumElts) {

      V1Mask[i] = M;

      FinalMask[i] = i;

      V1Zero &= Zeroable[i];

      IsAlternating &= (i & 1) == 0;

    } else if (M >= NumElts) {

      V2Mask[i] = M - NumElts;

      FinalMask[i] = i + NumElts;

      V2Zero &= Zeroable[i];

      IsAlternating &= (i & 1) == 1;

    }

  }


  // If we effectively only demand the 0'th element of \p Input, and not only

  // as 0'th element, then broadcast said input,

  // and change \p InputMask to be a no-op (identity) mask.

  auto canonicalizeBroadcastableInput = [DL, VT, &Subtarget,

                                         &DAG](SDValue &Input,

                                               MutableArrayRef<int> InputMask) {

    unsigned EltSizeInBits = Input.getScalarValueSizeInBits();

    if (!Subtarget.hasAVX2() && (!Subtarget.hasAVX() || EltSizeInBits < 32 ||

                                 !X86::mayFoldLoad(Input, Subtarget)))

      return;

    if (isNoopShuffleMask(InputMask))

      return;

    assert(isBroadcastShuffleMask(InputMask) &&

           "Expected to demand only the 0'th element.");

    Input = DAG.getNode(X86ISD::VBROADCAST, DL, VT, Input);

    for (auto I : enumerate(InputMask)) {

      int &InputMaskElt = I.value();

      if (InputMaskElt >= 0)

        InputMaskElt = I.index();

    }

  };


  // Currently, we may need to produce one shuffle per input, and blend results.

  // It is possible that the shuffle for one of the inputs is already a no-op.

  // See if we can simplify non-no-op shuffles into broadcasts,

  // which we consider to be strictly better than an arbitrary shuffle.

  if (isNoopOrBroadcastShuffleMask(V1Mask) &&

      isNoopOrBroadcastShuffleMask(V2Mask)) {

    canonicalizeBroadcastableInput(V1, V1Mask);

    canonicalizeBroadcastableInput(V2, V2Mask);

  }


  // Try to lower with the simpler initial blend/unpack/rotate strategies unless

  // one of the input shuffles would be a no-op. We prefer to shuffle inputs as

  // the shuffle may be able to fold with a load or other benefit. However, when

  // we'll have to do 2x as many shuffles in order to achieve this, a 2-input

  // pre-shuffle first is a better strategy.

  if (!isNoopShuffleMask(V1Mask) && !isNoopShuffleMask(V2Mask)) {

    // If we don't have blends, see if we can create a cheap unpack.

    if (!Subtarget.hasSSE41() && VT.is128BitVector() &&

        (is128BitUnpackShuffleMask(V1Mask, DAG) ||

         is128BitUnpackShuffleMask(V2Mask, DAG)))

      if (SDValue PermUnpack = lowerShuffleAsPermuteAndUnpack(

              DL, VT, V1, V2, Mask, Subtarget, DAG))

        return PermUnpack;


    // Only prefer immediate blends to unpack/rotate.

    if (SDValue BlendPerm =

            lowerShuffleAsBlendAndPermute(DL, VT, V1, V2, Mask, DAG, true))

      return BlendPerm;


    // If either input vector provides only a single element which is repeated

    // multiple times, unpacking from both input vectors would generate worse

    // code. e.g. for

    // t5: v16i8 = vector_shuffle<16,0,16,1,16,2,16,3,16,4,16,5,16,6,16,7> t2, t4

    // it is better to process t4 first to create a vector of t4[0], then unpack

    // that vector with t2.

    if (!V1Zero && !V2Zero && !isSingleElementRepeatedMask(V1Mask) &&

        !isSingleElementRepeatedMask(V2Mask))

      if (SDValue UnpackPerm =

              lowerShuffleAsUNPCKAndPermute(DL, VT, V1, V2, Mask, DAG))

        return UnpackPerm;


    if (SDValue RotatePerm = lowerShuffleAsByteRotateAndPermute(

            DL, VT, V1, V2, Mask, Subtarget, DAG))

      return RotatePerm;


    // Unpack/rotate failed - try again with variable blends.

    if (SDValue BlendPerm = lowerShuffleAsBlendAndPermute(DL, VT, V1, V2, Mask,

                                                          DAG))

      return BlendPerm;


    if (VT.getScalarSizeInBits() >= 32)

      if (SDValue PermUnpack = lowerShuffleAsPermuteAndUnpack(

              DL, VT, V1, V2, Mask, Subtarget, DAG))

        return PermUnpack;

  }


  // If the final mask is an alternating blend of vXi8/vXi16, convert to an

  // UNPCKL(SHUFFLE, SHUFFLE) pattern.

  // TODO: It doesn't have to be alternating - but each lane mustn't have more

  // than half the elements coming from each source.

  if (IsAlternating && VT.getScalarSizeInBits() < 32) {

    V1Mask.assign(NumElts, -1);

    V2Mask.assign(NumElts, -1);

    FinalMask.assign(NumElts, -1);

    for (int i = 0; i != NumElts; i += NumEltsPerLane)

      for (int j = 0; j != NumEltsPerLane; ++j) {

        int M = Mask[i + j];

        if (M >= 0 && M < NumElts) {

          V1Mask[i + (j / 2)] = M;

          FinalMask[i + j] = i + (j / 2);

        } else if (M >= NumElts) {

          V2Mask[i + (j / 2)] = M - NumElts;

          FinalMask[i + j] = i + (j / 2) + NumElts;

        }

      }

  }


  V1 = DAG.getVectorShuffle(VT, DL, V1, DAG.getUNDEF(VT), V1Mask);

  V2 = DAG.getVectorShuffle(VT, DL, V2, DAG.getUNDEF(VT), V2Mask);

  return DAG.getVectorShuffle(VT, DL, V1, V2, FinalMask);

}


static int matchShuffleAsBitRotate(MVT &RotateVT, int EltSizeInBits,

                                   const X86Subtarget &Subtarget,

                                   ArrayRef<int> Mask) {

  assert(!isNoopShuffleMask(Mask) && "We shouldn't lower no-op shuffles!");

  assert(EltSizeInBits < 64 && "Can't rotate 64-bit integers");


  // AVX512 only has vXi32/vXi64 rotates, so limit the rotation sub group size.

  int MinSubElts = Subtarget.hasAVX512() ? std::max(32 / EltSizeInBits, 2) : 2;

  int MaxSubElts = 64 / EltSizeInBits;

  unsigned RotateAmt, NumSubElts;

  if (!ShuffleVectorInst::isBitRotateMask(Mask, EltSizeInBits, MinSubElts,

                                          MaxSubElts, NumSubElts, RotateAmt))

    return -1;

  unsigned NumElts = Mask.size();

  MVT RotateSVT = MVT::getIntegerVT(EltSizeInBits * NumSubElts);

  RotateVT = MVT::getVectorVT(RotateSVT, NumElts / NumSubElts);

  return RotateAmt;

}


/// Lower shuffle using X86ISD::VROTLI rotations.


static SDValue lowerShuffleAsBitRotate(const SDLoc &DL, MVT VT, SDValue V1,

                                       ArrayRef<int> Mask,

                                       const X86Subtarget &Subtarget,

                                       SelectionDAG &DAG) {

  // Only XOP + AVX512 targets have bit rotation instructions.

  // If we at least have SSSE3 (PSHUFB) then we shouldn't attempt to use this.

  bool IsLegal =

      (VT.is128BitVector() && Subtarget.hasXOP()) || Subtarget.hasAVX512();

  if (!IsLegal && Subtarget.hasSSE3())

    return SDValue();


  MVT RotateVT;

  int RotateAmt = matchShuffleAsBitRotate(RotateVT, VT.getScalarSizeInBits(),

                                          Subtarget, Mask);

  if (RotateAmt < 0)

    return SDValue();


  // For pre-SSSE3 targets, if we are shuffling vXi8 elts then ISD::ROTL,

  // expanded to OR(SRL,SHL), will be more efficient, but if they can

  // widen to vXi16 or more then existing lowering should will be better.

  if (!IsLegal) {

    if ((RotateAmt % 16) == 0)

      return SDValue();

    // TODO: Use getTargetVShiftByConstNode.

    unsigned ShlAmt = RotateAmt;

    unsigned SrlAmt = RotateVT.getScalarSizeInBits() - RotateAmt;

    V1 = DAG.getBitcast(RotateVT, V1);

    SDValue SHL = DAG.getNode(X86ISD::VSHLI, DL, RotateVT, V1,

                              DAG.getTargetConstant(ShlAmt, DL, MVT::i8));

    SDValue SRL = DAG.getNode(X86ISD::VSRLI, DL, RotateVT, V1,

                              DAG.getTargetConstant(SrlAmt, DL, MVT::i8));

    SDValue Rot = DAG.getNode(ISD::OR, DL, RotateVT, SHL, SRL);

    return DAG.getBitcast(VT, Rot);

  }


  SDValue Rot =

      DAG.getNode(X86ISD::VROTLI, DL, RotateVT, DAG.getBitcast(RotateVT, V1),

                  DAG.getTargetConstant(RotateAmt, DL, MVT::i8));

  return DAG.getBitcast(VT, Rot);

}


/// Try to match a vector shuffle as an element rotation.

///

/// This is used for support PALIGNR for SSSE3 or VALIGND/Q for AVX512.


static int matchShuffleAsElementRotate(SDValue &V1, SDValue &V2,

                                       ArrayRef<int> Mask) {

  int NumElts = Mask.size();


  // We need to detect various ways of spelling a rotation:

  //   [11, 12, 13, 14, 15,  0,  1,  2]

  //   [-1, 12, 13, 14, -1, -1,  1, -1]

  //   [-1, -1, -1, -1, -1, -1,  1,  2]

  //   [ 3,  4,  5,  6,  7,  8,  9, 10]

  //   [-1,  4,  5,  6, -1, -1,  9, -1]

  //   [-1,  4,  5,  6, -1, -1, -1, -1]

  int Rotation = 0;

  SDValue Lo, Hi;

  for (int i = 0; i < NumElts; ++i) {

    int M = Mask[i];

    assert((M == SM_SentinelUndef || (0 <= M && M < (2*NumElts))) &&

           "Unexpected mask index.");

    if (M < 0)

      continue;


    // Determine where a rotated vector would have started.

    int StartIdx = i - (M % NumElts);

    if (StartIdx == 0)

      // The identity rotation isn't interesting, stop.

      return -1;


    // If we found the tail of a vector the rotation must be the missing

    // front. If we found the head of a vector, it must be how much of the

    // head.

    int CandidateRotation = StartIdx < 0 ? -StartIdx : NumElts - StartIdx;


    if (Rotation == 0)

      Rotation = CandidateRotation;

    else if (Rotation != CandidateRotation)

      // The rotations don't match, so we can't match this mask.

      return -1;


    // Compute which value this mask is pointing at.

    SDValue MaskV = M < NumElts ? V1 : V2;


    // Compute which of the two target values this index should be assigned

    // to. This reflects whether the high elements are remaining or the low

    // elements are remaining.

    SDValue &TargetV = StartIdx < 0 ? Hi : Lo;


    // Either set up this value if we've not encountered it before, or check

    // that it remains consistent.

    if (!TargetV)

      TargetV = MaskV;

    else if (TargetV != MaskV)

      // This may be a rotation, but it pulls from the inputs in some

      // unsupported interleaving.

      return -1;

  }


  // Check that we successfully analyzed the mask, and normalize the results.

  assert(Rotation != 0 && "Failed to locate a viable rotation!");

  assert((Lo || Hi) && "Failed to find a rotated input vector!");

  if (!Lo)

    Lo = Hi;

  else if (!Hi)

    Hi = Lo;


  V1 = Lo;

  V2 = Hi;


  return Rotation;

}


/// Try to lower a vector shuffle as a byte rotation.

///

/// SSSE3 has a generic PALIGNR instruction in x86 that will do an arbitrary

/// byte-rotation of the concatenation of two vectors; pre-SSSE3 can use

/// a PSRLDQ/PSLLDQ/POR pattern to get a similar effect. This routine will

/// try to generically lower a vector shuffle through such an pattern. It

/// does not check for the profitability of lowering either as PALIGNR or

/// PSRLDQ/PSLLDQ/POR, only whether the mask is valid to lower in that form.

/// This matches shuffle vectors that look like:

///

///   v8i16 [11, 12, 13, 14, 15, 0, 1, 2]

///

/// Essentially it concatenates V1 and V2, shifts right by some number of

/// elements, and takes the low elements as the result. Note that while this is

/// specified as a *right shift* because x86 is little-endian, it is a *left

/// rotate* of the vector lanes.


static int matchShuffleAsByteRotate(MVT VT, SDValue &V1, SDValue &V2,

                                    ArrayRef<int> Mask) {

  // Don't accept any shuffles with zero elements.

  if (isAnyZero(Mask))

    return -1;


  // PALIGNR works on 128-bit lanes.

  SmallVector<int, 16> RepeatedMask;

  if (!is128BitLaneRepeatedShuffleMask(VT, Mask, RepeatedMask))

    return -1;


  int Rotation = matchShuffleAsElementRotate(V1, V2, RepeatedMask);

  if (Rotation <= 0)

    return -1;


  // PALIGNR rotates bytes, so we need to scale the

  // rotation based on how many bytes are in the vector lane.

  int NumElts = RepeatedMask.size();

  int Scale = 16 / NumElts;

  return Rotation * Scale;

}


static SDValue lowerShuffleAsByteRotate(const SDLoc &DL, MVT VT, SDValue V1,

                                        SDValue V2, ArrayRef<int> Mask,

                                        const X86Subtarget &Subtarget,

                                        SelectionDAG &DAG) {

  assert(!isNoopShuffleMask(Mask) && "We shouldn't lower no-op shuffles!");


  SDValue Lo = V1, Hi = V2;

  int ByteRotation = matchShuffleAsByteRotate(VT, Lo, Hi, Mask);

  if (ByteRotation <= 0)

    return SDValue();


  // Cast the inputs to i8 vector of correct length to match PALIGNR or

  // PSLLDQ/PSRLDQ.

  MVT ByteVT = MVT::getVectorVT(MVT::i8, VT.getSizeInBits() / 8);

  Lo = DAG.getBitcast(ByteVT, Lo);

  Hi = DAG.getBitcast(ByteVT, Hi);


  // SSSE3 targets can use the palignr instruction.

  if (Subtarget.hasSSSE3()) {

    assert((!VT.is512BitVector() || Subtarget.hasBWI()) &&

           "512-bit PALIGNR requires BWI instructions");

    return DAG.getBitcast(

        VT, DAG.getNode(X86ISD::PALIGNR, DL, ByteVT, Lo, Hi,

                        DAG.getTargetConstant(ByteRotation, DL, MVT::i8)));

  }


  assert(VT.is128BitVector() &&

         "Rotate-based lowering only supports 128-bit lowering!");

  assert(Mask.size() <= 16 &&

         "Can shuffle at most 16 bytes in a 128-bit vector!");

  assert(ByteVT == MVT::v16i8 &&

         "SSE2 rotate lowering only needed for v16i8!");


  // Default SSE2 implementation

  int LoByteShift = 16 - ByteRotation;

  int HiByteShift = ByteRotation;


  SDValue LoShift =

      DAG.getNode(X86ISD::VSHLDQ, DL, MVT::v16i8, Lo,

                  DAG.getTargetConstant(LoByteShift, DL, MVT::i8));

  SDValue HiShift =

      DAG.getNode(X86ISD::VSRLDQ, DL, MVT::v16i8, Hi,

                  DAG.getTargetConstant(HiByteShift, DL, MVT::i8));

  return DAG.getBitcast(VT,

                        DAG.getNode(ISD::OR, DL, MVT::v16i8, LoShift, HiShift));

}


/// Try to lower a vector shuffle as a dword/qword rotation.

///

/// AVX512 has a VALIGND/VALIGNQ instructions that will do an arbitrary

/// rotation of the concatenation of two vectors; This routine will

/// try to generically lower a vector shuffle through such an pattern.

///

/// Essentially it concatenates V1 and V2, shifts right by some number of

/// elements, and takes the low elements as the result. Note that while this is

/// specified as a *right shift* because x86 is little-endian, it is a *left

/// rotate* of the vector lanes.


static SDValue lowerShuffleAsVALIGN(const SDLoc &DL, MVT VT, SDValue V1,

                                    SDValue V2, ArrayRef<int> Mask,

                                    const APInt &Zeroable,

                                    const X86Subtarget &Subtarget,

                                    SelectionDAG &DAG) {

  assert((VT.getScalarType() == MVT::i32 || VT.getScalarType() == MVT::i64) &&

         "Only 32-bit and 64-bit elements are supported!");


  // 128/256-bit vectors are only supported with VLX.

  assert((Subtarget.hasVLX() || (!VT.is128BitVector() && !VT.is256BitVector()))

         && "VLX required for 128/256-bit vectors");


  SDValue Lo = V1, Hi = V2;

  int Rotation = matchShuffleAsElementRotate(Lo, Hi, Mask);

  if (0 < Rotation)

    return DAG.getNode(X86ISD::VALIGN, DL, VT, Lo, Hi,

                       DAG.getTargetConstant(Rotation, DL, MVT::i8));


  // See if we can use VALIGN as a cross-lane version of VSHLDQ/VSRLDQ.

  // TODO: Pull this out as a matchShuffleAsElementShift helper?

  // TODO: We can probably make this more aggressive and use shift-pairs like

  // lowerShuffleAsByteShiftMask.

  unsigned NumElts = Mask.size();

  unsigned ZeroLo = Zeroable.countr_one();

  unsigned ZeroHi = Zeroable.countl_one();

  assert((ZeroLo + ZeroHi) < NumElts && "Zeroable shuffle detected");

  if (!ZeroLo && !ZeroHi)

    return SDValue();


  if (ZeroLo) {

    SDValue Src = Mask[ZeroLo] < (int)NumElts ? V1 : V2;

    int Low = Mask[ZeroLo] < (int)NumElts ? 0 : NumElts;

    if (isSequentialOrUndefInRange(Mask, ZeroLo, NumElts - ZeroLo, Low))

      return DAG.getNode(X86ISD::VALIGN, DL, VT, Src,

                         getZeroVector(VT, Subtarget, DAG, DL),

                         DAG.getTargetConstant(NumElts - ZeroLo, DL, MVT::i8));

  }


  if (ZeroHi) {

    SDValue Src = Mask[0] < (int)NumElts ? V1 : V2;

    int Low = Mask[0] < (int)NumElts ? 0 : NumElts;

    if (isSequentialOrUndefInRange(Mask, 0, NumElts - ZeroHi, Low + ZeroHi))

      return DAG.getNode(X86ISD::VALIGN, DL, VT,

                         getZeroVector(VT, Subtarget, DAG, DL), Src,

                         DAG.getTargetConstant(ZeroHi, DL, MVT::i8));

  }


  return SDValue();

}


/// Try to lower a vector shuffle as a byte shift sequence.


static SDValue lowerShuffleAsByteShiftMask(const SDLoc &DL, MVT VT, SDValue V1,

                                           SDValue V2, ArrayRef<int> Mask,

                                           const APInt &Zeroable,

                                           const X86Subtarget &Subtarget,

                                           SelectionDAG &DAG) {

  assert(!isNoopShuffleMask(Mask) && "We shouldn't lower no-op shuffles!");

  assert(VT.is128BitVector() && "Only 128-bit vectors supported");


  // We need a shuffle that has zeros at one/both ends and a sequential

  // shuffle from one source within.

  unsigned ZeroLo = Zeroable.countr_one();

  unsigned ZeroHi = Zeroable.countl_one();

  if (!ZeroLo && !ZeroHi)

    return SDValue();


  unsigned NumElts = Mask.size();

  unsigned Len = NumElts - (ZeroLo + ZeroHi);

  if (!isSequentialOrUndefInRange(Mask, ZeroLo, Len, Mask[ZeroLo]))

    return SDValue();


  unsigned Scale = VT.getScalarSizeInBits() / 8;

  ArrayRef<int> StubMask = Mask.slice(ZeroLo, Len);

  if (!isUndefOrInRange(StubMask, 0, NumElts) &&

      !isUndefOrInRange(StubMask, NumElts, 2 * NumElts))

    return SDValue();


  SDValue Res = Mask[ZeroLo] < (int)NumElts ? V1 : V2;

  Res = DAG.getBitcast(MVT::v16i8, Res);


  // Use VSHLDQ/VSRLDQ ops to zero the ends of a vector and leave an

  // inner sequential set of elements, possibly offset:

  // 01234567 --> zzzzzz01 --> 1zzzzzzz

  // 01234567 --> 4567zzzz --> zzzzz456

  // 01234567 --> z0123456 --> 3456zzzz --> zz3456zz

  if (ZeroLo == 0) {

    unsigned Shift = (NumElts - 1) - (Mask[ZeroLo + Len - 1] % NumElts);

    Res = DAG.getNode(X86ISD::VSHLDQ, DL, MVT::v16i8, Res,

                      DAG.getTargetConstant(Scale * Shift, DL, MVT::i8));

    Res = DAG.getNode(X86ISD::VSRLDQ, DL, MVT::v16i8, Res,

                      DAG.getTargetConstant(Scale * ZeroHi, DL, MVT::i8));

  } else if (ZeroHi == 0) {

    unsigned Shift = Mask[ZeroLo] % NumElts;

    Res = DAG.getNode(X86ISD::VSRLDQ, DL, MVT::v16i8, Res,

                      DAG.getTargetConstant(Scale * Shift, DL, MVT::i8));

    Res = DAG.getNode(X86ISD::VSHLDQ, DL, MVT::v16i8, Res,

                      DAG.getTargetConstant(Scale * ZeroLo, DL, MVT::i8));

  } else if (!Subtarget.hasSSSE3()) {

    // If we don't have PSHUFB then its worth avoiding an AND constant mask

    // by performing 3 byte shifts. Shuffle combining can kick in above that.

    // TODO: There may be some cases where VSH{LR}DQ+PAND is still better.

    unsigned Shift = (NumElts - 1) - (Mask[ZeroLo + Len - 1] % NumElts);

    Res = DAG.getNode(X86ISD::VSHLDQ, DL, MVT::v16i8, Res,

                      DAG.getTargetConstant(Scale * Shift, DL, MVT::i8));

    Shift += Mask[ZeroLo] % NumElts;

    Res = DAG.getNode(X86ISD::VSRLDQ, DL, MVT::v16i8, Res,

                      DAG.getTargetConstant(Scale * Shift, DL, MVT::i8));

    Res = DAG.getNode(X86ISD::VSHLDQ, DL, MVT::v16i8, Res,

                      DAG.getTargetConstant(Scale * ZeroLo, DL, MVT::i8));

  } else

    return SDValue();


  return DAG.getBitcast(VT, Res);

}


/// Try to lower a vector shuffle as a bit shift (shifts in zeros).

///

/// Attempts to match a shuffle mask against the PSLL(W/D/Q/DQ) and

/// PSRL(W/D/Q/DQ) SSE2 and AVX2 logical bit-shift instructions. The function

/// matches elements from one of the input vectors shuffled to the left or

/// right with zeroable elements 'shifted in'. It handles both the strictly

/// bit-wise element shifts and the byte shift across an entire 128-bit double

/// quad word lane.

///

/// PSHL : (little-endian) left bit shift.

/// [ zz, 0, zz,  2 ]

/// [ -1, 4, zz, -1 ]

/// PSRL : (little-endian) right bit shift.

/// [  1, zz,  3, zz]

/// [ -1, -1,  7, zz]

/// PSLLDQ : (little-endian) left byte shift

/// [ zz,  0,  1,  2,  3,  4,  5,  6]

/// [ zz, zz, -1, -1,  2,  3,  4, -1]

/// [ zz, zz, zz, zz, zz, zz, -1,  1]

/// PSRLDQ : (little-endian) right byte shift

/// [  5, 6,  7, zz, zz, zz, zz, zz]

/// [ -1, 5,  6,  7, zz, zz, zz, zz]

/// [  1, 2, -1, -1, -1, -1, zz, zz]


static int matchShuffleAsShift(MVT &ShiftVT, unsigned &Opcode,

                               unsigned ScalarSizeInBits, ArrayRef<int> Mask,

                               int MaskOffset, const APInt &Zeroable,

                               const X86Subtarget &Subtarget) {

  int Size = Mask.size();

  unsigned SizeInBits = Size * ScalarSizeInBits;


  auto CheckZeros = [&](int Shift, int Scale, bool Left) {

    for (int i = 0; i < Size; i += Scale)

      for (int j = 0; j < Shift; ++j)

        if (!Zeroable[i + j + (Left ? 0 : (Scale - Shift))])

          return false;


    return true;

  };


  auto MatchShift = [&](int Shift, int Scale, bool Left) {

    for (int i = 0; i != Size; i += Scale) {

      unsigned Pos = Left ? i + Shift : i;

      unsigned Low = Left ? i : i + Shift;

      unsigned Len = Scale - Shift;

      if (!isSequentialOrUndefInRange(Mask, Pos, Len, Low + MaskOffset))

        return -1;

    }


    int ShiftEltBits = ScalarSizeInBits * Scale;

    bool ByteShift = ShiftEltBits > 64;

    Opcode = Left ? (ByteShift ? X86ISD::VSHLDQ : X86ISD::VSHLI)

                  : (ByteShift ? X86ISD::VSRLDQ : X86ISD::VSRLI);

    int ShiftAmt = Shift * ScalarSizeInBits / (ByteShift ? 8 : 1);


    // Normalize the scale for byte shifts to still produce an i64 element

    // type.

    Scale = ByteShift ? Scale / 2 : Scale;


    // We need to round trip through the appropriate type for the shift.

    MVT ShiftSVT = MVT::getIntegerVT(ScalarSizeInBits * Scale);

    ShiftVT = ByteShift ? MVT::getVectorVT(MVT::i8, SizeInBits / 8)

                        : MVT::getVectorVT(ShiftSVT, Size / Scale);

    return ShiftAmt;

  };


  // SSE/AVX supports logical shifts up to 64-bit integers - so we can just

  // keep doubling the size of the integer elements up to that. We can

  // then shift the elements of the integer vector by whole multiples of

  // their width within the elements of the larger integer vector. Test each

  // multiple to see if we can find a match with the moved element indices

  // and that the shifted in elements are all zeroable.

  unsigned MaxWidth = ((SizeInBits == 512) && !Subtarget.hasBWI() ? 64 : 128);

  for (int Scale = 2; Scale * ScalarSizeInBits <= MaxWidth; Scale *= 2)

    for (int Shift = 1; Shift != Scale; ++Shift)

      for (bool Left : {true, false})

        if (CheckZeros(Shift, Scale, Left)) {

          int ShiftAmt = MatchShift(Shift, Scale, Left);

          if (0 < ShiftAmt)

            return ShiftAmt;

        }


  // no match

  return -1;

}


static SDValue lowerShuffleAsShift(const SDLoc &DL, MVT VT, SDValue V1,

                                   SDValue V2, ArrayRef<int> Mask,

                                   const APInt &Zeroable,

                                   const X86Subtarget &Subtarget,

                                   SelectionDAG &DAG, bool BitwiseOnly) {

  int Size = Mask.size();

  assert(Size == (int)VT.getVectorNumElements() && "Unexpected mask size");


  MVT ShiftVT;

  SDValue V = V1;

  unsigned Opcode;


  // Try to match shuffle against V1 shift.

  int ShiftAmt = matchShuffleAsShift(ShiftVT, Opcode, VT.getScalarSizeInBits(),

                                     Mask, 0, Zeroable, Subtarget);


  // If V1 failed, try to match shuffle against V2 shift.

  if (ShiftAmt < 0) {

    ShiftAmt = matchShuffleAsShift(ShiftVT, Opcode, VT.getScalarSizeInBits(),

                                   Mask, Size, Zeroable, Subtarget);

    V = V2;

  }


  if (ShiftAmt < 0)

    return SDValue();


  if (BitwiseOnly && (Opcode == X86ISD::VSHLDQ || Opcode == X86ISD::VSRLDQ))

    return SDValue();


  assert(DAG.getTargetLoweringInfo().isTypeLegal(ShiftVT) &&

         "Illegal integer vector type");

  V = DAG.getBitcast(ShiftVT, V);

  V = DAG.getNode(Opcode, DL, ShiftVT, V,

                  DAG.getTargetConstant(ShiftAmt, DL, MVT::i8));

  return DAG.getBitcast(VT, V);

}


// EXTRQ: Extract Len elements from lower half of source, starting at Idx.

// Remainder of lower half result is zero and upper half is all undef.


static bool matchShuffleAsEXTRQ(MVT VT, SDValue &V1, SDValue &V2,

                                ArrayRef<int> Mask, uint64_t &BitLen,

                                uint64_t &BitIdx, const APInt &Zeroable) {

  int Size = Mask.size();

  int HalfSize = Size / 2;

  assert(Size == (int)VT.getVectorNumElements() && "Unexpected mask size");

  assert(!Zeroable.isAllOnes() && "Fully zeroable shuffle mask");


  // Upper half must be undefined.

  if (!isUndefUpperHalf(Mask))

    return false;


  // Determine the extraction length from the part of the

  // lower half that isn't zeroable.

  int Len = HalfSize;

  for (; Len > 0; --Len)

    if (!Zeroable[Len - 1])

      break;

  assert(Len > 0 && "Zeroable shuffle mask");


  // Attempt to match first Len sequential elements from the lower half.

  SDValue Src;

  int Idx = -1;

  for (int i = 0; i != Len; ++i) {

    int M = Mask[i];

    if (M == SM_SentinelUndef)

      continue;

    SDValue &V = (M < Size ? V1 : V2);

    M = M % Size;


    // The extracted elements must start at a valid index and all mask

    // elements must be in the lower half.

    if (i > M || M >= HalfSize)

      return false;


    if (Idx < 0 || (Src == V && Idx == (M - i))) {

      Src = V;

      Idx = M - i;

      continue;

    }

    return false;

  }


  if (!Src || Idx < 0)

    return false;


  assert((Idx + Len) <= HalfSize && "Illegal extraction mask");

  BitLen = (Len * VT.getScalarSizeInBits()) & 0x3f;

  BitIdx = (Idx * VT.getScalarSizeInBits()) & 0x3f;

  V1 = Src;

  return true;

}


// INSERTQ: Extract lowest Len elements from lower half of second source and

// insert over first source, starting at Idx.

// { A[0], .., A[Idx-1], B[0], .., B[Len-1], A[Idx+Len], .., UNDEF, ... }


static bool matchShuffleAsINSERTQ(MVT VT, SDValue &V1, SDValue &V2,

                                  ArrayRef<int> Mask, uint64_t &BitLen,

                                  uint64_t &BitIdx) {

  int Size = Mask.size();

  int HalfSize = Size / 2;

  assert(Size == (int)VT.getVectorNumElements() && "Unexpected mask size");


  // Upper half must be undefined.

  if (!isUndefUpperHalf(Mask))

    return false;


  for (int Idx = 0; Idx != HalfSize; ++Idx) {

    SDValue Base;


    // Attempt to match first source from mask before insertion point.

    if (isUndefInRange(Mask, 0, Idx)) {

      /* EMPTY */

    } else if (isSequentialOrUndefInRange(Mask, 0, Idx, 0)) {

      Base = V1;

    } else if (isSequentialOrUndefInRange(Mask, 0, Idx, Size)) {

      Base = V2;

    } else {

      continue;

    }


    // Extend the extraction length looking to match both the insertion of

    // the second source and the remaining elements of the first.

    for (int Hi = Idx + 1; Hi <= HalfSize; ++Hi) {

      SDValue Insert;

      int Len = Hi - Idx;


      // Match insertion.

      if (isSequentialOrUndefInRange(Mask, Idx, Len, 0)) {

        Insert = V1;

      } else if (isSequentialOrUndefInRange(Mask, Idx, Len, Size)) {

        Insert = V2;

      } else {

        continue;

      }


      // Match the remaining elements of the lower half.

      if (isUndefInRange(Mask, Hi, HalfSize - Hi)) {

        /* EMPTY */

      } else if ((!Base || (Base == V1)) &&

                 isSequentialOrUndefInRange(Mask, Hi, HalfSize - Hi, Hi)) {

        Base = V1;

      } else if ((!Base || (Base == V2)) &&

                 isSequentialOrUndefInRange(Mask, Hi, HalfSize - Hi,

                                            Size + Hi)) {

        Base = V2;

      } else {

        continue;

      }


      BitLen = (Len * VT.getScalarSizeInBits()) & 0x3f;

      BitIdx = (Idx * VT.getScalarSizeInBits()) & 0x3f;

      V1 = Base;

      V2 = Insert;

      return true;

    }

  }


  return false;

}


/// Try to lower a vector shuffle using SSE4a EXTRQ/INSERTQ.


static SDValue lowerShuffleWithSSE4A(const SDLoc &DL, MVT VT, SDValue V1,

                                     SDValue V2, ArrayRef<int> Mask,

                                     const APInt &Zeroable, SelectionDAG &DAG) {

  uint64_t BitLen, BitIdx;

  if (matchShuffleAsEXTRQ(VT, V1, V2, Mask, BitLen, BitIdx, Zeroable))

    return DAG.getNode(X86ISD::EXTRQI, DL, VT, V1,

                       DAG.getTargetConstant(BitLen, DL, MVT::i8),

                       DAG.getTargetConstant(BitIdx, DL, MVT::i8));


  if (matchShuffleAsINSERTQ(VT, V1, V2, Mask, BitLen, BitIdx))

    return DAG.getNode(X86ISD::INSERTQI, DL, VT, V1 ? V1 : DAG.getUNDEF(VT),

                       V2 ? V2 : DAG.getUNDEF(VT),

                       DAG.getTargetConstant(BitLen, DL, MVT::i8),

                       DAG.getTargetConstant(BitIdx, DL, MVT::i8));


  return SDValue();

}


/// Lower a vector shuffle as an any/signed/zero extension.

///

/// Given a specific number of elements, element bit width, and extension

/// stride, produce either an extension based on the available

/// features of the subtarget. The extended elements are consecutive and

/// begin and can start from an offsetted element index in the input; to

/// avoid excess shuffling the offset must either being in the bottom lane

/// or at the start of a higher lane. All extended elements must be from

/// the same lane.


static SDValue lowerShuffleAsSpecificExtension(const SDLoc &DL, MVT VT,

                                               int Scale, int Offset,

                                               unsigned ExtOpc, SDValue InputV,

                                               ArrayRef<int> Mask,

                                               const X86Subtarget &Subtarget,

                                               SelectionDAG &DAG) {

  assert(Scale > 1 && "Need a scale to extend.");

  assert(ISD::isExtOpcode(ExtOpc) && "Unsupported extension");

  int EltBits = VT.getScalarSizeInBits();

  int NumElements = VT.getVectorNumElements();

  int NumEltsPerLane = 128 / EltBits;

  int OffsetLane = Offset / NumEltsPerLane;

  assert((EltBits == 8 || EltBits == 16 || EltBits == 32) &&

         "Only 8, 16, and 32 bit elements can be extended.");

  assert(Scale * EltBits <= 64 && "Cannot zero extend past 64 bits.");

  assert(0 <= Offset && "Extension offset must be positive.");

  assert((Offset < NumEltsPerLane || Offset % NumEltsPerLane == 0) &&

         "Extension offset must be in the first lane or start an upper lane.");


  // Check that an index is in same lane as the base offset.

  auto SafeOffset = [&](int Idx) {

    return OffsetLane == (Idx / NumEltsPerLane);

  };


  // Shift along an input so that the offset base moves to the first element.

  auto ShuffleOffset = [&](SDValue V) {

    if (!Offset)

      return V;


    SmallVector<int, 8> ShMask((unsigned)NumElements, -1);

    for (int i = 0; i * Scale < NumElements; ++i) {

      int SrcIdx = i + Offset;

      ShMask[i] = SafeOffset(SrcIdx) ? SrcIdx : -1;

    }

    return DAG.getVectorShuffle(VT, DL, V, DAG.getUNDEF(VT), ShMask);

  };


  // Found a valid a/zext mask! Try various lowering strategies based on the

  // input type and available ISA extensions.

  if (Subtarget.hasSSE41()) {

    // Not worth offsetting 128-bit vectors if scale == 2, a pattern using

    // PUNPCK will catch this in a later shuffle match.

    if (Offset && Scale == 2 && VT.is128BitVector())

      return SDValue();

    MVT ExtVT = MVT::getVectorVT(MVT::getIntegerVT(EltBits * Scale),

                                 NumElements / Scale);

    InputV = DAG.getBitcast(VT, InputV);

    InputV = ShuffleOffset(InputV);

    InputV = getEXTEND_VECTOR_INREG(ExtOpc, DL, ExtVT, InputV, DAG);

    return DAG.getBitcast(VT, InputV);

  }


  assert(VT.is128BitVector() && "Only 128-bit vectors can be extended.");

  InputV = DAG.getBitcast(VT, InputV);

  bool AnyExt = ExtOpc == ISD::ANY_EXTEND;


  // TODO: Add pre-SSE41 SIGN_EXTEND_VECTOR_INREG handling.

  if (ExtOpc == ISD::SIGN_EXTEND)

    return SDValue();


  // For any extends we can cheat for larger element sizes and use shuffle

  // instructions that can fold with a load and/or copy.

  if (AnyExt && EltBits == 32) {

    int PSHUFDMask[4] = {Offset, -1, SafeOffset(Offset + 1) ? Offset + 1 : -1,

                         -1};

    return DAG.getBitcast(

        VT, DAG.getNode(X86ISD::PSHUFD, DL, MVT::v4i32,

                        DAG.getBitcast(MVT::v4i32, InputV),

                        getV4X86ShuffleImm8ForMask(PSHUFDMask, DL, DAG)));

  }

  if (AnyExt && EltBits == 16 && Scale > 2) {

    int PSHUFDMask[4] = {Offset / 2, -1,

                         SafeOffset(Offset + 1) ? (Offset + 1) / 2 : -1, -1};

    InputV = DAG.getNode(X86ISD::PSHUFD, DL, MVT::v4i32,

                         DAG.getBitcast(MVT::v4i32, InputV),

                         getV4X86ShuffleImm8ForMask(PSHUFDMask, DL, DAG));

    int PSHUFWMask[4] = {1, -1, -1, -1};

    unsigned OddEvenOp = (Offset & 1) ? X86ISD::PSHUFLW : X86ISD::PSHUFHW;

    return DAG.getBitcast(

        VT, DAG.getNode(OddEvenOp, DL, MVT::v8i16,

                        DAG.getBitcast(MVT::v8i16, InputV),

                        getV4X86ShuffleImm8ForMask(PSHUFWMask, DL, DAG)));

  }


  // The SSE4A EXTRQ instruction can efficiently extend the first 2 lanes

  // to 64-bits.

  if ((Scale * EltBits) == 64 && EltBits < 32 && Subtarget.hasSSE4A()) {

    assert(NumElements == (int)Mask.size() && "Unexpected shuffle mask size!");

    assert(VT.is128BitVector() && "Unexpected vector width!");


    int LoIdx = Offset * EltBits;

    SDValue Lo = DAG.getBitcast(

        MVT::v2i64, DAG.getNode(X86ISD::EXTRQI, DL, VT, InputV,

                                DAG.getTargetConstant(EltBits, DL, MVT::i8),

                                DAG.getTargetConstant(LoIdx, DL, MVT::i8)));


    if (isUndefUpperHalf(Mask) || !SafeOffset(Offset + 1))

      return DAG.getBitcast(VT, Lo);


    int HiIdx = (Offset + 1) * EltBits;

    SDValue Hi = DAG.getBitcast(

        MVT::v2i64, DAG.getNode(X86ISD::EXTRQI, DL, VT, InputV,

                                DAG.getTargetConstant(EltBits, DL, MVT::i8),

                                DAG.getTargetConstant(HiIdx, DL, MVT::i8)));

    return DAG.getBitcast(VT,

                          DAG.getNode(X86ISD::UNPCKL, DL, MVT::v2i64, Lo, Hi));

  }


  // If this would require more than 2 unpack instructions to expand, use

  // pshufb when available. We can only use more than 2 unpack instructions

  // when zero extending i8 elements which also makes it easier to use pshufb.

  if (Scale > 4 && EltBits == 8 && Subtarget.hasSSSE3()) {

    assert(NumElements == 16 && "Unexpected byte vector width!");

    SDValue PSHUFBMask[16];

    for (int i = 0; i < 16; ++i) {

      int Idx = Offset + (i / Scale);

      if ((i % Scale == 0 && SafeOffset(Idx))) {

        PSHUFBMask[i] = DAG.getConstant(Idx, DL, MVT::i8);

        continue;

      }

      PSHUFBMask[i] =

          AnyExt ? DAG.getUNDEF(MVT::i8) : DAG.getConstant(0x80, DL, MVT::i8);

    }

    InputV = DAG.getBitcast(MVT::v16i8, InputV);

    return DAG.getBitcast(

        VT, DAG.getNode(X86ISD::PSHUFB, DL, MVT::v16i8, InputV,

                        DAG.getBuildVector(MVT::v16i8, DL, PSHUFBMask)));

  }


  // If we are extending from an offset, ensure we start on a boundary that

  // we can unpack from.

  int AlignToUnpack = Offset % (NumElements / Scale);

  if (AlignToUnpack) {

    SmallVector<int, 8> ShMask((unsigned)NumElements, -1);

    for (int i = AlignToUnpack; i < NumElements; ++i)

      ShMask[i - AlignToUnpack] = i;

    InputV = DAG.getVectorShuffle(VT, DL, InputV, DAG.getUNDEF(VT), ShMask);

    Offset -= AlignToUnpack;

  }


  // Otherwise emit a sequence of unpacks.

  do {

    unsigned UnpackLoHi = X86ISD::UNPCKL;

    if (Offset >= (NumElements / 2)) {

      UnpackLoHi = X86ISD::UNPCKH;

      Offset -= (NumElements / 2);

    }


    MVT InputVT = MVT::getVectorVT(MVT::getIntegerVT(EltBits), NumElements);

    SDValue Ext = AnyExt ? DAG.getUNDEF(InputVT)

                         : getZeroVector(InputVT, Subtarget, DAG, DL);

    InputV = DAG.getBitcast(InputVT, InputV);

    InputV = DAG.getNode(UnpackLoHi, DL, InputVT, InputV, Ext);

    Scale /= 2;

    EltBits *= 2;

    NumElements /= 2;

  } while (Scale > 1);

  return DAG.getBitcast(VT, InputV);

}


/// Try to lower a vector shuffle as a zero extension on any microarch.

///

/// This routine will try to do everything in its power to cleverly lower

/// a shuffle which happens to match the pattern of a zero extend. It doesn't

/// check for the profitability of this lowering,  it tries to aggressively

/// match this pattern. It will use all of the micro-architectural details it

/// can to emit an efficient lowering. It handles both blends with all-zero

/// inputs to explicitly zero-extend and undef-lanes (sometimes undef due to

/// masking out later).

///

/// The reason we have dedicated lowering for zext-style shuffles is that they

/// are both incredibly common and often quite performance sensitive.


static SDValue lowerShuffleAsZeroOrAnyExtend(

    const SDLoc &DL, MVT VT, SDValue V1, SDValue V2, ArrayRef<int> Mask,

    const APInt &Zeroable, const X86Subtarget &Subtarget,

    SelectionDAG &DAG) {

  int Bits = VT.getSizeInBits();

  int NumLanes = Bits / 128;

  int NumElements = VT.getVectorNumElements();

  int NumEltsPerLane = NumElements / NumLanes;

  assert(VT.getScalarSizeInBits() <= 32 &&

         "Exceeds 32-bit integer zero extension limit");

  assert((int)Mask.size() == NumElements && "Unexpected shuffle mask size");


  // Define a helper function to check a particular ext-scale and lower to it if

  // valid.

  auto Lower = [&](int Scale) -> SDValue {

    SDValue InputV;

    bool AnyExt = true;

    int Offset = 0;

    int Matches = 0;

    for (int i = 0; i < NumElements; ++i) {

      int M = Mask[i];

      if (M < 0)

        continue; // Valid anywhere but doesn't tell us anything.

      if (i % Scale != 0) {

        // Each of the extended elements need to be zeroable.

        if (!Zeroable[i])

          return SDValue();


        // We no longer are in the anyext case.

        AnyExt = false;

        continue;

      }


      // Each of the base elements needs to be consecutive indices into the

      // same input vector.

      SDValue V = M < NumElements ? V1 : V2;

      M = M % NumElements;

      if (!InputV) {

        InputV = V;

        Offset = M - (i / Scale);

      } else if (InputV != V)

        return SDValue(); // Flip-flopping inputs.


      // Offset must start in the lowest 128-bit lane or at the start of an

      // upper lane.

      // FIXME: Is it ever worth allowing a negative base offset?

      if (!((0 <= Offset && Offset < NumEltsPerLane) ||

            (Offset % NumEltsPerLane) == 0))

        return SDValue();


      // If we are offsetting, all referenced entries must come from the same

      // lane.

      if (Offset && (Offset / NumEltsPerLane) != (M / NumEltsPerLane))

        return SDValue();


      if ((M % NumElements) != (Offset + (i / Scale)))

        return SDValue(); // Non-consecutive strided elements.

      Matches++;

    }


    // If we fail to find an input, we have a zero-shuffle which should always

    // have already been handled.

    // FIXME: Maybe handle this here in case during blending we end up with one?

    if (!InputV)

      return SDValue();


    // If we are offsetting, don't extend if we only match a single input, we

    // can always do better by using a basic PSHUF or PUNPCK.

    if (Offset != 0 && Matches < 2)

      return SDValue();


    unsigned ExtOpc = AnyExt ? ISD::ANY_EXTEND : ISD::ZERO_EXTEND;

    return lowerShuffleAsSpecificExtension(DL, VT, Scale, Offset, ExtOpc,

                                           InputV, Mask, Subtarget, DAG);

  };


  // The widest scale possible for extending is to a 64-bit integer.

  assert(Bits % 64 == 0 &&

         "The number of bits in a vector must be divisible by 64 on x86!");

  int NumExtElements = Bits / 64;


  // Each iteration, try extending the elements half as much, but into twice as

  // many elements.

  for (; NumExtElements < NumElements; NumExtElements *= 2) {

    assert(NumElements % NumExtElements == 0 &&

           "The input vector size must be divisible by the extended size.");

    if (SDValue V = Lower(NumElements / NumExtElements))

      return V;

  }


  // General extends failed, but 128-bit vectors may be able to use MOVQ.

  if (Bits != 128)

    return SDValue();


  // Returns one of the source operands if the shuffle can be reduced to a

  // MOVQ, copying the lower 64-bits and zero-extending to the upper 64-bits.

  auto CanZExtLowHalf = [&]() {

    for (int i = NumElements / 2; i != NumElements; ++i)

      if (!Zeroable[i])

        return SDValue();

    if (isSequentialOrUndefInRange(Mask, 0, NumElements / 2, 0))

      return V1;

    if (isSequentialOrUndefInRange(Mask, 0, NumElements / 2, NumElements))

      return V2;

    return SDValue();

  };


  if (SDValue V = CanZExtLowHalf()) {

    V = DAG.getBitcast(MVT::v2i64, V);

    V = DAG.getNode(X86ISD::VZEXT_MOVL, DL, MVT::v2i64, V);

    return DAG.getBitcast(VT, V);

  }


  // No viable ext lowering found.

  return SDValue();

}


/// Try to get a scalar value for a specific element of a vector.

///

/// Looks through BUILD_VECTOR and SCALAR_TO_VECTOR nodes to find a scalar.


static SDValue getScalarValueForVectorElement(SDValue V, int Idx,

                                              SelectionDAG &DAG) {

  MVT VT = V.getSimpleValueType();

  MVT EltVT = VT.getVectorElementType();

  V = peekThroughBitcasts(V);


  // If the bitcasts shift the element size, we can't extract an equivalent

  // element from it.

  MVT NewVT = V.getSimpleValueType();

  if (!NewVT.isVector() || NewVT.getScalarSizeInBits() != VT.getScalarSizeInBits())

    return SDValue();


  if (V.getOpcode() == ISD::BUILD_VECTOR ||

      (Idx == 0 && V.getOpcode() == ISD::SCALAR_TO_VECTOR)) {

    // Ensure the scalar operand is the same size as the destination.

    // FIXME: Add support for scalar truncation where possible.

    SDValue S = V.getOperand(Idx);

    if (EltVT.getSizeInBits() == S.getSimpleValueType().getSizeInBits())

      return DAG.getBitcast(EltVT, S);

  }


  return SDValue();

}


/// Helper to test for a load that can be folded with x86 shuffles.

///

/// This is particularly important because the set of instructions varies

/// significantly based on whether the operand is a load or not.


static bool isShuffleFoldableLoad(SDValue V) {

  return V.hasOneUse() &&

         ISD::isNON_EXTLoad(peekThroughOneUseBitcasts(V).getNode());

}


template<typename T>


static bool isSoftF16(T VT, const X86Subtarget &Subtarget) {

  T EltVT = VT.getScalarType();

  return (EltVT == MVT::bf16 && !Subtarget.hasAVX10_2()) ||

         (EltVT == MVT::f16 && !Subtarget.hasFP16());

}


/// Try to lower insertion of a single element into a zero vector.

///

/// This is a common pattern that we have especially efficient patterns to lower

/// across all subtarget feature sets.


static SDValue lowerShuffleAsElementInsertion(

    const SDLoc &DL, MVT VT, SDValue V1, SDValue V2, ArrayRef<int> Mask,

    const APInt &Zeroable, const X86Subtarget &Subtarget,

    SelectionDAG &DAG) {

  MVT ExtVT = VT;

  MVT EltVT = VT.getVectorElementType();

  unsigned NumElts = VT.getVectorNumElements();

  unsigned EltBits = VT.getScalarSizeInBits();


  if (isSoftF16(EltVT, Subtarget))

    return SDValue();


  int V2Index =

      find_if(Mask, [&Mask](int M) { return M >= (int)Mask.size(); }) -

      Mask.begin();

  bool IsV1Constant = getTargetConstantFromNode(V1) != nullptr;

  bool IsV1Zeroable = true;

  for (int i = 0, Size = Mask.size(); i < Size; ++i)

    if (i != V2Index && !Zeroable[i]) {

      IsV1Zeroable = false;

      break;

    }


  // Bail if a non-zero V1 isn't used in place.

  if (!IsV1Zeroable) {

    SmallVector<int, 8> V1Mask(Mask);

    V1Mask[V2Index] = -1;

    if (!isNoopShuffleMask(V1Mask))

      return SDValue();

  }


  // Check for a single input from a SCALAR_TO_VECTOR node.

  // FIXME: All of this should be canonicalized into INSERT_VECTOR_ELT and

  // all the smarts here sunk into that routine. However, the current

  // lowering of BUILD_VECTOR makes that nearly impossible until the old

  // vector shuffle lowering is dead.

  SDValue V2S = getScalarValueForVectorElement(V2, Mask[V2Index] - Mask.size(),

                                               DAG);

  if (V2S && DAG.getTargetLoweringInfo().isTypeLegal(V2S.getValueType())) {

    // We need to zext the scalar if it is smaller than an i32.

    V2S = DAG.getBitcast(EltVT, V2S);

    if (EltVT == MVT::i8 || (EltVT == MVT::i16 && !Subtarget.hasFP16())) {

      // Using zext to expand a narrow element won't work for non-zero

      // insertions. But we can use a masked constant vector if we're

      // inserting V2 into the bottom of V1.

      if (!IsV1Zeroable && !(IsV1Constant && V2Index == 0))

        return SDValue();


      // Zero-extend directly to i32.

      ExtVT = MVT::getVectorVT(MVT::i32, ExtVT.getSizeInBits() / 32);

      V2S = DAG.getNode(ISD::ZERO_EXTEND, DL, MVT::i32, V2S);


      // If we're inserting into a constant, mask off the inserted index

      // and OR with the zero-extended scalar.

      if (!IsV1Zeroable) {

        SmallVector<APInt> Bits(NumElts, APInt::getAllOnes(EltBits));

        Bits[V2Index] = APInt::getZero(EltBits);

        SDValue BitMask = getConstVector(Bits, VT, DAG, DL);

        V1 = DAG.getNode(ISD::AND, DL, VT, V1, BitMask);

        V2 = DAG.getNode(ISD::SCALAR_TO_VECTOR, DL, ExtVT, V2S);

        V2 = DAG.getBitcast(VT, DAG.getNode(X86ISD::VZEXT_MOVL, DL, ExtVT, V2));

        return DAG.getNode(ISD::OR, DL, VT, V1, V2);

      }

    }

    V2 = DAG.getNode(ISD::SCALAR_TO_VECTOR, DL, ExtVT, V2S);

  } else if (Mask[V2Index] != (int)Mask.size() || EltVT == MVT::i8 ||

             (EltVT == MVT::i16 && !Subtarget.hasAVX10_2())) {

    // Either not inserting from the low element of the input or the input

    // element size is too small to use VZEXT_MOVL to clear the high bits.

    return SDValue();

  }


  if (!IsV1Zeroable) {

    // If V1 can't be treated as a zero vector we have fewer options to lower

    // this. We can't support integer vectors or non-zero targets cheaply.

    assert(VT == ExtVT && "Cannot change extended type when non-zeroable!");

    if (!VT.isFloatingPoint() || V2Index != 0)

      return SDValue();

    if (!VT.is128BitVector())

      return SDValue();


    // Otherwise, use MOVSD, MOVSS or MOVSH.

    unsigned MovOpc = 0;

    if (EltVT == MVT::f16)

      MovOpc = X86ISD::MOVSH;

    else if (EltVT == MVT::f32)

      MovOpc = X86ISD::MOVSS;

    else if (EltVT == MVT::f64)

      MovOpc = X86ISD::MOVSD;

    else

      llvm_unreachable("Unsupported floating point element type to handle!");

    return DAG.getNode(MovOpc, DL, ExtVT, V1, V2);

  }


  // This lowering only works for the low element with floating point vectors.

  if (VT.isFloatingPoint() && V2Index != 0)

    return SDValue();


  V2 = DAG.getNode(X86ISD::VZEXT_MOVL, DL, ExtVT, V2);

  if (ExtVT != VT)

    V2 = DAG.getBitcast(VT, V2);


  if (V2Index != 0) {

    // If we have 4 or fewer lanes we can cheaply shuffle the element into

    // the desired position. Otherwise it is more efficient to do a vector

    // shift left. We know that we can do a vector shift left because all

    // the inputs are zero.

    if (VT.isFloatingPoint() || NumElts <= 4) {

      SmallVector<int, 4> V2Shuffle(Mask.size(), 1);

      V2Shuffle[V2Index] = 0;

      V2 = DAG.getVectorShuffle(VT, DL, V2, DAG.getUNDEF(VT), V2Shuffle);

    } else {

      V2 = DAG.getBitcast(MVT::v16i8, V2);

      V2 = DAG.getNode(

          X86ISD::VSHLDQ, DL, MVT::v16i8, V2,

          DAG.getTargetConstant(V2Index * EltBits / 8, DL, MVT::i8));

      V2 = DAG.getBitcast(VT, V2);

    }

  }

  return V2;

}


/// Try to lower broadcast of a single - truncated - integer element,

/// coming from a scalar_to_vector/build_vector node \p V0 with larger elements.

///

/// This assumes we have AVX2.


static SDValue lowerShuffleAsTruncBroadcast(const SDLoc &DL, MVT VT, SDValue V0,

                                            int BroadcastIdx,

                                            const X86Subtarget &Subtarget,

                                            SelectionDAG &DAG) {

  assert(Subtarget.hasAVX2() &&

         "We can only lower integer broadcasts with AVX2!");


  MVT EltVT = VT.getVectorElementType();

  MVT V0VT = V0.getSimpleValueType();


  assert(VT.isInteger() && "Unexpected non-integer trunc broadcast!");

  assert(V0VT.isVector() && "Unexpected non-vector vector-sized value!");


  MVT V0EltVT = V0VT.getVectorElementType();

  if (!V0EltVT.isInteger())

    return SDValue();


  const unsigned EltSize = EltVT.getSizeInBits();

  const unsigned V0EltSize = V0EltVT.getSizeInBits();


  // This is only a truncation if the original element type is larger.

  if (V0EltSize <= EltSize)

    return SDValue();


  assert(((V0EltSize % EltSize) == 0) &&

         "Scalar type sizes must all be powers of 2 on x86!");


  const unsigned V0Opc = V0.getOpcode();

  const unsigned Scale = V0EltSize / EltSize;

  const unsigned V0BroadcastIdx = BroadcastIdx / Scale;


  if ((V0Opc != ISD::SCALAR_TO_VECTOR || V0BroadcastIdx != 0) &&

      V0Opc != ISD::BUILD_VECTOR)

    return SDValue();


  SDValue Scalar = V0.getOperand(V0BroadcastIdx);


  // If we're extracting non-least-significant bits, shift so we can truncate.

  // Hopefully, we can fold away the trunc/srl/load into the broadcast.

  // Even if we can't (and !isShuffleFoldableLoad(Scalar)), prefer

  // vpbroadcast+vmovd+shr to vpshufb(m)+vmovd.

  if (const int OffsetIdx = BroadcastIdx % Scale)

    Scalar = DAG.getNode(ISD::SRL, DL, Scalar.getValueType(), Scalar,

                         DAG.getConstant(OffsetIdx * EltSize, DL, MVT::i8));


  return DAG.getNode(X86ISD::VBROADCAST, DL, VT,

                     DAG.getNode(ISD::TRUNCATE, DL, EltVT, Scalar));

}


/// Test whether this can be lowered with a single SHUFPS instruction.

///

/// This is used to disable more specialized lowerings when the shufps lowering

/// will happen to be efficient.


static bool isSingleSHUFPSMask(ArrayRef<int> Mask) {

  // This routine only handles 128-bit shufps.

  assert(Mask.size() == 4 && "Unsupported mask size!");

  assert(Mask[0] >= -1 && Mask[0] < 8 && "Out of bound mask element!");

  assert(Mask[1] >= -1 && Mask[1] < 8 && "Out of bound mask element!");

  assert(Mask[2] >= -1 && Mask[2] < 8 && "Out of bound mask element!");

  assert(Mask[3] >= -1 && Mask[3] < 8 && "Out of bound mask element!");


  // To lower with a single SHUFPS we need to have the low half and high half

  // each requiring a single input.

  if (Mask[0] >= 0 && Mask[1] >= 0 && (Mask[0] < 4) != (Mask[1] < 4))

    return false;

  if (Mask[2] >= 0 && Mask[3] >= 0 && (Mask[2] < 4) != (Mask[3] < 4))

    return false;


  return true;

}


/// Test whether the specified input (0 or 1) is in-place blended by the

/// given mask.

///

/// This returns true if the elements from a particular input are already in the

/// slot required by the given mask and require no permutation.


static bool isShuffleMaskInputInPlace(int Input, ArrayRef<int> Mask) {

  assert((Input == 0 || Input == 1) && "Only two inputs to shuffles.");

  int Size = Mask.size();

  for (int i = 0; i < Size; ++i)

    if (Mask[i] >= 0 && Mask[i] / Size == Input && Mask[i] % Size != i)

      return false;


  return true;

}


/// Test whether the specified input (0 or 1) is a broadcast/splat blended by

/// the given mask.

///


static bool isShuffleMaskInputBroadcastable(int Input, ArrayRef<int> Mask,

                                            int BroadcastableElement = 0) {

  assert((Input == 0 || Input == 1) && "Only two inputs to shuffles.");

  int Size = Mask.size();

  for (int i = 0; i < Size; ++i)

    if (Mask[i] >= 0 && Mask[i] / Size == Input &&

        Mask[i] % Size != BroadcastableElement)

      return false;

  return true;

}


/// If we are extracting two 128-bit halves of a vector and shuffling the

/// result, match that to a 256-bit AVX2 vperm* instruction to avoid a

/// multi-shuffle lowering.


static SDValue lowerShuffleOfExtractsAsVperm(const SDLoc &DL, SDValue N0,

                                             SDValue N1, ArrayRef<int> Mask,

                                             SelectionDAG &DAG) {

  MVT VT = N0.getSimpleValueType();

  assert((VT.is128BitVector() &&

          (VT.getScalarSizeInBits() == 32 || VT.getScalarSizeInBits() == 64)) &&

         "VPERM* family of shuffles requires 32-bit or 64-bit elements");


  // Check that both sources are extracts of the same source vector.

  if (N0.getOpcode() != ISD::EXTRACT_SUBVECTOR ||

      N1.getOpcode() != ISD::EXTRACT_SUBVECTOR ||

      N0.getOperand(0) != N1.getOperand(0) ||

      !N0.hasOneUse() || !N1.hasOneUse())

    return SDValue();


  SDValue WideVec = N0.getOperand(0);

  MVT WideVT = WideVec.getSimpleValueType();

  if (!WideVT.is256BitVector())

    return SDValue();


  // Match extracts of each half of the wide source vector. Commute the shuffle

  // if the extract of the low half is N1.

  unsigned NumElts = VT.getVectorNumElements();

  SmallVector<int, 4> NewMask(Mask);

  const APInt &ExtIndex0 = N0.getConstantOperandAPInt(1);

  const APInt &ExtIndex1 = N1.getConstantOperandAPInt(1);

  if (ExtIndex1 == 0 && ExtIndex0 == NumElts)

    ShuffleVectorSDNode::commuteMask(NewMask);

  else if (ExtIndex0 != 0 || ExtIndex1 != NumElts)

    return SDValue();


  // Final bailout: if the mask is simple, we are better off using an extract

  // and a simple narrow shuffle. Prefer extract+unpack(h/l)ps to vpermps

  // because that avoids a constant load from memory.

  if (NumElts == 4 &&

      (isSingleSHUFPSMask(NewMask) || is128BitUnpackShuffleMask(NewMask, DAG)))

    return SDValue();


  // Extend the shuffle mask with undef elements.

  NewMask.append(NumElts, -1);


  // shuf (extract X, 0), (extract X, 4), M --> extract (shuf X, undef, M'), 0

  SDValue Shuf = DAG.getVectorShuffle(WideVT, DL, WideVec, DAG.getUNDEF(WideVT),

                                      NewMask);

  // This is free: ymm -> xmm.

  return DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, VT, Shuf,

                     DAG.getVectorIdxConstant(0, DL));

}


/// Try to lower broadcast of a single element.

///

/// For convenience, this code also bundles all of the subtarget feature set

/// filtering. While a little annoying to re-dispatch on type here, there isn't

/// a convenient way to factor it out.


static SDValue lowerShuffleAsBroadcast(const SDLoc &DL, MVT VT, SDValue V1,

                                       SDValue V2, ArrayRef<int> Mask,

                                       const X86Subtarget &Subtarget,

                                       SelectionDAG &DAG) {

  MVT EltVT = VT.getVectorElementType();

  if (!((Subtarget.hasSSE3() && VT == MVT::v2f64) ||

        (Subtarget.hasAVX() && (EltVT == MVT::f64 || EltVT == MVT::f32)) ||

        (Subtarget.hasAVX2() && (VT.isInteger() || EltVT == MVT::f16))))

    return SDValue();


  // With MOVDDUP (v2f64) we can broadcast from a register or a load, otherwise

  // we can only broadcast from a register with AVX2.

  unsigned NumEltBits = VT.getScalarSizeInBits();

  unsigned Opcode = (VT == MVT::v2f64 && !Subtarget.hasAVX2())

                        ? X86ISD::MOVDDUP

                        : X86ISD::VBROADCAST;

  bool BroadcastFromReg = (Opcode == X86ISD::MOVDDUP) || Subtarget.hasAVX2();


  // Check that the mask is a broadcast.

  int BroadcastIdx = getSplatIndex(Mask);

  if (BroadcastIdx < 0) {

    // Check for hidden broadcast.

    SmallVector<int, 16> BroadcastMask(VT.getVectorNumElements(), 0);

    if (!isShuffleEquivalent(Mask, BroadcastMask, V1, V2))

      return SDValue();

    BroadcastIdx = 0;

  }

  assert(BroadcastIdx < (int)Mask.size() && "We only expect to be called with "

                                            "a sorted mask where the broadcast "

                                            "comes from V1.");

  int NumActiveElts = count_if(Mask, [](int M) { return M >= 0; });


  // Go up the chain of (vector) values to find a scalar load that we can

  // combine with the broadcast.

  // TODO: Combine this logic with findEltLoadSrc() used by

  //       EltsFromConsecutiveLoads().

  int BitOffset = BroadcastIdx * NumEltBits;

  SDValue V = V1;

  for (;;) {

    switch (V.getOpcode()) {

    case ISD::BITCAST: {

      V = V.getOperand(0);

      continue;

    }

    case ISD::CONCAT_VECTORS: {

      int OpBitWidth = V.getOperand(0).getValueSizeInBits();

      int OpIdx = BitOffset / OpBitWidth;

      V = V.getOperand(OpIdx);

      BitOffset %= OpBitWidth;

      continue;

    }

    case ISD::EXTRACT_SUBVECTOR: {

      // The extraction index adds to the existing offset.

      unsigned EltBitWidth = V.getScalarValueSizeInBits();

      unsigned Idx = V.getConstantOperandVal(1);

      unsigned BeginOffset = Idx * EltBitWidth;

      BitOffset += BeginOffset;

      V = V.getOperand(0);

      continue;

    }

    case ISD::INSERT_SUBVECTOR: {

      SDValue VOuter = V.getOperand(0), VInner = V.getOperand(1);

      int EltBitWidth = VOuter.getScalarValueSizeInBits();

      int Idx = (int)V.getConstantOperandVal(2);

      int NumSubElts = (int)VInner.getSimpleValueType().getVectorNumElements();

      int BeginOffset = Idx * EltBitWidth;

      int EndOffset = BeginOffset + NumSubElts * EltBitWidth;

      if (BeginOffset <= BitOffset && BitOffset < EndOffset) {

        BitOffset -= BeginOffset;

        V = VInner;

      } else {

        V = VOuter;

      }

      continue;

    }

    }

    break;

  }

  assert((BitOffset % NumEltBits) == 0 && "Illegal bit-offset");

  BroadcastIdx = BitOffset / NumEltBits;


  // Do we need to bitcast the source to retrieve the original broadcast index?

  bool BitCastSrc = V.getScalarValueSizeInBits() != NumEltBits;


  // Check if this is a broadcast of a scalar. We special case lowering

  // for scalars so that we can more effectively fold with loads.

  // If the original value has a larger element type than the shuffle, the

  // broadcast element is in essence truncated. Make that explicit to ease

  // folding.

  if (BitCastSrc && VT.isInteger())

    if (SDValue TruncBroadcast = lowerShuffleAsTruncBroadcast(

            DL, VT, V, BroadcastIdx, Subtarget, DAG))

      return TruncBroadcast;


  // Also check the simpler case, where we can directly reuse the scalar.

  if (!BitCastSrc &&

      ((V.getOpcode() == ISD::BUILD_VECTOR && V.hasOneUse()) ||

       (V.getOpcode() == ISD::SCALAR_TO_VECTOR && BroadcastIdx == 0))) {

    V = V.getOperand(BroadcastIdx);


    // If we can't broadcast from a register, check that the input is a load.

    if (!BroadcastFromReg && !isShuffleFoldableLoad(V))

      return SDValue();

  } else if (ISD::isNormalLoad(V.getNode()) &&

             cast<LoadSDNode>(V)->isSimple()) {

    // We do not check for one-use of the vector load because a broadcast load

    // is expected to be a win for code size, register pressure, and possibly

    // uops even if the original vector load is not eliminated.


    // Reduce the vector load and shuffle to a broadcasted scalar load.

    auto *Ld = cast<LoadSDNode>(V);

    SDValue BaseAddr = Ld->getBasePtr();

    MVT SVT = VT.getScalarType();

    unsigned Offset = BroadcastIdx * SVT.getStoreSize();

    assert((int)(Offset * 8) == BitOffset && "Unexpected bit-offset");

    SDValue NewAddr =

        DAG.getMemBasePlusOffset(BaseAddr, TypeSize::getFixed(Offset), DL);


    // Directly form VBROADCAST_LOAD if we're using VBROADCAST opcode rather

    // than MOVDDUP.

    // FIXME: Should we add VBROADCAST_LOAD isel patterns for pre-AVX?

    if (Opcode == X86ISD::VBROADCAST) {

      SDVTList Tys = DAG.getVTList(VT, MVT::Other);

      SDValue Ops[] = {Ld->getChain(), NewAddr};

      V = DAG.getMemIntrinsicNode(

          X86ISD::VBROADCAST_LOAD, DL, Tys, Ops, SVT,

          DAG.getMachineFunction().getMachineMemOperand(

              Ld->getMemOperand(), Offset, SVT.getStoreSize()));

      DAG.makeEquivalentMemoryOrdering(Ld, V);

      return DAG.getBitcast(VT, V);

    }

    assert(SVT == MVT::f64 && "Unexpected VT!");

    V = DAG.getLoad(SVT, DL, Ld->getChain(), NewAddr,

                    DAG.getMachineFunction().getMachineMemOperand(

                        Ld->getMemOperand(), Offset, SVT.getStoreSize()));

    DAG.makeEquivalentMemoryOrdering(Ld, V);

  } else if (!BroadcastFromReg) {

    // We can't broadcast from a vector register.

    return SDValue();

  } else if (BitOffset != 0) {

    // We can only broadcast from the zero-element of a vector register,

    // but it can be advantageous to broadcast from the zero-element of a

    // subvector.

    if (!VT.is256BitVector() && !VT.is512BitVector())

      return SDValue();


    // VPERMQ/VPERMPD can perform the cross-lane shuffle directly.

    if (VT == MVT::v4f64 || VT == MVT::v4i64)

      return SDValue();


    // If we are broadcasting an element from the lowest 128-bit subvector, try

    // to move the element in position.

    if (BitOffset < 128 && NumActiveElts > 1 &&

        V.getScalarValueSizeInBits() == NumEltBits) {

      assert((BitOffset % V.getScalarValueSizeInBits()) == 0 &&

             "Unexpected bit-offset");

      SmallVector<int, 16> ExtractMask(128 / NumEltBits, SM_SentinelUndef);

      ExtractMask[0] = BitOffset / V.getScalarValueSizeInBits();

      V = extractSubVector(V, 0, DAG, DL, 128);

      V = DAG.getVectorShuffle(V.getValueType(), DL, V, V, ExtractMask);

    } else {

      // Only broadcast the zero-element of a 128-bit subvector.

      if ((BitOffset % 128) != 0)

        return SDValue();


      assert((BitOffset % V.getScalarValueSizeInBits()) == 0 &&

             "Unexpected bit-offset");

      assert((V.getValueSizeInBits() == 256 || V.getValueSizeInBits() == 512) &&

             "Unexpected vector size");

      unsigned ExtractIdx = BitOffset / V.getScalarValueSizeInBits();

      V = extract128BitVector(V, ExtractIdx, DAG, DL);

    }

  }


  // On AVX we can use VBROADCAST directly for scalar sources.

  if (Opcode == X86ISD::MOVDDUP && !V.getValueType().isVector()) {

    V = DAG.getBitcast(MVT::f64, V);

    if (Subtarget.hasAVX()) {

      V = DAG.getNode(X86ISD::VBROADCAST, DL, MVT::v2f64, V);

      return DAG.getBitcast(VT, V);

    }

    V = DAG.getNode(ISD::SCALAR_TO_VECTOR, DL, MVT::v2f64, V);

  }


  // If this is a scalar, do the broadcast on this type and bitcast.

  if (!V.getValueType().isVector()) {

    assert(V.getScalarValueSizeInBits() == NumEltBits &&

           "Unexpected scalar size");

    MVT BroadcastVT = MVT::getVectorVT(V.getSimpleValueType(),

                                       VT.getVectorNumElements());

    return DAG.getBitcast(VT, DAG.getNode(Opcode, DL, BroadcastVT, V));

  }


  // We only support broadcasting from 128-bit vectors to minimize the

  // number of patterns we need to deal with in isel. So extract down to

  // 128-bits, removing as many bitcasts as possible.

  if (V.getValueSizeInBits() > 128)

    V = extract128BitVector(peekThroughBitcasts(V), 0, DAG, DL);


  // Otherwise cast V to a vector with the same element type as VT, but

  // possibly narrower than VT. Then perform the broadcast.

  unsigned NumSrcElts = V.getValueSizeInBits() / NumEltBits;

  MVT CastVT = MVT::getVectorVT(VT.getVectorElementType(), NumSrcElts);

  return DAG.getNode(Opcode, DL, VT, DAG.getBitcast(CastVT, V));

}


// Check for whether we can use INSERTPS to perform the shuffle. We only use

// INSERTPS when the V1 elements are already in the correct locations

// because otherwise we can just always use two SHUFPS instructions which

// are much smaller to encode than a SHUFPS and an INSERTPS. We can also

// perform INSERTPS if a single V1 element is out of place and all V2

// elements are zeroable.


static bool matchShuffleAsInsertPS(SDValue &V1, SDValue &V2,

                                   unsigned &InsertPSMask,

                                   const APInt &Zeroable,

                                   ArrayRef<int> Mask, SelectionDAG &DAG) {

  assert(V1.getSimpleValueType().is128BitVector() && "Bad operand type!");

  assert(V2.getSimpleValueType().is128BitVector() && "Bad operand type!");

  assert(Mask.size() == 4 && "Unexpected mask size for v4 shuffle!");


  // Attempt to match INSERTPS with one element from VA or VB being

  // inserted into VA (or undef). If successful, V1, V2 and InsertPSMask

  // are updated.

  auto matchAsInsertPS = [&](SDValue VA, SDValue VB,

                             ArrayRef<int> CandidateMask) {

    unsigned ZMask = 0;

    int VADstIndex = -1;

    int VBDstIndex = -1;

    bool VAUsedInPlace = false;


    for (int i = 0; i < 4; ++i) {

      // Synthesize a zero mask from the zeroable elements (includes undefs).

      if (Zeroable[i]) {

        ZMask |= 1 << i;

        continue;

      }


      // Flag if we use any VA inputs in place.

      if (i == CandidateMask[i]) {

        VAUsedInPlace = true;

        continue;

      }


      // We can only insert a single non-zeroable element.

      if (VADstIndex >= 0 || VBDstIndex >= 0)

        return false;


      if (CandidateMask[i] < 4) {

        // VA input out of place for insertion.

        VADstIndex = i;

      } else {

        // VB input for insertion.

        VBDstIndex = i;

      }

    }


    // Don't bother if we have no (non-zeroable) element for insertion.

    if (VADstIndex < 0 && VBDstIndex < 0)

      return false;


    // Determine element insertion src/dst indices. The src index is from the

    // start of the inserted vector, not the start of the concatenated vector.

    unsigned VBSrcIndex = 0;

    if (VADstIndex >= 0) {

      // If we have a VA input out of place, we use VA as the V2 element

      // insertion and don't use the original V2 at all.

      VBSrcIndex = CandidateMask[VADstIndex];

      VBDstIndex = VADstIndex;

      VB = VA;

    } else {

      VBSrcIndex = CandidateMask[VBDstIndex] - 4;

    }


    // If no V1 inputs are used in place, then the result is created only from

    // the zero mask and the V2 insertion - so remove V1 dependency.

    if (!VAUsedInPlace)

      VA = DAG.getUNDEF(MVT::v4f32);


    // Update V1, V2 and InsertPSMask accordingly.

    V1 = VA;

    V2 = VB;


    // Insert the V2 element into the desired position.

    InsertPSMask = VBSrcIndex << 6 | VBDstIndex << 4 | ZMask;

    assert((InsertPSMask & ~0xFFu) == 0 && "Invalid mask!");

    return true;

  };


  if (matchAsInsertPS(V1, V2, Mask))

    return true;


  // Commute and try again.

  SmallVector<int, 4> CommutedMask(Mask);

  ShuffleVectorSDNode::commuteMask(CommutedMask);

  if (matchAsInsertPS(V2, V1, CommutedMask))

    return true;


  return false;

}


static SDValue lowerShuffleAsInsertPS(const SDLoc &DL, SDValue V1, SDValue V2,

                                      ArrayRef<int> Mask, const APInt &Zeroable,

                                      SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v4f32 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v4f32 && "Bad operand type!");


  // Attempt to match the insertps pattern.

  unsigned InsertPSMask = 0;

  if (!matchShuffleAsInsertPS(V1, V2, InsertPSMask, Zeroable, Mask, DAG))

    return SDValue();


  // Insert the V2 element into the desired position.

  return DAG.getNode(X86ISD::INSERTPS, DL, MVT::v4f32, V1, V2,

                     DAG.getTargetConstant(InsertPSMask, DL, MVT::i8));

}


/// Handle lowering of 2-lane 64-bit floating point shuffles.

///

/// This is the basis function for the 2-lane 64-bit shuffles as we have full

/// support for floating point shuffles but not integer shuffles. These

/// instructions will incur a domain crossing penalty on some chips though so

/// it is better to avoid lowering through this for integer vectors where

/// possible.


static SDValue lowerV2F64Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                 const APInt &Zeroable, SDValue V1, SDValue V2,

                                 const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v2f64 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v2f64 && "Bad operand type!");

  assert(Mask.size() == 2 && "Unexpected mask size for v2 shuffle!");


  if (V2.isUndef()) {

    // Check for being able to broadcast a single element.

    if (SDValue Broadcast = lowerShuffleAsBroadcast(DL, MVT::v2f64, V1, V2,

                                                    Mask, Subtarget, DAG))

      return Broadcast;


    // Straight shuffle of a single input vector. Simulate this by using the

    // single input as both of the "inputs" to this instruction..

    unsigned SHUFPDMask = (Mask[0] == 1) | ((Mask[1] == 1) << 1);


    if (Subtarget.hasAVX()) {

      // If we have AVX, we can use VPERMILPS which will allow folding a load

      // into the shuffle.

      return DAG.getNode(X86ISD::VPERMILPI, DL, MVT::v2f64, V1,

                         DAG.getTargetConstant(SHUFPDMask, DL, MVT::i8));

    }


    return DAG.getNode(

        X86ISD::SHUFP, DL, MVT::v2f64,

        Mask[0] == SM_SentinelUndef ? DAG.getUNDEF(MVT::v2f64) : V1,

        Mask[1] == SM_SentinelUndef ? DAG.getUNDEF(MVT::v2f64) : V1,

        DAG.getTargetConstant(SHUFPDMask, DL, MVT::i8));

  }

  assert(Mask[0] >= 0 && "No undef lanes in multi-input v2 shuffles!");

  assert(Mask[1] >= 0 && "No undef lanes in multi-input v2 shuffles!");

  assert(Mask[0] < 2 && "We sort V1 to be the first input.");

  assert(Mask[1] >= 2 && "We sort V2 to be the second input.");


  if (Subtarget.hasAVX2())

    if (SDValue Extract = lowerShuffleOfExtractsAsVperm(DL, V1, V2, Mask, DAG))

      return Extract;


  // When loading a scalar and then shuffling it into a vector we can often do

  // the insertion cheaply.

  if (SDValue Insertion = lowerShuffleAsElementInsertion(

          DL, MVT::v2f64, V1, V2, Mask, Zeroable, Subtarget, DAG))

    return Insertion;

  // Try inverting the insertion since for v2 masks it is easy to do and we

  // can't reliably sort the mask one way or the other.

  int InverseMask[2] = {Mask[0] < 0 ? -1 : (Mask[0] ^ 2),

                        Mask[1] < 0 ? -1 : (Mask[1] ^ 2)};

  if (SDValue Insertion = lowerShuffleAsElementInsertion(

          DL, MVT::v2f64, V2, V1, InverseMask, Zeroable, Subtarget, DAG))

    return Insertion;


  // Try to use one of the special instruction patterns to handle two common

  // blend patterns if a zero-blend above didn't work.

  if (isShuffleEquivalent(Mask, {0, 3}, V1, V2) ||

      isShuffleEquivalent(Mask, {1, 3}, V1, V2))

    if (SDValue V1S = getScalarValueForVectorElement(V1, Mask[0], DAG))

      // We can either use a special instruction to load over the low double or

      // to move just the low double.

      return DAG.getNode(

          X86ISD::MOVSD, DL, MVT::v2f64, V2,

          DAG.getNode(ISD::SCALAR_TO_VECTOR, DL, MVT::v2f64, V1S));


  if (Subtarget.hasSSE41())

    if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v2f64, V1, V2, Mask,

                                            Zeroable, Subtarget, DAG))

      return Blend;


  // Use dedicated unpack instructions for masks that match their pattern.

  if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v2f64, V1, V2, Mask, DAG))

    return V;


  unsigned SHUFPDMask = (Mask[0] == 1) | (((Mask[1] - 2) == 1) << 1);

  return DAG.getNode(X86ISD::SHUFP, DL, MVT::v2f64, V1, V2,

                     DAG.getTargetConstant(SHUFPDMask, DL, MVT::i8));

}


/// Handle lowering of 2-lane 64-bit integer shuffles.

///

/// Tries to lower a 2-lane 64-bit shuffle using shuffle operations provided by

/// the integer unit to minimize domain crossing penalties. However, for blends

/// it falls back to the floating point shuffle operation with appropriate bit

/// casting.


static SDValue lowerV2I64Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                 const APInt &Zeroable, SDValue V1, SDValue V2,

                                 const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v2i64 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v2i64 && "Bad operand type!");

  assert(Mask.size() == 2 && "Unexpected mask size for v2 shuffle!");


  if (V2.isUndef()) {

    // Check for being able to broadcast a single element.

    if (SDValue Broadcast = lowerShuffleAsBroadcast(DL, MVT::v2i64, V1, V2,

                                                    Mask, Subtarget, DAG))

      return Broadcast;


    // Straight shuffle of a single input vector. For everything from SSE2

    // onward this has a single fast instruction with no scary immediates.

    // We have to map the mask as it is actually a v4i32 shuffle instruction.

    V1 = DAG.getBitcast(MVT::v4i32, V1);

    int WidenedMask[4] = {Mask[0] < 0 ? -1 : (Mask[0] * 2),

                          Mask[0] < 0 ? -1 : ((Mask[0] * 2) + 1),

                          Mask[1] < 0 ? -1 : (Mask[1] * 2),

                          Mask[1] < 0 ? -1 : ((Mask[1] * 2) + 1)};

    return DAG.getBitcast(

        MVT::v2i64,

        DAG.getNode(X86ISD::PSHUFD, DL, MVT::v4i32, V1,

                    getV4X86ShuffleImm8ForMask(WidenedMask, DL, DAG)));

  }

  assert(Mask[0] != -1 && "No undef lanes in multi-input v2 shuffles!");

  assert(Mask[1] != -1 && "No undef lanes in multi-input v2 shuffles!");

  assert(Mask[0] < 2 && "We sort V1 to be the first input.");

  assert(Mask[1] >= 2 && "We sort V2 to be the second input.");


  if (Subtarget.hasAVX2())

    if (SDValue Extract = lowerShuffleOfExtractsAsVperm(DL, V1, V2, Mask, DAG))

      return Extract;


  // Try to use shift instructions.

  if (SDValue Shift =

          lowerShuffleAsShift(DL, MVT::v2i64, V1, V2, Mask, Zeroable, Subtarget,

                              DAG, /*BitwiseOnly*/ false))

    return Shift;


  // When loading a scalar and then shuffling it into a vector we can often do

  // the insertion cheaply.

  if (SDValue Insertion = lowerShuffleAsElementInsertion(

          DL, MVT::v2i64, V1, V2, Mask, Zeroable, Subtarget, DAG))

    return Insertion;

  // Try inverting the insertion since for v2 masks it is easy to do and we

  // can't reliably sort the mask one way or the other.

  int InverseMask[2] = {Mask[0] ^ 2, Mask[1] ^ 2};

  if (SDValue Insertion = lowerShuffleAsElementInsertion(

          DL, MVT::v2i64, V2, V1, InverseMask, Zeroable, Subtarget, DAG))

    return Insertion;


  // We have different paths for blend lowering, but they all must use the

  // *exact* same predicate.

  bool IsBlendSupported = Subtarget.hasSSE41();

  if (IsBlendSupported)

    if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v2i64, V1, V2, Mask,

                                            Zeroable, Subtarget, DAG))

      return Blend;


  // Use dedicated unpack instructions for masks that match their pattern.

  if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v2i64, V1, V2, Mask, DAG))

    return V;


  // Try to use byte rotation instructions.

  // Its more profitable for pre-SSSE3 to use shuffles/unpacks.

  if (Subtarget.hasSSSE3()) {

    if (Subtarget.hasVLX())

      if (SDValue Rotate = lowerShuffleAsVALIGN(DL, MVT::v2i64, V1, V2, Mask,

                                                Zeroable, Subtarget, DAG))

        return Rotate;


    if (SDValue Rotate = lowerShuffleAsByteRotate(DL, MVT::v2i64, V1, V2, Mask,

                                                  Subtarget, DAG))

      return Rotate;

  }


  // If we have direct support for blends, we should lower by decomposing into

  // a permute. That will be faster than the domain cross.

  if (IsBlendSupported)

    return lowerShuffleAsDecomposedShuffleMerge(DL, MVT::v2i64, V1, V2, Mask,

                                                Zeroable, Subtarget, DAG);


  // We implement this with SHUFPD which is pretty lame because it will likely

  // incur 2 cycles of stall for integer vectors on Nehalem and older chips.

  // However, all the alternatives are still more cycles and newer chips don't

  // have this problem. It would be really nice if x86 had better shuffles here.

  V1 = DAG.getBitcast(MVT::v2f64, V1);

  V2 = DAG.getBitcast(MVT::v2f64, V2);

  return DAG.getBitcast(MVT::v2i64,

                        DAG.getVectorShuffle(MVT::v2f64, DL, V1, V2, Mask));

}


/// Lower a vector shuffle using the SHUFPS instruction.

///

/// This is a helper routine dedicated to lowering vector shuffles using SHUFPS.

/// It makes no assumptions about whether this is the *best* lowering, it simply

/// uses it.


static SDValue lowerShuffleWithSHUFPS(const SDLoc &DL, MVT VT,

                                      ArrayRef<int> Mask, SDValue V1,

                                      SDValue V2, SelectionDAG &DAG) {

  SDValue LowV = V1, HighV = V2;

  SmallVector<int, 4> NewMask(Mask);

  int NumV2Elements = count_if(Mask, [](int M) { return M >= 4; });


  if (NumV2Elements == 1) {

    int V2Index = find_if(Mask, [](int M) { return M >= 4; }) - Mask.begin();


    // Compute the index adjacent to V2Index and in the same half by toggling

    // the low bit.

    int V2AdjIndex = V2Index ^ 1;


    if (Mask[V2AdjIndex] < 0) {

      // Handles all the cases where we have a single V2 element and an undef.

      // This will only ever happen in the high lanes because we commute the

      // vector otherwise.

      if (V2Index < 2)

        std::swap(LowV, HighV);

      NewMask[V2Index] -= 4;

    } else {

      // Handle the case where the V2 element ends up adjacent to a V1 element.

      // To make this work, blend them together as the first step.

      int V1Index = V2AdjIndex;

      int BlendMask[4] = {Mask[V2Index] - 4, 0, Mask[V1Index], 0};

      V2 = DAG.getNode(X86ISD::SHUFP, DL, VT, V2, V1,

                       getV4X86ShuffleImm8ForMask(BlendMask, DL, DAG));


      // Now proceed to reconstruct the final blend as we have the necessary

      // high or low half formed.

      if (V2Index < 2) {

        LowV = V2;

        HighV = V1;

      } else {

        HighV = V2;

      }

      NewMask[V1Index] = 2; // We put the V1 element in V2[2].

      NewMask[V2Index] = 0; // We shifted the V2 element into V2[0].

    }

  } else if (NumV2Elements == 2) {

    if (Mask[0] < 4 && Mask[1] < 4) {

      // Handle the easy case where we have V1 in the low lanes and V2 in the

      // high lanes.

      NewMask[2] -= 4;

      NewMask[3] -= 4;

    } else if (Mask[2] < 4 && Mask[3] < 4) {

      // We also handle the reversed case because this utility may get called

      // when we detect a SHUFPS pattern but can't easily commute the shuffle to

      // arrange things in the right direction.

      NewMask[0] -= 4;

      NewMask[1] -= 4;

      HighV = V1;

      LowV = V2;

    } else {

      // We have a mixture of V1 and V2 in both low and high lanes. Rather than

      // trying to place elements directly, just blend them and set up the final

      // shuffle to place them.


      // The first two blend mask elements are for V1, the second two are for

      // V2.

      int BlendMask[4] = {Mask[0] < 4 ? Mask[0] : Mask[1],

                          Mask[2] < 4 ? Mask[2] : Mask[3],

                          (Mask[0] >= 4 ? Mask[0] : Mask[1]) - 4,

                          (Mask[2] >= 4 ? Mask[2] : Mask[3]) - 4};

      V1 = DAG.getNode(X86ISD::SHUFP, DL, VT, V1, V2,

                       getV4X86ShuffleImm8ForMask(BlendMask, DL, DAG));


      // Now we do a normal shuffle of V1 by giving V1 as both operands to

      // a blend.

      LowV = HighV = V1;

      NewMask[0] = Mask[0] < 4 ? 0 : 2;

      NewMask[1] = Mask[0] < 4 ? 2 : 0;

      NewMask[2] = Mask[2] < 4 ? 1 : 3;

      NewMask[3] = Mask[2] < 4 ? 3 : 1;

    }

  } else if (NumV2Elements == 3) {

    // Ideally canonicalizeShuffleMaskWithCommute should have caught this, but

    // we can get here due to other paths (e.g repeated mask matching) that we

    // don't want to do another round of lowerVECTOR_SHUFFLE.

    ShuffleVectorSDNode::commuteMask(NewMask);

    return lowerShuffleWithSHUFPS(DL, VT, NewMask, V2, V1, DAG);

  }

  return DAG.getNode(X86ISD::SHUFP, DL, VT, LowV, HighV,

                     getV4X86ShuffleImm8ForMask(NewMask, DL, DAG));

}


/// Lower 4-lane 32-bit floating point shuffles.

///

/// Uses instructions exclusively from the floating point unit to minimize

/// domain crossing penalties, as these are sufficient to implement all v4f32

/// shuffles.


static SDValue lowerV4F32Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                 const APInt &Zeroable, SDValue V1, SDValue V2,

                                 const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v4f32 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v4f32 && "Bad operand type!");

  assert(Mask.size() == 4 && "Unexpected mask size for v4 shuffle!");


  if (Subtarget.hasSSE41())

    if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v4f32, V1, V2, Mask,

                                            Zeroable, Subtarget, DAG))

      return Blend;


  int NumV2Elements = count_if(Mask, [](int M) { return M >= 4; });


  if (NumV2Elements == 0) {

    // Check for being able to broadcast a single element.

    if (SDValue Broadcast = lowerShuffleAsBroadcast(DL, MVT::v4f32, V1, V2,

                                                    Mask, Subtarget, DAG))

      return Broadcast;


    // Use even/odd duplicate instructions for masks that match their pattern.

    if (Subtarget.hasSSE3()) {

      if (isShuffleEquivalent(Mask, {0, 0, 2, 2}, V1, V2))

        return DAG.getNode(X86ISD::MOVSLDUP, DL, MVT::v4f32, V1);

      if (isShuffleEquivalent(Mask, {1, 1, 3, 3}, V1, V2))

        return DAG.getNode(X86ISD::MOVSHDUP, DL, MVT::v4f32, V1);

    }


    if (Subtarget.hasAVX()) {

      // If we have AVX, we can use VPERMILPS which will allow folding a load

      // into the shuffle.

      return DAG.getNode(X86ISD::VPERMILPI, DL, MVT::v4f32, V1,

                         getV4X86ShuffleImm8ForMask(Mask, DL, DAG));

    }


    // Use MOVLHPS/MOVHLPS to simulate unary shuffles. These are only valid

    // in SSE1 because otherwise they are widened to v2f64 and never get here.

    if (!Subtarget.hasSSE2()) {

      if (isShuffleEquivalent(Mask, {0, 1, 0, 1}, V1, V2))

        return DAG.getNode(X86ISD::MOVLHPS, DL, MVT::v4f32, V1, V1);

      if (isShuffleEquivalent(Mask, {2, 3, 2, 3}, V1, V2))

        return DAG.getNode(X86ISD::MOVHLPS, DL, MVT::v4f32, V1, V1);

    }


    // Otherwise, use a straight shuffle of a single input vector. We pass the

    // input vector to both operands to simulate this with a SHUFPS.

    return DAG.getNode(X86ISD::SHUFP, DL, MVT::v4f32, V1, V1,

                       getV4X86ShuffleImm8ForMask(Mask, DL, DAG));

  }


  if (Subtarget.hasSSE2())

    if (SDValue ZExt = lowerShuffleAsZeroOrAnyExtend(

            DL, MVT::v4i32, V1, V2, Mask, Zeroable, Subtarget, DAG)) {

      ZExt = DAG.getBitcast(MVT::v4f32, ZExt);

      return ZExt;

    }


  if (Subtarget.hasAVX2())

    if (SDValue Extract = lowerShuffleOfExtractsAsVperm(DL, V1, V2, Mask, DAG))

      return Extract;


  // There are special ways we can lower some single-element blends. However, we

  // have custom ways we can lower more complex single-element blends below that

  // we defer to if both this and BLENDPS fail to match, so restrict this to

  // when the V2 input is targeting element 0 of the mask -- that is the fast

  // case here.

  if (NumV2Elements == 1 && Mask[0] >= 4)

    if (SDValue V = lowerShuffleAsElementInsertion(DL, MVT::v4f32, V1, V2, Mask,

                                                   Zeroable, Subtarget, DAG))

      return V;


  if (Subtarget.hasSSE41()) {

    bool MatchesShufPS = isSingleSHUFPSMask(Mask);


    // Use INSERTPS if we can complete the shuffle efficiently.

    if (!MatchesShufPS || Zeroable == 0x3 || Zeroable == 0xC)

      if (SDValue V = lowerShuffleAsInsertPS(DL, V1, V2, Mask, Zeroable, DAG))

        return V;


    if (!MatchesShufPS)

      if (SDValue BlendPerm =

              lowerShuffleAsBlendAndPermute(DL, MVT::v4f32, V1, V2, Mask, DAG))

        return BlendPerm;

  }


  // Use low/high mov instructions. These are only valid in SSE1 because

  // otherwise they are widened to v2f64 and never get here.

  if (!Subtarget.hasSSE2()) {

    if (isShuffleEquivalent(Mask, {0, 1, 4, 5}, V1, V2))

      return DAG.getNode(X86ISD::MOVLHPS, DL, MVT::v4f32, V1, V2);

    if (isShuffleEquivalent(Mask, {2, 3, 6, 7}, V1, V2))

      return DAG.getNode(X86ISD::MOVHLPS, DL, MVT::v4f32, V2, V1);

  }


  // Use dedicated unpack instructions for masks that match their pattern.

  if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v4f32, V1, V2, Mask, DAG))

    return V;


  // Otherwise fall back to a SHUFPS lowering strategy.

  return lowerShuffleWithSHUFPS(DL, MVT::v4f32, Mask, V1, V2, DAG);

}


/// Lower 4-lane i32 vector shuffles.

///

/// We try to handle these with integer-domain shuffles where we can, but for

/// blends we use the floating point domain blend instructions.


static SDValue lowerV4I32Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                 const APInt &Zeroable, SDValue V1, SDValue V2,

                                 const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v4i32 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v4i32 && "Bad operand type!");

  assert(Mask.size() == 4 && "Unexpected mask size for v4 shuffle!");


  // Whenever we can lower this as a zext, that instruction is strictly faster

  // than any alternative. It also allows us to fold memory operands into the

  // shuffle in many cases.

  if (SDValue ZExt = lowerShuffleAsZeroOrAnyExtend(DL, MVT::v4i32, V1, V2, Mask,

                                                   Zeroable, Subtarget, DAG))

    return ZExt;


  int NumV2Elements = count_if(Mask, [](int M) { return M >= 4; });


  // Try to use shift instructions if fast.

  if (Subtarget.preferLowerShuffleAsShift()) {

    if (SDValue Shift =

            lowerShuffleAsShift(DL, MVT::v4i32, V1, V2, Mask, Zeroable,

                                Subtarget, DAG, /*BitwiseOnly*/ true))

      return Shift;

    if (NumV2Elements == 0)

      if (SDValue Rotate =

              lowerShuffleAsBitRotate(DL, MVT::v4i32, V1, Mask, Subtarget, DAG))

        return Rotate;

  }


  if (NumV2Elements == 0) {

    // Try to use broadcast unless the mask only has one non-undef element.

    if (count_if(Mask, [](int M) { return M >= 0 && M < 4; }) > 1) {

      if (SDValue Broadcast = lowerShuffleAsBroadcast(DL, MVT::v4i32, V1, V2,

                                                      Mask, Subtarget, DAG))

        return Broadcast;

    }


    // Straight shuffle of a single input vector. For everything from SSE2

    // onward this has a single fast instruction with no scary immediates.

    // We coerce the shuffle pattern to be compatible with UNPCK instructions

    // but we aren't actually going to use the UNPCK instruction because doing

    // so prevents folding a load into this instruction or making a copy.

    const int UnpackLoMask[] = {0, 0, 1, 1};

    const int UnpackHiMask[] = {2, 2, 3, 3};

    if (!isSingleElementRepeatedMask(Mask)) {

      if (isShuffleEquivalent(Mask, {0, 0, 1, 1}, V1, V2))

        Mask = UnpackLoMask;

      else if (isShuffleEquivalent(Mask, {2, 2, 3, 3}, V1, V2))

        Mask = UnpackHiMask;

    }


    return DAG.getNode(X86ISD::PSHUFD, DL, MVT::v4i32, V1,

                       getV4X86ShuffleImm8ForMask(Mask, DL, DAG));

  }


  if (Subtarget.hasAVX2())

    if (SDValue Extract = lowerShuffleOfExtractsAsVperm(DL, V1, V2, Mask, DAG))

      return Extract;


  // Try to use shift instructions.

  if (SDValue Shift =

          lowerShuffleAsShift(DL, MVT::v4i32, V1, V2, Mask, Zeroable, Subtarget,

                              DAG, /*BitwiseOnly*/ false))

    return Shift;


  // There are special ways we can lower some single-element blends.

  if (NumV2Elements == 1)

    if (SDValue V = lowerShuffleAsElementInsertion(

            DL, MVT::v4i32, V1, V2, Mask, Zeroable, Subtarget, DAG))

      return V;


  // We have different paths for blend lowering, but they all must use the

  // *exact* same predicate.

  bool IsBlendSupported = Subtarget.hasSSE41();

  if (IsBlendSupported)

    if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v4i32, V1, V2, Mask,

                                            Zeroable, Subtarget, DAG))

      return Blend;


  if (SDValue Masked = lowerShuffleAsBitMask(DL, MVT::v4i32, V1, V2, Mask,

                                             Zeroable, Subtarget, DAG))

    return Masked;


  // Use dedicated unpack instructions for masks that match their pattern.

  if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v4i32, V1, V2, Mask, DAG))

    return V;


  // Try to use byte rotation instructions.

  // Its more profitable for pre-SSSE3 to use shuffles/unpacks.

  if (Subtarget.hasSSSE3()) {

    if (Subtarget.hasVLX())

      if (SDValue Rotate = lowerShuffleAsVALIGN(DL, MVT::v4i32, V1, V2, Mask,

                                                Zeroable, Subtarget, DAG))

        return Rotate;


    if (SDValue Rotate = lowerShuffleAsByteRotate(DL, MVT::v4i32, V1, V2, Mask,

                                                  Subtarget, DAG))

      return Rotate;

  }


  // Assume that a single SHUFPS is faster than an alternative sequence of

  // multiple instructions (even if the CPU has a domain penalty).

  // If some CPU is harmed by the domain switch, we can fix it in a later pass.

  if (!isSingleSHUFPSMask(Mask)) {

    // If we have direct support for blends, we should lower by decomposing into

    // a permute. That will be faster than the domain cross.

    if (IsBlendSupported)

      return lowerShuffleAsDecomposedShuffleMerge(DL, MVT::v4i32, V1, V2, Mask,

                                                  Zeroable, Subtarget, DAG);


    // Try to lower by permuting the inputs into an unpack instruction.

    if (SDValue Unpack = lowerShuffleAsPermuteAndUnpack(DL, MVT::v4i32, V1, V2,

                                                        Mask, Subtarget, DAG))

      return Unpack;

  }


  // We implement this with SHUFPS because it can blend from two vectors.

  // Because we're going to eventually use SHUFPS, we use SHUFPS even to build

  // up the inputs, bypassing domain shift penalties that we would incur if we

  // directly used PSHUFD on Nehalem and older. For newer chips, this isn't

  // relevant.

  SDValue CastV1 = DAG.getBitcast(MVT::v4f32, V1);

  SDValue CastV2 = DAG.getBitcast(MVT::v4f32, V2);

  SDValue ShufPS = DAG.getVectorShuffle(MVT::v4f32, DL, CastV1, CastV2, Mask);

  return DAG.getBitcast(MVT::v4i32, ShufPS);

}


/// Lowering of single-input v8i16 shuffles is the cornerstone of SSE2

/// shuffle lowering, and the most complex part.

///

/// The lowering strategy is to try to form pairs of input lanes which are

/// targeted at the same half of the final vector, and then use a dword shuffle

/// to place them onto the right half, and finally unpack the paired lanes into

/// their final position.

///

/// The exact breakdown of how to form these dword pairs and align them on the

/// correct sides is really tricky. See the comments within the function for

/// more of the details.

///

/// This code also handles repeated 128-bit lanes of v8i16 shuffles, but each

/// lane must shuffle the *exact* same way. In fact, you must pass a v8 Mask to

/// this routine for it to work correctly. To shuffle a 256-bit or 512-bit i16

/// vector, form the analogous 128-bit 8-element Mask.


static SDValue lowerV8I16GeneralSingleInputShuffle(

    const SDLoc &DL, MVT VT, SDValue V, MutableArrayRef<int> Mask,

    const X86Subtarget &Subtarget, SelectionDAG &DAG) {

  assert(VT.getVectorElementType() == MVT::i16 && "Bad input type!");

  MVT PSHUFDVT = MVT::getVectorVT(MVT::i32, VT.getVectorNumElements() / 2);


  assert(Mask.size() == 8 && "Shuffle mask length doesn't match!");

  MutableArrayRef<int> LoMask = Mask.slice(0, 4);

  MutableArrayRef<int> HiMask = Mask.slice(4, 4);


  // Attempt to directly match PSHUFLW or PSHUFHW.

  if (isUndefOrInRange(LoMask, 0, 4) &&

      isSequentialOrUndefInRange(HiMask, 0, 4, 4)) {

    return DAG.getNode(X86ISD::PSHUFLW, DL, VT, V,

                       getV4X86ShuffleImm8ForMask(LoMask, DL, DAG));

  }

  if (isUndefOrInRange(HiMask, 4, 8) &&

      isSequentialOrUndefInRange(LoMask, 0, 4, 0)) {

    for (int i = 0; i != 4; ++i)

      HiMask[i] = (HiMask[i] < 0 ? HiMask[i] : (HiMask[i] - 4));

    return DAG.getNode(X86ISD::PSHUFHW, DL, VT, V,

                       getV4X86ShuffleImm8ForMask(HiMask, DL, DAG));

  }


  SmallVector<int, 4> LoInputs;

  copy_if(LoMask, std::back_inserter(LoInputs), [](int M) { return M >= 0; });

  array_pod_sort(LoInputs.begin(), LoInputs.end());

  LoInputs.erase(llvm::unique(LoInputs), LoInputs.end());

  SmallVector<int, 4> HiInputs;

  copy_if(HiMask, std::back_inserter(HiInputs), [](int M) { return M >= 0; });

  array_pod_sort(HiInputs.begin(), HiInputs.end());

  HiInputs.erase(llvm::unique(HiInputs), HiInputs.end());

  int NumLToL = llvm::lower_bound(LoInputs, 4) - LoInputs.begin();

  int NumHToL = LoInputs.size() - NumLToL;

  int NumLToH = llvm::lower_bound(HiInputs, 4) - HiInputs.begin();

  int NumHToH = HiInputs.size() - NumLToH;

  MutableArrayRef<int> LToLInputs(LoInputs.data(), NumLToL);

  MutableArrayRef<int> LToHInputs(HiInputs.data(), NumLToH);

  MutableArrayRef<int> HToLInputs(LoInputs.data() + NumLToL, NumHToL);

  MutableArrayRef<int> HToHInputs(HiInputs.data() + NumLToH, NumHToH);


  // If we are shuffling values from one half - check how many different DWORD

  // pairs we need to create. If only 1 or 2 then we can perform this as a

  // PSHUFLW/PSHUFHW + PSHUFD instead of the PSHUFD+PSHUFLW+PSHUFHW chain below.

  auto ShuffleDWordPairs = [&](ArrayRef<int> PSHUFHalfMask,

                               ArrayRef<int> PSHUFDMask, unsigned ShufWOp) {

    V = DAG.getNode(ShufWOp, DL, VT, V,

                    getV4X86ShuffleImm8ForMask(PSHUFHalfMask, DL, DAG));

    V = DAG.getBitcast(PSHUFDVT, V);

    V = DAG.getNode(X86ISD::PSHUFD, DL, PSHUFDVT, V,

                    getV4X86ShuffleImm8ForMask(PSHUFDMask, DL, DAG));

    return DAG.getBitcast(VT, V);

  };


  if ((NumHToL + NumHToH) == 0 || (NumLToL + NumLToH) == 0) {

    int PSHUFDMask[4] = { -1, -1, -1, -1 };

    SmallVector<std::pair<int, int>, 4> DWordPairs;

    int DOffset = ((NumHToL + NumHToH) == 0 ? 0 : 2);


    // Collect the different DWORD pairs.

    for (int DWord = 0; DWord != 4; ++DWord) {

      int M0 = Mask[2 * DWord + 0];

      int M1 = Mask[2 * DWord + 1];

      M0 = (M0 >= 0 ? M0 % 4 : M0);

      M1 = (M1 >= 0 ? M1 % 4 : M1);

      if (M0 < 0 && M1 < 0)

        continue;


      bool Match = false;

      for (int j = 0, e = DWordPairs.size(); j < e; ++j) {

        auto &DWordPair = DWordPairs[j];

        if ((M0 < 0 || isUndefOrEqual(DWordPair.first, M0)) &&

            (M1 < 0 || isUndefOrEqual(DWordPair.second, M1))) {

          DWordPair.first = (M0 >= 0 ? M0 : DWordPair.first);

          DWordPair.second = (M1 >= 0 ? M1 : DWordPair.second);

          PSHUFDMask[DWord] = DOffset + j;

          Match = true;

          break;

        }

      }

      if (!Match) {

        PSHUFDMask[DWord] = DOffset + DWordPairs.size();

        DWordPairs.push_back(std::make_pair(M0, M1));

      }

    }


    if (DWordPairs.size() <= 2) {

      DWordPairs.resize(2, std::make_pair(-1, -1));

      int PSHUFHalfMask[4] = {DWordPairs[0].first, DWordPairs[0].second,

                              DWordPairs[1].first, DWordPairs[1].second};

      // For splat, ensure we widen the PSHUFDMask to allow vXi64 folds.

      if (ShuffleVectorSDNode::isSplatMask(PSHUFDMask) &&

          ShuffleVectorSDNode::isSplatMask(PSHUFHalfMask)) {

        int SplatIdx = ShuffleVectorSDNode::getSplatMaskIndex(PSHUFHalfMask);

        std::fill(PSHUFHalfMask, PSHUFHalfMask + 4, SplatIdx);

        PSHUFDMask[0] = PSHUFDMask[2] = DOffset + 0;

        PSHUFDMask[1] = PSHUFDMask[3] = DOffset + 1;

      }

      if ((NumHToL + NumHToH) == 0)

        return ShuffleDWordPairs(PSHUFHalfMask, PSHUFDMask, X86ISD::PSHUFLW);

      if ((NumLToL + NumLToH) == 0)

        return ShuffleDWordPairs(PSHUFHalfMask, PSHUFDMask, X86ISD::PSHUFHW);

    }

  }


  // Simplify the 1-into-3 and 3-into-1 cases with a single pshufd. For all

  // such inputs we can swap two of the dwords across the half mark and end up

  // with <=2 inputs to each half in each half. Once there, we can fall through

  // to the generic code below. For example:

  //

  // Input: [a, b, c, d, e, f, g, h] -PSHUFD[0,2,1,3]-> [a, b, e, f, c, d, g, h]

  // Mask:  [0, 1, 2, 7, 4, 5, 6, 3] -----------------> [0, 1, 4, 7, 2, 3, 6, 5]

  //

  // However in some very rare cases we have a 1-into-3 or 3-into-1 on one half

  // and an existing 2-into-2 on the other half. In this case we may have to

  // pre-shuffle the 2-into-2 half to avoid turning it into a 3-into-1 or

  // 1-into-3 which could cause us to cycle endlessly fixing each side in turn.

  // Fortunately, we don't have to handle anything but a 2-into-2 pattern

  // because any other situation (including a 3-into-1 or 1-into-3 in the other

  // half than the one we target for fixing) will be fixed when we re-enter this

  // path. We will also combine away any sequence of PSHUFD instructions that

  // result into a single instruction. Here is an example of the tricky case:

  //

  // Input: [a, b, c, d, e, f, g, h] -PSHUFD[0,2,1,3]-> [a, b, e, f, c, d, g, h]

  // Mask:  [3, 7, 1, 0, 2, 7, 3, 5] -THIS-IS-BAD!!!!-> [5, 7, 1, 0, 4, 7, 5, 3]

  //

  // This now has a 1-into-3 in the high half! Instead, we do two shuffles:

  //

  // Input: [a, b, c, d, e, f, g, h] PSHUFHW[0,2,1,3]-> [a, b, c, d, e, g, f, h]

  // Mask:  [3, 7, 1, 0, 2, 7, 3, 5] -----------------> [3, 7, 1, 0, 2, 7, 3, 6]

  //

  // Input: [a, b, c, d, e, g, f, h] -PSHUFD[0,2,1,3]-> [a, b, e, g, c, d, f, h]

  // Mask:  [3, 7, 1, 0, 2, 7, 3, 6] -----------------> [5, 7, 1, 0, 4, 7, 5, 6]

  //

  // The result is fine to be handled by the generic logic.

  auto balanceSides = [&](ArrayRef<int> AToAInputs, ArrayRef<int> BToAInputs,

                          ArrayRef<int> BToBInputs, ArrayRef<int> AToBInputs,

                          int AOffset, int BOffset) {

    assert((AToAInputs.size() == 3 || AToAInputs.size() == 1) &&

           "Must call this with A having 3 or 1 inputs from the A half.");

    assert((BToAInputs.size() == 1 || BToAInputs.size() == 3) &&

           "Must call this with B having 1 or 3 inputs from the B half.");

    assert(AToAInputs.size() + BToAInputs.size() == 4 &&

           "Must call this with either 3:1 or 1:3 inputs (summing to 4).");


    bool ThreeAInputs = AToAInputs.size() == 3;


    // Compute the index of dword with only one word among the three inputs in

    // a half by taking the sum of the half with three inputs and subtracting

    // the sum of the actual three inputs. The difference is the remaining

    // slot.

    int ADWord = 0, BDWord = 0;

    int &TripleDWord = ThreeAInputs ? ADWord : BDWord;

    int &OneInputDWord = ThreeAInputs ? BDWord : ADWord;

    int TripleInputOffset = ThreeAInputs ? AOffset : BOffset;

    ArrayRef<int> TripleInputs = ThreeAInputs ? AToAInputs : BToAInputs;

    int OneInput = ThreeAInputs ? BToAInputs[0] : AToAInputs[0];

    int TripleInputSum = 0 + 1 + 2 + 3 + (4 * TripleInputOffset);

    int TripleNonInputIdx =

        TripleInputSum - std::accumulate(TripleInputs.begin(), TripleInputs.end(), 0);

    TripleDWord = TripleNonInputIdx / 2;


    // We use xor with one to compute the adjacent DWord to whichever one the

    // OneInput is in.

    OneInputDWord = (OneInput / 2) ^ 1;


    // Check for one tricky case: We're fixing a 3<-1 or a 1<-3 shuffle for AToA

    // and BToA inputs. If there is also such a problem with the BToB and AToB

    // inputs, we don't try to fix it necessarily -- we'll recurse and see it in

    // the next pass. However, if we have a 2<-2 in the BToB and AToB inputs, it

    // is essential that we don't *create* a 3<-1 as then we might oscillate.

    if (BToBInputs.size() == 2 && AToBInputs.size() == 2) {

      // Compute how many inputs will be flipped by swapping these DWords. We

      // need

      // to balance this to ensure we don't form a 3-1 shuffle in the other

      // half.

      int NumFlippedAToBInputs = llvm::count(AToBInputs, 2 * ADWord) +

                                 llvm::count(AToBInputs, 2 * ADWord + 1);

      int NumFlippedBToBInputs = llvm::count(BToBInputs, 2 * BDWord) +

                                 llvm::count(BToBInputs, 2 * BDWord + 1);

      if ((NumFlippedAToBInputs == 1 &&

           (NumFlippedBToBInputs == 0 || NumFlippedBToBInputs == 2)) ||

          (NumFlippedBToBInputs == 1 &&

           (NumFlippedAToBInputs == 0 || NumFlippedAToBInputs == 2))) {

        // We choose whether to fix the A half or B half based on whether that

        // half has zero flipped inputs. At zero, we may not be able to fix it

        // with that half. We also bias towards fixing the B half because that

        // will more commonly be the high half, and we have to bias one way.

        auto FixFlippedInputs = [&V, &DL, &Mask, &DAG](int PinnedIdx, int DWord,

                                                       ArrayRef<int> Inputs) {

          int FixIdx = PinnedIdx ^ 1; // The adjacent slot to the pinned slot.

          bool IsFixIdxInput = is_contained(Inputs, PinnedIdx ^ 1);

          // Determine whether the free index is in the flipped dword or the

          // unflipped dword based on where the pinned index is. We use this bit

          // in an xor to conditionally select the adjacent dword.

          int FixFreeIdx = 2 * (DWord ^ (PinnedIdx / 2 == DWord));

          bool IsFixFreeIdxInput = is_contained(Inputs, FixFreeIdx);

          if (IsFixIdxInput == IsFixFreeIdxInput)

            FixFreeIdx += 1;

          IsFixFreeIdxInput = is_contained(Inputs, FixFreeIdx);

          assert(IsFixIdxInput != IsFixFreeIdxInput &&

                 "We need to be changing the number of flipped inputs!");

          int PSHUFHalfMask[] = {0, 1, 2, 3};

          std::swap(PSHUFHalfMask[FixFreeIdx % 4], PSHUFHalfMask[FixIdx % 4]);

          V = DAG.getNode(

              FixIdx < 4 ? X86ISD::PSHUFLW : X86ISD::PSHUFHW, DL,

              MVT::getVectorVT(MVT::i16, V.getValueSizeInBits() / 16), V,

              getV4X86ShuffleImm8ForMask(PSHUFHalfMask, DL, DAG));


          for (int &M : Mask)

            if (M >= 0 && M == FixIdx)

              M = FixFreeIdx;

            else if (M >= 0 && M == FixFreeIdx)

              M = FixIdx;

        };

        if (NumFlippedBToBInputs != 0) {

          int BPinnedIdx =

              BToAInputs.size() == 3 ? TripleNonInputIdx : OneInput;

          FixFlippedInputs(BPinnedIdx, BDWord, BToBInputs);

        } else {

          assert(NumFlippedAToBInputs != 0 && "Impossible given predicates!");

          int APinnedIdx = ThreeAInputs ? TripleNonInputIdx : OneInput;

          FixFlippedInputs(APinnedIdx, ADWord, AToBInputs);

        }

      }

    }


    int PSHUFDMask[] = {0, 1, 2, 3};

    PSHUFDMask[ADWord] = BDWord;

    PSHUFDMask[BDWord] = ADWord;

    V = DAG.getBitcast(

        VT,

        DAG.getNode(X86ISD::PSHUFD, DL, PSHUFDVT, DAG.getBitcast(PSHUFDVT, V),

                    getV4X86ShuffleImm8ForMask(PSHUFDMask, DL, DAG)));


    // Adjust the mask to match the new locations of A and B.

    for (int &M : Mask)

      if (M >= 0 && M/2 == ADWord)

        M = 2 * BDWord + M % 2;

      else if (M >= 0 && M/2 == BDWord)

        M = 2 * ADWord + M % 2;


    // Recurse back into this routine to re-compute state now that this isn't

    // a 3 and 1 problem.

    return lowerV8I16GeneralSingleInputShuffle(DL, VT, V, Mask, Subtarget, DAG);

  };

  if ((NumLToL == 3 && NumHToL == 1) || (NumLToL == 1 && NumHToL == 3))

    return balanceSides(LToLInputs, HToLInputs, HToHInputs, LToHInputs, 0, 4);

  if ((NumHToH == 3 && NumLToH == 1) || (NumHToH == 1 && NumLToH == 3))

    return balanceSides(HToHInputs, LToHInputs, LToLInputs, HToLInputs, 4, 0);


  // At this point there are at most two inputs to the low and high halves from

  // each half. That means the inputs can always be grouped into dwords and

  // those dwords can then be moved to the correct half with a dword shuffle.

  // We use at most one low and one high word shuffle to collect these paired

  // inputs into dwords, and finally a dword shuffle to place them.

  int PSHUFLMask[4] = {-1, -1, -1, -1};

  int PSHUFHMask[4] = {-1, -1, -1, -1};

  int PSHUFDMask[4] = {-1, -1, -1, -1};


  // First fix the masks for all the inputs that are staying in their

  // original halves. This will then dictate the targets of the cross-half

  // shuffles.

  auto fixInPlaceInputs =

      [&PSHUFDMask](ArrayRef<int> InPlaceInputs, ArrayRef<int> IncomingInputs,

                    MutableArrayRef<int> SourceHalfMask,

                    MutableArrayRef<int> HalfMask, int HalfOffset) {

    if (InPlaceInputs.empty())

      return;

    if (InPlaceInputs.size() == 1) {

      SourceHalfMask[InPlaceInputs[0] - HalfOffset] =

          InPlaceInputs[0] - HalfOffset;

      PSHUFDMask[InPlaceInputs[0] / 2] = InPlaceInputs[0] / 2;

      return;

    }

    if (IncomingInputs.empty()) {

      // Just fix all of the in place inputs.

      for (int Input : InPlaceInputs) {

        SourceHalfMask[Input - HalfOffset] = Input - HalfOffset;

        PSHUFDMask[Input / 2] = Input / 2;

      }

      return;

    }


    assert(InPlaceInputs.size() == 2 && "Cannot handle 3 or 4 inputs!");

    SourceHalfMask[InPlaceInputs[0] - HalfOffset] =

        InPlaceInputs[0] - HalfOffset;

    // Put the second input next to the first so that they are packed into

    // a dword. We find the adjacent index by toggling the low bit.

    int AdjIndex = InPlaceInputs[0] ^ 1;

    SourceHalfMask[AdjIndex - HalfOffset] = InPlaceInputs[1] - HalfOffset;

    llvm::replace(HalfMask, InPlaceInputs[1], AdjIndex);

    PSHUFDMask[AdjIndex / 2] = AdjIndex / 2;

  };

  fixInPlaceInputs(LToLInputs, HToLInputs, PSHUFLMask, LoMask, 0);

  fixInPlaceInputs(HToHInputs, LToHInputs, PSHUFHMask, HiMask, 4);


  // Now gather the cross-half inputs and place them into a free dword of

  // their target half.

  // FIXME: This operation could almost certainly be simplified dramatically to

  // look more like the 3-1 fixing operation.

  auto moveInputsToRightHalf = [&PSHUFDMask](

      MutableArrayRef<int> IncomingInputs, ArrayRef<int> ExistingInputs,

      MutableArrayRef<int> SourceHalfMask, MutableArrayRef<int> HalfMask,

      MutableArrayRef<int> FinalSourceHalfMask, int SourceOffset,

      int DestOffset) {

    auto isWordClobbered = [](ArrayRef<int> SourceHalfMask, int Word) {

      return SourceHalfMask[Word] >= 0 && SourceHalfMask[Word] != Word;

    };

    auto isDWordClobbered = [&isWordClobbered](ArrayRef<int> SourceHalfMask,

                                               int Word) {

      int LowWord = Word & ~1;

      int HighWord = Word | 1;

      return isWordClobbered(SourceHalfMask, LowWord) ||

             isWordClobbered(SourceHalfMask, HighWord);

    };


    if (IncomingInputs.empty())

      return;


    if (ExistingInputs.empty()) {

      // Map any dwords with inputs from them into the right half.

      for (int Input : IncomingInputs) {

        // If the source half mask maps over the inputs, turn those into

        // swaps and use the swapped lane.

        if (isWordClobbered(SourceHalfMask, Input - SourceOffset)) {

          if (SourceHalfMask[SourceHalfMask[Input - SourceOffset]] < 0) {

            SourceHalfMask[SourceHalfMask[Input - SourceOffset]] =

                Input - SourceOffset;

            // We have to swap the uses in our half mask in one sweep.

            for (int &M : HalfMask)

              if (M == SourceHalfMask[Input - SourceOffset] + SourceOffset)

                M = Input;

              else if (M == Input)

                M = SourceHalfMask[Input - SourceOffset] + SourceOffset;

          } else {

            assert(SourceHalfMask[SourceHalfMask[Input - SourceOffset]] ==

                       Input - SourceOffset &&

                   "Previous placement doesn't match!");

          }

          // Note that this correctly re-maps both when we do a swap and when

          // we observe the other side of the swap above. We rely on that to

          // avoid swapping the members of the input list directly.

          Input = SourceHalfMask[Input - SourceOffset] + SourceOffset;

        }


        // Map the input's dword into the correct half.

        if (PSHUFDMask[(Input - SourceOffset + DestOffset) / 2] < 0)

          PSHUFDMask[(Input - SourceOffset + DestOffset) / 2] = Input / 2;

        else

          assert(PSHUFDMask[(Input - SourceOffset + DestOffset) / 2] ==

                     Input / 2 &&

                 "Previous placement doesn't match!");

      }


      // And just directly shift any other-half mask elements to be same-half

      // as we will have mirrored the dword containing the element into the

      // same position within that half.

      for (int &M : HalfMask)

        if (M >= SourceOffset && M < SourceOffset + 4) {

          M = M - SourceOffset + DestOffset;

          assert(M >= 0 && "This should never wrap below zero!");

        }

      return;

    }


    // Ensure we have the input in a viable dword of its current half. This

    // is particularly tricky because the original position may be clobbered

    // by inputs being moved and *staying* in that half.

    if (IncomingInputs.size() == 1) {

      if (isWordClobbered(SourceHalfMask, IncomingInputs[0] - SourceOffset)) {

        int InputFixed = find(SourceHalfMask, -1) - std::begin(SourceHalfMask) +

                         SourceOffset;

        SourceHalfMask[InputFixed - SourceOffset] =

            IncomingInputs[0] - SourceOffset;

        llvm::replace(HalfMask, IncomingInputs[0], InputFixed);

        IncomingInputs[0] = InputFixed;

      }

    } else if (IncomingInputs.size() == 2) {

      if (IncomingInputs[0] / 2 != IncomingInputs[1] / 2 ||

          isDWordClobbered(SourceHalfMask, IncomingInputs[0] - SourceOffset)) {

        // We have two non-adjacent or clobbered inputs we need to extract from

        // the source half. To do this, we need to map them into some adjacent

        // dword slot in the source mask.

        int InputsFixed[2] = {IncomingInputs[0] - SourceOffset,

                              IncomingInputs[1] - SourceOffset};


        // If there is a free slot in the source half mask adjacent to one of

        // the inputs, place the other input in it. We use (Index XOR 1) to

        // compute an adjacent index.

        if (!isWordClobbered(SourceHalfMask, InputsFixed[0]) &&

            SourceHalfMask[InputsFixed[0] ^ 1] < 0) {

          SourceHalfMask[InputsFixed[0]] = InputsFixed[0];

          SourceHalfMask[InputsFixed[0] ^ 1] = InputsFixed[1];

          InputsFixed[1] = InputsFixed[0] ^ 1;

        } else if (!isWordClobbered(SourceHalfMask, InputsFixed[1]) &&

                   SourceHalfMask[InputsFixed[1] ^ 1] < 0) {

          SourceHalfMask[InputsFixed[1]] = InputsFixed[1];

          SourceHalfMask[InputsFixed[1] ^ 1] = InputsFixed[0];

          InputsFixed[0] = InputsFixed[1] ^ 1;

        } else if (SourceHalfMask[2 * ((InputsFixed[0] / 2) ^ 1)] < 0 &&

                   SourceHalfMask[2 * ((InputsFixed[0] / 2) ^ 1) + 1] < 0) {

          // The two inputs are in the same DWord but it is clobbered and the

          // adjacent DWord isn't used at all. Move both inputs to the free

          // slot.

          SourceHalfMask[2 * ((InputsFixed[0] / 2) ^ 1)] = InputsFixed[0];

          SourceHalfMask[2 * ((InputsFixed[0] / 2) ^ 1) + 1] = InputsFixed[1];

          InputsFixed[0] = 2 * ((InputsFixed[0] / 2) ^ 1);

          InputsFixed[1] = 2 * ((InputsFixed[0] / 2) ^ 1) + 1;

        } else {

          // The only way we hit this point is if there is no clobbering

          // (because there are no off-half inputs to this half) and there is no

          // free slot adjacent to one of the inputs. In this case, we have to

          // swap an input with a non-input.

          for (int i = 0; i < 4; ++i)

            assert((SourceHalfMask[i] < 0 || SourceHalfMask[i] == i) &&

                   "We can't handle any clobbers here!");

          assert(InputsFixed[1] != (InputsFixed[0] ^ 1) &&

                 "Cannot have adjacent inputs here!");


          SourceHalfMask[InputsFixed[0] ^ 1] = InputsFixed[1];

          SourceHalfMask[InputsFixed[1]] = InputsFixed[0] ^ 1;


          // We also have to update the final source mask in this case because

          // it may need to undo the above swap.

          for (int &M : FinalSourceHalfMask)

            if (M == (InputsFixed[0] ^ 1) + SourceOffset)

              M = InputsFixed[1] + SourceOffset;

            else if (M == InputsFixed[1] + SourceOffset)

              M = (InputsFixed[0] ^ 1) + SourceOffset;


          InputsFixed[1] = InputsFixed[0] ^ 1;

        }


        // Point everything at the fixed inputs.

        for (int &M : HalfMask)

          if (M == IncomingInputs[0])

            M = InputsFixed[0] + SourceOffset;

          else if (M == IncomingInputs[1])

            M = InputsFixed[1] + SourceOffset;


        IncomingInputs[0] = InputsFixed[0] + SourceOffset;

        IncomingInputs[1] = InputsFixed[1] + SourceOffset;

      }

    } else {

      llvm_unreachable("Unhandled input size!");

    }


    // Now hoist the DWord down to the right half.

    int FreeDWord = (PSHUFDMask[DestOffset / 2] < 0 ? 0 : 1) + DestOffset / 2;

    assert(PSHUFDMask[FreeDWord] < 0 && "DWord not free");

    PSHUFDMask[FreeDWord] = IncomingInputs[0] / 2;

    for (int &M : HalfMask)

      for (int Input : IncomingInputs)

        if (M == Input)

          M = FreeDWord * 2 + Input % 2;

  };

  moveInputsToRightHalf(HToLInputs, LToLInputs, PSHUFHMask, LoMask, HiMask,

                        /*SourceOffset*/ 4, /*DestOffset*/ 0);

  moveInputsToRightHalf(LToHInputs, HToHInputs, PSHUFLMask, HiMask, LoMask,

                        /*SourceOffset*/ 0, /*DestOffset*/ 4);


  // Now enact all the shuffles we've computed to move the inputs into their

  // target half.

  if (!isNoopShuffleMask(PSHUFLMask))

    V = DAG.getNode(X86ISD::PSHUFLW, DL, VT, V,

                    getV4X86ShuffleImm8ForMask(PSHUFLMask, DL, DAG));

  if (!isNoopShuffleMask(PSHUFHMask))

    V = DAG.getNode(X86ISD::PSHUFHW, DL, VT, V,

                    getV4X86ShuffleImm8ForMask(PSHUFHMask, DL, DAG));

  if (!isNoopShuffleMask(PSHUFDMask))

    V = DAG.getBitcast(

        VT,

        DAG.getNode(X86ISD::PSHUFD, DL, PSHUFDVT, DAG.getBitcast(PSHUFDVT, V),

                    getV4X86ShuffleImm8ForMask(PSHUFDMask, DL, DAG)));


  // At this point, each half should contain all its inputs, and we can then

  // just shuffle them into their final position.

  assert(none_of(LoMask, [](int M) { return M >= 4; }) &&

         "Failed to lift all the high half inputs to the low mask!");

  assert(none_of(HiMask, [](int M) { return M >= 0 && M < 4; }) &&

         "Failed to lift all the low half inputs to the high mask!");


  // Do a half shuffle for the low mask.

  if (!isNoopShuffleMask(LoMask))

    V = DAG.getNode(X86ISD::PSHUFLW, DL, VT, V,

                    getV4X86ShuffleImm8ForMask(LoMask, DL, DAG));


  // Do a half shuffle with the high mask after shifting its values down.

  for (int &M : HiMask)

    if (M >= 0)

      M -= 4;

  if (!isNoopShuffleMask(HiMask))

    V = DAG.getNode(X86ISD::PSHUFHW, DL, VT, V,

                    getV4X86ShuffleImm8ForMask(HiMask, DL, DAG));


  return V;

}


/// Helper to form a PSHUFB-based shuffle+blend, opportunistically avoiding the

/// blend if only one input is used.


static SDValue lowerShuffleAsBlendOfPSHUFBs(

    const SDLoc &DL, MVT VT, SDValue V1, SDValue V2, ArrayRef<int> Mask,

    const APInt &Zeroable, SelectionDAG &DAG, bool &V1InUse, bool &V2InUse) {

  assert(!is128BitLaneCrossingShuffleMask(VT, Mask) &&

         "Lane crossing shuffle masks not supported");


  int NumBytes = VT.getSizeInBits() / 8;

  int Size = Mask.size();

  int Scale = NumBytes / Size;


  SmallVector<SDValue, 64> V1Mask(NumBytes, DAG.getUNDEF(MVT::i8));

  SmallVector<SDValue, 64> V2Mask(NumBytes, DAG.getUNDEF(MVT::i8));

  V1InUse = false;

  V2InUse = false;


  for (int i = 0; i < NumBytes; ++i) {

    int M = Mask[i / Scale];

    if (M < 0)

      continue;


    const int ZeroMask = 0x80;

    int V1Idx = M < Size ? M * Scale + i % Scale : ZeroMask;

    int V2Idx = M < Size ? ZeroMask : (M - Size) * Scale + i % Scale;

    if (Zeroable[i / Scale])

      V1Idx = V2Idx = ZeroMask;


    V1Mask[i] = DAG.getConstant(V1Idx, DL, MVT::i8);

    V2Mask[i] = DAG.getConstant(V2Idx, DL, MVT::i8);

    V1InUse |= (ZeroMask != V1Idx);

    V2InUse |= (ZeroMask != V2Idx);

  }


  MVT ShufVT = MVT::getVectorVT(MVT::i8, NumBytes);

  if (V1InUse)

    V1 = DAG.getNode(X86ISD::PSHUFB, DL, ShufVT, DAG.getBitcast(ShufVT, V1),

                     DAG.getBuildVector(ShufVT, DL, V1Mask));

  if (V2InUse)

    V2 = DAG.getNode(X86ISD::PSHUFB, DL, ShufVT, DAG.getBitcast(ShufVT, V2),

                     DAG.getBuildVector(ShufVT, DL, V2Mask));


  // If we need shuffled inputs from both, blend the two.

  SDValue V;

  if (V1InUse && V2InUse)

    V = DAG.getNode(ISD::OR, DL, ShufVT, V1, V2);

  else

    V = V1InUse ? V1 : V2;


  // Cast the result back to the correct type.

  return DAG.getBitcast(VT, V);

}


/// Generic lowering of 8-lane i16 shuffles.

///

/// This handles both single-input shuffles and combined shuffle/blends with

/// two inputs. The single input shuffles are immediately delegated to

/// a dedicated lowering routine.

///

/// The blends are lowered in one of three fundamental ways. If there are few

/// enough inputs, it delegates to a basic UNPCK-based strategy. If the shuffle

/// of the input is significantly cheaper when lowered as an interleaving of

/// the two inputs, try to interleave them. Otherwise, blend the low and high

/// halves of the inputs separately (making them have relatively few inputs)

/// and then concatenate them.


static SDValue lowerV8I16Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                 const APInt &Zeroable, SDValue V1, SDValue V2,

                                 const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v8i16 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v8i16 && "Bad operand type!");

  assert(Mask.size() == 8 && "Unexpected mask size for v8 shuffle!");


  // Whenever we can lower this as a zext, that instruction is strictly faster

  // than any alternative.

  if (SDValue ZExt = lowerShuffleAsZeroOrAnyExtend(DL, MVT::v8i16, V1, V2, Mask,

                                                   Zeroable, Subtarget, DAG))

    return ZExt;


  // Try to use lower using a truncation.

  if (SDValue V = lowerShuffleWithVPMOV(DL, MVT::v8i16, V1, V2, Mask, Zeroable,

                                        Subtarget, DAG))

    return V;


  int NumV2Inputs = count_if(Mask, [](int M) { return M >= 8; });


  if (NumV2Inputs == 0) {

    // Try to use shift instructions.

    if (SDValue Shift =

            lowerShuffleAsShift(DL, MVT::v8i16, V1, V1, Mask, Zeroable,

                                Subtarget, DAG, /*BitwiseOnly*/ false))

      return Shift;


    // Check for being able to broadcast a single element.

    if (SDValue Broadcast = lowerShuffleAsBroadcast(DL, MVT::v8i16, V1, V2,

                                                    Mask, Subtarget, DAG))

      return Broadcast;


    // Try to use bit rotation instructions.

    if (SDValue Rotate = lowerShuffleAsBitRotate(DL, MVT::v8i16, V1, Mask,

                                                 Subtarget, DAG))

      return Rotate;


    // Use dedicated unpack instructions for masks that match their pattern.

    if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v8i16, V1, V2, Mask, DAG))

      return V;


    // Use dedicated pack instructions for masks that match their pattern.

    if (SDValue V =

            lowerShuffleWithPACK(DL, MVT::v8i16, V1, V2, Mask, Subtarget, DAG))

      return V;


    // Try to use byte rotation instructions.

    if (SDValue Rotate = lowerShuffleAsByteRotate(DL, MVT::v8i16, V1, V1, Mask,

                                                  Subtarget, DAG))

      return Rotate;


    // Make a copy of the mask so it can be modified.

    SmallVector<int, 8> MutableMask(Mask);

    return lowerV8I16GeneralSingleInputShuffle(DL, MVT::v8i16, V1, MutableMask,

                                               Subtarget, DAG);

  }


  assert(llvm::any_of(Mask, [](int M) { return M >= 0 && M < 8; }) &&

         "All single-input shuffles should be canonicalized to be V1-input "

         "shuffles.");


  // Try to use shift instructions.

  if (SDValue Shift =

          lowerShuffleAsShift(DL, MVT::v8i16, V1, V2, Mask, Zeroable, Subtarget,

                              DAG, /*BitwiseOnly*/ false))

    return Shift;


  // See if we can use SSE4A Extraction / Insertion.

  if (Subtarget.hasSSE4A())

    if (SDValue V = lowerShuffleWithSSE4A(DL, MVT::v8i16, V1, V2, Mask,

                                          Zeroable, DAG))

      return V;


  // There are special ways we can lower some single-element blends.

  if (NumV2Inputs == 1)

    if (SDValue V = lowerShuffleAsElementInsertion(

            DL, MVT::v8i16, V1, V2, Mask, Zeroable, Subtarget, DAG))

      return V;


  // We have different paths for blend lowering, but they all must use the

  // *exact* same predicate.

  bool IsBlendSupported = Subtarget.hasSSE41();

  if (IsBlendSupported)

    if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v8i16, V1, V2, Mask,

                                            Zeroable, Subtarget, DAG))

      return Blend;


  if (SDValue Masked = lowerShuffleAsBitMask(DL, MVT::v8i16, V1, V2, Mask,

                                             Zeroable, Subtarget, DAG))

    return Masked;


  // Use dedicated unpack instructions for masks that match their pattern.

  if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v8i16, V1, V2, Mask, DAG))

    return V;


  // Use dedicated pack instructions for masks that match their pattern.

  if (SDValue V =

          lowerShuffleWithPACK(DL, MVT::v8i16, V1, V2, Mask, Subtarget, DAG))

    return V;


  // Try to use lower using a truncation.

  if (SDValue V = lowerShuffleAsVTRUNC(DL, MVT::v8i16, V1, V2, Mask, Zeroable,

                                       Subtarget, DAG))

    return V;


  // Try to use byte rotation instructions.

  if (SDValue Rotate = lowerShuffleAsByteRotate(DL, MVT::v8i16, V1, V2, Mask,

                                                Subtarget, DAG))

    return Rotate;


  if (SDValue BitBlend =

          lowerShuffleAsBitBlend(DL, MVT::v8i16, V1, V2, Mask, DAG))

    return BitBlend;


  // Try to use byte shift instructions to mask.

  if (SDValue V = lowerShuffleAsByteShiftMask(DL, MVT::v8i16, V1, V2, Mask,

                                              Zeroable, Subtarget, DAG))

    return V;


  // Attempt to lower using compaction, SSE41 is necessary for PACKUSDW.

  int NumEvenDrops = canLowerByDroppingElements(Mask, true, false);

  if ((NumEvenDrops == 1 || (NumEvenDrops == 2 && Subtarget.hasSSE41())) &&

      !Subtarget.hasVLX()) {

    // Check if this is part of a 256-bit vector truncation.

    unsigned PackOpc = 0;

    if (NumEvenDrops == 2 && Subtarget.hasAVX2() &&

        peekThroughBitcasts(V1).getOpcode() == ISD::EXTRACT_SUBVECTOR &&

        peekThroughBitcasts(V2).getOpcode() == ISD::EXTRACT_SUBVECTOR) {

      SDValue V1V2 = concatSubVectors(V1, V2, DAG, DL);

      V1V2 = DAG.getNode(X86ISD::BLENDI, DL, MVT::v16i16, V1V2,

                         getZeroVector(MVT::v16i16, Subtarget, DAG, DL),

                         DAG.getTargetConstant(0xEE, DL, MVT::i8));

      V1V2 = DAG.getBitcast(MVT::v8i32, V1V2);

      V1 = extract128BitVector(V1V2, 0, DAG, DL);

      V2 = extract128BitVector(V1V2, 4, DAG, DL);

      PackOpc = X86ISD::PACKUS;

    } else if (Subtarget.hasSSE41()) {

      SmallVector<SDValue, 4> DWordClearOps(4,

                                            DAG.getConstant(0, DL, MVT::i32));

      for (unsigned i = 0; i != 4; i += 1 << (NumEvenDrops - 1))

        DWordClearOps[i] = DAG.getConstant(0xFFFF, DL, MVT::i32);

      SDValue DWordClearMask =

          DAG.getBuildVector(MVT::v4i32, DL, DWordClearOps);

      V1 = DAG.getNode(ISD::AND, DL, MVT::v4i32, DAG.getBitcast(MVT::v4i32, V1),

                       DWordClearMask);

      V2 = DAG.getNode(ISD::AND, DL, MVT::v4i32, DAG.getBitcast(MVT::v4i32, V2),

                       DWordClearMask);

      PackOpc = X86ISD::PACKUS;

    } else if (!Subtarget.hasSSSE3()) {

      SDValue ShAmt = DAG.getTargetConstant(16, DL, MVT::i8);

      V1 = DAG.getBitcast(MVT::v4i32, V1);

      V2 = DAG.getBitcast(MVT::v4i32, V2);

      V1 = DAG.getNode(X86ISD::VSHLI, DL, MVT::v4i32, V1, ShAmt);

      V2 = DAG.getNode(X86ISD::VSHLI, DL, MVT::v4i32, V2, ShAmt);

      V1 = DAG.getNode(X86ISD::VSRAI, DL, MVT::v4i32, V1, ShAmt);

      V2 = DAG.getNode(X86ISD::VSRAI, DL, MVT::v4i32, V2, ShAmt);

      PackOpc = X86ISD::PACKSS;

    }

    if (PackOpc) {

      // Now pack things back together.

      SDValue Result = DAG.getNode(PackOpc, DL, MVT::v8i16, V1, V2);

      if (NumEvenDrops == 2) {

        Result = DAG.getBitcast(MVT::v4i32, Result);

        Result = DAG.getNode(PackOpc, DL, MVT::v8i16, Result, Result);

      }

      return Result;

    }

  }


  // When compacting odd (upper) elements, use PACKSS pre-SSE41.

  int NumOddDrops = canLowerByDroppingElements(Mask, false, false);

  if (NumOddDrops == 1) {

    bool HasSSE41 = Subtarget.hasSSE41();

    V1 = DAG.getNode(HasSSE41 ? X86ISD::VSRLI : X86ISD::VSRAI, DL, MVT::v4i32,

                     DAG.getBitcast(MVT::v4i32, V1),

                     DAG.getTargetConstant(16, DL, MVT::i8));

    V2 = DAG.getNode(HasSSE41 ? X86ISD::VSRLI : X86ISD::VSRAI, DL, MVT::v4i32,

                     DAG.getBitcast(MVT::v4i32, V2),

                     DAG.getTargetConstant(16, DL, MVT::i8));

    return DAG.getNode(HasSSE41 ? X86ISD::PACKUS : X86ISD::PACKSS, DL,

                       MVT::v8i16, V1, V2);

  }


  // Try to lower by permuting the inputs into an unpack instruction.

  if (SDValue Unpack = lowerShuffleAsPermuteAndUnpack(DL, MVT::v8i16, V1, V2,

                                                      Mask, Subtarget, DAG))

    return Unpack;


  // If we can't directly blend but can use PSHUFB, that will be better as it

  // can both shuffle and set up the inefficient blend.

  if (!IsBlendSupported && Subtarget.hasSSSE3()) {

    bool V1InUse, V2InUse;

    return lowerShuffleAsBlendOfPSHUFBs(DL, MVT::v8i16, V1, V2, Mask,

                                        Zeroable, DAG, V1InUse, V2InUse);

  }


  // We can always bit-blend if we have to so the fallback strategy is to

  // decompose into single-input permutes and blends/unpacks.

  return lowerShuffleAsDecomposedShuffleMerge(DL, MVT::v8i16, V1, V2, Mask,

                                              Zeroable, Subtarget, DAG);

}


/// Lower 8-lane 16-bit floating point shuffles.


static SDValue lowerV8F16Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                 const APInt &Zeroable, SDValue V1, SDValue V2,

                                 const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v8f16 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v8f16 && "Bad operand type!");

  assert(Mask.size() == 8 && "Unexpected mask size for v8 shuffle!");

  int NumV2Elements = count_if(Mask, [](int M) { return M >= 8; });


  if (Subtarget.hasFP16()) {

    if (NumV2Elements == 0) {

      // Check for being able to broadcast a single element.

      if (SDValue Broadcast = lowerShuffleAsBroadcast(DL, MVT::v8f16, V1, V2,

                                                      Mask, Subtarget, DAG))

        return Broadcast;

    }

    if (NumV2Elements == 1 && Mask[0] >= 8)

      if (SDValue V = lowerShuffleAsElementInsertion(

              DL, MVT::v8f16, V1, V2, Mask, Zeroable, Subtarget, DAG))

        return V;

  }


  V1 = DAG.getBitcast(MVT::v8i16, V1);

  V2 = DAG.getBitcast(MVT::v8i16, V2);

  return DAG.getBitcast(MVT::v8f16,

                        DAG.getVectorShuffle(MVT::v8i16, DL, V1, V2, Mask));

}


// Lowers unary/binary shuffle as VPERMV/VPERMV3, for non-VLX targets,

// sub-512-bit shuffles are padded to 512-bits for the shuffle and then

// the active subvector is extracted.


static SDValue lowerShuffleWithPERMV(const SDLoc &DL, MVT VT,

                                     ArrayRef<int> OriginalMask, SDValue V1,

                                     SDValue V2, const X86Subtarget &Subtarget,

                                     SelectionDAG &DAG) {

  // Commute binary inputs so V2 is a load to simplify VPERMI2/T2 folds.

  SmallVector<int, 32> Mask(OriginalMask);

  if (!V2.isUndef() && isShuffleFoldableLoad(V1) &&

      !isShuffleFoldableLoad(V2)) {

    ShuffleVectorSDNode::commuteMask(Mask);

    std::swap(V1, V2);

  }


  MVT MaskVT = VT.changeTypeToInteger();

  SDValue MaskNode;

  MVT ShuffleVT = VT;

  if (!VT.is512BitVector() && !Subtarget.hasVLX()) {

    V1 = widenSubVector(V1, false, Subtarget, DAG, DL, 512);

    V2 = widenSubVector(V2, false, Subtarget, DAG, DL, 512);

    ShuffleVT = V1.getSimpleValueType();


    // Adjust mask to correct indices for the second input.

    int NumElts = VT.getVectorNumElements();

    unsigned Scale = 512 / VT.getSizeInBits();

    SmallVector<int, 32> AdjustedMask(Mask);

    for (int &M : AdjustedMask)

      if (NumElts <= M)

        M += (Scale - 1) * NumElts;

    MaskNode = getConstVector(AdjustedMask, MaskVT, DAG, DL, true);

    MaskNode = widenSubVector(MaskNode, false, Subtarget, DAG, DL, 512);

  } else {

    MaskNode = getConstVector(Mask, MaskVT, DAG, DL, true);

  }


  SDValue Result;

  if (V2.isUndef())

    Result = DAG.getNode(X86ISD::VPERMV, DL, ShuffleVT, MaskNode, V1);

  else

    Result = DAG.getNode(X86ISD::VPERMV3, DL, ShuffleVT, V1, MaskNode, V2);


  if (VT != ShuffleVT)

    Result = extractSubVector(Result, 0, DAG, DL, VT.getSizeInBits());


  return Result;

}


/// Generic lowering of v16i8 shuffles.

///

/// This is a hybrid strategy to lower v16i8 vectors. It first attempts to

/// detect any complexity reducing interleaving. If that doesn't help, it uses

/// UNPCK to spread the i8 elements across two i16-element vectors, and uses

/// the existing lowering for v8i16 blends on each half, finally PACK-ing them

/// back together.


static SDValue lowerV16I8Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                 const APInt &Zeroable, SDValue V1, SDValue V2,

                                 const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v16i8 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v16i8 && "Bad operand type!");

  assert(Mask.size() == 16 && "Unexpected mask size for v16 shuffle!");


  // Try to use shift instructions.

  if (SDValue Shift =

          lowerShuffleAsShift(DL, MVT::v16i8, V1, V2, Mask, Zeroable, Subtarget,

                              DAG, /*BitwiseOnly*/ false))

    return Shift;


  // Try to use byte rotation instructions.

  if (SDValue Rotate = lowerShuffleAsByteRotate(DL, MVT::v16i8, V1, V2, Mask,

                                                Subtarget, DAG))

    return Rotate;


  // Use dedicated pack instructions for masks that match their pattern.

  if (SDValue V =

          lowerShuffleWithPACK(DL, MVT::v16i8, V1, V2, Mask, Subtarget, DAG))

    return V;


  // Try to use a zext lowering.

  if (SDValue ZExt = lowerShuffleAsZeroOrAnyExtend(DL, MVT::v16i8, V1, V2, Mask,

                                                   Zeroable, Subtarget, DAG))

    return ZExt;


  // Try to use lower using a truncation.

  if (SDValue V = lowerShuffleWithVPMOV(DL, MVT::v16i8, V1, V2, Mask, Zeroable,

                                        Subtarget, DAG))

    return V;


  if (SDValue V = lowerShuffleAsVTRUNC(DL, MVT::v16i8, V1, V2, Mask, Zeroable,

                                       Subtarget, DAG))

    return V;


  // See if we can use SSE4A Extraction / Insertion.

  if (Subtarget.hasSSE4A())

    if (SDValue V = lowerShuffleWithSSE4A(DL, MVT::v16i8, V1, V2, Mask,

                                          Zeroable, DAG))

      return V;


  int NumV2Elements = count_if(Mask, [](int M) { return M >= 16; });


  // For single-input shuffles, there are some nicer lowering tricks we can use.

  if (NumV2Elements == 0) {

    // Check for being able to broadcast a single element.

    if (SDValue Broadcast = lowerShuffleAsBroadcast(DL, MVT::v16i8, V1, V2,

                                                    Mask, Subtarget, DAG))

      return Broadcast;


    // Try to use bit rotation instructions.

    if (SDValue Rotate = lowerShuffleAsBitRotate(DL, MVT::v16i8, V1, Mask,

                                                 Subtarget, DAG))

      return Rotate;


    if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v16i8, V1, V2, Mask, DAG))

      return V;


    // Check whether we can widen this to an i16 shuffle by duplicating bytes.

    // Notably, this handles splat and partial-splat shuffles more efficiently.

    // However, it only makes sense if the pre-duplication shuffle simplifies

    // things significantly. Currently, this means we need to be able to

    // express the pre-duplication shuffle as an i16 shuffle.

    //

    // FIXME: We should check for other patterns which can be widened into an

    // i16 shuffle as well.

    auto canWidenViaDuplication = [](ArrayRef<int> Mask) {

      for (int i = 0; i < 16; i += 2)

        if (Mask[i] >= 0 && Mask[i + 1] >= 0 && Mask[i] != Mask[i + 1])

          return false;


      return true;

    };

    auto tryToWidenViaDuplication = [&]() -> SDValue {

      if (!canWidenViaDuplication(Mask))

        return SDValue();

      SmallVector<int, 4> LoInputs;

      copy_if(Mask, std::back_inserter(LoInputs),

              [](int M) { return M >= 0 && M < 8; });

      array_pod_sort(LoInputs.begin(), LoInputs.end());

      LoInputs.erase(llvm::unique(LoInputs), LoInputs.end());

      SmallVector<int, 4> HiInputs;

      copy_if(Mask, std::back_inserter(HiInputs), [](int M) { return M >= 8; });

      array_pod_sort(HiInputs.begin(), HiInputs.end());

      HiInputs.erase(llvm::unique(HiInputs), HiInputs.end());


      bool TargetLo = LoInputs.size() >= HiInputs.size();

      ArrayRef<int> InPlaceInputs = TargetLo ? LoInputs : HiInputs;

      ArrayRef<int> MovingInputs = TargetLo ? HiInputs : LoInputs;


      int PreDupI16Shuffle[] = {-1, -1, -1, -1, -1, -1, -1, -1};

      SmallDenseMap<int, int, 8> LaneMap;

      for (int I : InPlaceInputs) {

        PreDupI16Shuffle[I/2] = I/2;

        LaneMap[I] = I;

      }

      int j = TargetLo ? 0 : 4, je = j + 4;

      for (int i = 0, ie = MovingInputs.size(); i < ie; ++i) {

        // Check if j is already a shuffle of this input. This happens when

        // there are two adjacent bytes after we move the low one.

        if (PreDupI16Shuffle[j] != MovingInputs[i] / 2) {

          // If we haven't yet mapped the input, search for a slot into which

          // we can map it.

          while (j < je && PreDupI16Shuffle[j] >= 0)

            ++j;


          if (j == je)

            // We can't place the inputs into a single half with a simple i16 shuffle, so bail.

            return SDValue();


          // Map this input with the i16 shuffle.

          PreDupI16Shuffle[j] = MovingInputs[i] / 2;

        }


        // Update the lane map based on the mapping we ended up with.

        LaneMap[MovingInputs[i]] = 2 * j + MovingInputs[i] % 2;

      }

      V1 = DAG.getBitcast(

          MVT::v16i8,

          DAG.getVectorShuffle(MVT::v8i16, DL, DAG.getBitcast(MVT::v8i16, V1),

                               DAG.getUNDEF(MVT::v8i16), PreDupI16Shuffle));


      // Unpack the bytes to form the i16s that will be shuffled into place.

      bool EvenInUse = false, OddInUse = false;

      for (int i = 0; i < 16; i += 2) {

        EvenInUse |= (Mask[i + 0] >= 0);

        OddInUse |= (Mask[i + 1] >= 0);

        if (EvenInUse && OddInUse)

          break;

      }

      V1 = DAG.getNode(TargetLo ? X86ISD::UNPCKL : X86ISD::UNPCKH, DL,

                       MVT::v16i8, EvenInUse ? V1 : DAG.getUNDEF(MVT::v16i8),

                       OddInUse ? V1 : DAG.getUNDEF(MVT::v16i8));


      int PostDupI16Shuffle[8] = {-1, -1, -1, -1, -1, -1, -1, -1};

      for (int i = 0; i < 16; ++i)

        if (Mask[i] >= 0) {

          int MappedMask = LaneMap[Mask[i]] - (TargetLo ? 0 : 8);

          assert(MappedMask < 8 && "Invalid v8 shuffle mask!");

          if (PostDupI16Shuffle[i / 2] < 0)

            PostDupI16Shuffle[i / 2] = MappedMask;

          else

            assert(PostDupI16Shuffle[i / 2] == MappedMask &&

                   "Conflicting entries in the original shuffle!");

        }

      return DAG.getBitcast(

          MVT::v16i8,

          DAG.getVectorShuffle(MVT::v8i16, DL, DAG.getBitcast(MVT::v8i16, V1),

                               DAG.getUNDEF(MVT::v8i16), PostDupI16Shuffle));

    };

    if (SDValue V = tryToWidenViaDuplication())

      return V;

  }


  if (SDValue Masked = lowerShuffleAsBitMask(DL, MVT::v16i8, V1, V2, Mask,

                                             Zeroable, Subtarget, DAG))

    return Masked;


  // Use dedicated unpack instructions for masks that match their pattern.

  if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v16i8, V1, V2, Mask, DAG))

    return V;


  // Try to use byte shift instructions to mask.

  if (SDValue V = lowerShuffleAsByteShiftMask(DL, MVT::v16i8, V1, V2, Mask,

                                              Zeroable, Subtarget, DAG))

    return V;


  // Check for compaction patterns.

  bool IsSingleInput = V2.isUndef();

  int NumEvenDrops = canLowerByDroppingElements(Mask, true, IsSingleInput);


  // Check for SSSE3 which lets us lower all v16i8 shuffles much more directly

  // with PSHUFB. It is important to do this before we attempt to generate any

  // blends but after all of the single-input lowerings. If the single input

  // lowerings can find an instruction sequence that is faster than a PSHUFB, we

  // want to preserve that and we can DAG combine any longer sequences into

  // a PSHUFB in the end. But once we start blending from multiple inputs,

  // the complexity of DAG combining bad patterns back into PSHUFB is too high,

  // and there are *very* few patterns that would actually be faster than the

  // PSHUFB approach because of its ability to zero lanes.

  //

  // If the mask is a binary compaction, we can more efficiently perform this

  // as a PACKUS(AND(),AND()) - which is quicker than UNPACK(PSHUFB(),PSHUFB()).

  //

  // FIXME: The only exceptions to the above are blends which are exact

  // interleavings with direct instructions supporting them. We currently don't

  // handle those well here.

  if (Subtarget.hasSSSE3() && (IsSingleInput || NumEvenDrops != 1)) {

    bool V1InUse = false;

    bool V2InUse = false;


    SDValue PSHUFB = lowerShuffleAsBlendOfPSHUFBs(

        DL, MVT::v16i8, V1, V2, Mask, Zeroable, DAG, V1InUse, V2InUse);


    // If both V1 and V2 are in use and we can use a direct blend or an unpack,

    // do so. This avoids using them to handle blends-with-zero which is

    // important as a single pshufb is significantly faster for that.

    if (V1InUse && V2InUse) {

      if (Subtarget.hasSSE41())

        if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v16i8, V1, V2, Mask,

                                                Zeroable, Subtarget, DAG))

          return Blend;


      // We can use an unpack to do the blending rather than an or in some

      // cases. Even though the or may be (very minorly) more efficient, we

      // preference this lowering because there are common cases where part of

      // the complexity of the shuffles goes away when we do the final blend as

      // an unpack.

      // FIXME: It might be worth trying to detect if the unpack-feeding

      // shuffles will both be pshufb, in which case we shouldn't bother with

      // this.

      if (SDValue Unpack = lowerShuffleAsPermuteAndUnpack(

              DL, MVT::v16i8, V1, V2, Mask, Subtarget, DAG))

        return Unpack;


      // AVX512VBMI can lower to VPERMB (non-VLX will pad to v64i8).

      if (Subtarget.hasVBMI())

        return lowerShuffleWithPERMV(DL, MVT::v16i8, Mask, V1, V2, Subtarget,

                                     DAG);


      // If we have XOP we can use one VPPERM instead of multiple PSHUFBs.

      if (Subtarget.hasXOP()) {

        SDValue MaskNode = getConstVector(Mask, MVT::v16i8, DAG, DL, true);

        return DAG.getNode(X86ISD::VPPERM, DL, MVT::v16i8, V1, V2, MaskNode);

      }


      // Use PALIGNR+Permute if possible - permute might become PSHUFB but the

      // PALIGNR will be cheaper than the second PSHUFB+OR.

      if (SDValue V = lowerShuffleAsByteRotateAndPermute(

              DL, MVT::v16i8, V1, V2, Mask, Subtarget, DAG))

        return V;

    }


    return PSHUFB;

  }


  // There are special ways we can lower some single-element blends.

  if (NumV2Elements == 1)

    if (SDValue V = lowerShuffleAsElementInsertion(

            DL, MVT::v16i8, V1, V2, Mask, Zeroable, Subtarget, DAG))

      return V;


  if (SDValue Blend = lowerShuffleAsBitBlend(DL, MVT::v16i8, V1, V2, Mask, DAG))

    return Blend;


  // Check whether a compaction lowering can be done. This handles shuffles

  // which take every Nth element for some even N. See the helper function for

  // details.

  //

  // We special case these as they can be particularly efficiently handled with

  // the PACKUSB instruction on x86 and they show up in common patterns of

  // rearranging bytes to truncate wide elements.

  if (NumEvenDrops) {

    // NumEvenDrops is the power of two stride of the elements. Another way of

    // thinking about it is that we need to drop the even elements this many

    // times to get the original input.


    // First we need to zero all the dropped bytes.

    assert(NumEvenDrops <= 3 &&

           "No support for dropping even elements more than 3 times.");

    SmallVector<SDValue, 8> WordClearOps(8, DAG.getConstant(0, DL, MVT::i16));

    for (unsigned i = 0; i != 8; i += 1 << (NumEvenDrops - 1))

      WordClearOps[i] = DAG.getConstant(0xFF, DL, MVT::i16);

    SDValue WordClearMask = DAG.getBuildVector(MVT::v8i16, DL, WordClearOps);

    V1 = DAG.getNode(ISD::AND, DL, MVT::v8i16, DAG.getBitcast(MVT::v8i16, V1),

                     WordClearMask);

    if (!IsSingleInput)

      V2 = DAG.getNode(ISD::AND, DL, MVT::v8i16, DAG.getBitcast(MVT::v8i16, V2),

                       WordClearMask);


    // Now pack things back together.

    SDValue Result = DAG.getNode(X86ISD::PACKUS, DL, MVT::v16i8, V1,

                                 IsSingleInput ? V1 : V2);

    for (int i = 1; i < NumEvenDrops; ++i) {

      Result = DAG.getBitcast(MVT::v8i16, Result);

      Result = DAG.getNode(X86ISD::PACKUS, DL, MVT::v16i8, Result, Result);

    }

    return Result;

  }


  int NumOddDrops = canLowerByDroppingElements(Mask, false, IsSingleInput);

  if (NumOddDrops == 1) {

    V1 = DAG.getNode(X86ISD::VSRLI, DL, MVT::v8i16,

                     DAG.getBitcast(MVT::v8i16, V1),

                     DAG.getTargetConstant(8, DL, MVT::i8));

    if (!IsSingleInput)

      V2 = DAG.getNode(X86ISD::VSRLI, DL, MVT::v8i16,

                       DAG.getBitcast(MVT::v8i16, V2),

                       DAG.getTargetConstant(8, DL, MVT::i8));

    return DAG.getNode(X86ISD::PACKUS, DL, MVT::v16i8, V1,

                       IsSingleInput ? V1 : V2);

  }


  // Handle multi-input cases by blending/unpacking single-input shuffles.

  if (NumV2Elements > 0)

    return lowerShuffleAsDecomposedShuffleMerge(DL, MVT::v16i8, V1, V2, Mask,

                                                Zeroable, Subtarget, DAG);


  // The fallback path for single-input shuffles widens this into two v8i16

  // vectors with unpacks, shuffles those, and then pulls them back together

  // with a pack.

  SDValue V = V1;


  std::array<int, 8> LoBlendMask = {{-1, -1, -1, -1, -1, -1, -1, -1}};

  std::array<int, 8> HiBlendMask = {{-1, -1, -1, -1, -1, -1, -1, -1}};

  for (int i = 0; i < 16; ++i)

    if (Mask[i] >= 0)

      (i < 8 ? LoBlendMask[i] : HiBlendMask[i % 8]) = Mask[i];


  SDValue VLoHalf, VHiHalf;

  // Check if any of the odd lanes in the v16i8 are used. If not, we can mask

  // them out and avoid using UNPCK{L,H} to extract the elements of V as

  // i16s.

  if (none_of(LoBlendMask, [](int M) { return M >= 0 && M % 2 == 1; }) &&

      none_of(HiBlendMask, [](int M) { return M >= 0 && M % 2 == 1; })) {

    // Use a mask to drop the high bytes.

    VLoHalf = DAG.getBitcast(MVT::v8i16, V);

    VLoHalf = DAG.getNode(ISD::AND, DL, MVT::v8i16, VLoHalf,

                          DAG.getConstant(0x00FF, DL, MVT::v8i16));


    // This will be a single vector shuffle instead of a blend so nuke VHiHalf.

    VHiHalf = DAG.getUNDEF(MVT::v8i16);


    // Squash the masks to point directly into VLoHalf.

    for (int &M : LoBlendMask)

      if (M >= 0)

        M /= 2;

    for (int &M : HiBlendMask)

      if (M >= 0)

        M /= 2;

  } else {

    // Otherwise just unpack the low half of V into VLoHalf and the high half into

    // VHiHalf so that we can blend them as i16s.

    SDValue Zero = getZeroVector(MVT::v16i8, Subtarget, DAG, DL);


    VLoHalf = DAG.getBitcast(

        MVT::v8i16, DAG.getNode(X86ISD::UNPCKL, DL, MVT::v16i8, V, Zero));

    VHiHalf = DAG.getBitcast(

        MVT::v8i16, DAG.getNode(X86ISD::UNPCKH, DL, MVT::v16i8, V, Zero));

  }


  SDValue LoV = DAG.getVectorShuffle(MVT::v8i16, DL, VLoHalf, VHiHalf, LoBlendMask);

  SDValue HiV = DAG.getVectorShuffle(MVT::v8i16, DL, VLoHalf, VHiHalf, HiBlendMask);


  return DAG.getNode(X86ISD::PACKUS, DL, MVT::v16i8, LoV, HiV);

}


/// Dispatching routine to lower various 128-bit x86 vector shuffles.

///

/// This routine breaks down the specific type of 128-bit shuffle and

/// dispatches to the lowering routines accordingly.


static SDValue lower128BitShuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                  MVT VT, SDValue V1, SDValue V2,

                                  const APInt &Zeroable,

                                  const X86Subtarget &Subtarget,

                                  SelectionDAG &DAG) {

  if (VT == MVT::v8bf16) {

    V1 = DAG.getBitcast(MVT::v8i16, V1);

    V2 = DAG.getBitcast(MVT::v8i16, V2);

    return DAG.getBitcast(VT,

                          DAG.getVectorShuffle(MVT::v8i16, DL, V1, V2, Mask));

  }


  switch (VT.SimpleTy) {

  case MVT::v2i64:

    return lowerV2I64Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v2f64:

    return lowerV2F64Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v4i32:

    return lowerV4I32Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v4f32:

    return lowerV4F32Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v8i16:

    return lowerV8I16Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v8f16:

    return lowerV8F16Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v16i8:

    return lowerV16I8Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);


  default:

    llvm_unreachable("Unimplemented!");

  }

}


/// Generic routine to split vector shuffle into half-sized shuffles.

///

/// This routine just extracts two subvectors, shuffles them independently, and

/// then concatenates them back together. This should work effectively with all

/// AVX vector shuffle types.


static SDValue splitAndLowerShuffle(const SDLoc &DL, MVT VT, SDValue V1,

                                    SDValue V2, ArrayRef<int> Mask,

                                    SelectionDAG &DAG, bool SimpleOnly) {

  assert(VT.getSizeInBits() >= 256 &&

         "Only for 256-bit or wider vector shuffles!");

  assert(V1.getSimpleValueType() == VT && "Bad operand type!");

  assert(V2.getSimpleValueType() == VT && "Bad operand type!");


  // If this came from the AVX1 v8i32 -> v8f32 bitcast, split using v4i32.

  if (VT == MVT::v8f32) {

    SDValue BC1 = peekThroughBitcasts(V1);

    SDValue BC2 = peekThroughBitcasts(V2);

    if (BC1.getValueType() == MVT::v8i32 && BC2.getValueType() == MVT::v8i32) {

      if (SDValue Split = splitAndLowerShuffle(DL, MVT::v8i32, BC1, BC2, Mask,

                                               DAG, SimpleOnly))

        return DAG.getBitcast(VT, Split);

    }

  }


  ArrayRef<int> LoMask = Mask.slice(0, Mask.size() / 2);

  ArrayRef<int> HiMask = Mask.slice(Mask.size() / 2);


  int NumElements = VT.getVectorNumElements();

  int SplitNumElements = NumElements / 2;

  MVT ScalarVT = VT.getVectorElementType();

  MVT SplitVT = MVT::getVectorVT(ScalarVT, SplitNumElements);


  // Use splitVector/extractSubVector so that split build-vectors just build two

  // narrower build vectors. This helps shuffling with splats and zeros.

  auto SplitVector = [&](SDValue V) {

    SDValue LoV, HiV;

    std::tie(LoV, HiV) = splitVector(peekThroughBitcasts(V), DAG, DL);

    return std::make_pair(DAG.getBitcast(SplitVT, LoV),

                          DAG.getBitcast(SplitVT, HiV));

  };


  SDValue LoV1, HiV1, LoV2, HiV2;

  std::tie(LoV1, HiV1) = SplitVector(V1);

  std::tie(LoV2, HiV2) = SplitVector(V2);


  // Now create two 4-way blends of these half-width vectors.

  auto GetHalfBlendPiecesReq = [&](const ArrayRef<int> &HalfMask, bool &UseLoV1,

                                   bool &UseHiV1, bool &UseLoV2,

                                   bool &UseHiV2) {

    UseLoV1 = UseHiV1 = UseLoV2 = UseHiV2 = false;

    for (int i = 0; i < SplitNumElements; ++i) {

      int M = HalfMask[i];

      if (M >= NumElements) {

        if (M >= NumElements + SplitNumElements)

          UseHiV2 = true;

        else

          UseLoV2 = true;

      } else if (M >= 0) {

        if (M >= SplitNumElements)

          UseHiV1 = true;

        else

          UseLoV1 = true;

      }

    }

  };


  auto CheckHalfBlendUsable = [&](const ArrayRef<int> &HalfMask) -> bool {

    if (!SimpleOnly)

      return true;


    bool UseLoV1, UseHiV1, UseLoV2, UseHiV2;

    GetHalfBlendPiecesReq(HalfMask, UseLoV1, UseHiV1, UseLoV2, UseHiV2);


    return !(UseHiV1 || UseHiV2);

  };


  auto HalfBlend = [&](ArrayRef<int> HalfMask) {

    SmallVector<int, 32> V1BlendMask((unsigned)SplitNumElements, -1);

    SmallVector<int, 32> V2BlendMask((unsigned)SplitNumElements, -1);

    SmallVector<int, 32> BlendMask((unsigned)SplitNumElements, -1);

    for (int i = 0; i < SplitNumElements; ++i) {

      int M = HalfMask[i];

      if (M >= NumElements) {

        V2BlendMask[i] = M - NumElements;

        BlendMask[i] = SplitNumElements + i;

      } else if (M >= 0) {

        V1BlendMask[i] = M;

        BlendMask[i] = i;

      }

    }


    bool UseLoV1, UseHiV1, UseLoV2, UseHiV2;

    GetHalfBlendPiecesReq(HalfMask, UseLoV1, UseHiV1, UseLoV2, UseHiV2);


    // Because the lowering happens after all combining takes place, we need to

    // manually combine these blend masks as much as possible so that we create

    // a minimal number of high-level vector shuffle nodes.

    assert((!SimpleOnly || (!UseHiV1 && !UseHiV2)) && "Shuffle isn't simple");


    // First try just blending the halves of V1 or V2.

    if (!UseLoV1 && !UseHiV1 && !UseLoV2 && !UseHiV2)

      return DAG.getUNDEF(SplitVT);

    if (!UseLoV2 && !UseHiV2)

      return DAG.getVectorShuffle(SplitVT, DL, LoV1, HiV1, V1BlendMask);

    if (!UseLoV1 && !UseHiV1)

      return DAG.getVectorShuffle(SplitVT, DL, LoV2, HiV2, V2BlendMask);


    SDValue V1Blend, V2Blend;

    if (UseLoV1 && UseHiV1) {

      V1Blend = DAG.getVectorShuffle(SplitVT, DL, LoV1, HiV1, V1BlendMask);

    } else {

      // We only use half of V1 so map the usage down into the final blend mask.

      V1Blend = UseLoV1 ? LoV1 : HiV1;

      for (int i = 0; i < SplitNumElements; ++i)

        if (BlendMask[i] >= 0 && BlendMask[i] < SplitNumElements)

          BlendMask[i] = V1BlendMask[i] - (UseLoV1 ? 0 : SplitNumElements);

    }

    if (UseLoV2 && UseHiV2) {

      V2Blend = DAG.getVectorShuffle(SplitVT, DL, LoV2, HiV2, V2BlendMask);

    } else {

      // We only use half of V2 so map the usage down into the final blend mask.

      V2Blend = UseLoV2 ? LoV2 : HiV2;

      for (int i = 0; i < SplitNumElements; ++i)

        if (BlendMask[i] >= SplitNumElements)

          BlendMask[i] = V2BlendMask[i] + (UseLoV2 ? SplitNumElements : 0);

    }

    return DAG.getVectorShuffle(SplitVT, DL, V1Blend, V2Blend, BlendMask);

  };


  if (!CheckHalfBlendUsable(LoMask) || !CheckHalfBlendUsable(HiMask))

    return SDValue();


  SDValue Lo = HalfBlend(LoMask);

  SDValue Hi = HalfBlend(HiMask);

  return DAG.getNode(ISD::CONCAT_VECTORS, DL, VT, Lo, Hi);

}


/// Either split a vector in halves or decompose the shuffles and the

/// blend/unpack.

///

/// This is provided as a good fallback for many lowerings of non-single-input

/// shuffles with more than one 128-bit lane. In those cases, we want to select

/// between splitting the shuffle into 128-bit components and stitching those

/// back together vs. extracting the single-input shuffles and blending those

/// results.


static SDValue lowerShuffleAsSplitOrBlend(const SDLoc &DL, MVT VT, SDValue V1,

                                          SDValue V2, ArrayRef<int> Mask,

                                          const APInt &Zeroable,

                                          const X86Subtarget &Subtarget,

                                          SelectionDAG &DAG) {

  assert(!V2.isUndef() && "This routine must not be used to lower single-input "

         "shuffles as it could then recurse on itself.");

  int Size = Mask.size();


  // If this can be modeled as a broadcast of two elements followed by a blend,

  // prefer that lowering. This is especially important because broadcasts can

  // often fold with memory operands.

  auto DoBothBroadcast = [&] {

    int V1BroadcastIdx = -1, V2BroadcastIdx = -1;

    for (int M : Mask)

      if (M >= Size) {

        if (V2BroadcastIdx < 0)

          V2BroadcastIdx = M - Size;

        else if ((M - Size) != V2BroadcastIdx &&

                 !IsElementEquivalent(Size, V2, V2, M - Size, V2BroadcastIdx))

          return false;

      } else if (M >= 0) {

        if (V1BroadcastIdx < 0)

          V1BroadcastIdx = M;

        else if (M != V1BroadcastIdx &&

                 !IsElementEquivalent(Size, V1, V1, M, V1BroadcastIdx))

          return false;

      }

    return true;

  };

  if (DoBothBroadcast())

    return lowerShuffleAsDecomposedShuffleMerge(DL, VT, V1, V2, Mask, Zeroable,

                                                Subtarget, DAG);


  // If the inputs all stem from a single 128-bit lane of each input, then we

  // split them rather than blending because the split will decompose to

  // unusually few instructions.

  int LaneCount = VT.getSizeInBits() / 128;

  int LaneSize = Size / LaneCount;

  SmallBitVector LaneInputs[2];

  LaneInputs[0].resize(LaneCount, false);

  LaneInputs[1].resize(LaneCount, false);

  for (int i = 0; i < Size; ++i)

    if (Mask[i] >= 0)

      LaneInputs[Mask[i] / Size][(Mask[i] % Size) / LaneSize] = true;

  if (LaneInputs[0].count() <= 1 && LaneInputs[1].count() <= 1)

    return splitAndLowerShuffle(DL, VT, V1, V2, Mask, DAG,

                                /*SimpleOnly*/ false);


  // Without AVX2, if we can freely split the subvectors then we're better off

  // performing half width shuffles.

  if (!Subtarget.hasAVX2()) {

    SDValue BC1 = peekThroughBitcasts(V1);

    SDValue BC2 = peekThroughBitcasts(V2);

    bool SplatOrSplitV1 = isFreeToSplitVector(BC1, DAG) ||

                          DAG.isSplatValue(BC1, /*AllowUndefs=*/true);

    bool SplatOrSplitV2 = isFreeToSplitVector(BC2, DAG) ||

                          DAG.isSplatValue(BC2, /*AllowUndefs=*/true);

    if (SplatOrSplitV1 && SplatOrSplitV2)

      return splitAndLowerShuffle(DL, VT, V1, V2, Mask, DAG,

                                  /*SimpleOnly*/ false);

  }


  // Otherwise, just fall back to decomposed shuffles and a blend/unpack. This

  // requires that the decomposed single-input shuffles don't end up here.

  return lowerShuffleAsDecomposedShuffleMerge(DL, VT, V1, V2, Mask, Zeroable,

                                              Subtarget, DAG);

}


// Lower as SHUFPD(VPERM2F128(V1, V2), VPERM2F128(V1, V2)).

// TODO: Extend to support v8f32 (+ 512-bit shuffles).


static SDValue lowerShuffleAsLanePermuteAndSHUFP(const SDLoc &DL, MVT VT,

                                                 SDValue V1, SDValue V2,

                                                 ArrayRef<int> Mask,

                                                 SelectionDAG &DAG) {

  assert(VT == MVT::v4f64 && "Only for v4f64 shuffles");


  int LHSMask[4] = {-1, -1, -1, -1};

  int RHSMask[4] = {-1, -1, -1, -1};

  int SHUFPDMask[4] = {-1, -1, -1, -1};


  // As SHUFPD uses a single LHS/RHS element per lane, we can always

  // perform the shuffle once the lanes have been shuffled in place.

  for (int i = 0; i != 4; ++i) {

    int M = Mask[i];

    if (M < 0)

      continue;

    int LaneBase = i & ~1;

    auto &LaneMask = (i & 1) ? RHSMask : LHSMask;

    LaneMask[LaneBase + (M & 1)] = M;

    SHUFPDMask[i] = M & 1;

  }


  SDValue LHS = DAG.getVectorShuffle(VT, DL, V1, V2, LHSMask);

  SDValue RHS = DAG.getVectorShuffle(VT, DL, V1, V2, RHSMask);

  return DAG.getNode(X86ISD::SHUFP, DL, VT, LHS, RHS,

                     getSHUFPDImmForMask(SHUFPDMask, DL, DAG));

}


/// Lower a vector shuffle crossing multiple 128-bit lanes as

/// a lane permutation followed by a per-lane permutation.

///

/// This is mainly for cases where we can have non-repeating permutes

/// in each lane.

///

/// TODO: This is very similar to lowerShuffleAsLanePermuteAndRepeatedMask,

/// we should investigate merging them.


static SDValue lowerShuffleAsLanePermuteAndPermute(

    const SDLoc &DL, MVT VT, SDValue V1, SDValue V2, ArrayRef<int> Mask,

    SelectionDAG &DAG, const X86Subtarget &Subtarget) {

  int NumElts = VT.getVectorNumElements();

  int NumLanes = VT.getSizeInBits() / 128;

  int NumEltsPerLane = NumElts / NumLanes;

  bool CanUseSublanes = Subtarget.hasAVX2() && V2.isUndef();


  /// Attempts to find a sublane permute with the given size

  /// that gets all elements into their target lanes.

  ///

  /// If successful, fills CrossLaneMask and InLaneMask and returns true.

  /// If unsuccessful, returns false and may overwrite InLaneMask.

  auto getSublanePermute = [&](int NumSublanes) -> SDValue {

    int NumSublanesPerLane = NumSublanes / NumLanes;

    int NumEltsPerSublane = NumElts / NumSublanes;


    SmallVector<int, 16> CrossLaneMask;

    SmallVector<int, 16> InLaneMask(NumElts, SM_SentinelUndef);

    // CrossLaneMask but one entry == one sublane.

    SmallVector<int, 16> CrossLaneMaskLarge(NumSublanes, SM_SentinelUndef);

    APInt DemandedCrossLane = APInt::getZero(NumElts);


    for (int i = 0; i != NumElts; ++i) {

      int M = Mask[i];

      if (M < 0)

        continue;


      int SrcSublane = M / NumEltsPerSublane;

      int DstLane = i / NumEltsPerLane;


      // We only need to get the elements into the right lane, not sublane.

      // So search all sublanes that make up the destination lane.

      bool Found = false;

      int DstSubStart = DstLane * NumSublanesPerLane;

      int DstSubEnd = DstSubStart + NumSublanesPerLane;

      for (int DstSublane = DstSubStart; DstSublane < DstSubEnd; ++DstSublane) {

        if (!isUndefOrEqual(CrossLaneMaskLarge[DstSublane], SrcSublane))

          continue;


        Found = true;

        CrossLaneMaskLarge[DstSublane] = SrcSublane;

        int DstSublaneOffset = DstSublane * NumEltsPerSublane;

        InLaneMask[i] = DstSublaneOffset + M % NumEltsPerSublane;

        DemandedCrossLane.setBit(InLaneMask[i]);

        break;

      }

      if (!Found)

        return SDValue();

    }


    // Fill CrossLaneMask using CrossLaneMaskLarge.

    narrowShuffleMaskElts(NumEltsPerSublane, CrossLaneMaskLarge, CrossLaneMask);


    if (!CanUseSublanes) {

      // If we're only shuffling a single lowest lane and the rest are identity

      // then don't bother.

      // TODO - isShuffleMaskInputInPlace could be extended to something like

      // this.

      int NumIdentityLanes = 0;

      bool OnlyShuffleLowestLane = true;

      for (int i = 0; i != NumLanes; ++i) {

        int LaneOffset = i * NumEltsPerLane;

        if (isSequentialOrUndefInRange(InLaneMask, LaneOffset, NumEltsPerLane,

                                       i * NumEltsPerLane))

          NumIdentityLanes++;

        else if (CrossLaneMask[LaneOffset] != 0)

          OnlyShuffleLowestLane = false;

      }

      if (OnlyShuffleLowestLane && NumIdentityLanes == (NumLanes - 1))

        return SDValue();

    }


    // Simplify CrossLaneMask based on the actual demanded elements.

    if (V1.hasOneUse())

      for (int i = 0; i != NumElts; ++i)

        if (!DemandedCrossLane[i])

          CrossLaneMask[i] = SM_SentinelUndef;


    // Avoid returning the same shuffle operation. For example,

    // t7: v16i16 = vector_shuffle<8,9,10,11,4,5,6,7,0,1,2,3,12,13,14,15> t5,

    //                             undef:v16i16

    if (CrossLaneMask == Mask || InLaneMask == Mask)

      return SDValue();


    SDValue CrossLane = DAG.getVectorShuffle(VT, DL, V1, V2, CrossLaneMask);

    return DAG.getVectorShuffle(VT, DL, CrossLane, DAG.getUNDEF(VT),

                                InLaneMask);

  };


  // First attempt a solution with full lanes.

  if (SDValue V = getSublanePermute(/*NumSublanes=*/NumLanes))

    return V;


  // The rest of the solutions use sublanes.

  if (!CanUseSublanes)

    return SDValue();


  // Then attempt a solution with 64-bit sublanes (vpermq).

  if (SDValue V = getSublanePermute(/*NumSublanes=*/NumLanes * 2))

    return V;


  // If that doesn't work and we have fast variable cross-lane shuffle,

  // attempt 32-bit sublanes (vpermd).

  if (!Subtarget.hasFastVariableCrossLaneShuffle())

    return SDValue();


  return getSublanePermute(/*NumSublanes=*/NumLanes * 4);

}


/// Helper to get compute inlane shuffle mask for a complete shuffle mask.


static void computeInLaneShuffleMask(const ArrayRef<int> &Mask, int LaneSize,

                                     SmallVector<int> &InLaneMask) {

  int Size = Mask.size();

  InLaneMask.assign(Mask.begin(), Mask.end());

  for (int i = 0; i < Size; ++i) {

    int &M = InLaneMask[i];

    if (M < 0)

      continue;

    if (((M % Size) / LaneSize) != (i / LaneSize))

      M = (M % LaneSize) + ((i / LaneSize) * LaneSize) + Size;

  }

}


/// Lower a vector shuffle crossing multiple 128-bit lanes by shuffling one

/// source with a lane permutation.

///

/// This lowering strategy results in four instructions in the worst case for a

/// single-input cross lane shuffle which is lower than any other fully general

/// cross-lane shuffle strategy I'm aware of. Special cases for each particular

/// shuffle pattern should be handled prior to trying this lowering.


static SDValue lowerShuffleAsLanePermuteAndShuffle(

    const SDLoc &DL, MVT VT, SDValue V1, SDValue V2, ArrayRef<int> Mask,

    SelectionDAG &DAG, const X86Subtarget &Subtarget) {

  // FIXME: This should probably be generalized for 512-bit vectors as well.

  assert(VT.is256BitVector() && "Only for 256-bit vector shuffles!");

  int Size = Mask.size();

  int LaneSize = Size / 2;


  // Fold to SHUFPD(VPERM2F128(V1, V2), VPERM2F128(V1, V2)).

  // Only do this if the elements aren't all from the lower lane,

  // otherwise we're (probably) better off doing a split.

  if (VT == MVT::v4f64 &&

      !all_of(Mask, [LaneSize](int M) { return M < LaneSize; }))

    return lowerShuffleAsLanePermuteAndSHUFP(DL, VT, V1, V2, Mask, DAG);


  // If there are only inputs from one 128-bit lane, splitting will in fact be

  // less expensive. The flags track whether the given lane contains an element

  // that crosses to another lane.

  bool AllLanes;

  if (!Subtarget.hasAVX2()) {

    bool LaneCrossing[2] = {false, false};

    for (int i = 0; i < Size; ++i)

      if (Mask[i] >= 0 && ((Mask[i] % Size) / LaneSize) != (i / LaneSize))

        LaneCrossing[(Mask[i] % Size) / LaneSize] = true;

    AllLanes = LaneCrossing[0] && LaneCrossing[1];

  } else {

    bool LaneUsed[2] = {false, false};

    for (int i = 0; i < Size; ++i)

      if (Mask[i] >= 0)

        LaneUsed[(Mask[i] % Size) / LaneSize] = true;

    AllLanes = LaneUsed[0] && LaneUsed[1];

  }


  // TODO - we could support shuffling V2 in the Flipped input.

  assert(V2.isUndef() &&

         "This last part of this routine only works on single input shuffles");


  SmallVector<int> InLaneMask;

  computeInLaneShuffleMask(Mask, Mask.size() / 2, InLaneMask);


  assert(!is128BitLaneCrossingShuffleMask(VT, InLaneMask) &&

         "In-lane shuffle mask expected");


  // If we're not using both lanes in each lane and the inlane mask is not

  // repeating, then we're better off splitting.

  if (!AllLanes && !is128BitLaneRepeatedShuffleMask(VT, InLaneMask))

    return splitAndLowerShuffle(DL, VT, V1, V2, Mask, DAG,

                                /*SimpleOnly*/ false);


  // Flip the lanes, and shuffle the results which should now be in-lane.

  MVT PVT = VT.isFloatingPoint() ? MVT::v4f64 : MVT::v4i64;

  SDValue Flipped = DAG.getBitcast(PVT, V1);

  Flipped =

      DAG.getVectorShuffle(PVT, DL, Flipped, DAG.getUNDEF(PVT), {2, 3, 0, 1});

  Flipped = DAG.getBitcast(VT, Flipped);

  return DAG.getVectorShuffle(VT, DL, V1, Flipped, InLaneMask);

}


/// Handle lowering 2-lane 128-bit shuffles.


static SDValue lowerV2X128Shuffle(const SDLoc &DL, MVT VT, SDValue V1,

                                  SDValue V2, ArrayRef<int> Mask,

                                  const APInt &Zeroable,

                                  const X86Subtarget &Subtarget,

                                  SelectionDAG &DAG) {

  if (V2.isUndef()) {

    // Attempt to match VBROADCAST*128 subvector broadcast load.

    bool SplatLo = isShuffleEquivalent(Mask, {0, 1, 0, 1}, V1);

    bool SplatHi = isShuffleEquivalent(Mask, {2, 3, 2, 3}, V1);

    if ((SplatLo || SplatHi) && !Subtarget.hasAVX512() && V1.hasOneUse() &&

        X86::mayFoldLoad(peekThroughOneUseBitcasts(V1), Subtarget)) {

      MVT MemVT = VT.getHalfNumVectorElementsVT();

      unsigned Ofs = SplatLo ? 0 : MemVT.getStoreSize();

      auto *Ld = cast<LoadSDNode>(peekThroughOneUseBitcasts(V1));

      if (SDValue BcstLd = getBROADCAST_LOAD(X86ISD::SUBV_BROADCAST_LOAD, DL,

                                             VT, MemVT, Ld, Ofs, DAG))

        return BcstLd;

    }


    // With AVX2, use VPERMQ/VPERMPD for unary shuffles to allow memory folding.

    if (Subtarget.hasAVX2())

      return SDValue();

  }


  bool V2IsZero = !V2.isUndef() && ISD::isBuildVectorAllZeros(V2.getNode());


  SmallVector<int, 4> WidenedMask;

  if (!canWidenShuffleElements(Mask, Zeroable, V2IsZero, WidenedMask))

    return SDValue();


  bool IsLowZero = (Zeroable & 0x3) == 0x3;

  bool IsHighZero = (Zeroable & 0xc) == 0xc;


  // Try to use an insert into a zero vector.

  if (WidenedMask[0] == 0 && IsHighZero) {

    MVT SubVT = MVT::getVectorVT(VT.getVectorElementType(), 2);

    SDValue LoV = DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, SubVT, V1,

                              DAG.getVectorIdxConstant(0, DL));

    return DAG.getNode(ISD::INSERT_SUBVECTOR, DL, VT,

                       getZeroVector(VT, Subtarget, DAG, DL), LoV,

                       DAG.getVectorIdxConstant(0, DL));

  }


  // TODO: If minimizing size and one of the inputs is a zero vector and the

  // the zero vector has only one use, we could use a VPERM2X128 to save the

  // instruction bytes needed to explicitly generate the zero vector.


  // Blends are faster and handle all the non-lane-crossing cases.

  if (SDValue Blend = lowerShuffleAsBlend(DL, VT, V1, V2, Mask, Zeroable,

                                          Subtarget, DAG))

    return Blend;


  // If either input operand is a zero vector, use VPERM2X128 because its mask

  // allows us to replace the zero input with an implicit zero.

  if (!IsLowZero && !IsHighZero) {

    // Check for patterns which can be matched with a single insert of a 128-bit

    // subvector.

    bool OnlyUsesV1 = isShuffleEquivalent(Mask, {0, 1, 0, 1}, V1, V2);

    if (OnlyUsesV1 || isShuffleEquivalent(Mask, {0, 1, 4, 5}, V1, V2)) {


      // With AVX1, use vperm2f128 (below) to allow load folding. Otherwise,

      // this will likely become vinsertf128 which can't fold a 256-bit memop.

      if (!isa<LoadSDNode>(peekThroughBitcasts(V1))) {

        MVT SubVT = MVT::getVectorVT(VT.getVectorElementType(), 2);

        SDValue SubVec =

            DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, SubVT, OnlyUsesV1 ? V1 : V2,

                        DAG.getVectorIdxConstant(0, DL));

        return DAG.getNode(ISD::INSERT_SUBVECTOR, DL, VT, V1, SubVec,

                           DAG.getVectorIdxConstant(2, DL));

      }

    }


    // Try to use SHUF128 if possible.

    if (Subtarget.hasVLX()) {

      if (WidenedMask[0] < 2 && WidenedMask[1] >= 2) {

        unsigned PermMask = ((WidenedMask[0] % 2) << 0) |

                            ((WidenedMask[1] % 2) << 1);

        return DAG.getNode(X86ISD::SHUF128, DL, VT, V1, V2,

                           DAG.getTargetConstant(PermMask, DL, MVT::i8));

      }

    }

  }


  // Otherwise form a 128-bit permutation. After accounting for undefs,

  // convert the 64-bit shuffle mask selection values into 128-bit

  // selection bits by dividing the indexes by 2 and shifting into positions

  // defined by a vperm2*128 instruction's immediate control byte.


  // The immediate permute control byte looks like this:

  //    [1:0] - select 128 bits from sources for low half of destination

  //    [2]   - ignore

  //    [3]   - zero low half of destination

  //    [5:4] - select 128 bits from sources for high half of destination

  //    [6]   - ignore

  //    [7]   - zero high half of destination


  assert((WidenedMask[0] >= 0 || IsLowZero) &&

         (WidenedMask[1] >= 0 || IsHighZero) && "Undef half?");


  unsigned PermMask = 0;

  PermMask |= IsLowZero  ? 0x08 : (WidenedMask[0] << 0);

  PermMask |= IsHighZero ? 0x80 : (WidenedMask[1] << 4);


  // Check the immediate mask and replace unused sources with undef.

  if ((PermMask & 0x0a) != 0x00 && (PermMask & 0xa0) != 0x00)

    V1 = DAG.getUNDEF(VT);

  if ((PermMask & 0x0a) != 0x02 && (PermMask & 0xa0) != 0x20)

    V2 = DAG.getUNDEF(VT);


  return DAG.getNode(X86ISD::VPERM2X128, DL, VT, V1, V2,

                     DAG.getTargetConstant(PermMask, DL, MVT::i8));

}


/// Lower a vector shuffle by first fixing the 128-bit lanes and then

/// shuffling each lane.

///

/// This attempts to create a repeated lane shuffle where each lane uses one

/// or two of the lanes of the inputs. The lanes of the input vectors are

/// shuffled in one or two independent shuffles to get the lanes into the

/// position needed by the final shuffle.


static SDValue lowerShuffleAsLanePermuteAndRepeatedMask(

    const SDLoc &DL, MVT VT, SDValue V1, SDValue V2, ArrayRef<int> Mask,

    const X86Subtarget &Subtarget, SelectionDAG &DAG) {

  // This is only useful for binary shuffle with a non-repeating mask.

  if (V2.isUndef() || is128BitLaneRepeatedShuffleMask(VT, Mask))

    return SDValue();


  int NumElts = Mask.size();

  int NumLanes = VT.getSizeInBits() / 128;

  int NumLaneElts = 128 / VT.getScalarSizeInBits();

  SmallVector<int, 16> RepeatMask(NumLaneElts, -1);

  SmallVector<std::array<int, 2>, 2> LaneSrcs(NumLanes, {{-1, -1}});


  // First pass will try to fill in the RepeatMask from lanes that need two

  // sources.

  for (int Lane = 0; Lane != NumLanes; ++Lane) {

    int Srcs[2] = {-1, -1};

    SmallVector<int, 16> InLaneMask(NumLaneElts, -1);

    for (int i = 0; i != NumLaneElts; ++i) {

      int M = Mask[(Lane * NumLaneElts) + i];

      if (M < 0)

        continue;

      // Determine which of the possible input lanes (NumLanes from each source)

      // this element comes from. Assign that as one of the sources for this

      // lane. We can assign up to 2 sources for this lane. If we run out

      // sources we can't do anything.

      int LaneSrc = M / NumLaneElts;

      int Src;

      if (Srcs[0] < 0 || Srcs[0] == LaneSrc)

        Src = 0;

      else if (Srcs[1] < 0 || Srcs[1] == LaneSrc)

        Src = 1;

      else

        return SDValue();


      Srcs[Src] = LaneSrc;

      InLaneMask[i] = (M % NumLaneElts) + Src * NumElts;

    }


    // If this lane has two sources, see if it fits with the repeat mask so far.

    if (Srcs[1] < 0)

      continue;


    LaneSrcs[Lane][0] = Srcs[0];

    LaneSrcs[Lane][1] = Srcs[1];


    auto MatchMasks = [](ArrayRef<int> M1, ArrayRef<int> M2) {

      assert(M1.size() == M2.size() && "Unexpected mask size");

      for (int i = 0, e = M1.size(); i != e; ++i)

        if (M1[i] >= 0 && M2[i] >= 0 && M1[i] != M2[i])

          return false;

      return true;

    };


    auto MergeMasks = [](ArrayRef<int> Mask, MutableArrayRef<int> MergedMask) {

      assert(Mask.size() == MergedMask.size() && "Unexpected mask size");

      for (int i = 0, e = MergedMask.size(); i != e; ++i) {

        int M = Mask[i];

        if (M < 0)

          continue;

        assert((MergedMask[i] < 0 || MergedMask[i] == M) &&

               "Unexpected mask element");

        MergedMask[i] = M;

      }

    };


    if (MatchMasks(InLaneMask, RepeatMask)) {

      // Merge this lane mask into the final repeat mask.

      MergeMasks(InLaneMask, RepeatMask);

      continue;

    }


    // Didn't find a match. Swap the operands and try again.

    std::swap(LaneSrcs[Lane][0], LaneSrcs[Lane][1]);

    ShuffleVectorSDNode::commuteMask(InLaneMask);


    if (MatchMasks(InLaneMask, RepeatMask)) {

      // Merge this lane mask into the final repeat mask.

      MergeMasks(InLaneMask, RepeatMask);

      continue;

    }


    // Couldn't find a match with the operands in either order.

    return SDValue();

  }


  // Now handle any lanes with only one source.

  for (int Lane = 0; Lane != NumLanes; ++Lane) {

    // If this lane has already been processed, skip it.

    if (LaneSrcs[Lane][0] >= 0)

      continue;


    for (int i = 0; i != NumLaneElts; ++i) {

      int M = Mask[(Lane * NumLaneElts) + i];

      if (M < 0)

        continue;


      // If RepeatMask isn't defined yet we can define it ourself.

      if (RepeatMask[i] < 0)

        RepeatMask[i] = M % NumLaneElts;


      if (RepeatMask[i] < NumElts) {

        if (RepeatMask[i] != M % NumLaneElts)

          return SDValue();

        LaneSrcs[Lane][0] = M / NumLaneElts;

      } else {

        if (RepeatMask[i] != ((M % NumLaneElts) + NumElts))

          return SDValue();

        LaneSrcs[Lane][1] = M / NumLaneElts;

      }

    }


    if (LaneSrcs[Lane][0] < 0 && LaneSrcs[Lane][1] < 0)

      return SDValue();

  }


  SmallVector<int, 16> NewMask(NumElts, -1);

  for (int Lane = 0; Lane != NumLanes; ++Lane) {

    int Src = LaneSrcs[Lane][0];

    for (int i = 0; i != NumLaneElts; ++i) {

      int M = -1;

      if (Src >= 0)

        M = Src * NumLaneElts + i;

      NewMask[Lane * NumLaneElts + i] = M;

    }

  }

  SDValue NewV1 = DAG.getVectorShuffle(VT, DL, V1, V2, NewMask);

  // Ensure we didn't get back the shuffle we started with.

  // FIXME: This is a hack to make up for some splat handling code in

  // getVectorShuffle.

  if (isa<ShuffleVectorSDNode>(NewV1) &&

      cast<ShuffleVectorSDNode>(NewV1)->getMask() == Mask)

    return SDValue();


  for (int Lane = 0; Lane != NumLanes; ++Lane) {

    int Src = LaneSrcs[Lane][1];

    for (int i = 0; i != NumLaneElts; ++i) {

      int M = -1;

      if (Src >= 0)

        M = Src * NumLaneElts + i;

      NewMask[Lane * NumLaneElts + i] = M;

    }

  }

  SDValue NewV2 = DAG.getVectorShuffle(VT, DL, V1, V2, NewMask);

  // Ensure we didn't get back the shuffle we started with.

  // FIXME: This is a hack to make up for some splat handling code in

  // getVectorShuffle.

  if (isa<ShuffleVectorSDNode>(NewV2) &&

      cast<ShuffleVectorSDNode>(NewV2)->getMask() == Mask)

    return SDValue();


  for (int i = 0; i != NumElts; ++i) {

    if (Mask[i] < 0) {

      NewMask[i] = -1;

      continue;

    }

    NewMask[i] = RepeatMask[i % NumLaneElts];

    if (NewMask[i] < 0)

      continue;


    NewMask[i] += (i / NumLaneElts) * NumLaneElts;

  }

  return DAG.getVectorShuffle(VT, DL, NewV1, NewV2, NewMask);

}


/// If the input shuffle mask results in a vector that is undefined in all upper

/// or lower half elements and that mask accesses only 2 halves of the

/// shuffle's operands, return true. A mask of half the width with mask indexes

/// adjusted to access the extracted halves of the original shuffle operands is

/// returned in HalfMask. HalfIdx1 and HalfIdx2 return whether the upper or

/// lower half of each input operand is accessed.

static bool


getHalfShuffleMask(ArrayRef<int> Mask, MutableArrayRef<int> HalfMask,

                   int &HalfIdx1, int &HalfIdx2) {

  assert((Mask.size() == HalfMask.size() * 2) &&

         "Expected input mask to be twice as long as output");


  // Exactly one half of the result must be undef to allow narrowing.

  bool UndefLower = isUndefLowerHalf(Mask);

  bool UndefUpper = isUndefUpperHalf(Mask);

  if (UndefLower == UndefUpper)

    return false;


  unsigned HalfNumElts = HalfMask.size();

  unsigned MaskIndexOffset = UndefLower ? HalfNumElts : 0;

  HalfIdx1 = -1;

  HalfIdx2 = -1;

  for (unsigned i = 0; i != HalfNumElts; ++i) {

    int M = Mask[i + MaskIndexOffset];

    if (M < 0) {

      HalfMask[i] = M;

      continue;

    }


    // Determine which of the 4 half vectors this element is from.

    // i.e. 0 = Lower V1, 1 = Upper V1, 2 = Lower V2, 3 = Upper V2.

    int HalfIdx = M / HalfNumElts;


    // Determine the element index into its half vector source.

    int HalfElt = M % HalfNumElts;


    // We can shuffle with up to 2 half vectors, set the new 'half'

    // shuffle mask accordingly.

    if (HalfIdx1 < 0 || HalfIdx1 == HalfIdx) {

      HalfMask[i] = HalfElt;

      HalfIdx1 = HalfIdx;

      continue;

    }

    if (HalfIdx2 < 0 || HalfIdx2 == HalfIdx) {

      HalfMask[i] = HalfElt + HalfNumElts;

      HalfIdx2 = HalfIdx;

      continue;

    }


    // Too many half vectors referenced.

    return false;

  }


  return true;

}


/// Given the output values from getHalfShuffleMask(), create a half width

/// shuffle of extracted vectors followed by an insert back to full width.


static SDValue getShuffleHalfVectors(const SDLoc &DL, SDValue V1, SDValue V2,

                                     ArrayRef<int> HalfMask, int HalfIdx1,

                                     int HalfIdx2, bool UndefLower,

                                     SelectionDAG &DAG, bool UseConcat = false) {

  assert(V1.getValueType() == V2.getValueType() && "Different sized vectors?");

  assert(V1.getValueType().isSimple() && "Expecting only simple types");


  MVT VT = V1.getSimpleValueType();

  MVT HalfVT = VT.getHalfNumVectorElementsVT();

  unsigned HalfNumElts = HalfVT.getVectorNumElements();


  auto getHalfVector = [&](int HalfIdx) {

    if (HalfIdx < 0)

      return DAG.getUNDEF(HalfVT);

    SDValue V = (HalfIdx < 2 ? V1 : V2);

    HalfIdx = (HalfIdx % 2) * HalfNumElts;

    return DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, HalfVT, V,

                       DAG.getVectorIdxConstant(HalfIdx, DL));

  };


  // ins undef, (shuf (ext V1, HalfIdx1), (ext V2, HalfIdx2), HalfMask), Offset

  SDValue Half1 = getHalfVector(HalfIdx1);

  SDValue Half2 = getHalfVector(HalfIdx2);

  SDValue V = DAG.getVectorShuffle(HalfVT, DL, Half1, Half2, HalfMask);

  if (UseConcat) {

    SDValue Op0 = V;

    SDValue Op1 = DAG.getUNDEF(HalfVT);

    if (UndefLower)

      std::swap(Op0, Op1);

    return DAG.getNode(ISD::CONCAT_VECTORS, DL, VT, Op0, Op1);

  }


  unsigned Offset = UndefLower ? HalfNumElts : 0;

  return DAG.getNode(ISD::INSERT_SUBVECTOR, DL, VT, DAG.getUNDEF(VT), V,

                     DAG.getVectorIdxConstant(Offset, DL));

}


/// Lower shuffles where an entire half of a 256 or 512-bit vector is UNDEF.

/// This allows for fast cases such as subvector extraction/insertion

/// or shuffling smaller vector types which can lower more efficiently.


static SDValue lowerShuffleWithUndefHalf(const SDLoc &DL, MVT VT, SDValue V1,

                                         SDValue V2, ArrayRef<int> Mask,

                                         const X86Subtarget &Subtarget,

                                         SelectionDAG &DAG) {

  assert((VT.is256BitVector() || VT.is512BitVector()) &&

         "Expected 256-bit or 512-bit vector");


  bool UndefLower = isUndefLowerHalf(Mask);

  if (!UndefLower && !isUndefUpperHalf(Mask))

    return SDValue();


  assert((!UndefLower || !isUndefUpperHalf(Mask)) &&

         "Completely undef shuffle mask should have been simplified already");


  // Upper half is undef and lower half is whole upper subvector.

  // e.g. vector_shuffle <4, 5, 6, 7, u, u, u, u> or <2, 3, u, u>

  MVT HalfVT = VT.getHalfNumVectorElementsVT();

  unsigned HalfNumElts = HalfVT.getVectorNumElements();

  if (!UndefLower &&

      isSequentialOrUndefInRange(Mask, 0, HalfNumElts, HalfNumElts)) {

    SDValue Hi = DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, HalfVT, V1,

                             DAG.getVectorIdxConstant(HalfNumElts, DL));

    return DAG.getNode(ISD::INSERT_SUBVECTOR, DL, VT, DAG.getUNDEF(VT), Hi,

                       DAG.getVectorIdxConstant(0, DL));

  }


  // Lower half is undef and upper half is whole lower subvector.

  // e.g. vector_shuffle <u, u, u, u, 0, 1, 2, 3> or <u, u, 0, 1>

  if (UndefLower &&

      isSequentialOrUndefInRange(Mask, HalfNumElts, HalfNumElts, 0)) {

    SDValue Hi = DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, HalfVT, V1,

                             DAG.getVectorIdxConstant(0, DL));

    return DAG.getNode(ISD::INSERT_SUBVECTOR, DL, VT, DAG.getUNDEF(VT), Hi,

                       DAG.getVectorIdxConstant(HalfNumElts, DL));

  }


  int HalfIdx1, HalfIdx2;

  SmallVector<int, 8> HalfMask(HalfNumElts);

  if (!getHalfShuffleMask(Mask, HalfMask, HalfIdx1, HalfIdx2))

    return SDValue();


  assert(HalfMask.size() == HalfNumElts && "Unexpected shuffle mask length");


  // Only shuffle the halves of the inputs when useful.

  unsigned NumLowerHalves =

      (HalfIdx1 == 0 || HalfIdx1 == 2) + (HalfIdx2 == 0 || HalfIdx2 == 2);

  unsigned NumUpperHalves =

      (HalfIdx1 == 1 || HalfIdx1 == 3) + (HalfIdx2 == 1 || HalfIdx2 == 3);

  assert(NumLowerHalves + NumUpperHalves <= 2 && "Only 1 or 2 halves allowed");


  // Determine the larger pattern of undef/halves, then decide if it's worth

  // splitting the shuffle based on subtarget capabilities and types.

  unsigned EltWidth = VT.getVectorElementType().getSizeInBits();

  if (!UndefLower) {

    // XXXXuuuu: no insert is needed.

    // Always extract lowers when setting lower - these are all free subreg ops.

    if (NumUpperHalves == 0)

      return getShuffleHalfVectors(DL, V1, V2, HalfMask, HalfIdx1, HalfIdx2,

                                   UndefLower, DAG);


    if (NumUpperHalves == 1) {

      // AVX2 has efficient 32/64-bit element cross-lane shuffles.

      if (Subtarget.hasAVX2()) {

        // extract128 + vunpckhps/vshufps, is better than vblend + vpermps.

        if (EltWidth == 32 && NumLowerHalves && HalfVT.is128BitVector() &&

            !is128BitUnpackShuffleMask(HalfMask, DAG) &&

            (!isSingleSHUFPSMask(HalfMask) ||

             Subtarget.hasFastVariableCrossLaneShuffle()))

          return SDValue();

        // If this is an unary shuffle (assume that the 2nd operand is

        // canonicalized to undef), then we can use vpermpd. Otherwise, we

        // are better off extracting the upper half of 1 operand and using a

        // narrow shuffle.

        if (EltWidth == 64 && V2.isUndef())

          return SDValue();

        // If this is an unary vXi8 shuffle with inplace halves, then perform as

        // full width pshufb, and then merge.

        if (EltWidth == 8 && HalfIdx1 == 0 && HalfIdx2 == 1)

          return SDValue();

      }

      // AVX512 has efficient cross-lane shuffles for all legal 512-bit types.

      if (Subtarget.hasAVX512() && VT.is512BitVector())

        return SDValue();

      // Extract + narrow shuffle is better than the wide alternative.

      return getShuffleHalfVectors(DL, V1, V2, HalfMask, HalfIdx1, HalfIdx2,

                                   UndefLower, DAG);

    }


    // Don't extract both uppers, instead shuffle and then extract.

    assert(NumUpperHalves == 2 && "Half vector count went wrong");

    return SDValue();

  }


  // UndefLower - uuuuXXXX: an insert to high half is required if we split this.

  if (NumUpperHalves == 0) {

    // AVX2 has efficient 64-bit element cross-lane shuffles.

    // TODO: Refine to account for unary shuffle, splat, and other masks?

    if (Subtarget.hasAVX2() && EltWidth == 64)

      return SDValue();

    // AVX512 has efficient cross-lane shuffles for all legal 512-bit types.

    if (Subtarget.hasAVX512() && VT.is512BitVector())

      return SDValue();

    // Narrow shuffle + insert is better than the wide alternative.

    return getShuffleHalfVectors(DL, V1, V2, HalfMask, HalfIdx1, HalfIdx2,

                                 UndefLower, DAG);

  }


  // NumUpperHalves != 0: don't bother with extract, shuffle, and then insert.

  return SDValue();

}


/// Handle case where shuffle sources are coming from the same 128-bit lane and

/// every lane can be represented as the same repeating mask - allowing us to

/// shuffle the sources with the repeating shuffle and then permute the result

/// to the destination lanes.


static SDValue lowerShuffleAsRepeatedMaskAndLanePermute(

    const SDLoc &DL, MVT VT, SDValue V1, SDValue V2, ArrayRef<int> Mask,

    const X86Subtarget &Subtarget, SelectionDAG &DAG) {

  int NumElts = VT.getVectorNumElements();

  int NumLanes = VT.getSizeInBits() / 128;

  int NumLaneElts = NumElts / NumLanes;


  // On AVX2 we may be able to just shuffle the lowest elements and then

  // broadcast the result.

  if (Subtarget.hasAVX2()) {

    for (unsigned BroadcastSize : {16, 32, 64}) {

      if (BroadcastSize <= VT.getScalarSizeInBits())

        continue;

      int NumBroadcastElts = BroadcastSize / VT.getScalarSizeInBits();


      // Attempt to match a repeating pattern every NumBroadcastElts,

      // accounting for UNDEFs but only references the lowest 128-bit

      // lane of the inputs.

      auto FindRepeatingBroadcastMask = [&](SmallVectorImpl<int> &RepeatMask) {

        for (int i = 0; i != NumElts; i += NumBroadcastElts)

          for (int j = 0; j != NumBroadcastElts; ++j) {

            int M = Mask[i + j];

            if (M < 0)

              continue;

            int &R = RepeatMask[j];

            if (0 != ((M % NumElts) / NumLaneElts))

              return false;

            if (0 <= R && R != M)

              return false;

            R = M;

          }

        return true;

      };


      SmallVector<int, 8> RepeatMask((unsigned)NumElts, -1);

      if (!FindRepeatingBroadcastMask(RepeatMask))

        continue;


      // Shuffle the (lowest) repeated elements in place for broadcast.

      SDValue RepeatShuf = DAG.getVectorShuffle(VT, DL, V1, V2, RepeatMask);


      // Shuffle the actual broadcast.

      SmallVector<int, 8> BroadcastMask((unsigned)NumElts, -1);

      for (int i = 0; i != NumElts; i += NumBroadcastElts)

        for (int j = 0; j != NumBroadcastElts; ++j)

          BroadcastMask[i + j] = j;


      // Avoid returning the same shuffle operation. For example,

      // v8i32 = vector_shuffle<0,1,0,1,0,1,0,1> t5, undef:v8i32

      if (BroadcastMask == Mask)

        return SDValue();


      return DAG.getVectorShuffle(VT, DL, RepeatShuf, DAG.getUNDEF(VT),

                                  BroadcastMask);

    }

  }


  // Bail if the shuffle mask doesn't cross 128-bit lanes.

  if (!is128BitLaneCrossingShuffleMask(VT, Mask))

    return SDValue();


  // Bail if we already have a repeated lane shuffle mask.

  if (is128BitLaneRepeatedShuffleMask(VT, Mask))

    return SDValue();


  // Helper to look for repeated mask in each split sublane, and that those

  // sublanes can then be permuted into place.

  auto ShuffleSubLanes = [&](int SubLaneScale) {

    int NumSubLanes = NumLanes * SubLaneScale;

    int NumSubLaneElts = NumLaneElts / SubLaneScale;


    // Check that all the sources are coming from the same lane and see if we

    // can form a repeating shuffle mask (local to each sub-lane). At the same

    // time, determine the source sub-lane for each destination sub-lane.

    int TopSrcSubLane = -1;

    SmallVector<int, 8> Dst2SrcSubLanes((unsigned)NumSubLanes, -1);

    SmallVector<SmallVector<int, 8>> RepeatedSubLaneMasks(

        SubLaneScale,

        SmallVector<int, 8>((unsigned)NumSubLaneElts, SM_SentinelUndef));


    for (int DstSubLane = 0; DstSubLane != NumSubLanes; ++DstSubLane) {

      // Extract the sub-lane mask, check that it all comes from the same lane

      // and normalize the mask entries to come from the first lane.

      int SrcLane = -1;

      SmallVector<int, 8> SubLaneMask((unsigned)NumSubLaneElts, -1);

      for (int Elt = 0; Elt != NumSubLaneElts; ++Elt) {

        int M = Mask[(DstSubLane * NumSubLaneElts) + Elt];

        if (M < 0)

          continue;

        int Lane = (M % NumElts) / NumLaneElts;

        if ((0 <= SrcLane) && (SrcLane != Lane))

          return SDValue();

        SrcLane = Lane;

        int LocalM = (M % NumLaneElts) + (M < NumElts ? 0 : NumElts);

        SubLaneMask[Elt] = LocalM;

      }


      // Whole sub-lane is UNDEF.

      if (SrcLane < 0)

        continue;


      // Attempt to match against the candidate repeated sub-lane masks.

      for (int SubLane = 0; SubLane != SubLaneScale; ++SubLane) {

        auto MatchMasks = [NumSubLaneElts](ArrayRef<int> M1, ArrayRef<int> M2) {

          for (int i = 0; i != NumSubLaneElts; ++i) {

            if (M1[i] < 0 || M2[i] < 0)

              continue;

            if (M1[i] != M2[i])

              return false;

          }

          return true;

        };


        auto &RepeatedSubLaneMask = RepeatedSubLaneMasks[SubLane];

        if (!MatchMasks(SubLaneMask, RepeatedSubLaneMask))

          continue;


        // Merge the sub-lane mask into the matching repeated sub-lane mask.

        for (int i = 0; i != NumSubLaneElts; ++i) {

          int M = SubLaneMask[i];

          if (M < 0)

            continue;

          assert((RepeatedSubLaneMask[i] < 0 || RepeatedSubLaneMask[i] == M) &&

                 "Unexpected mask element");

          RepeatedSubLaneMask[i] = M;

        }


        // Track the top most source sub-lane - by setting the remaining to

        // UNDEF we can greatly simplify shuffle matching.

        int SrcSubLane = (SrcLane * SubLaneScale) + SubLane;

        TopSrcSubLane = std::max(TopSrcSubLane, SrcSubLane);

        Dst2SrcSubLanes[DstSubLane] = SrcSubLane;

        break;

      }


      // Bail if we failed to find a matching repeated sub-lane mask.

      if (Dst2SrcSubLanes[DstSubLane] < 0)

        return SDValue();

    }

    assert(0 <= TopSrcSubLane && TopSrcSubLane < NumSubLanes &&

           "Unexpected source lane");


    // Create a repeating shuffle mask for the entire vector.

    SmallVector<int, 8> RepeatedMask((unsigned)NumElts, -1);

    for (int SubLane = 0; SubLane <= TopSrcSubLane; ++SubLane) {

      int Lane = SubLane / SubLaneScale;

      auto &RepeatedSubLaneMask = RepeatedSubLaneMasks[SubLane % SubLaneScale];

      for (int Elt = 0; Elt != NumSubLaneElts; ++Elt) {

        int M = RepeatedSubLaneMask[Elt];

        if (M < 0)

          continue;

        int Idx = (SubLane * NumSubLaneElts) + Elt;

        RepeatedMask[Idx] = M + (Lane * NumLaneElts);

      }

    }


    // Shuffle each source sub-lane to its destination.

    SmallVector<int, 8> SubLaneMask((unsigned)NumElts, -1);

    for (int i = 0; i != NumElts; i += NumSubLaneElts) {

      int SrcSubLane = Dst2SrcSubLanes[i / NumSubLaneElts];

      if (SrcSubLane < 0)

        continue;

      for (int j = 0; j != NumSubLaneElts; ++j)

        SubLaneMask[i + j] = j + (SrcSubLane * NumSubLaneElts);

    }


    // Avoid returning the same shuffle operation.

    // v8i32 = vector_shuffle<0,1,4,5,2,3,6,7> t5, undef:v8i32

    if (RepeatedMask == Mask || SubLaneMask == Mask)

      return SDValue();


    SDValue RepeatedShuffle =

        DAG.getVectorShuffle(VT, DL, V1, V2, RepeatedMask);


    return DAG.getVectorShuffle(VT, DL, RepeatedShuffle, DAG.getUNDEF(VT),

                                SubLaneMask);

  };


  // On AVX2 targets we can permute 256-bit vectors as 64-bit sub-lanes

  // (with PERMQ/PERMPD). On AVX2/AVX512BW targets, permuting 32-bit sub-lanes,

  // even with a variable shuffle, can be worth it for v32i8/v64i8 vectors.

  // Otherwise we can only permute whole 128-bit lanes.

  int MinSubLaneScale = 1, MaxSubLaneScale = 1;

  if (Subtarget.hasAVX2() && VT.is256BitVector()) {

    bool OnlyLowestElts = isUndefOrInRange(Mask, 0, NumLaneElts);

    MinSubLaneScale = 2;

    MaxSubLaneScale =

        (!OnlyLowestElts && V2.isUndef() && VT == MVT::v32i8) ? 4 : 2;

  }

  if (Subtarget.hasBWI() && VT == MVT::v64i8)

    MinSubLaneScale = MaxSubLaneScale = 4;


  for (int Scale = MinSubLaneScale; Scale <= MaxSubLaneScale; Scale *= 2)

    if (SDValue Shuffle = ShuffleSubLanes(Scale))

      return Shuffle;


  return SDValue();

}


static bool matchShuffleWithSHUFPD(MVT VT, SDValue &V1, SDValue &V2,

                                   bool &ForceV1Zero, bool &ForceV2Zero,

                                   unsigned &ShuffleImm, ArrayRef<int> Mask,

                                   const APInt &Zeroable) {

  int NumElts = VT.getVectorNumElements();

  assert(VT.getScalarSizeInBits() == 64 &&

         (NumElts == 2 || NumElts == 4 || NumElts == 8) &&

         "Unexpected data type for VSHUFPD");

  assert(isUndefOrZeroOrInRange(Mask, 0, 2 * NumElts) &&

         "Illegal shuffle mask");


  bool ZeroLane[2] = { true, true };

  for (int i = 0; i < NumElts; ++i)

    ZeroLane[i & 1] &= Zeroable[i];


  // Mask for V8F64: 0/1,  8/9,  2/3,  10/11, 4/5, ..

  // Mask for V4F64; 0/1,  4/5,  2/3,  6/7..

  bool IsSHUFPD = true;

  bool IsCommutable = true;

  SmallVector<int, 8> SHUFPDMask(NumElts, -1);

  for (int i = 0; i < NumElts; ++i) {

    if (Mask[i] == SM_SentinelUndef || ZeroLane[i & 1])

      continue;

    if (Mask[i] < 0)

      return false;

    int Val = (i & 6) + NumElts * (i & 1);

    int CommutVal = (i & 0xe) + NumElts * ((i & 1) ^ 1);

    if (Mask[i] < Val || Mask[i] > Val + 1)

      IsSHUFPD = false;

    if (Mask[i] < CommutVal || Mask[i] > CommutVal + 1)

      IsCommutable = false;

    SHUFPDMask[i] = Mask[i] % 2;

  }


  if (!IsSHUFPD && !IsCommutable)

    return false;


  if (!IsSHUFPD && IsCommutable)

    std::swap(V1, V2);


  ForceV1Zero = ZeroLane[0];

  ForceV2Zero = ZeroLane[1];

  ShuffleImm = getSHUFPDImm(SHUFPDMask);

  return true;

}


static SDValue lowerShuffleWithSHUFPD(const SDLoc &DL, MVT VT, SDValue V1,

                                      SDValue V2, ArrayRef<int> Mask,

                                      const APInt &Zeroable,

                                      const X86Subtarget &Subtarget,

                                      SelectionDAG &DAG) {

  assert((VT == MVT::v2f64 || VT == MVT::v4f64 || VT == MVT::v8f64) &&

         "Unexpected data type for VSHUFPD");


  unsigned Immediate = 0;

  bool ForceV1Zero = false, ForceV2Zero = false;

  if (!matchShuffleWithSHUFPD(VT, V1, V2, ForceV1Zero, ForceV2Zero, Immediate,

                              Mask, Zeroable))

    return SDValue();


  // Create a REAL zero vector - ISD::isBuildVectorAllZeros allows UNDEFs.

  if (ForceV1Zero)

    V1 = getZeroVector(VT, Subtarget, DAG, DL);

  if (ForceV2Zero)

    V2 = getZeroVector(VT, Subtarget, DAG, DL);


  return DAG.getNode(X86ISD::SHUFP, DL, VT, V1, V2,

                     DAG.getTargetConstant(Immediate, DL, MVT::i8));

}


// Look for {0, 8, 16, 24, 32, 40, 48, 56 } in the first 8 elements. Followed

// by zeroable elements in the remaining 24 elements. Turn this into two

// vmovqb instructions shuffled together.


static SDValue lowerShuffleAsVTRUNCAndUnpack(const SDLoc &DL, MVT VT,

                                             SDValue V1, SDValue V2,

                                             ArrayRef<int> Mask,

                                             const APInt &Zeroable,

                                             SelectionDAG &DAG) {

  assert(VT == MVT::v32i8 && "Unexpected type!");


  // The first 8 indices should be every 8th element.

  if (!isSequentialOrUndefInRange(Mask, 0, 8, 0, 8))

    return SDValue();


  // Remaining elements need to be zeroable.

  if (Zeroable.countl_one() < (Mask.size() - 8))

    return SDValue();


  V1 = DAG.getBitcast(MVT::v4i64, V1);

  V2 = DAG.getBitcast(MVT::v4i64, V2);


  V1 = DAG.getNode(X86ISD::VTRUNC, DL, MVT::v16i8, V1);

  V2 = DAG.getNode(X86ISD::VTRUNC, DL, MVT::v16i8, V2);


  // The VTRUNCs will put 0s in the upper 12 bytes. Use them to put zeroes in

  // the upper bits of the result using an unpckldq.

  SDValue Unpack = DAG.getVectorShuffle(MVT::v16i8, DL, V1, V2,

                                        { 0, 1, 2, 3, 16, 17, 18, 19,

                                          4, 5, 6, 7, 20, 21, 22, 23 });

  // Insert the unpckldq into a zero vector to widen to v32i8.

  return DAG.getNode(ISD::INSERT_SUBVECTOR, DL, MVT::v32i8,

                     DAG.getConstant(0, DL, MVT::v32i8), Unpack,

                     DAG.getVectorIdxConstant(0, DL));

}


// a = shuffle v1, v2, mask1    ; interleaving lower lanes of v1 and v2

// b = shuffle v1, v2, mask2    ; interleaving higher lanes of v1 and v2

//     =>

// ul = unpckl v1, v2

// uh = unpckh v1, v2

// a = vperm ul, uh

// b = vperm ul, uh

//

// Pattern-match interleave(256b v1, 256b v2) -> 512b v3 and lower it into unpck

// and permute. We cannot directly match v3 because it is split into two

// 256-bit vectors in earlier isel stages. Therefore, this function matches a

// pair of 256-bit shuffles and makes sure the masks are consecutive.

//

// Once unpck and permute nodes are created, the permute corresponding to this

// shuffle is returned, while the other permute replaces the other half of the

// shuffle in the selection dag.


static SDValue lowerShufflePairAsUNPCKAndPermute(const SDLoc &DL, MVT VT,

                                                 SDValue V1, SDValue V2,

                                                 ArrayRef<int> Mask,

                                                 SelectionDAG &DAG) {

  if (VT != MVT::v8f32 && VT != MVT::v8i32 && VT != MVT::v16i16 &&

      VT != MVT::v32i8)

    return SDValue();

  // <B0, B1, B0+1, B1+1, ..., >

  auto IsInterleavingPattern = [&](ArrayRef<int> Mask, unsigned Begin0,

                                   unsigned Begin1) {

    size_t Size = Mask.size();

    assert(Size % 2 == 0 && "Expected even mask size");

    for (unsigned I = 0; I < Size; I += 2) {

      if (Mask[I] != (int)(Begin0 + I / 2) ||

          Mask[I + 1] != (int)(Begin1 + I / 2))

        return false;

    }

    return true;

  };

  // Check which half is this shuffle node

  int NumElts = VT.getVectorNumElements();

  size_t FirstQtr = NumElts / 2;

  size_t ThirdQtr = NumElts + NumElts / 2;

  bool IsFirstHalf = IsInterleavingPattern(Mask, 0, NumElts);

  bool IsSecondHalf = IsInterleavingPattern(Mask, FirstQtr, ThirdQtr);

  if (!IsFirstHalf && !IsSecondHalf)

    return SDValue();


  // Find the intersection between shuffle users of V1 and V2.

  SmallVector<SDNode *, 2> Shuffles;

  for (SDNode *User : V1->users())

    if (User->getOpcode() == ISD::VECTOR_SHUFFLE && User->getOperand(0) == V1 &&

        User->getOperand(1) == V2)

      Shuffles.push_back(User);

  // Limit user size to two for now.

  if (Shuffles.size() != 2)

    return SDValue();

  // Find out which half of the 512-bit shuffles is each smaller shuffle

  auto *SVN1 = cast<ShuffleVectorSDNode>(Shuffles[0]);

  auto *SVN2 = cast<ShuffleVectorSDNode>(Shuffles[1]);

  SDNode *FirstHalf;

  SDNode *SecondHalf;

  if (IsInterleavingPattern(SVN1->getMask(), 0, NumElts) &&

      IsInterleavingPattern(SVN2->getMask(), FirstQtr, ThirdQtr)) {

    FirstHalf = Shuffles[0];

    SecondHalf = Shuffles[1];

  } else if (IsInterleavingPattern(SVN1->getMask(), FirstQtr, ThirdQtr) &&

             IsInterleavingPattern(SVN2->getMask(), 0, NumElts)) {

    FirstHalf = Shuffles[1];

    SecondHalf = Shuffles[0];

  } else {

    return SDValue();

  }

  // Lower into unpck and perm. Return the perm of this shuffle and replace

  // the other.

  SDValue Unpckl = DAG.getNode(X86ISD::UNPCKL, DL, VT, V1, V2);

  SDValue Unpckh = DAG.getNode(X86ISD::UNPCKH, DL, VT, V1, V2);

  SDValue Perm1 = DAG.getNode(X86ISD::VPERM2X128, DL, VT, Unpckl, Unpckh,

                              DAG.getTargetConstant(0x20, DL, MVT::i8));

  SDValue Perm2 = DAG.getNode(X86ISD::VPERM2X128, DL, VT, Unpckl, Unpckh,

                              DAG.getTargetConstant(0x31, DL, MVT::i8));

  if (IsFirstHalf) {

    DAG.ReplaceAllUsesWith(SecondHalf, &Perm2);

    return Perm1;

  }

  DAG.ReplaceAllUsesWith(FirstHalf, &Perm1);

  return Perm2;

}


/// Handle lowering of 4-lane 64-bit floating point shuffles.

///

/// Also ends up handling lowering of 4-lane 64-bit integer shuffles when AVX2

/// isn't available.


static SDValue lowerV4F64Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                 const APInt &Zeroable, SDValue V1, SDValue V2,

                                 const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v4f64 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v4f64 && "Bad operand type!");

  assert(Mask.size() == 4 && "Unexpected mask size for v4 shuffle!");


  if (SDValue V = lowerV2X128Shuffle(DL, MVT::v4f64, V1, V2, Mask, Zeroable,

                                     Subtarget, DAG))

    return V;


  if (V2.isUndef()) {

    // Check for being able to broadcast a single element.

    if (SDValue Broadcast = lowerShuffleAsBroadcast(DL, MVT::v4f64, V1, V2,

                                                    Mask, Subtarget, DAG))

      return Broadcast;


    // Use low duplicate instructions for masks that match their pattern.

    if (isShuffleEquivalent(Mask, {0, 0, 2, 2}, V1, V2))

      return DAG.getNode(X86ISD::MOVDDUP, DL, MVT::v4f64, V1);


    if (!is128BitLaneCrossingShuffleMask(MVT::v4f64, Mask)) {

      // Non-half-crossing single input shuffles can be lowered with an

      // interleaved permutation.

      unsigned VPERMILPMask = (Mask[0] == 1) | ((Mask[1] == 1) << 1) |

                              ((Mask[2] == 3) << 2) | ((Mask[3] == 3) << 3);

      return DAG.getNode(X86ISD::VPERMILPI, DL, MVT::v4f64, V1,

                         DAG.getTargetConstant(VPERMILPMask, DL, MVT::i8));

    }


    // With AVX2 we have direct support for this permutation.

    if (Subtarget.hasAVX2())

      return DAG.getNode(X86ISD::VPERMI, DL, MVT::v4f64, V1,

                         getV4X86ShuffleImm8ForMask(Mask, DL, DAG));


    // Try to create an in-lane repeating shuffle mask and then shuffle the

    // results into the target lanes.

    if (SDValue V = lowerShuffleAsRepeatedMaskAndLanePermute(

            DL, MVT::v4f64, V1, V2, Mask, Subtarget, DAG))

      return V;


    // Try to permute the lanes and then use a per-lane permute.

    if (SDValue V = lowerShuffleAsLanePermuteAndPermute(DL, MVT::v4f64, V1, V2,

                                                        Mask, DAG, Subtarget))

      return V;


    // Otherwise, fall back.

    return lowerShuffleAsLanePermuteAndShuffle(DL, MVT::v4f64, V1, V2, Mask,

                                               DAG, Subtarget);

  }


  if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v4f64, V1, V2, Mask,

                                          Zeroable, Subtarget, DAG))

    return Blend;


  // Use dedicated unpack instructions for masks that match their pattern.

  if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v4f64, V1, V2, Mask, DAG))

    return V;


  if (SDValue Op = lowerShuffleWithSHUFPD(DL, MVT::v4f64, V1, V2, Mask,

                                          Zeroable, Subtarget, DAG))

    return Op;


  bool V1IsInPlace = isShuffleMaskInputInPlace(0, Mask);

  bool V2IsInPlace = isShuffleMaskInputInPlace(1, Mask);

  bool V1IsSplat = isShuffleMaskInputBroadcastable(0, Mask);

  bool V2IsSplat = isShuffleMaskInputBroadcastable(1, Mask);


  // If we have lane crossing shuffles AND they don't all come from the lower

  // lane elements, lower to SHUFPD(VPERM2F128(V1, V2), VPERM2F128(V1, V2)).

  // TODO: Handle BUILD_VECTOR sources which getVectorShuffle currently

  // canonicalize to a blend of splat which isn't necessary for this combine.

  if (is128BitLaneCrossingShuffleMask(MVT::v4f64, Mask) &&

      !all_of(Mask, [](int M) { return M < 2 || (4 <= M && M < 6); }) &&

      (V1.getOpcode() != ISD::BUILD_VECTOR) &&

      (V2.getOpcode() != ISD::BUILD_VECTOR) &&

      (!Subtarget.hasAVX2() ||

       !((V1IsInPlace || V1IsSplat) && (V2IsInPlace || V2IsSplat))))

    return lowerShuffleAsLanePermuteAndSHUFP(DL, MVT::v4f64, V1, V2, Mask, DAG);


  // If we have one input in place, then we can permute the other input and

  // blend the result.

  if (V1IsInPlace || V2IsInPlace)

    return lowerShuffleAsDecomposedShuffleMerge(DL, MVT::v4f64, V1, V2, Mask,

                                                Zeroable, Subtarget, DAG);


  // Try to create an in-lane repeating shuffle mask and then shuffle the

  // results into the target lanes.

  if (SDValue V = lowerShuffleAsRepeatedMaskAndLanePermute(

          DL, MVT::v4f64, V1, V2, Mask, Subtarget, DAG))

    return V;


  // Try to simplify this by merging 128-bit lanes to enable a lane-based

  // shuffle. However, if we have AVX2 and either inputs are already in place,

  // we will be able to shuffle even across lanes the other input in a single

  // instruction so skip this pattern.

  if (!(Subtarget.hasAVX2() && (V1IsInPlace || V2IsInPlace)))

    if (SDValue V = lowerShuffleAsLanePermuteAndRepeatedMask(

            DL, MVT::v4f64, V1, V2, Mask, Subtarget, DAG))

      return V;


  // If we have VLX support, we can use VEXPAND.

  if (Subtarget.hasVLX())

    if (SDValue V = lowerShuffleWithEXPAND(DL, MVT::v4f64, V1, V2, Mask,

                                           Zeroable, Subtarget, DAG))

      return V;


  // If we have AVX2 then we always want to lower with a blend because an v4 we

  // can fully permute the elements.

  if (Subtarget.hasAVX2())

    return lowerShuffleAsDecomposedShuffleMerge(DL, MVT::v4f64, V1, V2, Mask,

                                                Zeroable, Subtarget, DAG);


  // Otherwise fall back on generic lowering.

  return lowerShuffleAsSplitOrBlend(DL, MVT::v4f64, V1, V2, Mask, Zeroable,

                                    Subtarget, DAG);

}


/// Handle lowering of 4-lane 64-bit integer shuffles.

///

/// This routine is only called when we have AVX2 and thus a reasonable

/// instruction set for v4i64 shuffling..


static SDValue lowerV4I64Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                 const APInt &Zeroable, SDValue V1, SDValue V2,

                                 const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v4i64 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v4i64 && "Bad operand type!");

  assert(Mask.size() == 4 && "Unexpected mask size for v4 shuffle!");

  assert(Subtarget.hasAVX2() && "We can only lower v4i64 with AVX2!");


  if (SDValue V = lowerV2X128Shuffle(DL, MVT::v4i64, V1, V2, Mask, Zeroable,

                                     Subtarget, DAG))

    return V;


  if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v4i64, V1, V2, Mask,

                                          Zeroable, Subtarget, DAG))

    return Blend;


  // Check for being able to broadcast a single element.

  if (SDValue Broadcast = lowerShuffleAsBroadcast(DL, MVT::v4i64, V1, V2, Mask,

                                                  Subtarget, DAG))

    return Broadcast;


  // Try to use shift instructions if fast.

  if (Subtarget.preferLowerShuffleAsShift())

    if (SDValue Shift =

            lowerShuffleAsShift(DL, MVT::v4i64, V1, V2, Mask, Zeroable,

                                Subtarget, DAG, /*BitwiseOnly*/ true))

      return Shift;


  if (V2.isUndef()) {

    // When the shuffle is mirrored between the 128-bit lanes of the unit, we

    // can use lower latency instructions that will operate on both lanes.

    SmallVector<int, 2> RepeatedMask;

    if (is128BitLaneRepeatedShuffleMask(MVT::v4i64, Mask, RepeatedMask)) {

      SmallVector<int, 4> PSHUFDMask;

      narrowShuffleMaskElts(2, RepeatedMask, PSHUFDMask);

      return DAG.getBitcast(

          MVT::v4i64,

          DAG.getNode(X86ISD::PSHUFD, DL, MVT::v8i32,

                      DAG.getBitcast(MVT::v8i32, V1),

                      getV4X86ShuffleImm8ForMask(PSHUFDMask, DL, DAG)));

    }


    // AVX2 provides a direct instruction for permuting a single input across

    // lanes.

    return DAG.getNode(X86ISD::VPERMI, DL, MVT::v4i64, V1,

                       getV4X86ShuffleImm8ForMask(Mask, DL, DAG));

  }


  // Try to use shift instructions.

  if (SDValue Shift =

          lowerShuffleAsShift(DL, MVT::v4i64, V1, V2, Mask, Zeroable, Subtarget,

                              DAG, /*BitwiseOnly*/ false))

    return Shift;


  // If we have VLX support, we can use VALIGN or VEXPAND.

  if (Subtarget.hasVLX()) {

    if (SDValue Rotate = lowerShuffleAsVALIGN(DL, MVT::v4i64, V1, V2, Mask,

                                              Zeroable, Subtarget, DAG))

      return Rotate;


    if (SDValue V = lowerShuffleWithEXPAND(DL, MVT::v4i64, V1, V2, Mask,

                                           Zeroable, Subtarget, DAG))

      return V;

  }


  // Try to use PALIGNR.

  if (SDValue Rotate = lowerShuffleAsByteRotate(DL, MVT::v4i64, V1, V2, Mask,

                                                Subtarget, DAG))

    return Rotate;


  // Use dedicated unpack instructions for masks that match their pattern.

  if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v4i64, V1, V2, Mask, DAG))

    return V;


  bool V1IsInPlace = isShuffleMaskInputInPlace(0, Mask);

  bool V2IsInPlace = isShuffleMaskInputInPlace(1, Mask);


  // If we have one input in place, then we can permute the other input and

  // blend the result.

  if (V1IsInPlace || V2IsInPlace)

    return lowerShuffleAsDecomposedShuffleMerge(DL, MVT::v4i64, V1, V2, Mask,

                                                Zeroable, Subtarget, DAG);


  // Try to create an in-lane repeating shuffle mask and then shuffle the

  // results into the target lanes.

  if (SDValue V = lowerShuffleAsRepeatedMaskAndLanePermute(

          DL, MVT::v4i64, V1, V2, Mask, Subtarget, DAG))

    return V;


  // Try to lower to PERMQ(BLENDD(V1,V2)).

  if (SDValue V =

          lowerShuffleAsBlendAndPermute(DL, MVT::v4i64, V1, V2, Mask, DAG))

    return V;


  // Try to simplify this by merging 128-bit lanes to enable a lane-based

  // shuffle. However, if we have AVX2 and either inputs are already in place,

  // we will be able to shuffle even across lanes the other input in a single

  // instruction so skip this pattern.

  if (!V1IsInPlace && !V2IsInPlace)

    if (SDValue Result = lowerShuffleAsLanePermuteAndRepeatedMask(

            DL, MVT::v4i64, V1, V2, Mask, Subtarget, DAG))

      return Result;


  // Otherwise fall back on generic blend lowering.

  return lowerShuffleAsDecomposedShuffleMerge(DL, MVT::v4i64, V1, V2, Mask,

                                              Zeroable, Subtarget, DAG);

}


/// Handle lowering of 8-lane 32-bit floating point shuffles.

///

/// Also ends up handling lowering of 8-lane 32-bit integer shuffles when AVX2

/// isn't available.


static SDValue lowerV8F32Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                 const APInt &Zeroable, SDValue V1, SDValue V2,

                                 const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v8f32 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v8f32 && "Bad operand type!");

  assert(Mask.size() == 8 && "Unexpected mask size for v8 shuffle!");


  if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v8f32, V1, V2, Mask,

                                          Zeroable, Subtarget, DAG))

    return Blend;


  // Check for being able to broadcast a single element.

  if (SDValue Broadcast = lowerShuffleAsBroadcast(DL, MVT::v8f32, V1, V2, Mask,

                                                  Subtarget, DAG))

    return Broadcast;


  if (!Subtarget.hasAVX2()) {

    SmallVector<int> InLaneMask;

    computeInLaneShuffleMask(Mask, Mask.size() / 2, InLaneMask);


    if (!is128BitLaneRepeatedShuffleMask(MVT::v8f32, InLaneMask))

      if (SDValue R = splitAndLowerShuffle(DL, MVT::v8f32, V1, V2, Mask, DAG,

                                           /*SimpleOnly*/ true))

        return R;

  }

  if (SDValue ZExt = lowerShuffleAsZeroOrAnyExtend(DL, MVT::v8i32, V1, V2, Mask,

                                                   Zeroable, Subtarget, DAG))

    return DAG.getBitcast(MVT::v8f32, ZExt);


  // If the shuffle mask is repeated in each 128-bit lane, we have many more

  // options to efficiently lower the shuffle.

  SmallVector<int, 4> RepeatedMask;

  if (is128BitLaneRepeatedShuffleMask(MVT::v8f32, Mask, RepeatedMask)) {

    assert(RepeatedMask.size() == 4 &&

           "Repeated masks must be half the mask width!");


    // Use even/odd duplicate instructions for masks that match their pattern.

    if (isShuffleEquivalent(RepeatedMask, {0, 0, 2, 2}, V1, V2))

      return DAG.getNode(X86ISD::MOVSLDUP, DL, MVT::v8f32, V1);

    if (isShuffleEquivalent(RepeatedMask, {1, 1, 3, 3}, V1, V2))

      return DAG.getNode(X86ISD::MOVSHDUP, DL, MVT::v8f32, V1);


    if (V2.isUndef())

      return DAG.getNode(X86ISD::VPERMILPI, DL, MVT::v8f32, V1,

                         getV4X86ShuffleImm8ForMask(RepeatedMask, DL, DAG));


    // Use dedicated unpack instructions for masks that match their pattern.

    if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v8f32, V1, V2, Mask, DAG))

      return V;


    // Otherwise, fall back to a SHUFPS sequence. Here it is important that we

    // have already handled any direct blends.

    return lowerShuffleWithSHUFPS(DL, MVT::v8f32, RepeatedMask, V1, V2, DAG);

  }


  // Try to create an in-lane repeating shuffle mask and then shuffle the

  // results into the target lanes.

  if (SDValue V = lowerShuffleAsRepeatedMaskAndLanePermute(

          DL, MVT::v8f32, V1, V2, Mask, Subtarget, DAG))

    return V;


  // If we have a single input shuffle with different shuffle patterns in the

  // two 128-bit lanes use the variable mask to VPERMILPS.

  if (V2.isUndef()) {

    if (!is128BitLaneCrossingShuffleMask(MVT::v8f32, Mask)) {

      SDValue VPermMask = getConstVector(Mask, MVT::v8i32, DAG, DL, true);

      return DAG.getNode(X86ISD::VPERMILPV, DL, MVT::v8f32, V1, VPermMask);

    }

    if (Subtarget.hasAVX2()) {

      SDValue VPermMask = getConstVector(Mask, MVT::v8i32, DAG, DL, true);

      return DAG.getNode(X86ISD::VPERMV, DL, MVT::v8f32, VPermMask, V1);

    }

    // Otherwise, fall back.

    return lowerShuffleAsLanePermuteAndShuffle(DL, MVT::v8f32, V1, V2, Mask,

                                               DAG, Subtarget);

  }


  // Try to simplify this by merging 128-bit lanes to enable a lane-based

  // shuffle.

  if (SDValue Result = lowerShuffleAsLanePermuteAndRepeatedMask(

          DL, MVT::v8f32, V1, V2, Mask, Subtarget, DAG))

    return Result;


  // If we have VLX support, we can use VEXPAND.

  if (Subtarget.hasVLX())

    if (SDValue V = lowerShuffleWithEXPAND(DL, MVT::v8f32, V1, V2, Mask,

                                           Zeroable, Subtarget, DAG))

      return V;


  // Try to match an interleave of two v8f32s and lower them as unpck and

  // permutes using ymms. This needs to go before we try to split the vectors.

  // Don't attempt on AVX1 if we're likely to split vectors anyway.

  if ((Subtarget.hasAVX2() ||

       !(isFreeToSplitVector(peekThroughBitcasts(V1), DAG) ||

         isFreeToSplitVector(peekThroughBitcasts(V2), DAG))) &&

      !Subtarget.hasAVX512())

    if (SDValue V = lowerShufflePairAsUNPCKAndPermute(DL, MVT::v8f32, V1, V2,

                                                      Mask, DAG))

      return V;


  // For non-AVX512 if the Mask is of 16bit elements in lane then try to split

  // since after split we get a more efficient code using vpunpcklwd and

  // vpunpckhwd instrs than vblend.

  if (!Subtarget.hasAVX512() && isUnpackWdShuffleMask(Mask, MVT::v8f32, DAG))

    return lowerShuffleAsSplitOrBlend(DL, MVT::v8f32, V1, V2, Mask, Zeroable,

                                      Subtarget, DAG);


  // If we have AVX2 then we always want to lower with a blend because at v8 we

  // can fully permute the elements.

  if (Subtarget.hasAVX2())

    return lowerShuffleAsDecomposedShuffleMerge(DL, MVT::v8f32, V1, V2, Mask,

                                                Zeroable, Subtarget, DAG);


  // Otherwise fall back on generic lowering.

  return lowerShuffleAsSplitOrBlend(DL, MVT::v8f32, V1, V2, Mask, Zeroable,

                                    Subtarget, DAG);

}


/// Handle lowering of 8-lane 32-bit integer shuffles.

///

/// This routine is only called when we have AVX2 and thus a reasonable

/// instruction set for v8i32 shuffling..


static SDValue lowerV8I32Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                 const APInt &Zeroable, SDValue V1, SDValue V2,

                                 const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v8i32 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v8i32 && "Bad operand type!");

  assert(Mask.size() == 8 && "Unexpected mask size for v8 shuffle!");

  assert(Subtarget.hasAVX2() && "We can only lower v8i32 with AVX2!");


  int NumV2Elements = count_if(Mask, [](int M) { return M >= 8; });


  // Whenever we can lower this as a zext, that instruction is strictly faster

  // than any alternative. It also allows us to fold memory operands into the

  // shuffle in many cases.

  if (SDValue ZExt = lowerShuffleAsZeroOrAnyExtend(DL, MVT::v8i32, V1, V2, Mask,

                                                   Zeroable, Subtarget, DAG))

    return ZExt;


  // Try to match an interleave of two v8i32s and lower them as unpck and

  // permutes using ymms. This needs to go before we try to split the vectors.

  if (!Subtarget.hasAVX512())

    if (SDValue V = lowerShufflePairAsUNPCKAndPermute(DL, MVT::v8i32, V1, V2,

                                                      Mask, DAG))

      return V;


  // For non-AVX512 if the Mask is of 16bit elements in lane then try to split

  // since after split we get a more efficient code than vblend by using

  // vpunpcklwd and vpunpckhwd instrs.

  if (isUnpackWdShuffleMask(Mask, MVT::v8i32, DAG) && !V2.isUndef() &&

      !Subtarget.hasAVX512())

    return lowerShuffleAsSplitOrBlend(DL, MVT::v8i32, V1, V2, Mask, Zeroable,

                                      Subtarget, DAG);


  if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v8i32, V1, V2, Mask,

                                          Zeroable, Subtarget, DAG))

    return Blend;


  // Check for being able to broadcast a single element.

  if (SDValue Broadcast = lowerShuffleAsBroadcast(DL, MVT::v8i32, V1, V2, Mask,

                                                  Subtarget, DAG))

    return Broadcast;


  // Try to use shift instructions if fast.

  if (Subtarget.preferLowerShuffleAsShift()) {

    if (SDValue Shift =

            lowerShuffleAsShift(DL, MVT::v8i32, V1, V2, Mask, Zeroable,

                                Subtarget, DAG, /*BitwiseOnly*/ true))

      return Shift;

    if (NumV2Elements == 0)

      if (SDValue Rotate =

              lowerShuffleAsBitRotate(DL, MVT::v8i32, V1, Mask, Subtarget, DAG))

        return Rotate;

  }


  // If the shuffle mask is repeated in each 128-bit lane we can use more

  // efficient instructions that mirror the shuffles across the two 128-bit

  // lanes.

  SmallVector<int, 4> RepeatedMask;

  bool Is128BitLaneRepeatedShuffle =

      is128BitLaneRepeatedShuffleMask(MVT::v8i32, Mask, RepeatedMask);

  if (Is128BitLaneRepeatedShuffle) {

    assert(RepeatedMask.size() == 4 && "Unexpected repeated mask size!");

    if (V2.isUndef())

      return DAG.getNode(X86ISD::PSHUFD, DL, MVT::v8i32, V1,

                         getV4X86ShuffleImm8ForMask(RepeatedMask, DL, DAG));


    // Use dedicated unpack instructions for masks that match their pattern.

    if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v8i32, V1, V2, Mask, DAG))

      return V;

  }


  // Try to use shift instructions.

  if (SDValue Shift =

          lowerShuffleAsShift(DL, MVT::v8i32, V1, V2, Mask, Zeroable, Subtarget,

                              DAG, /*BitwiseOnly*/ false))

    return Shift;


  if (!Subtarget.preferLowerShuffleAsShift() && NumV2Elements == 0)

    if (SDValue Rotate =

            lowerShuffleAsBitRotate(DL, MVT::v8i32, V1, Mask, Subtarget, DAG))

      return Rotate;


  // If we have VLX support, we can use VALIGN or EXPAND.

  if (Subtarget.hasVLX()) {

    if (SDValue Rotate = lowerShuffleAsVALIGN(DL, MVT::v8i32, V1, V2, Mask,

                                              Zeroable, Subtarget, DAG))

      return Rotate;


    if (SDValue V = lowerShuffleWithEXPAND(DL, MVT::v8i32, V1, V2, Mask,

                                           Zeroable, Subtarget, DAG))

      return V;

  }


  // Try to use byte rotation instructions.

  if (SDValue Rotate = lowerShuffleAsByteRotate(DL, MVT::v8i32, V1, V2, Mask,

                                                Subtarget, DAG))

    return Rotate;


  // Try to create an in-lane repeating shuffle mask and then shuffle the

  // results into the target lanes.

  if (SDValue V = lowerShuffleAsRepeatedMaskAndLanePermute(

          DL, MVT::v8i32, V1, V2, Mask, Subtarget, DAG))

    return V;


  if (V2.isUndef()) {

    // Try to produce a fixed cross-128-bit lane permute followed by unpack

    // because that should be faster than the variable permute alternatives.

    if (SDValue V = lowerShuffleWithUNPCK256(DL, MVT::v8i32, V1, V2, Mask, DAG))

      return V;


    // If the shuffle patterns aren't repeated but it's a single input, directly

    // generate a cross-lane VPERMD instruction.

    SDValue VPermMask = getConstVector(Mask, MVT::v8i32, DAG, DL, true);

    return DAG.getNode(X86ISD::VPERMV, DL, MVT::v8i32, VPermMask, V1);

  }


  // Assume that a single SHUFPS is faster than an alternative sequence of

  // multiple instructions (even if the CPU has a domain penalty).

  // If some CPU is harmed by the domain switch, we can fix it in a later pass.

  if (Is128BitLaneRepeatedShuffle && isSingleSHUFPSMask(RepeatedMask)) {

    SDValue CastV1 = DAG.getBitcast(MVT::v8f32, V1);

    SDValue CastV2 = DAG.getBitcast(MVT::v8f32, V2);

    SDValue ShufPS = lowerShuffleWithSHUFPS(DL, MVT::v8f32, RepeatedMask,

                                            CastV1, CastV2, DAG);

    return DAG.getBitcast(MVT::v8i32, ShufPS);

  }


  // Try to simplify this by merging 128-bit lanes to enable a lane-based

  // shuffle.

  if (SDValue Result = lowerShuffleAsLanePermuteAndRepeatedMask(

          DL, MVT::v8i32, V1, V2, Mask, Subtarget, DAG))

    return Result;


  // Otherwise fall back on generic blend lowering.

  return lowerShuffleAsDecomposedShuffleMerge(DL, MVT::v8i32, V1, V2, Mask,

                                              Zeroable, Subtarget, DAG);

}


/// Handle lowering of 16-lane 16-bit integer shuffles.

///

/// This routine is only called when we have AVX2 and thus a reasonable

/// instruction set for v16i16 shuffling..


static SDValue lowerV16I16Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                  const APInt &Zeroable, SDValue V1, SDValue V2,

                                  const X86Subtarget &Subtarget,

                                  SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v16i16 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v16i16 && "Bad operand type!");

  assert(Mask.size() == 16 && "Unexpected mask size for v16 shuffle!");

  assert(Subtarget.hasAVX2() && "We can only lower v16i16 with AVX2!");


  // Whenever we can lower this as a zext, that instruction is strictly faster

  // than any alternative. It also allows us to fold memory operands into the

  // shuffle in many cases.

  if (SDValue ZExt = lowerShuffleAsZeroOrAnyExtend(

          DL, MVT::v16i16, V1, V2, Mask, Zeroable, Subtarget, DAG))

    return ZExt;


  // Check for being able to broadcast a single element.

  if (SDValue Broadcast = lowerShuffleAsBroadcast(DL, MVT::v16i16, V1, V2, Mask,

                                                  Subtarget, DAG))

    return Broadcast;


  if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v16i16, V1, V2, Mask,

                                          Zeroable, Subtarget, DAG))

    return Blend;


  // Use dedicated unpack instructions for masks that match their pattern.

  if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v16i16, V1, V2, Mask, DAG))

    return V;


  // Use dedicated pack instructions for masks that match their pattern.

  if (SDValue V =

          lowerShuffleWithPACK(DL, MVT::v16i16, V1, V2, Mask, Subtarget, DAG))

    return V;


  // Try to use lower using a truncation.

  if (SDValue V = lowerShuffleAsVTRUNC(DL, MVT::v16i16, V1, V2, Mask, Zeroable,

                                       Subtarget, DAG))

    return V;


  // Try to use shift instructions.

  if (SDValue Shift =

          lowerShuffleAsShift(DL, MVT::v16i16, V1, V2, Mask, Zeroable,

                              Subtarget, DAG, /*BitwiseOnly*/ false))

    return Shift;


  // Try to use byte rotation instructions.

  if (SDValue Rotate = lowerShuffleAsByteRotate(DL, MVT::v16i16, V1, V2, Mask,

                                                Subtarget, DAG))

    return Rotate;


  // Try to create an in-lane repeating shuffle mask and then shuffle the

  // results into the target lanes.

  if (SDValue V = lowerShuffleAsRepeatedMaskAndLanePermute(

          DL, MVT::v16i16, V1, V2, Mask, Subtarget, DAG))

    return V;


  if (V2.isUndef()) {

    // Try to use bit rotation instructions.

    if (SDValue Rotate =

            lowerShuffleAsBitRotate(DL, MVT::v16i16, V1, Mask, Subtarget, DAG))

      return Rotate;


    // Try to produce a fixed cross-128-bit lane permute followed by unpack

    // because that should be faster than the variable permute alternatives.

    if (SDValue V = lowerShuffleWithUNPCK256(DL, MVT::v16i16, V1, V2, Mask, DAG))

      return V;


    // There are no generalized cross-lane shuffle operations available on i16

    // element types.

    if (is128BitLaneCrossingShuffleMask(MVT::v16i16, Mask)) {

      if (SDValue V = lowerShuffleAsLanePermuteAndPermute(

              DL, MVT::v16i16, V1, V2, Mask, DAG, Subtarget))

        return V;


      return lowerShuffleAsLanePermuteAndShuffle(DL, MVT::v16i16, V1, V2, Mask,

                                                 DAG, Subtarget);

    }


    SmallVector<int, 8> RepeatedMask;

    if (is128BitLaneRepeatedShuffleMask(MVT::v16i16, Mask, RepeatedMask)) {

      // As this is a single-input shuffle, the repeated mask should be

      // a strictly valid v8i16 mask that we can pass through to the v8i16

      // lowering to handle even the v16 case.

      return lowerV8I16GeneralSingleInputShuffle(

          DL, MVT::v16i16, V1, RepeatedMask, Subtarget, DAG);

    }

  }


  if (SDValue PSHUFB = lowerShuffleWithPSHUFB(DL, MVT::v16i16, Mask, V1, V2,

                                              Zeroable, Subtarget, DAG))

    return PSHUFB;


  // AVX512BW can lower to VPERMW (non-VLX will pad to v32i16).

  if (Subtarget.hasBWI())

    return lowerShuffleWithPERMV(DL, MVT::v16i16, Mask, V1, V2, Subtarget, DAG);


  // Try to simplify this by merging 128-bit lanes to enable a lane-based

  // shuffle.

  if (SDValue Result = lowerShuffleAsLanePermuteAndRepeatedMask(

          DL, MVT::v16i16, V1, V2, Mask, Subtarget, DAG))

    return Result;


  // Try to permute the lanes and then use a per-lane permute.

  if (SDValue V = lowerShuffleAsLanePermuteAndPermute(

          DL, MVT::v16i16, V1, V2, Mask, DAG, Subtarget))

    return V;


  // Try to match an interleave of two v16i16s and lower them as unpck and

  // permutes using ymms.

  if (!Subtarget.hasAVX512())

    if (SDValue V = lowerShufflePairAsUNPCKAndPermute(DL, MVT::v16i16, V1, V2,

                                                      Mask, DAG))

      return V;


  // Otherwise fall back on generic lowering.

  return lowerShuffleAsSplitOrBlend(DL, MVT::v16i16, V1, V2, Mask, Zeroable,

                                    Subtarget, DAG);

}


/// Handle lowering of 32-lane 8-bit integer shuffles.

///

/// This routine is only called when we have AVX2 and thus a reasonable

/// instruction set for v32i8 shuffling..


static SDValue lowerV32I8Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                 const APInt &Zeroable, SDValue V1, SDValue V2,

                                 const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v32i8 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v32i8 && "Bad operand type!");

  assert(Mask.size() == 32 && "Unexpected mask size for v32 shuffle!");

  assert(Subtarget.hasAVX2() && "We can only lower v32i8 with AVX2!");


  // Whenever we can lower this as a zext, that instruction is strictly faster

  // than any alternative. It also allows us to fold memory operands into the

  // shuffle in many cases.

  if (SDValue ZExt = lowerShuffleAsZeroOrAnyExtend(DL, MVT::v32i8, V1, V2, Mask,

                                                   Zeroable, Subtarget, DAG))

    return ZExt;


  // Check for being able to broadcast a single element.

  if (SDValue Broadcast = lowerShuffleAsBroadcast(DL, MVT::v32i8, V1, V2, Mask,

                                                  Subtarget, DAG))

    return Broadcast;


  if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v32i8, V1, V2, Mask,

                                          Zeroable, Subtarget, DAG))

    return Blend;


  // Use dedicated unpack instructions for masks that match their pattern.

  if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v32i8, V1, V2, Mask, DAG))

    return V;


  // Use dedicated pack instructions for masks that match their pattern.

  if (SDValue V =

          lowerShuffleWithPACK(DL, MVT::v32i8, V1, V2, Mask, Subtarget, DAG))

    return V;


  // Try to use lower using a truncation.

  if (SDValue V = lowerShuffleAsVTRUNC(DL, MVT::v32i8, V1, V2, Mask, Zeroable,

                                       Subtarget, DAG))

    return V;


  // Try to use shift instructions.

  if (SDValue Shift =

          lowerShuffleAsShift(DL, MVT::v32i8, V1, V2, Mask, Zeroable, Subtarget,

                              DAG, /*BitwiseOnly*/ false))

    return Shift;


  // Try to use byte rotation instructions.

  if (SDValue Rotate = lowerShuffleAsByteRotate(DL, MVT::v32i8, V1, V2, Mask,

                                                Subtarget, DAG))

    return Rotate;


  // Try to use bit rotation instructions.

  if (V2.isUndef())

    if (SDValue Rotate =

            lowerShuffleAsBitRotate(DL, MVT::v32i8, V1, Mask, Subtarget, DAG))

      return Rotate;


  // Try to create an in-lane repeating shuffle mask and then shuffle the

  // results into the target lanes.

  if (SDValue V = lowerShuffleAsRepeatedMaskAndLanePermute(

          DL, MVT::v32i8, V1, V2, Mask, Subtarget, DAG))

    return V;


  // There are no generalized cross-lane shuffle operations available on i8

  // element types.

  if (V2.isUndef() && is128BitLaneCrossingShuffleMask(MVT::v32i8, Mask)) {

    // Try to produce a fixed cross-128-bit lane permute followed by unpack

    // because that should be faster than the variable permute alternatives.

    if (SDValue V = lowerShuffleWithUNPCK256(DL, MVT::v32i8, V1, V2, Mask, DAG))

      return V;


    if (SDValue V = lowerShuffleAsLanePermuteAndPermute(

            DL, MVT::v32i8, V1, V2, Mask, DAG, Subtarget))

      return V;


    return lowerShuffleAsLanePermuteAndShuffle(DL, MVT::v32i8, V1, V2, Mask,

                                               DAG, Subtarget);

  }


  if (SDValue PSHUFB = lowerShuffleWithPSHUFB(DL, MVT::v32i8, Mask, V1, V2,

                                              Zeroable, Subtarget, DAG))

    return PSHUFB;


  // AVX512VBMI can lower to VPERMB (non-VLX will pad to v64i8).

  if (Subtarget.hasVBMI())

    return lowerShuffleWithPERMV(DL, MVT::v32i8, Mask, V1, V2, Subtarget, DAG);


  // Try to simplify this by merging 128-bit lanes to enable a lane-based

  // shuffle.

  if (SDValue Result = lowerShuffleAsLanePermuteAndRepeatedMask(

          DL, MVT::v32i8, V1, V2, Mask, Subtarget, DAG))

    return Result;


  // Try to permute the lanes and then use a per-lane permute.

  if (SDValue V = lowerShuffleAsLanePermuteAndPermute(

          DL, MVT::v32i8, V1, V2, Mask, DAG, Subtarget))

    return V;


  // Look for {0, 8, 16, 24, 32, 40, 48, 56 } in the first 8 elements. Followed

  // by zeroable elements in the remaining 24 elements. Turn this into two

  // vmovqb instructions shuffled together.

  if (Subtarget.hasVLX())

    if (SDValue V = lowerShuffleAsVTRUNCAndUnpack(DL, MVT::v32i8, V1, V2,

                                                  Mask, Zeroable, DAG))

      return V;


  // Try to match an interleave of two v32i8s and lower them as unpck and

  // permutes using ymms.

  if (!Subtarget.hasAVX512())

    if (SDValue V = lowerShufflePairAsUNPCKAndPermute(DL, MVT::v32i8, V1, V2,

                                                      Mask, DAG))

      return V;


  // Otherwise fall back on generic lowering.

  return lowerShuffleAsSplitOrBlend(DL, MVT::v32i8, V1, V2, Mask, Zeroable,

                                    Subtarget, DAG);

}


/// High-level routine to lower various 256-bit x86 vector shuffles.

///

/// This routine either breaks down the specific type of a 256-bit x86 vector

/// shuffle or splits it into two 128-bit shuffles and fuses the results back

/// together based on the available instructions.


static SDValue lower256BitShuffle(const SDLoc &DL, ArrayRef<int> Mask, MVT VT,

                                  SDValue V1, SDValue V2, const APInt &Zeroable,

                                  const X86Subtarget &Subtarget,

                                  SelectionDAG &DAG) {

  // If we have a single input to the zero element, insert that into V1 if we

  // can do so cheaply.

  int NumElts = VT.getVectorNumElements();

  int NumV2Elements = count_if(Mask, [NumElts](int M) { return M >= NumElts; });


  if (NumV2Elements == 1 && Mask[0] >= NumElts)

    if (SDValue Insertion = lowerShuffleAsElementInsertion(

            DL, VT, V1, V2, Mask, Zeroable, Subtarget, DAG))

      return Insertion;


  // Handle special cases where the lower or upper half is UNDEF.

  if (SDValue V =

          lowerShuffleWithUndefHalf(DL, VT, V1, V2, Mask, Subtarget, DAG))

    return V;


  // There is a really nice hard cut-over between AVX1 and AVX2 that means we

  // can check for those subtargets here and avoid much of the subtarget

  // querying in the per-vector-type lowering routines. With AVX1 we have

  // essentially *zero* ability to manipulate a 256-bit vector with integer

  // types. Since we'll use floating point types there eventually, just

  // immediately cast everything to a float and operate entirely in that domain.

  if (VT.isInteger() && !Subtarget.hasAVX2()) {

    int ElementBits = VT.getScalarSizeInBits();

    if (ElementBits < 32) {

      // No floating point type available, if we can't use the bit operations

      // for masking/blending then decompose into 128-bit vectors.

      if (SDValue V = lowerShuffleAsBitMask(DL, VT, V1, V2, Mask, Zeroable,

                                            Subtarget, DAG))

        return V;

      if (SDValue V = lowerShuffleAsBitBlend(DL, VT, V1, V2, Mask, DAG))

        return V;

      return splitAndLowerShuffle(DL, VT, V1, V2, Mask, DAG, /*SimpleOnly*/ false);

    }


    MVT FpVT = MVT::getVectorVT(MVT::getFloatingPointVT(ElementBits),

                                VT.getVectorNumElements());

    V1 = DAG.getBitcast(FpVT, V1);

    V2 = DAG.getBitcast(FpVT, V2);

    return DAG.getBitcast(VT, DAG.getVectorShuffle(FpVT, DL, V1, V2, Mask));

  }


  if (VT == MVT::v16f16 || VT == MVT::v16bf16) {

    V1 = DAG.getBitcast(MVT::v16i16, V1);

    V2 = DAG.getBitcast(MVT::v16i16, V2);

    return DAG.getBitcast(VT,

                          DAG.getVectorShuffle(MVT::v16i16, DL, V1, V2, Mask));

  }


  switch (VT.SimpleTy) {

  case MVT::v4f64:

    return lowerV4F64Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v4i64:

    return lowerV4I64Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v8f32:

    return lowerV8F32Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v8i32:

    return lowerV8I32Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v16i16:

    return lowerV16I16Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v32i8:

    return lowerV32I8Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);


  default:

    llvm_unreachable("Not a valid 256-bit x86 vector type!");

  }

}


/// Try to lower a vector shuffle as a 128-bit shuffles.


static SDValue lowerV4X128Shuffle(const SDLoc &DL, MVT VT, ArrayRef<int> Mask,

                                  const APInt &Zeroable, SDValue V1, SDValue V2,

                                  const X86Subtarget &Subtarget,

                                  SelectionDAG &DAG) {

  assert(VT.getScalarSizeInBits() == 64 &&

         "Unexpected element type size for 128bit shuffle.");


  // To handle 256 bit vector requires VLX and most probably

  // function lowerV2X128VectorShuffle() is better solution.

  assert(VT.is512BitVector() && "Unexpected vector size for 512bit shuffle.");


  // TODO - use Zeroable like we do for lowerV2X128VectorShuffle?

  SmallVector<int, 4> Widened128Mask;

  if (!canWidenShuffleElements(Mask, Widened128Mask))

    return SDValue();

  assert(Widened128Mask.size() == 4 && "Shuffle widening mismatch");


  // Try to use an insert into a zero vector.

  if (Widened128Mask[0] == 0 && (Zeroable & 0xf0) == 0xf0 &&

      (Widened128Mask[1] == 1 || (Zeroable & 0x0c) == 0x0c)) {

    unsigned NumElts = ((Zeroable & 0x0c) == 0x0c) ? 2 : 4;

    MVT SubVT = MVT::getVectorVT(VT.getVectorElementType(), NumElts);

    SDValue LoV = DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, SubVT, V1,

                              DAG.getVectorIdxConstant(0, DL));

    return DAG.getNode(ISD::INSERT_SUBVECTOR, DL, VT,

                       getZeroVector(VT, Subtarget, DAG, DL), LoV,

                       DAG.getVectorIdxConstant(0, DL));

  }


  // Check for patterns which can be matched with a single insert of a 256-bit

  // subvector.

  bool OnlyUsesV1 = isShuffleEquivalent(Mask, {0, 1, 2, 3, 0, 1, 2, 3}, V1, V2);

  if (OnlyUsesV1 ||

      isShuffleEquivalent(Mask, {0, 1, 2, 3, 8, 9, 10, 11}, V1, V2)) {

    MVT SubVT = MVT::getVectorVT(VT.getVectorElementType(), 4);

    SDValue SubVec =

        DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, SubVT, OnlyUsesV1 ? V1 : V2,

                    DAG.getVectorIdxConstant(0, DL));

    return DAG.getNode(ISD::INSERT_SUBVECTOR, DL, VT, V1, SubVec,

                       DAG.getVectorIdxConstant(4, DL));

  }


  // See if this is an insertion of the lower 128-bits of V2 into V1.

  bool IsInsert = true;

  int V2Index = -1;

  for (int i = 0; i < 4; ++i) {

    assert(Widened128Mask[i] >= -1 && "Illegal shuffle sentinel value");

    if (Widened128Mask[i] < 0)

      continue;


    // Make sure all V1 subvectors are in place.

    if (Widened128Mask[i] < 4) {

      if (Widened128Mask[i] != i) {

        IsInsert = false;

        break;

      }

    } else {

      // Make sure we only have a single V2 index and its the lowest 128-bits.

      if (V2Index >= 0 || Widened128Mask[i] != 4) {

        IsInsert = false;

        break;

      }

      V2Index = i;

    }

  }

  if (IsInsert && V2Index >= 0) {

    MVT SubVT = MVT::getVectorVT(VT.getVectorElementType(), 2);

    SDValue Subvec = DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, SubVT, V2,

                                 DAG.getVectorIdxConstant(0, DL));

    return insert128BitVector(V1, Subvec, V2Index * 2, DAG, DL);

  }


  // See if we can widen to a 256-bit lane shuffle, we're going to lose 128-lane

  // UNDEF info by lowering to X86ISD::SHUF128 anyway, so by widening where

  // possible we at least ensure the lanes stay sequential to help later

  // combines.

  SmallVector<int, 2> Widened256Mask;

  if (canWidenShuffleElements(Widened128Mask, Widened256Mask)) {

    Widened128Mask.clear();

    narrowShuffleMaskElts(2, Widened256Mask, Widened128Mask);

  }


  // Try to lower to vshuf64x2/vshuf32x4.

  SDValue Ops[2] = {DAG.getUNDEF(VT), DAG.getUNDEF(VT)};

  int PermMask[4] = {-1, -1, -1, -1};

  // Ensure elements came from the same Op.

  for (int i = 0; i < 4; ++i) {

    assert(Widened128Mask[i] >= -1 && "Illegal shuffle sentinel value");

    if (Widened128Mask[i] < 0)

      continue;


    SDValue Op = Widened128Mask[i] >= 4 ? V2 : V1;

    unsigned OpIndex = i / 2;

    if (Ops[OpIndex].isUndef())

      Ops[OpIndex] = Op;

    else if (Ops[OpIndex] != Op)

      return SDValue();


    PermMask[i] = Widened128Mask[i] % 4;

  }


  return DAG.getNode(X86ISD::SHUF128, DL, VT, Ops[0], Ops[1],

                     getV4X86ShuffleImm8ForMask(PermMask, DL, DAG));

}


/// Handle lowering of 8-lane 64-bit floating point shuffles.


static SDValue lowerV8F64Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                 const APInt &Zeroable, SDValue V1, SDValue V2,

                                 const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v8f64 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v8f64 && "Bad operand type!");

  assert(Mask.size() == 8 && "Unexpected mask size for v8 shuffle!");


  if (V2.isUndef()) {

    // Use low duplicate instructions for masks that match their pattern.

    if (isShuffleEquivalent(Mask, {0, 0, 2, 2, 4, 4, 6, 6}, V1, V2))

      return DAG.getNode(X86ISD::MOVDDUP, DL, MVT::v8f64, V1);


    if (!is128BitLaneCrossingShuffleMask(MVT::v8f64, Mask)) {

      // Non-half-crossing single input shuffles can be lowered with an

      // interleaved permutation.

      unsigned VPERMILPMask = (Mask[0] == 1) | ((Mask[1] == 1) << 1) |

                              ((Mask[2] == 3) << 2) | ((Mask[3] == 3) << 3) |

                              ((Mask[4] == 5) << 4) | ((Mask[5] == 5) << 5) |

                              ((Mask[6] == 7) << 6) | ((Mask[7] == 7) << 7);

      return DAG.getNode(X86ISD::VPERMILPI, DL, MVT::v8f64, V1,

                         DAG.getTargetConstant(VPERMILPMask, DL, MVT::i8));

    }


    SmallVector<int, 4> RepeatedMask;

    if (is256BitLaneRepeatedShuffleMask(MVT::v8f64, Mask, RepeatedMask))

      return DAG.getNode(X86ISD::VPERMI, DL, MVT::v8f64, V1,

                         getV4X86ShuffleImm8ForMask(RepeatedMask, DL, DAG));

  }


  if (SDValue Shuf128 = lowerV4X128Shuffle(DL, MVT::v8f64, Mask, Zeroable, V1,

                                           V2, Subtarget, DAG))

    return Shuf128;


  if (SDValue Unpck = lowerShuffleWithUNPCK(DL, MVT::v8f64, V1, V2, Mask, DAG))

    return Unpck;


  // Check if the blend happens to exactly fit that of SHUFPD.

  if (SDValue Op = lowerShuffleWithSHUFPD(DL, MVT::v8f64, V1, V2, Mask,

                                          Zeroable, Subtarget, DAG))

    return Op;


  if (SDValue V = lowerShuffleWithEXPAND(DL, MVT::v8f64, V1, V2, Mask, Zeroable,

                                         Subtarget, DAG))

    return V;


  if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v8f64, V1, V2, Mask,

                                          Zeroable, Subtarget, DAG))

    return Blend;


  return lowerShuffleWithPERMV(DL, MVT::v8f64, Mask, V1, V2, Subtarget, DAG);

}


/// Handle lowering of 16-lane 32-bit floating point shuffles.


static SDValue lowerV16F32Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                  const APInt &Zeroable, SDValue V1, SDValue V2,

                                  const X86Subtarget &Subtarget,

                                  SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v16f32 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v16f32 && "Bad operand type!");

  assert(Mask.size() == 16 && "Unexpected mask size for v16 shuffle!");


  // If the shuffle mask is repeated in each 128-bit lane, we have many more

  // options to efficiently lower the shuffle.

  SmallVector<int, 4> RepeatedMask;

  if (is128BitLaneRepeatedShuffleMask(MVT::v16f32, Mask, RepeatedMask)) {

    assert(RepeatedMask.size() == 4 && "Unexpected repeated mask size!");


    // Use even/odd duplicate instructions for masks that match their pattern.

    if (isShuffleEquivalent(RepeatedMask, {0, 0, 2, 2}, V1, V2))

      return DAG.getNode(X86ISD::MOVSLDUP, DL, MVT::v16f32, V1);

    if (isShuffleEquivalent(RepeatedMask, {1, 1, 3, 3}, V1, V2))

      return DAG.getNode(X86ISD::MOVSHDUP, DL, MVT::v16f32, V1);


    if (V2.isUndef())

      return DAG.getNode(X86ISD::VPERMILPI, DL, MVT::v16f32, V1,

                         getV4X86ShuffleImm8ForMask(RepeatedMask, DL, DAG));


    // Use dedicated unpack instructions for masks that match their pattern.

    if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v16f32, V1, V2, Mask, DAG))

      return V;


    if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v16f32, V1, V2, Mask,

                                            Zeroable, Subtarget, DAG))

      return Blend;


    // Otherwise, fall back to a SHUFPS sequence.

    return lowerShuffleWithSHUFPS(DL, MVT::v16f32, RepeatedMask, V1, V2, DAG);

  }


  if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v16f32, V1, V2, Mask,

                                          Zeroable, Subtarget, DAG))

    return Blend;


  if (SDValue ZExt = lowerShuffleAsZeroOrAnyExtend(

          DL, MVT::v16i32, V1, V2, Mask, Zeroable, Subtarget, DAG))

    return DAG.getBitcast(MVT::v16f32, ZExt);


  // Try to create an in-lane repeating shuffle mask and then shuffle the

  // results into the target lanes.

  if (SDValue V = lowerShuffleAsRepeatedMaskAndLanePermute(

          DL, MVT::v16f32, V1, V2, Mask, Subtarget, DAG))

    return V;


  // If we have a single input shuffle with different shuffle patterns in the

  // 128-bit lanes and don't lane cross, use variable mask VPERMILPS.

  if (V2.isUndef() &&

      !is128BitLaneCrossingShuffleMask(MVT::v16f32, Mask)) {

    SDValue VPermMask = getConstVector(Mask, MVT::v16i32, DAG, DL, true);

    return DAG.getNode(X86ISD::VPERMILPV, DL, MVT::v16f32, V1, VPermMask);

  }


  // If we have AVX512F support, we can use VEXPAND.

  if (SDValue V = lowerShuffleWithEXPAND(DL, MVT::v16f32, V1, V2, Mask,

                                         Zeroable, Subtarget, DAG))

    return V;


  return lowerShuffleWithPERMV(DL, MVT::v16f32, Mask, V1, V2, Subtarget, DAG);

}


/// Handle lowering of 8-lane 64-bit integer shuffles.


static SDValue lowerV8I64Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                 const APInt &Zeroable, SDValue V1, SDValue V2,

                                 const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v8i64 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v8i64 && "Bad operand type!");

  assert(Mask.size() == 8 && "Unexpected mask size for v8 shuffle!");


  // Try to use shift instructions if fast.

  if (Subtarget.preferLowerShuffleAsShift())

    if (SDValue Shift =

            lowerShuffleAsShift(DL, MVT::v8i64, V1, V2, Mask, Zeroable,

                                Subtarget, DAG, /*BitwiseOnly*/ true))

      return Shift;


  if (V2.isUndef()) {

    // When the shuffle is mirrored between the 128-bit lanes of the unit, we

    // can use lower latency instructions that will operate on all four

    // 128-bit lanes.

    SmallVector<int, 2> Repeated128Mask;

    if (is128BitLaneRepeatedShuffleMask(MVT::v8i64, Mask, Repeated128Mask)) {

      SmallVector<int, 4> PSHUFDMask;

      narrowShuffleMaskElts(2, Repeated128Mask, PSHUFDMask);

      return DAG.getBitcast(

          MVT::v8i64,

          DAG.getNode(X86ISD::PSHUFD, DL, MVT::v16i32,

                      DAG.getBitcast(MVT::v16i32, V1),

                      getV4X86ShuffleImm8ForMask(PSHUFDMask, DL, DAG)));

    }


    SmallVector<int, 4> Repeated256Mask;

    if (is256BitLaneRepeatedShuffleMask(MVT::v8i64, Mask, Repeated256Mask))

      return DAG.getNode(X86ISD::VPERMI, DL, MVT::v8i64, V1,

                         getV4X86ShuffleImm8ForMask(Repeated256Mask, DL, DAG));

  }


  if (SDValue Shuf128 = lowerV4X128Shuffle(DL, MVT::v8i64, Mask, Zeroable, V1,

                                           V2, Subtarget, DAG))

    return Shuf128;


  // Try to use shift instructions.

  if (SDValue Shift =

          lowerShuffleAsShift(DL, MVT::v8i64, V1, V2, Mask, Zeroable, Subtarget,

                              DAG, /*BitwiseOnly*/ false))

    return Shift;


  // Try to use VALIGN.

  if (SDValue Rotate = lowerShuffleAsVALIGN(DL, MVT::v8i64, V1, V2, Mask,

                                            Zeroable, Subtarget, DAG))

    return Rotate;


  // Try to use PALIGNR.

  if (Subtarget.hasBWI())

    if (SDValue Rotate = lowerShuffleAsByteRotate(DL, MVT::v8i64, V1, V2, Mask,

                                                  Subtarget, DAG))

      return Rotate;


  if (SDValue Unpck = lowerShuffleWithUNPCK(DL, MVT::v8i64, V1, V2, Mask, DAG))

    return Unpck;


  // If we have AVX512F support, we can use VEXPAND.

  if (SDValue V = lowerShuffleWithEXPAND(DL, MVT::v8i64, V1, V2, Mask, Zeroable,

                                         Subtarget, DAG))

    return V;


  if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v8i64, V1, V2, Mask,

                                          Zeroable, Subtarget, DAG))

    return Blend;


  return lowerShuffleWithPERMV(DL, MVT::v8i64, Mask, V1, V2, Subtarget, DAG);

}


/// Handle lowering of 16-lane 32-bit integer shuffles.


static SDValue lowerV16I32Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                  const APInt &Zeroable, SDValue V1, SDValue V2,

                                  const X86Subtarget &Subtarget,

                                  SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v16i32 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v16i32 && "Bad operand type!");

  assert(Mask.size() == 16 && "Unexpected mask size for v16 shuffle!");


  int NumV2Elements = count_if(Mask, [](int M) { return M >= 16; });


  // Whenever we can lower this as a zext, that instruction is strictly faster

  // than any alternative. It also allows us to fold memory operands into the

  // shuffle in many cases.

  if (SDValue ZExt = lowerShuffleAsZeroOrAnyExtend(

          DL, MVT::v16i32, V1, V2, Mask, Zeroable, Subtarget, DAG))

    return ZExt;


  // Try to use shift instructions if fast.

  if (Subtarget.preferLowerShuffleAsShift()) {

    if (SDValue Shift =

            lowerShuffleAsShift(DL, MVT::v16i32, V1, V2, Mask, Zeroable,

                                Subtarget, DAG, /*BitwiseOnly*/ true))

      return Shift;

    if (NumV2Elements == 0)

      if (SDValue Rotate = lowerShuffleAsBitRotate(DL, MVT::v16i32, V1, Mask,

                                                   Subtarget, DAG))

        return Rotate;

  }


  // If the shuffle mask is repeated in each 128-bit lane we can use more

  // efficient instructions that mirror the shuffles across the four 128-bit

  // lanes.

  SmallVector<int, 4> RepeatedMask;

  bool Is128BitLaneRepeatedShuffle =

      is128BitLaneRepeatedShuffleMask(MVT::v16i32, Mask, RepeatedMask);

  if (Is128BitLaneRepeatedShuffle) {

    assert(RepeatedMask.size() == 4 && "Unexpected repeated mask size!");

    if (V2.isUndef())

      return DAG.getNode(X86ISD::PSHUFD, DL, MVT::v16i32, V1,

                         getV4X86ShuffleImm8ForMask(RepeatedMask, DL, DAG));


    // Use dedicated unpack instructions for masks that match their pattern.

    if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v16i32, V1, V2, Mask, DAG))

      return V;

  }


  // Try to use shift instructions.

  if (SDValue Shift =

          lowerShuffleAsShift(DL, MVT::v16i32, V1, V2, Mask, Zeroable,

                              Subtarget, DAG, /*BitwiseOnly*/ false))

    return Shift;


  if (!Subtarget.preferLowerShuffleAsShift() && NumV2Elements != 0)

    if (SDValue Rotate =

            lowerShuffleAsBitRotate(DL, MVT::v16i32, V1, Mask, Subtarget, DAG))

      return Rotate;


  // Try to use VALIGN.

  if (SDValue Rotate = lowerShuffleAsVALIGN(DL, MVT::v16i32, V1, V2, Mask,

                                            Zeroable, Subtarget, DAG))

    return Rotate;


  // Try to use byte rotation instructions.

  if (Subtarget.hasBWI())

    if (SDValue Rotate = lowerShuffleAsByteRotate(DL, MVT::v16i32, V1, V2, Mask,

                                                  Subtarget, DAG))

      return Rotate;


  // Assume that a single SHUFPS is faster than using a permv shuffle.

  // If some CPU is harmed by the domain switch, we can fix it in a later pass.

  if (Is128BitLaneRepeatedShuffle && isSingleSHUFPSMask(RepeatedMask)) {

    SDValue CastV1 = DAG.getBitcast(MVT::v16f32, V1);

    SDValue CastV2 = DAG.getBitcast(MVT::v16f32, V2);

    SDValue ShufPS = lowerShuffleWithSHUFPS(DL, MVT::v16f32, RepeatedMask,

                                            CastV1, CastV2, DAG);

    return DAG.getBitcast(MVT::v16i32, ShufPS);

  }


  // Try to create an in-lane repeating shuffle mask and then shuffle the

  // results into the target lanes.

  if (SDValue V = lowerShuffleAsRepeatedMaskAndLanePermute(

          DL, MVT::v16i32, V1, V2, Mask, Subtarget, DAG))

    return V;


  // If we have AVX512F support, we can use VEXPAND.

  if (SDValue V = lowerShuffleWithEXPAND(DL, MVT::v16i32, V1, V2, Mask,

                                         Zeroable, Subtarget, DAG))

    return V;


  if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v16i32, V1, V2, Mask,

                                          Zeroable, Subtarget, DAG))

    return Blend;


  return lowerShuffleWithPERMV(DL, MVT::v16i32, Mask, V1, V2, Subtarget, DAG);

}


/// Handle lowering of 32-lane 16-bit integer shuffles.


static SDValue lowerV32I16Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                  const APInt &Zeroable, SDValue V1, SDValue V2,

                                  const X86Subtarget &Subtarget,

                                  SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v32i16 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v32i16 && "Bad operand type!");

  assert(Mask.size() == 32 && "Unexpected mask size for v32 shuffle!");

  assert(Subtarget.hasBWI() && "We can only lower v32i16 with AVX-512-BWI!");


  // Whenever we can lower this as a zext, that instruction is strictly faster

  // than any alternative. It also allows us to fold memory operands into the

  // shuffle in many cases.

  if (SDValue ZExt = lowerShuffleAsZeroOrAnyExtend(

          DL, MVT::v32i16, V1, V2, Mask, Zeroable, Subtarget, DAG))

    return ZExt;


  // Use dedicated unpack instructions for masks that match their pattern.

  if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v32i16, V1, V2, Mask, DAG))

    return V;


  // Use dedicated pack instructions for masks that match their pattern.

  if (SDValue V =

          lowerShuffleWithPACK(DL, MVT::v32i16, V1, V2, Mask, Subtarget, DAG))

    return V;


  // Try to use shift instructions.

  if (SDValue Shift =

          lowerShuffleAsShift(DL, MVT::v32i16, V1, V2, Mask, Zeroable,

                              Subtarget, DAG, /*BitwiseOnly*/ false))

    return Shift;


  // Try to use byte rotation instructions.

  if (SDValue Rotate = lowerShuffleAsByteRotate(DL, MVT::v32i16, V1, V2, Mask,

                                                Subtarget, DAG))

    return Rotate;


  if (V2.isUndef()) {

    // Try to use bit rotation instructions.

    if (SDValue Rotate =

            lowerShuffleAsBitRotate(DL, MVT::v32i16, V1, Mask, Subtarget, DAG))

      return Rotate;


    SmallVector<int, 8> RepeatedMask;

    if (is128BitLaneRepeatedShuffleMask(MVT::v32i16, Mask, RepeatedMask)) {

      // As this is a single-input shuffle, the repeated mask should be

      // a strictly valid v8i16 mask that we can pass through to the v8i16

      // lowering to handle even the v32 case.

      return lowerV8I16GeneralSingleInputShuffle(DL, MVT::v32i16, V1,

                                                 RepeatedMask, Subtarget, DAG);

    }

  }


  if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v32i16, V1, V2, Mask,

                                          Zeroable, Subtarget, DAG))

    return Blend;


  if (SDValue PSHUFB = lowerShuffleWithPSHUFB(DL, MVT::v32i16, Mask, V1, V2,

                                              Zeroable, Subtarget, DAG))

    return PSHUFB;


  // Try to simplify this by merging 128-bit lanes to enable a lane-based

  // shuffle.

  if (SDValue Result = lowerShuffleAsLanePermuteAndRepeatedMask(

          DL, MVT::v32i16, V1, V2, Mask, Subtarget, DAG))

    return Result;


  return lowerShuffleWithPERMV(DL, MVT::v32i16, Mask, V1, V2, Subtarget, DAG);

}


/// Handle lowering of 64-lane 8-bit integer shuffles.


static SDValue lowerV64I8Shuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                 const APInt &Zeroable, SDValue V1, SDValue V2,

                                 const X86Subtarget &Subtarget,

                                 SelectionDAG &DAG) {

  assert(V1.getSimpleValueType() == MVT::v64i8 && "Bad operand type!");

  assert(V2.getSimpleValueType() == MVT::v64i8 && "Bad operand type!");

  assert(Mask.size() == 64 && "Unexpected mask size for v64 shuffle!");

  assert(Subtarget.hasBWI() && "We can only lower v64i8 with AVX-512-BWI!");


  // Whenever we can lower this as a zext, that instruction is strictly faster

  // than any alternative. It also allows us to fold memory operands into the

  // shuffle in many cases.

  if (SDValue ZExt = lowerShuffleAsZeroOrAnyExtend(

          DL, MVT::v64i8, V1, V2, Mask, Zeroable, Subtarget, DAG))

    return ZExt;


  // Use dedicated unpack instructions for masks that match their pattern.

  if (SDValue V = lowerShuffleWithUNPCK(DL, MVT::v64i8, V1, V2, Mask, DAG))

    return V;


  // Use dedicated pack instructions for masks that match their pattern.

  if (SDValue V =

          lowerShuffleWithPACK(DL, MVT::v64i8, V1, V2, Mask, Subtarget, DAG))

    return V;


  // Try to use shift instructions.

  if (SDValue Shift =

          lowerShuffleAsShift(DL, MVT::v64i8, V1, V2, Mask, Zeroable, Subtarget,

                              DAG, /*BitwiseOnly*/ false))

    return Shift;


  // Try to use byte rotation instructions.

  if (SDValue Rotate = lowerShuffleAsByteRotate(DL, MVT::v64i8, V1, V2, Mask,

                                                Subtarget, DAG))

    return Rotate;


  // Try to use bit rotation instructions.

  if (V2.isUndef())

    if (SDValue Rotate =

            lowerShuffleAsBitRotate(DL, MVT::v64i8, V1, Mask, Subtarget, DAG))

      return Rotate;


  // Lower as AND if possible.

  if (SDValue Masked = lowerShuffleAsBitMask(DL, MVT::v64i8, V1, V2, Mask,

                                             Zeroable, Subtarget, DAG))

    return Masked;


  if (SDValue PSHUFB = lowerShuffleWithPSHUFB(DL, MVT::v64i8, Mask, V1, V2,

                                              Zeroable, Subtarget, DAG))

    return PSHUFB;


  // Try to create an in-lane repeating shuffle mask and then shuffle the

  // results into the target lanes.

  // FIXME: Avoid on VBMI targets as the post lane permute often interferes

  // with shuffle combining (should be fixed by topological DAG sorting).

  if (!Subtarget.hasVBMI())

    if (SDValue V = lowerShuffleAsRepeatedMaskAndLanePermute(

            DL, MVT::v64i8, V1, V2, Mask, Subtarget, DAG))

      return V;


  if (SDValue Result = lowerShuffleAsLanePermuteAndPermute(

          DL, MVT::v64i8, V1, V2, Mask, DAG, Subtarget))

    return Result;


  if (SDValue Blend = lowerShuffleAsBlend(DL, MVT::v64i8, V1, V2, Mask,

                                          Zeroable, Subtarget, DAG))

    return Blend;


  if (!is128BitLaneCrossingShuffleMask(MVT::v64i8, Mask)) {

    // Use PALIGNR+Permute if possible - permute might become PSHUFB but the

    // PALIGNR will be cheaper than the second PSHUFB+OR.

    if (SDValue V = lowerShuffleAsByteRotateAndPermute(DL, MVT::v64i8, V1, V2,

                                                       Mask, Subtarget, DAG))

      return V;


    // VBMI can use VPERMV/VPERMV3 byte shuffles more efficiently than

    // OR(PSHUFB,PSHUFB).

    if (Subtarget.hasVBMI())

      return lowerShuffleWithPERMV(DL, MVT::v64i8, Mask, V1, V2, Subtarget,

                                   DAG);


    // If we can't directly blend but can use PSHUFB, that will be better as it

    // can both shuffle and set up the inefficient blend.

    bool V1InUse, V2InUse;

    return lowerShuffleAsBlendOfPSHUFBs(DL, MVT::v64i8, V1, V2, Mask, Zeroable,

                                        DAG, V1InUse, V2InUse);

  }


  // Try to simplify this by merging 128-bit lanes to enable a lane-based

  // shuffle.

  if (SDValue Result = lowerShuffleAsLanePermuteAndRepeatedMask(

          DL, MVT::v64i8, V1, V2, Mask, Subtarget, DAG))

    return Result;


  // VBMI can use VPERMV/VPERMV3 byte shuffles.

  if (Subtarget.hasVBMI())

    return lowerShuffleWithPERMV(DL, MVT::v64i8, Mask, V1, V2, Subtarget, DAG);


  return splitAndLowerShuffle(DL, MVT::v64i8, V1, V2, Mask, DAG,

                              /*SimpleOnly*/ false);

}


/// High-level routine to lower various 512-bit x86 vector shuffles.

///

/// This routine either breaks down the specific type of a 512-bit x86 vector

/// shuffle or splits it into two 256-bit shuffles and fuses the results back

/// together based on the available instructions.


static SDValue lower512BitShuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                  MVT VT, SDValue V1, SDValue V2,

                                  const APInt &Zeroable,

                                  const X86Subtarget &Subtarget,

                                  SelectionDAG &DAG) {

  assert(Subtarget.hasAVX512() &&

         "Cannot lower 512-bit vectors w/ basic ISA!");


  // If we have a single input to the zero element, insert that into V1 if we

  // can do so cheaply.

  int NumElts = Mask.size();

  int NumV2Elements = count_if(Mask, [NumElts](int M) { return M >= NumElts; });


  if (NumV2Elements == 1 && Mask[0] >= NumElts)

    if (SDValue Insertion = lowerShuffleAsElementInsertion(

            DL, VT, V1, V2, Mask, Zeroable, Subtarget, DAG))

      return Insertion;


  // Handle special cases where the lower or upper half is UNDEF.

  if (SDValue V =

          lowerShuffleWithUndefHalf(DL, VT, V1, V2, Mask, Subtarget, DAG))

    return V;


  // Check for being able to broadcast a single element.

  if (SDValue Broadcast = lowerShuffleAsBroadcast(DL, VT, V1, V2, Mask,

                                                  Subtarget, DAG))

    return Broadcast;


  if ((VT == MVT::v32i16 || VT == MVT::v64i8) && !Subtarget.hasBWI()) {

    // Try using bit ops for masking and blending before falling back to

    // splitting.

    if (SDValue V = lowerShuffleAsBitMask(DL, VT, V1, V2, Mask, Zeroable,

                                          Subtarget, DAG))

      return V;

    if (SDValue V = lowerShuffleAsBitBlend(DL, VT, V1, V2, Mask, DAG))

      return V;


    return splitAndLowerShuffle(DL, VT, V1, V2, Mask, DAG, /*SimpleOnly*/ false);

  }


  if (VT == MVT::v32f16 || VT == MVT::v32bf16) {

    if (!Subtarget.hasBWI())

      return splitAndLowerShuffle(DL, VT, V1, V2, Mask, DAG,

                                  /*SimpleOnly*/ false);


    V1 = DAG.getBitcast(MVT::v32i16, V1);

    V2 = DAG.getBitcast(MVT::v32i16, V2);

    return DAG.getBitcast(VT,

                          DAG.getVectorShuffle(MVT::v32i16, DL, V1, V2, Mask));

  }


  // Dispatch to each element type for lowering. If we don't have support for

  // specific element type shuffles at 512 bits, immediately split them and

  // lower them. Each lowering routine of a given type is allowed to assume that

  // the requisite ISA extensions for that element type are available.

  switch (VT.SimpleTy) {

  case MVT::v8f64:

    return lowerV8F64Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v16f32:

    return lowerV16F32Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v8i64:

    return lowerV8I64Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v16i32:

    return lowerV16I32Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v32i16:

    return lowerV32I16Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);

  case MVT::v64i8:

    return lowerV64I8Shuffle(DL, Mask, Zeroable, V1, V2, Subtarget, DAG);


  default:

    llvm_unreachable("Not a valid 512-bit x86 vector type!");

  }

}


static SDValue lower1BitShuffleAsKSHIFTR(const SDLoc &DL, ArrayRef<int> Mask,

                                         MVT VT, SDValue V1, SDValue V2,

                                         const X86Subtarget &Subtarget,

                                         SelectionDAG &DAG) {

  // Shuffle should be unary.

  if (!V2.isUndef())

    return SDValue();


  int ShiftAmt = -1;

  int NumElts = Mask.size();

  for (int i = 0; i != NumElts; ++i) {

    int M = Mask[i];

    assert((M == SM_SentinelUndef || (0 <= M && M < NumElts)) &&

           "Unexpected mask index.");

    if (M < 0)

      continue;


    // The first non-undef element determines our shift amount.

    if (ShiftAmt < 0) {

      ShiftAmt = M - i;

      // Need to be shifting right.

      if (ShiftAmt <= 0)

        return SDValue();

    }

    // All non-undef elements must shift by the same amount.

    if (ShiftAmt != M - i)

      return SDValue();

  }

  assert(ShiftAmt >= 0 && "All undef?");


  // Great we found a shift right.

  SDValue Res = widenMaskVector(V1, false, Subtarget, DAG, DL);

  Res = DAG.getNode(X86ISD::KSHIFTR, DL, Res.getValueType(), Res,

                    DAG.getTargetConstant(ShiftAmt, DL, MVT::i8));

  return DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, VT, Res,

                     DAG.getVectorIdxConstant(0, DL));

}


// Determine if this shuffle can be implemented with a KSHIFT instruction.

// Returns the shift amount if possible or -1 if not. This is a simplified

// version of matchShuffleAsShift.


static int match1BitShuffleAsKSHIFT(unsigned &Opcode, ArrayRef<int> Mask,

                                    int MaskOffset, const APInt &Zeroable) {

  int Size = Mask.size();


  auto CheckZeros = [&](int Shift, bool Left) {

    for (int j = 0; j < Shift; ++j)

      if (!Zeroable[j + (Left ? 0 : (Size - Shift))])

        return false;


    return true;

  };


  auto MatchShift = [&](int Shift, bool Left) {

    unsigned Pos = Left ? Shift : 0;

    unsigned Low = Left ? 0 : Shift;

    unsigned Len = Size - Shift;

    return isSequentialOrUndefInRange(Mask, Pos, Len, Low + MaskOffset);

  };


  for (int Shift = 1; Shift != Size; ++Shift)

    for (bool Left : {true, false})

      if (CheckZeros(Shift, Left) && MatchShift(Shift, Left)) {

        Opcode = Left ? X86ISD::KSHIFTL : X86ISD::KSHIFTR;

        return Shift;

      }


  return -1;

}


// Lower vXi1 vector shuffles.

// There is no a dedicated instruction on AVX-512 that shuffles the masks.

// The only way to shuffle bits is to sign-extend the mask vector to SIMD

// vector, shuffle and then truncate it back.


static SDValue lower1BitShuffle(const SDLoc &DL, ArrayRef<int> Mask,

                                MVT VT, SDValue V1, SDValue V2,

                                const APInt &Zeroable,

                                const X86Subtarget &Subtarget,

                                SelectionDAG &DAG) {

  assert(Subtarget.hasAVX512() &&

         "Cannot lower 512-bit vectors w/o basic ISA!");


  int NumElts = Mask.size();

  int NumV2Elements = count_if(Mask, [NumElts](int M) { return M >= NumElts; });


  // Try to recognize shuffles that are just padding a subvector with zeros.

  int SubvecElts = 0;

  int Src = -1;

  for (int i = 0; i != NumElts; ++i) {

    if (Mask[i] >= 0) {

      // Grab the source from the first valid mask. All subsequent elements need

      // to use this same source.

      if (Src < 0)

        Src = Mask[i] / NumElts;

      if (Src != (Mask[i] / NumElts) || (Mask[i] % NumElts) != i)

        break;

    }


    ++SubvecElts;

  }

  assert(SubvecElts != NumElts && "Identity shuffle?");


  // Clip to a power 2.

  SubvecElts = llvm::bit_floor<uint32_t>(SubvecElts);


  // Make sure the number of zeroable bits in the top at least covers the bits

  // not covered by the subvector.

  if ((int)Zeroable.countl_one() >= (NumElts - SubvecElts)) {

    assert(Src >= 0 && "Expected a source!");

    MVT ExtractVT = MVT::getVectorVT(MVT::i1, SubvecElts);

    SDValue Extract =

        DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, ExtractVT, Src == 0 ? V1 : V2,

                    DAG.getVectorIdxConstant(0, DL));

    return DAG.getNode(ISD::INSERT_SUBVECTOR, DL, VT,

                       DAG.getConstant(0, DL, VT), Extract,

                       DAG.getVectorIdxConstant(0, DL));

  }


  // Try a simple shift right with undef elements. Later we'll try with zeros.

  if (SDValue Shift =

          lower1BitShuffleAsKSHIFTR(DL, Mask, VT, V1, V2, Subtarget, DAG))

    return Shift;


  // Try to match KSHIFTs.

  unsigned Offset = 0;

  for (SDValue V : {V1, V2}) {

    unsigned Opcode;

    int ShiftAmt = match1BitShuffleAsKSHIFT(Opcode, Mask, Offset, Zeroable);

    if (ShiftAmt >= 0) {

      SDValue Res = widenMaskVector(V, false, Subtarget, DAG, DL);

      MVT WideVT = Res.getSimpleValueType();

      // Widened right shifts need two shifts to ensure we shift in zeroes.

      if (Opcode == X86ISD::KSHIFTR && WideVT != VT) {

        int WideElts = WideVT.getVectorNumElements();

        // Shift left to put the original vector in the MSBs of the new size.

        Res =

            DAG.getNode(X86ISD::KSHIFTL, DL, WideVT, Res,

                        DAG.getTargetConstant(WideElts - NumElts, DL, MVT::i8));

        // Increase the shift amount to account for the left shift.

        ShiftAmt += WideElts - NumElts;

      }


      Res = DAG.getNode(Opcode, DL, WideVT, Res,

                        DAG.getTargetConstant(ShiftAmt, DL, MVT::i8));

      return DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, VT, Res,

                         DAG.getVectorIdxConstant(0, DL));

    }

    Offset += NumElts; // Increment for next iteration.

  }


  // If we're performing an unary shuffle on a SETCC result, try to shuffle the

  // ops instead.

  // TODO: What other unary shuffles would benefit from this?

  if (NumV2Elements == 0 && V1.getOpcode() == ISD::SETCC && V1->hasOneUse()) {

    SDValue Op0 = V1.getOperand(0);

    SDValue Op1 = V1.getOperand(1);

    ISD::CondCode CC = cast<CondCodeSDNode>(V1.getOperand(2))->get();

    EVT OpVT = Op0.getValueType();

    if (OpVT.getScalarSizeInBits() >= 32 || isBroadcastShuffleMask(Mask))

      return DAG.getSetCC(

          DL, VT, DAG.getVectorShuffle(OpVT, DL, Op0, DAG.getUNDEF(OpVT), Mask),

          DAG.getVectorShuffle(OpVT, DL, Op1, DAG.getUNDEF(OpVT), Mask), CC);

  }


  // If this is a sequential shuffle with zero'd elements - then lower to AND.

  bool IsBlendWithZero = all_of(enumerate(Mask), [&Zeroable](auto M) {

    return Zeroable[M.index()] || (M.value() == (int)M.index());

  });

  if (IsBlendWithZero) {

    const unsigned Width = std::max<unsigned>(NumElts, 8u);

    MVT IntVT = MVT::getIntegerVT(Width);


    APInt MaskValue = (~Zeroable).zextOrTrunc(Width);

    SDValue MaskNode = DAG.getConstant(MaskValue, DL, IntVT);


    MVT MaskVecVT = MVT::getVectorVT(MVT::i1, Width);

    SDValue MaskVecNode = DAG.getBitcast(MaskVecVT, MaskNode);


    SDValue MaskVec = DAG.getExtractSubvector(DL, VT, MaskVecNode, 0);

    return DAG.getNode(ISD::AND, DL, VT, V1, MaskVec);

  }


  MVT ExtVT;

  switch (VT.SimpleTy) {

  default:

    llvm_unreachable("Expected a vector of i1 elements");

  case MVT::v2i1:

    ExtVT = MVT::v2i64;

    break;

  case MVT::v4i1:

    ExtVT = MVT::v4i32;

    break;

  case MVT::v8i1:

    // Take 512-bit type, more shuffles on KNL. If we have VLX use a 256-bit

    // shuffle.

    ExtVT = Subtarget.hasVLX() ? MVT::v8i32 : MVT::v8i64;

    break;

  case MVT::v16i1:

    // Take 512-bit type, unless we are avoiding 512-bit types and have the

    // 256-bit operation available.

    ExtVT = Subtarget.canExtendTo512DQ() ? MVT::v16i32 : MVT::v16i16;

    break;

  case MVT::v32i1:

    // Take 512-bit type, unless we are avoiding 512-bit types and have the

    // 256-bit operation available.

    assert(Subtarget.hasBWI() && "Expected AVX512BW support");

    ExtVT = Subtarget.canExtendTo512BW() ? MVT::v32i16 : MVT::v32i8;

    break;

  case MVT::v64i1:

    // Fall back to scalarization. FIXME: We can do better if the shuffle

    // can be partitioned cleanly.

    if (!Subtarget.useBWIRegs())

      return SDValue();

    ExtVT = MVT::v64i8;

    break;

  }


  V1 = DAG.getNode(ISD::SIGN_EXTEND, DL, ExtVT, V1);

  V2 = DAG.getNode(ISD::SIGN_EXTEND, DL, ExtVT, V2);


  SDValue Shuffle = DAG.getVectorShuffle(ExtVT, DL, V1, V2, Mask);

  // i1 was sign extended we can use X86ISD::CVT2MASK.

  int NumElems = VT.getVectorNumElements();

  if ((Subtarget.hasBWI() && (NumElems >= 32)) ||

      (Subtarget.hasDQI() && (NumElems < 32)))

    return DAG.getSetCC(DL, VT, DAG.getConstant(0, DL, ExtVT),

                       Shuffle, ISD::SETGT);


  return DAG.getNode(ISD::TRUNCATE, DL, VT, Shuffle);

}


/// Helper function that returns true if the shuffle mask should be

/// commuted to improve canonicalization.


static bool canonicalizeShuffleMaskWithCommute(ArrayRef<int> Mask) {

  int NumElements = Mask.size();


  int NumV1Elements = 0, NumV2Elements = 0;

  for (int M : Mask)

    if (M < 0)

      continue;

    else if (M < NumElements)

      ++NumV1Elements;

    else

      ++NumV2Elements;


  // Commute the shuffle as needed such that more elements come from V1 than

  // V2. This allows us to match the shuffle pattern strictly on how many

  // elements come from V1 without handling the symmetric cases.

  if (NumV2Elements > NumV1Elements)

    return true;


  assert(NumV1Elements > 0 && "No V1 indices");


  if (NumV2Elements == 0)

    return false;


  // When the number of V1 and V2 elements are the same, try to minimize the

  // number of uses of V2 in the low half of the vector. When that is tied,

  // ensure that the sum of indices for V1 is equal to or lower than the sum

  // indices for V2. When those are equal, try to ensure that the number of odd

  // indices for V1 is lower than the number of odd indices for V2.

  if (NumV1Elements == NumV2Elements) {

    int LowV1Elements = 0, LowV2Elements = 0;

    for (int M : Mask.slice(0, NumElements / 2))

      if (M >= NumElements)

        ++LowV2Elements;

      else if (M >= 0)

        ++LowV1Elements;

    if (LowV2Elements > LowV1Elements)

      return true;

    if (LowV2Elements == LowV1Elements) {

      int SumV1Indices = 0, SumV2Indices = 0;

      for (int i = 0, Size = Mask.size(); i < Size; ++i)

        if (Mask[i] >= NumElements)

          SumV2Indices += i;

        else if (Mask[i] >= 0)

          SumV1Indices += i;

      if (SumV2Indices < SumV1Indices)

        return true;

      if (SumV2Indices == SumV1Indices) {

        int NumV1OddIndices = 0, NumV2OddIndices = 0;

        for (int i = 0, Size = Mask.size(); i < Size; ++i)

          if (Mask[i] >= NumElements)

            NumV2OddIndices += i % 2;

          else if (Mask[i] >= 0)

            NumV1OddIndices += i % 2;

        if (NumV2OddIndices < NumV1OddIndices)

          return true;

      }

    }

  }


  return false;

}


static bool canCombineAsMaskOperation(SDValue V,

                                      const X86Subtarget &Subtarget) {

  if (!Subtarget.hasAVX512())

    return false;


  if (!V.getValueType().isSimple())

    return false;


  MVT VT = V.getSimpleValueType().getScalarType();

  if ((VT == MVT::i16 || VT == MVT::i8) && !Subtarget.hasBWI())

    return false;


  // If vec width < 512, widen i8/i16 even with BWI as blendd/blendps/blendpd

  // are preferable to blendw/blendvb/masked-mov.

  if ((VT == MVT::i16 || VT == MVT::i8) &&

      V.getSimpleValueType().getSizeInBits() < 512)

    return false;


  auto HasMaskOperation = [&](SDValue V) {

    // TODO: Currently we only check limited opcode. We probably extend

    // it to all binary operation by checking TLI.isBinOp().

    switch (V->getOpcode()) {

    default:

      return false;

    case ISD::ADD:

    case ISD::SUB:

    case ISD::AND:

    case ISD::XOR:

    case ISD::OR:

    case ISD::SMAX:

    case ISD::SMIN:

    case ISD::UMAX:

    case ISD::UMIN:

    case ISD::ABS:

    case ISD::SHL:

    case ISD::SRL:

    case ISD::SRA:

    case ISD::MUL:

      break;

    }

    if (!V->hasOneUse())

      return false;


    return true;

  };


  if (HasMaskOperation(V))

    return true;


  return false;

}


// Forward declaration.

static SDValue canonicalizeShuffleMaskWithHorizOp(

    MutableArrayRef<SDValue> Ops, MutableArrayRef<int> Mask,

    unsigned RootSizeInBits, const SDLoc &DL, SelectionDAG &DAG,

    const X86Subtarget &Subtarget);


    /// Top-level lowering for x86 vector shuffles.

///

/// This handles decomposition, canonicalization, and lowering of all x86

/// vector shuffles. Most of the specific lowering strategies are encapsulated

/// above in helper routines. The canonicalization attempts to widen shuffles

/// to involve fewer lanes of wider elements, consolidate symmetric patterns

/// s.t. only one of the two inputs needs to be tested, etc.


static SDValue lowerVECTOR_SHUFFLE(SDValue Op, const X86Subtarget &Subtarget,

                                   SelectionDAG &DAG) {

  ShuffleVectorSDNode *SVOp = cast<ShuffleVectorSDNode>(Op);

  ArrayRef<int> OrigMask = SVOp->getMask();

  SDValue V1 = Op.getOperand(0);

  SDValue V2 = Op.getOperand(1);

  MVT VT = Op.getSimpleValueType();

  int NumElements = VT.getVectorNumElements();

  SDLoc DL(Op);

  bool Is1BitVector = (VT.getVectorElementType() == MVT::i1);


  assert((VT.getSizeInBits() != 64 || Is1BitVector) &&

         "Can't lower MMX shuffles");


  bool V1IsUndef = V1.isUndef();

  bool V2IsUndef = V2.isUndef();

  if (V1IsUndef && V2IsUndef)

    return DAG.getUNDEF(VT);


  // When we create a shuffle node we put the UNDEF node to second operand,

  // but in some cases the first operand may be transformed to UNDEF.

  // In this case we should just commute the node.

  if (V1IsUndef)

    return DAG.getCommutedVectorShuffle(*SVOp);


  // Check for non-undef masks pointing at an undef vector and make the masks

  // undef as well. This makes it easier to match the shuffle based solely on

  // the mask.

  if (V2IsUndef &&

      any_of(OrigMask, [NumElements](int M) { return M >= NumElements; })) {

    SmallVector<int, 8> NewMask(OrigMask);

    for (int &M : NewMask)

      if (M >= NumElements)

        M = -1;

    return DAG.getVectorShuffle(VT, DL, V1, V2, NewMask);

  }


  // Check for illegal shuffle mask element index values.

  int MaskUpperLimit = OrigMask.size() * (V2IsUndef ? 1 : 2);

  (void)MaskUpperLimit;

  assert(llvm::all_of(OrigMask,

                      [&](int M) { return -1 <= M && M < MaskUpperLimit; }) &&

         "Out of bounds shuffle index");


  // We actually see shuffles that are entirely re-arrangements of a set of

  // zero inputs. This mostly happens while decomposing complex shuffles into

  // simple ones. Directly lower these as a buildvector of zeros.

  APInt KnownUndef, KnownZero;

  computeZeroableShuffleElements(OrigMask, V1, V2, KnownUndef, KnownZero);


  APInt Zeroable = KnownUndef | KnownZero;

  if (Zeroable.isAllOnes())

    return getZeroVector(VT, Subtarget, DAG, DL);


  bool V2IsZero = !V2IsUndef && ISD::isBuildVectorAllZeros(V2.getNode());


  // Try to collapse shuffles into using a vector type with fewer elements but

  // wider element types. We cap this to not form integers or floating point

  // elements wider than 64 bits. It does not seem beneficial to form i128

  // integers to handle flipping the low and high halves of AVX 256-bit vectors.

  SmallVector<int, 16> WidenedMask;

  if (VT.getScalarSizeInBits() < 64 && !Is1BitVector &&

      !canCombineAsMaskOperation(V1, Subtarget) &&

      !canCombineAsMaskOperation(V2, Subtarget) &&

      canWidenShuffleElements(OrigMask, Zeroable, V2IsZero, WidenedMask)) {

    // Shuffle mask widening should not interfere with a broadcast opportunity

    // by obfuscating the operands with bitcasts.

    // TODO: Avoid lowering directly from this top-level function: make this

    // a query (canLowerAsBroadcast) and defer lowering to the type-based calls.

    if (SDValue Broadcast = lowerShuffleAsBroadcast(DL, VT, V1, V2, OrigMask,

                                                    Subtarget, DAG))

      return Broadcast;


    MVT NewEltVT = VT.isFloatingPoint()

                       ? MVT::getFloatingPointVT(VT.getScalarSizeInBits() * 2)

                       : MVT::getIntegerVT(VT.getScalarSizeInBits() * 2);

    int NewNumElts = NumElements / 2;

    MVT NewVT = MVT::getVectorVT(NewEltVT, NewNumElts);

    // Make sure that the new vector type is legal. For example, v2f64 isn't

    // legal on SSE1.

    if (DAG.getTargetLoweringInfo().isTypeLegal(NewVT)) {

      if (V2IsZero) {

        // Modify the new Mask to take all zeros from the all-zero vector.

        // Choose indices that are blend-friendly.

        bool UsedZeroVector = false;

        assert(is_contained(WidenedMask, SM_SentinelZero) &&

               "V2's non-undef elements are used?!");

        for (int i = 0; i != NewNumElts; ++i)

          if (WidenedMask[i] == SM_SentinelZero) {

            WidenedMask[i] = i + NewNumElts;

            UsedZeroVector = true;

          }

        // Ensure all elements of V2 are zero - isBuildVectorAllZeros permits

        // some elements to be undef.

        if (UsedZeroVector)

          V2 = getZeroVector(NewVT, Subtarget, DAG, DL);

      }

      V1 = DAG.getBitcast(NewVT, V1);

      V2 = DAG.getBitcast(NewVT, V2);

      return DAG.getBitcast(

          VT, DAG.getVectorShuffle(NewVT, DL, V1, V2, WidenedMask));

    }

  }


  SmallVector<SDValue> Ops = {V1, V2};

  SmallVector<int> Mask(OrigMask);


  // Canonicalize the shuffle with any horizontal ops inputs.

  // Don't attempt this if the shuffle can still be widened as we may lose

  // whole lane shuffle patterns.

  // NOTE: This may update Ops and Mask.

  if (!canWidenShuffleElements(Mask)) {

    if (SDValue HOp = canonicalizeShuffleMaskWithHorizOp(

            Ops, Mask, VT.getSizeInBits(), DL, DAG, Subtarget))

      return DAG.getBitcast(VT, HOp);


    V1 = DAG.getBitcast(VT, Ops[0]);

    V2 = DAG.getBitcast(VT, Ops[1]);

    assert(NumElements == (int)Mask.size() &&

           "canonicalizeShuffleMaskWithHorizOp "

           "shouldn't alter the shuffle mask size");

  }


  // Canonicalize zeros/ones/fp splat constants to ensure no undefs.

  // These will be materialized uniformly anyway, so make splat matching easier.

  // TODO: Allow all int constants?

  auto CanonicalizeConstant = [VT, &DL, &DAG](SDValue V) {

    if (auto *BV = dyn_cast<BuildVectorSDNode>(V)) {

      BitVector Undefs;

      if (SDValue Splat = BV->getSplatValue(&Undefs)) {

        if (Undefs.any() &&

            (isNullConstant(Splat) || isAllOnesConstant(Splat) ||

             isa<ConstantFPSDNode>(Splat))) {

          V = DAG.getBitcast(VT, DAG.getSplat(BV->getValueType(0), DL, Splat));

        }

      }

    }

    return V;

  };

  V1 = CanonicalizeConstant(V1);

  V2 = CanonicalizeConstant(V2);


  // Commute the shuffle if it will improve canonicalization.

  if (canonicalizeShuffleMaskWithCommute(Mask)) {

    ShuffleVectorSDNode::commuteMask(Mask);

    std::swap(V1, V2);

  }


  // For each vector width, delegate to a specialized lowering routine.

  if (VT.is128BitVector())

    return lower128BitShuffle(DL, Mask, VT, V1, V2, Zeroable, Subtarget, DAG);


  if (VT.is256BitVector())

    return lower256BitShuffle(DL, Mask, VT, V1, V2, Zeroable, Subtarget, DAG);


  if (VT.is512BitVector())

    return lower512BitShuffle(DL, Mask, VT, V1, V2, Zeroable, Subtarget, DAG);


  if (Is1BitVector)

    return lower1BitShuffle(DL, Mask, VT, V1, V2, Zeroable, Subtarget, DAG);


  llvm_unreachable("Unimplemented!");

}


// As legal vpcompress instructions depend on various AVX512 extensions, try to

// convert illegal vector sizes to legal ones to avoid expansion.


static SDValue lowerVECTOR_COMPRESS(SDValue Op, const X86Subtarget &Subtarget,

                                    SelectionDAG &DAG) {

  assert(Subtarget.hasAVX512() &&

         "Need AVX512 for custom VECTOR_COMPRESS lowering.");


  SDLoc DL(Op);

  SDValue Vec = Op.getOperand(0);

  SDValue Mask = Op.getOperand(1);

  SDValue Passthru = Op.getOperand(2);


  EVT VecVT = Vec.getValueType();

  EVT ElementVT = VecVT.getVectorElementType();

  unsigned NumElements = VecVT.getVectorNumElements();

  unsigned NumVecBits = VecVT.getFixedSizeInBits();

  unsigned NumElementBits = ElementVT.getFixedSizeInBits();


  // 128- and 256-bit vectors with <= 16 elements can be converted to and

  // compressed as 512-bit vectors in AVX512F.

  if (NumVecBits != 128 && NumVecBits != 256)

    return SDValue();


  if (NumElementBits == 32 || NumElementBits == 64) {

    unsigned NumLargeElements = 512 / NumElementBits;

    MVT LargeVecVT =

        MVT::getVectorVT(ElementVT.getSimpleVT(), NumLargeElements);

    MVT LargeMaskVT = MVT::getVectorVT(MVT::i1, NumLargeElements);


    Vec = widenSubVector(LargeVecVT, Vec, /*ZeroNewElements=*/false, Subtarget,

                         DAG, DL);

    Mask = widenSubVector(LargeMaskVT, Mask, /*ZeroNewElements=*/true,

                          Subtarget, DAG, DL);

    Passthru = Passthru.isUndef() ? DAG.getUNDEF(LargeVecVT)

                                  : widenSubVector(LargeVecVT, Passthru,

                                                   /*ZeroNewElements=*/false,

                                                   Subtarget, DAG, DL);


    SDValue Compressed =

        DAG.getNode(ISD::VECTOR_COMPRESS, DL, LargeVecVT, Vec, Mask, Passthru);

    return DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, VecVT, Compressed,

                       DAG.getConstant(0, DL, MVT::i64));

  }


  if (VecVT == MVT::v8i16 || VecVT == MVT::v8i8 || VecVT == MVT::v16i8 ||

      VecVT == MVT::v16i16) {

    MVT LageElementVT = MVT::getIntegerVT(512 / NumElements);

    EVT LargeVecVT = MVT::getVectorVT(LageElementVT, NumElements);


    Vec = DAG.getNode(ISD::ANY_EXTEND, DL, LargeVecVT, Vec);

    Passthru = Passthru.isUndef()

                   ? DAG.getUNDEF(LargeVecVT)

                   : DAG.getNode(ISD::ANY_EXTEND, DL, LargeVecVT, Passthru);


    SDValue Compressed =

        DAG.getNode(ISD::VECTOR_COMPRESS, DL, LargeVecVT, Vec, Mask, Passthru);

    return DAG.getNode(ISD::TRUNCATE, DL, VecVT, Compressed);

  }


  return SDValue();

}


/// Try to lower a VSELECT instruction to a vector shuffle.


static SDValue lowerVSELECTtoVectorShuffle(SDValue Op,

                                           const X86Subtarget &Subtarget,

                                           SelectionDAG &DAG) {

  SDValue Cond = Op.getOperand(0);

  SDValue LHS = Op.getOperand(1);

  SDValue RHS = Op.getOperand(2);

  MVT VT = Op.getSimpleValueType();


  // Only non-legal VSELECTs reach this lowering, convert those into generic

  // shuffles and re-use the shuffle lowering path for blends.

  if (ISD::isBuildVectorOfConstantSDNodes(Cond.getNode())) {

    SmallVector<int, 32> Mask;

    if (createShuffleMaskFromVSELECT(Mask, Cond))

      return DAG.getVectorShuffle(VT, SDLoc(Op), LHS, RHS, Mask);

  }


  return SDValue();

}


SDValue X86TargetLowering::LowerVSELECT(SDValue Op, SelectionDAG &DAG) const {

  SDValue Cond = Op.getOperand(0);

  SDValue LHS = Op.getOperand(1);

  SDValue RHS = Op.getOperand(2);


  SDLoc dl(Op);

  MVT VT = Op.getSimpleValueType();

  if (isSoftF16(VT, Subtarget)) {

    MVT NVT = VT.changeVectorElementTypeToInteger();

    return DAG.getBitcast(VT, DAG.getNode(ISD::VSELECT, dl, NVT, Cond,

                                          DAG.getBitcast(NVT, LHS),

                                          DAG.getBitcast(NVT, RHS)));

  }


  // A vselect where all conditions and data are constants can be optimized into

  // a single vector load by SelectionDAGLegalize::ExpandBUILD_VECTOR().

  if (ISD::isBuildVectorOfConstantSDNodes(Cond.getNode()) &&

      ISD::isBuildVectorOfConstantSDNodes(LHS.getNode()) &&

      ISD::isBuildVectorOfConstantSDNodes(RHS.getNode()))

    return SDValue();


  // Try to lower this to a blend-style vector shuffle. This can handle all

  // constant condition cases.

  if (SDValue BlendOp = lowerVSELECTtoVectorShuffle(Op, Subtarget, DAG))

    return BlendOp;


  // If this VSELECT has a vector if i1 as a mask, it will be directly matched

  // with patterns on the mask registers on AVX-512.

  MVT CondVT = Cond.getSimpleValueType();

  unsigned CondEltSize = Cond.getScalarValueSizeInBits();

  if (CondEltSize == 1)

    return Op;


  // Variable blends are only legal from SSE4.1 onward.

  if (!Subtarget.hasSSE41())

    return SDValue();


  unsigned EltSize = VT.getScalarSizeInBits();

  unsigned NumElts = VT.getVectorNumElements();


  // Expand v32i16/v64i8 without BWI.

  if ((VT == MVT::v32i16 || VT == MVT::v64i8) && !Subtarget.hasBWI())

    return SDValue();


  // If the VSELECT is on a 512-bit type, we have to convert a non-i1 condition

  // into an i1 condition so that we can use the mask-based 512-bit blend

  // instructions.

  if (VT.getSizeInBits() == 512) {

    // Build a mask by testing the condition against zero.

    MVT MaskVT = MVT::getVectorVT(MVT::i1, NumElts);

    SDValue Mask = DAG.getSetCC(dl, MaskVT, Cond,

                                DAG.getConstant(0, dl, CondVT),

                                ISD::SETNE);

    // Now return a new VSELECT using the mask.

    return DAG.getSelect(dl, VT, Mask, LHS, RHS);

  }


  // SEXT/TRUNC cases where the mask doesn't match the destination size.

  if (CondEltSize != EltSize) {

    // If we don't have a sign splat, rely on the expansion.

    if (CondEltSize != DAG.ComputeNumSignBits(Cond))

      return SDValue();


    MVT NewCondSVT = MVT::getIntegerVT(EltSize);

    MVT NewCondVT = MVT::getVectorVT(NewCondSVT, NumElts);

    Cond = DAG.getSExtOrTrunc(Cond, dl, NewCondVT);

    return DAG.getNode(ISD::VSELECT, dl, VT, Cond, LHS, RHS);

  }


  // v16i16/v32i8 selects without AVX2, if the condition and another operand

  // are free to split, then better to split before expanding the

  // select. Don't bother with XOP as it has the fast VPCMOV instruction.

  // TODO: This is very similar to narrowVectorSelect.

  // TODO: Add Load splitting to isFreeToSplitVector ?

  if (EltSize < 32 && VT.is256BitVector() && !Subtarget.hasAVX2() &&

      !Subtarget.hasXOP()) {

    bool FreeCond = isFreeToSplitVector(Cond, DAG);

    bool FreeLHS = isFreeToSplitVector(LHS, DAG) ||

                   (ISD::isNormalLoad(LHS.getNode()) && LHS.hasOneUse());

    bool FreeRHS = isFreeToSplitVector(RHS, DAG) ||

                   (ISD::isNormalLoad(RHS.getNode()) && RHS.hasOneUse());

    if (FreeCond && (FreeLHS || FreeRHS))

      return splitVectorOp(Op, DAG, dl);

  }


  // Only some types will be legal on some subtargets. If we can emit a legal

  // VSELECT-matching blend, return Op, and but if we need to expand, return

  // a null value.

  switch (VT.SimpleTy) {

  default:

    // Most of the vector types have blends past SSE4.1.

    return Op;


  case MVT::v32i8:

    // The byte blends for AVX vectors were introduced only in AVX2.

    if (Subtarget.hasAVX2())

      return Op;


    return SDValue();


  case MVT::v8i16:

  case MVT::v16i16:

  case MVT::v8f16:

  case MVT::v16f16: {

    // Bitcast everything to the vXi8 type and use a vXi8 vselect.

    MVT CastVT = MVT::getVectorVT(MVT::i8, NumElts * 2);

    Cond = DAG.getBitcast(CastVT, Cond);

    LHS = DAG.getBitcast(CastVT, LHS);

    RHS = DAG.getBitcast(CastVT, RHS);

    SDValue Select = DAG.getNode(ISD::VSELECT, dl, CastVT, Cond, LHS, RHS);

    return DAG.getBitcast(VT, Select);

  }

  }

}


static SDValue LowerEXTRACT_VECTOR_ELT_SSE4(SDValue Op, SelectionDAG &DAG) {

  MVT VT = Op.getSimpleValueType();

  SDValue Vec = Op.getOperand(0);

  SDValue Idx = Op.getOperand(1);

  assert(isa<ConstantSDNode>(Idx) && "Constant index expected");

  SDLoc dl(Op);


  if (!Vec.getSimpleValueType().is128BitVector())

    return SDValue();


  if (VT.getSizeInBits() == 8) {

    // If IdxVal is 0, it's cheaper to do a move instead of a pextrb, unless

    // we're going to zero extend the register or fold the store.

    if (llvm::isNullConstant(Idx) && !X86::mayFoldIntoZeroExtend(Op) &&

        !X86::mayFoldIntoStore(Op))

      return DAG.getNode(ISD::TRUNCATE, dl, MVT::i8,

                         DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, MVT::i32,

                                     DAG.getBitcast(MVT::v4i32, Vec), Idx));


    unsigned IdxVal = Idx->getAsZExtVal();

    SDValue Extract = DAG.getNode(X86ISD::PEXTRB, dl, MVT::i32, Vec,

                                  DAG.getTargetConstant(IdxVal, dl, MVT::i8));

    return DAG.getNode(ISD::TRUNCATE, dl, VT, Extract);

  }


  if (VT == MVT::f32) {

    // EXTRACTPS outputs to a GPR32 register which will require a movd to copy

    // the result back to FR32 register. It's only worth matching if the

    // result has a single use which is a store or a bitcast to i32.  And in

    // the case of a store, it's not worth it if the index is a constant 0,

    // because a MOVSSmr can be used instead, which is smaller and faster.

    if (!Op.hasOneUse())

      return SDValue();

    SDNode *User = *Op.getNode()->user_begin();

    if ((User->getOpcode() != ISD::STORE || isNullConstant(Idx)) &&

        (User->getOpcode() != ISD::BITCAST ||

         User->getValueType(0) != MVT::i32))

      return SDValue();

    SDValue Extract = DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, MVT::i32,

                                  DAG.getBitcast(MVT::v4i32, Vec), Idx);

    return DAG.getBitcast(MVT::f32, Extract);

  }


  if (VT == MVT::i32 || VT == MVT::i64)

      return Op;


  return SDValue();

}


/// Extract one bit from mask vector, like v16i1 or v8i1.

/// AVX-512 feature.


static SDValue ExtractBitFromMaskVector(SDValue Op, SelectionDAG &DAG,

                                        const X86Subtarget &Subtarget) {

  SDValue Vec = Op.getOperand(0);

  SDLoc dl(Vec);

  MVT VecVT = Vec.getSimpleValueType();

  SDValue Idx = Op.getOperand(1);

  auto* IdxC = dyn_cast<ConstantSDNode>(Idx);

  MVT EltVT = Op.getSimpleValueType();


  assert((VecVT.getVectorNumElements() <= 16 || Subtarget.hasBWI()) &&

         "Unexpected vector type in ExtractBitFromMaskVector");


  // variable index can't be handled in mask registers,

  // extend vector to VR512/128

  if (!IdxC) {

    unsigned NumElts = VecVT.getVectorNumElements();

    // Extending v8i1/v16i1 to 512-bit get better performance on KNL

    // than extending to 128/256bit.

    if (NumElts == 1) {

      Vec = widenMaskVector(Vec, false, Subtarget, DAG, dl);

      MVT IntVT = MVT::getIntegerVT(Vec.getValueType().getVectorNumElements());

      return DAG.getNode(ISD::TRUNCATE, dl, MVT::i8, DAG.getBitcast(IntVT, Vec));

    }

    MVT ExtEltVT = (NumElts <= 8) ? MVT::getIntegerVT(128 / NumElts) : MVT::i8;

    MVT ExtVecVT = MVT::getVectorVT(ExtEltVT, NumElts);

    SDValue Ext = DAG.getNode(ISD::SIGN_EXTEND, dl, ExtVecVT, Vec);

    SDValue Elt = DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, ExtEltVT, Ext, Idx);

    return DAG.getNode(ISD::TRUNCATE, dl, EltVT, Elt);

  }


  unsigned IdxVal = IdxC->getZExtValue();

  if (IdxVal == 0) // the operation is legal

    return Op;


  // Extend to natively supported kshift.

  Vec = widenMaskVector(Vec, false, Subtarget, DAG, dl);


  // Use kshiftr instruction to move to the lower element.

  Vec = DAG.getNode(X86ISD::KSHIFTR, dl, Vec.getSimpleValueType(), Vec,

                    DAG.getTargetConstant(IdxVal, dl, MVT::i8));


  return DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, Op.getValueType(), Vec,

                     DAG.getVectorIdxConstant(0, dl));

}


// Helper to find all the extracted elements from a vector.


static APInt getExtractedDemandedElts(SDNode *N) {

  MVT VT = N->getSimpleValueType(0);

  unsigned NumElts = VT.getVectorNumElements();

  APInt DemandedElts = APInt::getZero(NumElts);

  for (SDNode *User : N->users()) {

    switch (User->getOpcode()) {

    case X86ISD::PEXTRB:

    case X86ISD::PEXTRW:

    case ISD::EXTRACT_VECTOR_ELT:

      if (!isa<ConstantSDNode>(User->getOperand(1))) {

        DemandedElts.setAllBits();

        return DemandedElts;

      }

      DemandedElts.setBit(User->getConstantOperandVal(1));

      break;

    case ISD::BITCAST: {

      if (!User->getValueType(0).isSimple() ||

          !User->getValueType(0).isVector()) {

        DemandedElts.setAllBits();

        return DemandedElts;

      }

      APInt DemandedSrcElts = getExtractedDemandedElts(User);

      DemandedElts |= APIntOps::ScaleBitMask(DemandedSrcElts, NumElts);

      break;

    }

    default:

      DemandedElts.setAllBits();

      return DemandedElts;

    }

  }

  return DemandedElts;

}


SDValue

X86TargetLowering::LowerEXTRACT_VECTOR_ELT(SDValue Op,

                                           SelectionDAG &DAG) const {

  SDLoc dl(Op);

  SDValue Vec = Op.getOperand(0);

  MVT VecVT = Vec.getSimpleValueType();

  SDValue Idx = Op.getOperand(1);

  auto* IdxC = dyn_cast<ConstantSDNode>(Idx);


  if (VecVT.getVectorElementType() == MVT::i1)

    return ExtractBitFromMaskVector(Op, DAG, Subtarget);


  if (!IdxC) {

    // Its more profitable to go through memory (1 cycles throughput)

    // than using VMOVD + VPERMV/PSHUFB sequence (2/3 cycles throughput)

    // IACA tool was used to get performance estimation

    // (https://software.intel.com/en-us/articles/intel-architecture-code-analyzer)

    //

    // example : extractelement <16 x i8> %a, i32 %i

    //

    // Block Throughput: 3.00 Cycles

    // Throughput Bottleneck: Port5

    //

    // | Num Of |   Ports pressure in cycles  |    |

    // |  Uops  |  0  - DV  |  5  |  6  |  7  |    |

    // ---------------------------------------------

    // |   1    |           | 1.0 |     |     | CP | vmovd xmm1, edi

    // |   1    |           | 1.0 |     |     | CP | vpshufb xmm0, xmm0, xmm1

    // |   2    | 1.0       | 1.0 |     |     | CP | vpextrb eax, xmm0, 0x0

    // Total Num Of Uops: 4

    //

    //

    // Block Throughput: 1.00 Cycles

    // Throughput Bottleneck: PORT2_AGU, PORT3_AGU, Port4

    //

    // |    |  Ports pressure in cycles   |  |

    // |Uops| 1 | 2 - D  |3 -  D  | 4 | 5 |  |

    // ---------------------------------------------------------

    // |2^  |   | 0.5    | 0.5    |1.0|   |CP| vmovaps xmmword ptr [rsp-0x18], xmm0

    // |1   |0.5|        |        |   |0.5|  | lea rax, ptr [rsp-0x18]

    // |1   |   |0.5, 0.5|0.5, 0.5|   |   |CP| mov al, byte ptr [rdi+rax*1]

    // Total Num Of Uops: 4


    return SDValue();

  }


  unsigned IdxVal = IdxC->getZExtValue();


  // If this is a 256-bit vector result, first extract the 128-bit vector and

  // then extract the element from the 128-bit vector.

  if (VecVT.is256BitVector() || VecVT.is512BitVector()) {

    // Get the 128-bit vector.

    Vec = extract128BitVector(Vec, IdxVal, DAG, dl);

    MVT EltVT = VecVT.getVectorElementType();


    unsigned ElemsPerChunk = 128 / EltVT.getSizeInBits();

    assert(isPowerOf2_32(ElemsPerChunk) && "Elements per chunk not power of 2");


    // Find IdxVal modulo ElemsPerChunk. Since ElemsPerChunk is a power of 2

    // this can be done with a mask.

    IdxVal &= ElemsPerChunk - 1;

    return DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, Op.getValueType(), Vec,

                       DAG.getVectorIdxConstant(IdxVal, dl));

  }


  assert(VecVT.is128BitVector() && "Unexpected vector length");


  MVT VT = Op.getSimpleValueType();


  if (VT == MVT::i16) {

    // If IdxVal is 0, it's cheaper to do a move instead of a pextrw, unless

    // we're going to zero extend the register or fold the store (SSE41 only).

    if (IdxVal == 0 && !X86::mayFoldIntoZeroExtend(Op) &&

        !(Subtarget.hasSSE41() && X86::mayFoldIntoStore(Op))) {

      if (Subtarget.hasFP16())

        return Op;


      return DAG.getNode(ISD::TRUNCATE, dl, MVT::i16,

                         DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, MVT::i32,

                                     DAG.getBitcast(MVT::v4i32, Vec), Idx));

    }


    SDValue Extract = DAG.getNode(X86ISD::PEXTRW, dl, MVT::i32, Vec,

                                  DAG.getTargetConstant(IdxVal, dl, MVT::i8));

    return DAG.getNode(ISD::TRUNCATE, dl, VT, Extract);

  }


  if (Subtarget.hasSSE41())

    if (SDValue Res = LowerEXTRACT_VECTOR_ELT_SSE4(Op, DAG))

      return Res;


  // Only extract a single element from a v16i8 source - determine the common

  // DWORD/WORD that all extractions share, and extract the sub-byte.

  // TODO: Add QWORD MOVQ extraction?

  if (VT == MVT::i8) {

    APInt DemandedElts = getExtractedDemandedElts(Vec.getNode());

    assert(DemandedElts.getBitWidth() == 16 && "Vector width mismatch");


    // Extract either the lowest i32 or any i16, and extract the sub-byte.

    int DWordIdx = IdxVal / 4;

    if (DWordIdx == 0 && DemandedElts == (DemandedElts & 15)) {

      SDValue Res = DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, MVT::i32,

                                DAG.getBitcast(MVT::v4i32, Vec),

                                DAG.getVectorIdxConstant(DWordIdx, dl));

      int ShiftVal = (IdxVal % 4) * 8;

      if (ShiftVal != 0)

        Res = DAG.getNode(ISD::SRL, dl, MVT::i32, Res,

                          DAG.getConstant(ShiftVal, dl, MVT::i8));

      return DAG.getNode(ISD::TRUNCATE, dl, VT, Res);

    }


    int WordIdx = IdxVal / 2;

    if (DemandedElts == (DemandedElts & (3 << (WordIdx * 2)))) {

      SDValue Res = DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, MVT::i16,

                                DAG.getBitcast(MVT::v8i16, Vec),

                                DAG.getVectorIdxConstant(WordIdx, dl));

      int ShiftVal = (IdxVal % 2) * 8;

      if (ShiftVal != 0)

        Res = DAG.getNode(ISD::SRL, dl, MVT::i16, Res,

                          DAG.getConstant(ShiftVal, dl, MVT::i8));

      return DAG.getNode(ISD::TRUNCATE, dl, VT, Res);

    }

  }


  if (VT == MVT::f16 || VT.getSizeInBits() == 32) {

    if (IdxVal == 0)

      return Op;


    // Shuffle the element to the lowest element, then movss or movsh.

    SmallVector<int, 8> Mask(VecVT.getVectorNumElements(), -1);

    Mask[0] = static_cast<int>(IdxVal);

    Vec = DAG.getVectorShuffle(VecVT, dl, Vec, DAG.getUNDEF(VecVT), Mask);

    return DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, VT, Vec,

                       DAG.getVectorIdxConstant(0, dl));

  }


  if (VT.getSizeInBits() == 64) {

    // FIXME: .td only matches this for <2 x f64>, not <2 x i64> on 32b

    // FIXME: seems like this should be unnecessary if mov{h,l}pd were taught

    //        to match extract_elt for f64.

    if (IdxVal == 0)

      return Op;


    // UNPCKHPD the element to the lowest double word, then movsd.

    // Note if the lower 64 bits of the result of the UNPCKHPD is then stored

    // to a f64mem, the whole operation is folded into a single MOVHPDmr.

    int Mask[2] = { 1, -1 };

    Vec = DAG.getVectorShuffle(VecVT, dl, Vec, DAG.getUNDEF(VecVT), Mask);

    return DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, VT, Vec,

                       DAG.getVectorIdxConstant(0, dl));

  }


  return SDValue();

}


/// Insert one bit to mask vector, like v16i1 or v8i1.

/// AVX-512 feature.


static SDValue InsertBitToMaskVector(SDValue Op, SelectionDAG &DAG,

                                     const X86Subtarget &Subtarget) {

  SDLoc dl(Op);

  SDValue Vec = Op.getOperand(0);

  SDValue Elt = Op.getOperand(1);

  SDValue Idx = Op.getOperand(2);

  MVT VecVT = Vec.getSimpleValueType();


  if (!isa<ConstantSDNode>(Idx)) {

    // Non constant index. Extend source and destination,

    // insert element and then truncate the result.

    unsigned NumElts = VecVT.getVectorNumElements();

    MVT ExtEltVT = (NumElts <= 8) ? MVT::getIntegerVT(128 / NumElts) : MVT::i8;

    MVT ExtVecVT = MVT::getVectorVT(ExtEltVT, NumElts);

    SDValue ExtOp = DAG.getNode(ISD::INSERT_VECTOR_ELT, dl, ExtVecVT,

      DAG.getNode(ISD::SIGN_EXTEND, dl, ExtVecVT, Vec),

      DAG.getNode(ISD::SIGN_EXTEND, dl, ExtEltVT, Elt), Idx);

    return DAG.getNode(ISD::TRUNCATE, dl, VecVT, ExtOp);

  }


  // Copy into a k-register, extract to v1i1 and insert_subvector.

  SDValue EltInVec = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, MVT::v1i1, Elt);

  return DAG.getNode(ISD::INSERT_SUBVECTOR, dl, VecVT, Vec, EltInVec, Idx);

}


SDValue X86TargetLowering::LowerINSERT_VECTOR_ELT(SDValue Op,

                                                  SelectionDAG &DAG) const {

  MVT VT = Op.getSimpleValueType();

  MVT EltVT = VT.getVectorElementType();

  unsigned NumElts = VT.getVectorNumElements();

  unsigned EltSizeInBits = EltVT.getScalarSizeInBits();


  if (EltVT == MVT::i1)

    return InsertBitToMaskVector(Op, DAG, Subtarget);


  SDLoc dl(Op);

  SDValue N0 = Op.getOperand(0);

  SDValue N1 = Op.getOperand(1);

  SDValue N2 = Op.getOperand(2);

  auto *N2C = dyn_cast<ConstantSDNode>(N2);


  if (EltVT == MVT::bf16) {

    MVT IVT = VT.changeVectorElementTypeToInteger();

    SDValue Res = DAG.getNode(ISD::INSERT_VECTOR_ELT, dl, IVT,

                              DAG.getBitcast(IVT, N0),

                              DAG.getBitcast(MVT::i16, N1), N2);

    return DAG.getBitcast(VT, Res);

  }


  if (!N2C) {

    // Variable insertion indices, usually we're better off spilling to stack,

    // but AVX512 can use a variable compare+select by comparing against all

    // possible vector indices, and FP insertion has less gpr->simd traffic.

    if (!(Subtarget.hasBWI() ||

          (Subtarget.hasAVX512() && EltSizeInBits >= 32) ||

          (Subtarget.hasSSE41() && (EltVT == MVT::f32 || EltVT == MVT::f64))))

      return SDValue();


    MVT IdxSVT = MVT::getIntegerVT(EltSizeInBits);

    MVT IdxVT = MVT::getVectorVT(IdxSVT, NumElts);

    if (!isTypeLegal(IdxSVT) || !isTypeLegal(IdxVT))

      return SDValue();


    SDValue IdxExt = DAG.getZExtOrTrunc(N2, dl, IdxSVT);

    SDValue IdxSplat = DAG.getSplatBuildVector(IdxVT, dl, IdxExt);

    SDValue EltSplat = DAG.getSplatBuildVector(VT, dl, N1);


    SmallVector<SDValue, 16> RawIndices;

    for (unsigned I = 0; I != NumElts; ++I)

      RawIndices.push_back(DAG.getConstant(I, dl, IdxSVT));

    SDValue Indices = DAG.getBuildVector(IdxVT, dl, RawIndices);


    // inselt N0, N1, N2 --> select (SplatN2 == {0,1,2...}) ? SplatN1 : N0.

    return DAG.getSelectCC(dl, IdxSplat, Indices, EltSplat, N0,

                           ISD::CondCode::SETEQ);

  }


  if (N2C->getAPIntValue().uge(NumElts))

    return SDValue();

  uint64_t IdxVal = N2C->getZExtValue();


  bool IsZeroElt = X86::isZeroNode(N1);

  bool IsAllOnesElt = VT.isInteger() && llvm::isAllOnesConstant(N1);


  if (IsZeroElt || IsAllOnesElt) {

    // Lower insertion of v16i8/v32i8/v64i16 -1 elts as an 'OR' blend.

    // We don't deal with i8 0 since it appears to be handled elsewhere.

    if (IsAllOnesElt &&

        ((VT == MVT::v16i8 && !Subtarget.hasSSE41()) ||

         ((VT == MVT::v32i8 || VT == MVT::v16i16) && !Subtarget.hasInt256()))) {

      SDValue ZeroCst = DAG.getConstant(0, dl, VT.getScalarType());

      SDValue OnesCst = DAG.getAllOnesConstant(dl, VT.getScalarType());

      SmallVector<SDValue, 8> CstVectorElts(NumElts, ZeroCst);

      CstVectorElts[IdxVal] = OnesCst;

      SDValue CstVector = DAG.getBuildVector(VT, dl, CstVectorElts);

      return DAG.getNode(ISD::OR, dl, VT, N0, CstVector);

    }

    // See if we can do this more efficiently with a blend shuffle with a

    // rematerializable vector.

    if (Subtarget.hasSSE41() &&

        (EltSizeInBits >= 16 || (IsZeroElt && !VT.is128BitVector()))) {

      SmallVector<int, 8> BlendMask;

      for (unsigned i = 0; i != NumElts; ++i)

        BlendMask.push_back(i == IdxVal ? i + NumElts : i);

      SDValue CstVector = IsZeroElt ? getZeroVector(VT, Subtarget, DAG, dl)

                                    : getOnesVector(VT, DAG, dl);

      return DAG.getVectorShuffle(VT, dl, N0, CstVector, BlendMask);

    }

  }


  // If the vector is wider than 128 bits, extract the 128-bit subvector, insert

  // into that, and then insert the subvector back into the result.

  if (VT.is256BitVector() || VT.is512BitVector()) {

    // With a 256-bit vector, we can insert into the zero element efficiently

    // using a blend if we have AVX or AVX2 and the right data type.

    if (VT.is256BitVector() && IdxVal == 0) {

      // TODO: It is worthwhile to cast integer to floating point and back

      // and incur a domain crossing penalty if that's what we'll end up

      // doing anyway after extracting to a 128-bit vector.

      if ((Subtarget.hasAVX() && (EltVT == MVT::f64 || EltVT == MVT::f32)) ||

          (Subtarget.hasAVX2() && (EltVT == MVT::i32 || EltVT == MVT::i64))) {

        SDValue N1Vec = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, VT, N1);

        return DAG.getNode(X86ISD::BLENDI, dl, VT, N0, N1Vec,

                           DAG.getTargetConstant(1, dl, MVT::i8));

      }

    }


    unsigned NumEltsIn128 = 128 / EltSizeInBits;

    assert(isPowerOf2_32(NumEltsIn128) &&

           "Vectors will always have power-of-two number of elements.");


    // If we are not inserting into the low 128-bit vector chunk,

    // then prefer the broadcast+blend sequence.

    // FIXME: relax the profitability check iff all N1 uses are insertions.

    if (IdxVal >= NumEltsIn128 &&

        ((Subtarget.hasAVX2() && EltSizeInBits != 8) ||

         (Subtarget.hasAVX() && (EltSizeInBits >= 32) &&

          X86::mayFoldLoad(N1, Subtarget)))) {

      SDValue N1SplatVec = DAG.getSplatBuildVector(VT, dl, N1);

      SmallVector<int, 8> BlendMask;

      for (unsigned i = 0; i != NumElts; ++i)

        BlendMask.push_back(i == IdxVal ? i + NumElts : i);

      return DAG.getVectorShuffle(VT, dl, N0, N1SplatVec, BlendMask);

    }


    // Get the desired 128-bit vector chunk.

    SDValue V = extract128BitVector(N0, IdxVal, DAG, dl);


    // Insert the element into the desired chunk.

    // Since NumEltsIn128 is a power of 2 we can use mask instead of modulo.

    unsigned IdxIn128 = IdxVal & (NumEltsIn128 - 1);


    V = DAG.getNode(ISD::INSERT_VECTOR_ELT, dl, V.getValueType(), V, N1,

                    DAG.getVectorIdxConstant(IdxIn128, dl));


    // Insert the changed part back into the bigger vector

    return insert128BitVector(N0, V, IdxVal, DAG, dl);

  }

  assert(VT.is128BitVector() && "Only 128-bit vector types should be left!");


  // This will be just movw/movd/movq/movsh/movss/movsd.

  if (IdxVal == 0 && ISD::isBuildVectorAllZeros(N0.getNode())) {

    if (EltVT == MVT::i32 || EltVT == MVT::f32 || EltVT == MVT::f64 ||

        EltVT == MVT::f16 || EltVT == MVT::i64) {

      N1 = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, VT, N1);

      return getShuffleVectorZeroOrUndef(N1, 0, true, Subtarget, DAG);

    }


    // We can't directly insert an i8 or i16 into a vector, so zero extend

    // it to i32 first.

    if (EltVT == MVT::i16 || EltVT == MVT::i8) {

      N1 = DAG.getNode(ISD::ZERO_EXTEND, dl, MVT::i32, N1);

      MVT ShufVT = MVT::getVectorVT(MVT::i32, VT.getSizeInBits() / 32);

      N1 = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, ShufVT, N1);

      N1 = getShuffleVectorZeroOrUndef(N1, 0, true, Subtarget, DAG);

      return DAG.getBitcast(VT, N1);

    }

  }


  // Transform it so it match pinsr{b,w} which expects a GR32 as its second

  // argument. SSE41 required for pinsrb.

  if (VT == MVT::v8i16 || (VT == MVT::v16i8 && Subtarget.hasSSE41())) {

    unsigned Opc;

    if (VT == MVT::v8i16) {

      assert(Subtarget.hasSSE2() && "SSE2 required for PINSRW");

      Opc = X86ISD::PINSRW;

    } else {

      assert(VT == MVT::v16i8 && "PINSRB requires v16i8 vector");

      assert(Subtarget.hasSSE41() && "SSE41 required for PINSRB");

      Opc = X86ISD::PINSRB;

    }


    assert(N1.getValueType() != MVT::i32 && "Unexpected VT");

    N1 = DAG.getNode(ISD::ANY_EXTEND, dl, MVT::i32, N1);

    N2 = DAG.getTargetConstant(IdxVal, dl, MVT::i8);

    return DAG.getNode(Opc, dl, VT, N0, N1, N2);

  }


  if (Subtarget.hasSSE41()) {

    if (EltVT == MVT::f32) {

      // Bits [7:6] of the constant are the source select. This will always be

      //   zero here. The DAG Combiner may combine an extract_elt index into

      //   these bits. For example (insert (extract, 3), 2) could be matched by

      //   putting the '3' into bits [7:6] of X86ISD::INSERTPS.

      // Bits [5:4] of the constant are the destination select. This is the

      //   value of the incoming immediate.

      // Bits [3:0] of the constant are the zero mask. The DAG Combiner may

      //   combine either bitwise AND or insert of float 0.0 to set these bits.


      bool MinSize = DAG.getMachineFunction().getFunction().hasMinSize();

      if (IdxVal == 0 && (!MinSize || !X86::mayFoldLoad(N1, Subtarget))) {

        // If this is an insertion of 32-bits into the low 32-bits of

        // a vector, we prefer to generate a blend with immediate rather

        // than an insertps. Blends are simpler operations in hardware and so

        // will always have equal or better performance than insertps.

        // But if optimizing for size and there's a load folding opportunity,

        // generate insertps because blendps does not have a 32-bit memory

        // operand form.

        N1 = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, MVT::v4f32, N1);

        return DAG.getNode(X86ISD::BLENDI, dl, VT, N0, N1,

                           DAG.getTargetConstant(1, dl, MVT::i8));

      }

      // Create this as a scalar to vector..

      N1 = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, MVT::v4f32, N1);

      return DAG.getNode(X86ISD::INSERTPS, dl, VT, N0, N1,

                         DAG.getTargetConstant(IdxVal << 4, dl, MVT::i8));

    }


    // PINSR* works with constant index.

    if (EltVT == MVT::i32 || EltVT == MVT::i64)

      return Op;

  }


  return SDValue();

}


static SDValue LowerFLDEXP(SDValue Op, const X86Subtarget &Subtarget,

                           SelectionDAG &DAG) {

  SDLoc DL(Op);

  SDValue X = Op.getOperand(0);

  MVT XTy = X.getSimpleValueType();

  SDValue Exp = Op.getOperand(1);


  switch (XTy.SimpleTy) {

  default:

    return SDValue();

  case MVT::f16:

    if (!Subtarget.hasFP16())

      X = DAG.getFPExtendOrRound(X, DL, MVT::f32);

    [[fallthrough]];

  case MVT::f32:

  case MVT::f64: {

    MVT VT = MVT::getVectorVT(X.getSimpleValueType(),

                              128 / X.getSimpleValueType().getSizeInBits());

    Exp = DAG.getNode(ISD::SINT_TO_FP, DL, X.getValueType(), Exp);

    SDValue VX = DAG.getNode(ISD::SCALAR_TO_VECTOR, DL, VT, X);

    SDValue VExp = DAG.getNode(ISD::SCALAR_TO_VECTOR, DL, VT, Exp);

    SDValue Scalefs = DAG.getNode(X86ISD::SCALEFS, DL, VT, VX, VExp);

    SDValue Final = DAG.getExtractVectorElt(DL, X.getValueType(), Scalefs, 0);

    return DAG.getFPExtendOrRound(Final, DL, XTy);

  }

  case MVT::v4f32:

  case MVT::v2f64:

  case MVT::v8f32:

  case MVT::v4f64:

  case MVT::v16f32:

  case MVT::v8f64:

    if (XTy.getSizeInBits() == 512 || Subtarget.hasVLX()) {

      Exp = DAG.getNode(ISD::SINT_TO_FP, DL, XTy, Exp);

      return DAG.getNode(X86ISD::SCALEF, DL, XTy, X, Exp);

    }

    break;

  case MVT::v8f16:

  case MVT::v16f16:

    if (Subtarget.hasFP16()) {

      if (Subtarget.hasVLX()) {

        Exp = DAG.getNode(ISD::SINT_TO_FP, DL, XTy, Exp);

        return DAG.getNode(X86ISD::SCALEF, DL, XTy, X, Exp);

      }

      break;

    }

    X = DAG.getFPExtendOrRound(X, DL, XTy.changeVectorElementType(MVT::f32));

    Exp = DAG.getSExtOrTrunc(Exp, DL,

                             X.getSimpleValueType().changeTypeToInteger());

    break;

  case MVT::v32f16:

    if (Subtarget.hasFP16()) {

      Exp = DAG.getNode(ISD::SINT_TO_FP, DL, XTy, Exp);

      return DAG.getNode(X86ISD::SCALEF, DL, XTy, X, Exp);

    }

    return splitVectorOp(Op, DAG, DL);

  }

  SDValue WideX = widenSubVector(X, true, Subtarget, DAG, DL, 512);

  SDValue WideExp = widenSubVector(Exp, true, Subtarget, DAG, DL, 512);

  Exp = DAG.getNode(ISD::SINT_TO_FP, DL, WideExp.getSimpleValueType(), Exp);

  SDValue Scalef =

      DAG.getNode(X86ISD::SCALEF, DL, WideX.getValueType(), WideX, WideExp);

  SDValue Final =

      DAG.getExtractSubvector(DL, X.getSimpleValueType(), Scalef, 0);

  return DAG.getFPExtendOrRound(Final, DL, XTy);

}


static SDValue LowerSCALAR_TO_VECTOR(SDValue Op, const X86Subtarget &Subtarget,

                                     SelectionDAG &DAG) {

  SDLoc dl(Op);

  MVT OpVT = Op.getSimpleValueType();


  // It's always cheaper to replace a xor+movd with xorps and simplifies further

  // combines.

  if (X86::isZeroNode(Op.getOperand(0)))

    return getZeroVector(OpVT, Subtarget, DAG, dl);


  // If this is a 256-bit vector result, first insert into a 128-bit

  // vector and then insert into the 256-bit vector.

  if (!OpVT.is128BitVector()) {

    // Insert into a 128-bit vector.

    unsigned SizeFactor = OpVT.getSizeInBits() / 128;

    MVT VT128 = MVT::getVectorVT(OpVT.getVectorElementType(),

                                 OpVT.getVectorNumElements() / SizeFactor);


    Op = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, VT128, Op.getOperand(0));


    // Insert the 128-bit vector.

    return insert128BitVector(DAG.getUNDEF(OpVT), Op, 0, DAG, dl);

  }

  assert(OpVT.is128BitVector() && OpVT.isInteger() && OpVT != MVT::v2i64 &&

         "Expected an SSE type!");


  // Pass through a v4i32 or V8i16 SCALAR_TO_VECTOR as that's what we use in

  // tblgen.

  if (OpVT == MVT::v4i32 || (OpVT == MVT::v8i16 && Subtarget.hasFP16()))

    return Op;


  SDValue AnyExt = DAG.getNode(ISD::ANY_EXTEND, dl, MVT::i32, Op.getOperand(0));

  return DAG.getBitcast(

      OpVT, DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, MVT::v4i32, AnyExt));

}


// Lower a node with an INSERT_SUBVECTOR opcode.  This may result in a

// simple superregister reference or explicit instructions to insert

// the upper bits of a vector.


static SDValue LowerINSERT_SUBVECTOR(SDValue Op, const X86Subtarget &Subtarget,

                                     SelectionDAG &DAG) {

  assert(Op.getSimpleValueType().getVectorElementType() == MVT::i1);


  return insert1BitVector(Op, DAG, Subtarget);

}


static SDValue LowerEXTRACT_SUBVECTOR(SDValue Op, const X86Subtarget &Subtarget,

                                      SelectionDAG &DAG) {

  assert(Op.getSimpleValueType().getVectorElementType() == MVT::i1 &&

         "Only vXi1 extract_subvectors need custom lowering");


  SDLoc dl(Op);

  SDValue Vec = Op.getOperand(0);

  uint64_t IdxVal = Op.getConstantOperandVal(1);


  if (IdxVal == 0) // the operation is legal

    return Op;


  // Extend to natively supported kshift.

  Vec = widenMaskVector(Vec, false, Subtarget, DAG, dl);


  // Shift to the LSB.

  Vec = DAG.getNode(X86ISD::KSHIFTR, dl, Vec.getSimpleValueType(), Vec,

                    DAG.getTargetConstant(IdxVal, dl, MVT::i8));


  return DAG.getNode(ISD::EXTRACT_SUBVECTOR, dl, Op.getValueType(), Vec,

                     DAG.getVectorIdxConstant(0, dl));

}


// Returns the appropriate wrapper opcode for a global reference.

unsigned X86TargetLowering::getGlobalWrapperKind(

    const GlobalValue *GV, const unsigned char OpFlags) const {

  // References to absolute symbols are never PC-relative.

  if (GV && GV->isAbsoluteSymbolRef())

    return X86ISD::Wrapper;


  // The following OpFlags under RIP-rel PIC use RIP.

  if (Subtarget.isPICStyleRIPRel() &&

      (OpFlags == X86II::MO_NO_FLAG || OpFlags == X86II::MO_COFFSTUB ||

       OpFlags == X86II::MO_DLLIMPORT))

    return X86ISD::WrapperRIP;


  // GOTPCREL references must always use RIP.

  if (OpFlags == X86II::MO_GOTPCREL || OpFlags == X86II::MO_GOTPCREL_NORELAX)

    return X86ISD::WrapperRIP;


  return X86ISD::Wrapper;

}


// ConstantPool, JumpTable, GlobalAddress, and ExternalSymbol are lowered as

// their target counterpart wrapped in the X86ISD::Wrapper node. Suppose N is

// one of the above mentioned nodes. It has to be wrapped because otherwise

// Select(N) returns N. So the raw TargetGlobalAddress nodes, etc. can only

// be used to form addressing mode. These wrapped nodes will be selected

// into MOV32ri.

SDValue

X86TargetLowering::LowerConstantPool(SDValue Op, SelectionDAG &DAG) const {

  ConstantPoolSDNode *CP = cast<ConstantPoolSDNode>(Op);


  // In PIC mode (unless we're in RIPRel PIC mode) we add an offset to the

  // global base reg.

  unsigned char OpFlag = Subtarget.classifyLocalReference(nullptr);


  auto PtrVT = getPointerTy(DAG.getDataLayout());

  SDValue Result = DAG.getTargetConstantPool(

      CP->getConstVal(), PtrVT, CP->getAlign(), CP->getOffset(), OpFlag);

  SDLoc DL(CP);

  Result =

      DAG.getNode(getGlobalWrapperKind(nullptr, OpFlag), DL, PtrVT, Result);

  // With PIC, the address is actually $g + Offset.

  if (OpFlag) {

    Result =

        DAG.getNode(ISD::ADD, DL, PtrVT,

                    DAG.getNode(X86ISD::GlobalBaseReg, SDLoc(), PtrVT), Result);

  }


  return Result;

}


SDValue X86TargetLowering::LowerJumpTable(SDValue Op, SelectionDAG &DAG) const {

  JumpTableSDNode *JT = cast<JumpTableSDNode>(Op);


  // In PIC mode (unless we're in RIPRel PIC mode) we add an offset to the

  // global base reg.

  unsigned char OpFlag = Subtarget.classifyLocalReference(nullptr);


  EVT PtrVT = Op.getValueType();

  SDValue Result = DAG.getTargetJumpTable(JT->getIndex(), PtrVT, OpFlag);

  SDLoc DL(JT);

  Result =

      DAG.getNode(getGlobalWrapperKind(nullptr, OpFlag), DL, PtrVT, Result);


  // With PIC, the address is actually $g + Offset.

  if (OpFlag)

    Result =

        DAG.getNode(ISD::ADD, DL, PtrVT,

                    DAG.getNode(X86ISD::GlobalBaseReg, SDLoc(), PtrVT), Result);


  return Result;

}


SDValue X86TargetLowering::LowerExternalSymbol(SDValue Op,

                                               SelectionDAG &DAG) const {

  return LowerGlobalOrExternal(Op, DAG, /*ForCall=*/false, nullptr);

}


SDValue

X86TargetLowering::LowerBlockAddress(SDValue Op, SelectionDAG &DAG) const {

  // Create the TargetBlockAddressAddress node.

  unsigned char OpFlags =

    Subtarget.classifyBlockAddressReference();

  const BlockAddress *BA = cast<BlockAddressSDNode>(Op)->getBlockAddress();

  int64_t Offset = cast<BlockAddressSDNode>(Op)->getOffset();

  SDLoc dl(Op);

  EVT PtrVT = Op.getValueType();

  SDValue Result = DAG.getTargetBlockAddress(BA, PtrVT, Offset, OpFlags);

  Result =

      DAG.getNode(getGlobalWrapperKind(nullptr, OpFlags), dl, PtrVT, Result);


  // With PIC, the address is actually $g + Offset.

  if (isGlobalRelativeToPICBase(OpFlags)) {

    Result = DAG.getNode(ISD::ADD, dl, PtrVT,

                         DAG.getNode(X86ISD::GlobalBaseReg, dl, PtrVT), Result);

  }


  return Result;

}


/// Creates target global address or external symbol nodes for calls or

/// other uses.

SDValue X86TargetLowering::LowerGlobalOrExternal(SDValue Op, SelectionDAG &DAG,

                                                 bool ForCall,

                                                 bool *IsImpCall) const {

  // Unpack the global address or external symbol.

  SDLoc dl(Op);

  const GlobalValue *GV = nullptr;

  int64_t Offset = 0;

  const char *ExternalSym = nullptr;

  if (const auto *G = dyn_cast<GlobalAddressSDNode>(Op)) {

    GV = G->getGlobal();

    Offset = G->getOffset();

  } else {

    const auto *ES = cast<ExternalSymbolSDNode>(Op);

    ExternalSym = ES->getSymbol();

  }


  // Calculate some flags for address lowering.

  const Module &Mod = *DAG.getMachineFunction().getFunction().getParent();

  unsigned char OpFlags;

  if (ForCall)

    OpFlags = Subtarget.classifyGlobalFunctionReference(GV, Mod);

  else

    OpFlags = Subtarget.classifyGlobalReference(GV, Mod);

  bool HasPICReg = isGlobalRelativeToPICBase(OpFlags);

  bool NeedsLoad = isGlobalStubReference(OpFlags);


  CodeModel::Model M = DAG.getTarget().getCodeModel();

  EVT PtrVT = Op.getValueType();

  SDValue Result;


  if (GV) {

    // Create a target global address if this is a global. If possible, fold the

    // offset into the global address reference. Otherwise, ADD it on later.

    // Suppress the folding if Offset is negative: movl foo-1, %eax is not

    // allowed because if the address of foo is 0, the ELF R_X86_64_32

    // relocation will compute to a negative value, which is invalid.

    int64_t GlobalOffset = 0;

    if (OpFlags == X86II::MO_NO_FLAG && Offset >= 0 &&

        X86::isOffsetSuitableForCodeModel(Offset, M, true)) {

      std::swap(GlobalOffset, Offset);

    }

    Result = DAG.getTargetGlobalAddress(GV, dl, PtrVT, GlobalOffset, OpFlags);

  } else {

    // If this is not a global address, this must be an external symbol.

    Result = DAG.getTargetExternalSymbol(ExternalSym, PtrVT, OpFlags);

  }


  // If this is a direct call, avoid the wrapper if we don't need to do any

  // loads or adds. This allows SDAG ISel to match direct calls.

  if (ForCall && !NeedsLoad && !HasPICReg && Offset == 0)

    return Result;


  // If Import Call Optimization is enabled and this is an imported function

  // then make a note of it and return the global address without wrapping.

  if (IsImpCall && (OpFlags == X86II::MO_DLLIMPORT) &&

      Mod.getModuleFlag("import-call-optimization")) {

    assert(ForCall && "Should only enable import call optimization if we are "

                      "lowering a call");

    *IsImpCall = true;

    return Result;

  }


  Result = DAG.getNode(getGlobalWrapperKind(GV, OpFlags), dl, PtrVT, Result);


  // With PIC, the address is actually $g + Offset.

  if (HasPICReg) {

    Result = DAG.getNode(ISD::ADD, dl, PtrVT,

                         DAG.getNode(X86ISD::GlobalBaseReg, dl, PtrVT), Result);

  }


  // For globals that require a load from a stub to get the address, emit the

  // load.

  if (NeedsLoad)

    Result = DAG.getLoad(PtrVT, dl, DAG.getEntryNode(), Result,

                         MachinePointerInfo::getGOT(DAG.getMachineFunction()));


  // If there was a non-zero offset that we didn't fold, create an explicit

  // addition for it.

  if (Offset != 0)

    Result = DAG.getNode(ISD::ADD, dl, PtrVT, Result,

                         DAG.getSignedConstant(Offset, dl, PtrVT));


  return Result;

}


SDValue

X86TargetLowering::LowerGlobalAddress(SDValue Op, SelectionDAG &DAG) const {

  return LowerGlobalOrExternal(Op, DAG, /*ForCall=*/false, nullptr);

}


static SDValue GetTLSADDR(SelectionDAG &DAG, GlobalAddressSDNode *GA,

                          const EVT PtrVT, unsigned ReturnReg,

                          unsigned char OperandFlags,

                          bool LoadGlobalBaseReg = false,

                          bool LocalDynamic = false) {

  MachineFrameInfo &MFI = DAG.getMachineFunction().getFrameInfo();

  SDVTList NodeTys = DAG.getVTList(MVT::Other, MVT::Glue);

  SDLoc dl(GA);

  SDValue TGA;

  bool UseTLSDESC = DAG.getTarget().useTLSDESC();

  SDValue Chain = DAG.getEntryNode();

  SDValue Ret;

  if (LocalDynamic && UseTLSDESC) {

    TGA = DAG.getTargetExternalSymbol("_TLS_MODULE_BASE_", PtrVT, OperandFlags);

    // Reuse existing GetTLSADDR node if we can find it.

    if (TGA->hasOneUse()) {

      // TLSDESC uses TGA.

      SDNode *TLSDescOp = *TGA->user_begin();

      assert(TLSDescOp->getOpcode() == X86ISD::TLSDESC &&

             "Unexpected TLSDESC DAG");

      // CALLSEQ_END uses TGA via a chain and glue.

      auto *CallSeqEndOp = TLSDescOp->getGluedUser();

      assert(CallSeqEndOp && CallSeqEndOp->getOpcode() == ISD::CALLSEQ_END &&

             "Unexpected TLSDESC DAG");

      // CopyFromReg uses CALLSEQ_END via a chain and glue.

      auto *CopyFromRegOp = CallSeqEndOp->getGluedUser();

      assert(CopyFromRegOp && CopyFromRegOp->getOpcode() == ISD::CopyFromReg &&

             "Unexpected TLSDESC DAG");

      Ret = SDValue(CopyFromRegOp, 0);

    }

  } else {

    TGA = DAG.getTargetGlobalAddress(GA->getGlobal(), dl, GA->getValueType(0),

                                     GA->getOffset(), OperandFlags);

  }


  if (!Ret) {

    unsigned CallType = UseTLSDESC     ? X86ISD::TLSDESC

                        : LocalDynamic ? X86ISD::TLSBASEADDR

                                       : X86ISD::TLSADDR;


    Chain = DAG.getCALLSEQ_START(Chain, 0, 0, dl);

    if (LoadGlobalBaseReg) {

      SDValue InGlue;

      Chain = DAG.getCopyToReg(Chain, dl, X86::EBX,

                               DAG.getNode(X86ISD::GlobalBaseReg, dl, PtrVT),

                               InGlue);

      InGlue = Chain.getValue(1);

      Chain = DAG.getNode(CallType, dl, NodeTys, {Chain, TGA, InGlue});

    } else {

      Chain = DAG.getNode(CallType, dl, NodeTys, {Chain, TGA});

    }

    Chain = DAG.getCALLSEQ_END(Chain, 0, 0, Chain.getValue(1), dl);


    // TLSADDR will be codegen'ed as call. Inform MFI that function has calls.

    MFI.setHasCalls(true);


    SDValue Glue = Chain.getValue(1);

    Ret = DAG.getCopyFromReg(Chain, dl, ReturnReg, PtrVT, Glue);

  }


  if (!UseTLSDESC)

    return Ret;


  const X86Subtarget &Subtarget = DAG.getSubtarget<X86Subtarget>();

  unsigned Seg = Subtarget.is64Bit() ? X86AS::FS : X86AS::GS;


  Value *Ptr = Constant::getNullValue(PointerType::get(*DAG.getContext(), Seg));

  SDValue Offset =

      DAG.getLoad(PtrVT, dl, DAG.getEntryNode(), DAG.getIntPtrConstant(0, dl),

                  MachinePointerInfo(Ptr));

  return DAG.getNode(ISD::ADD, dl, PtrVT, Ret, Offset);

}


// Lower ISD::GlobalTLSAddress using the "general dynamic" model, 32 bit

static SDValue


LowerToTLSGeneralDynamicModel32(GlobalAddressSDNode *GA, SelectionDAG &DAG,

                                const EVT PtrVT) {

  return GetTLSADDR(DAG, GA, PtrVT, X86::EAX, X86II::MO_TLSGD,

                    /*LoadGlobalBaseReg=*/true);

}


// Lower ISD::GlobalTLSAddress using the "general dynamic" model, 64 bit LP64

static SDValue


LowerToTLSGeneralDynamicModel64(GlobalAddressSDNode *GA, SelectionDAG &DAG,

                                const EVT PtrVT) {

  return GetTLSADDR(DAG, GA, PtrVT, X86::RAX, X86II::MO_TLSGD);

}


// Lower ISD::GlobalTLSAddress using the "general dynamic" model, 64 bit ILP32

static SDValue


LowerToTLSGeneralDynamicModelX32(GlobalAddressSDNode *GA, SelectionDAG &DAG,

                                 const EVT PtrVT) {

  return GetTLSADDR(DAG, GA, PtrVT, X86::EAX, X86II::MO_TLSGD);

}


static SDValue LowerToTLSLocalDynamicModel(GlobalAddressSDNode *GA,

                                           SelectionDAG &DAG, const EVT PtrVT,

                                           bool Is64Bit, bool Is64BitLP64) {

  SDLoc dl(GA);


  // Get the start address of the TLS block for this module.

  X86MachineFunctionInfo *MFI =

      DAG.getMachineFunction().getInfo<X86MachineFunctionInfo>();

  MFI->incNumLocalDynamicTLSAccesses();


  SDValue Base;

  if (Is64Bit) {

    unsigned ReturnReg = Is64BitLP64 ? X86::RAX : X86::EAX;

    Base = GetTLSADDR(DAG, GA, PtrVT, ReturnReg, X86II::MO_TLSLD,

                      /*LoadGlobalBaseReg=*/false,

                      /*LocalDynamic=*/true);

  } else {

    Base = GetTLSADDR(DAG, GA, PtrVT, X86::EAX, X86II::MO_TLSLDM,

                      /*LoadGlobalBaseReg=*/true,

                      /*LocalDynamic=*/true);

  }


  // Note: the CleanupLocalDynamicTLSPass will remove redundant computations

  // of Base.


  // Build x@dtpoff.

  unsigned char OperandFlags = X86II::MO_DTPOFF;

  unsigned WrapperKind = X86ISD::Wrapper;

  SDValue TGA = DAG.getTargetGlobalAddress(GA->getGlobal(), dl,

                                           GA->getValueType(0),

                                           GA->getOffset(), OperandFlags);

  SDValue Offset = DAG.getNode(WrapperKind, dl, PtrVT, TGA);


  // Add x@dtpoff with the base.

  return DAG.getNode(ISD::ADD, dl, PtrVT, Offset, Base);

}


// Lower ISD::GlobalTLSAddress using the "initial exec" or "local exec" model.


static SDValue LowerToTLSExecModel(GlobalAddressSDNode *GA, SelectionDAG &DAG,

                                   const EVT PtrVT, TLSModel::Model model,

                                   bool is64Bit, bool isPIC) {

  SDLoc dl(GA);


  // Get the Thread Pointer, which is %gs:0 (32-bit) or %fs:0 (64-bit).

  Value *Ptr = Constant::getNullValue(

      PointerType::get(*DAG.getContext(), is64Bit ? X86AS::FS : X86AS::GS));


  SDValue ThreadPointer =

      DAG.getLoad(PtrVT, dl, DAG.getEntryNode(), DAG.getIntPtrConstant(0, dl),

                  MachinePointerInfo(Ptr));


  unsigned char OperandFlags = 0;

  // Most TLS accesses are not RIP relative, even on x86-64.  One exception is

  // initialexec.

  unsigned WrapperKind = X86ISD::Wrapper;

  if (model == TLSModel::LocalExec) {

    OperandFlags = is64Bit ? X86II::MO_TPOFF : X86II::MO_NTPOFF;

  } else if (model == TLSModel::InitialExec) {

    if (is64Bit) {

      OperandFlags = X86II::MO_GOTTPOFF;

      WrapperKind = X86ISD::WrapperRIP;

    } else {

      OperandFlags = isPIC ? X86II::MO_GOTNTPOFF : X86II::MO_INDNTPOFF;

    }

  } else {

    llvm_unreachable("Unexpected model");

  }


  // emit "addl x@ntpoff,%eax" (local exec)

  // or "addl x@indntpoff,%eax" (initial exec)

  // or "addl x@gotntpoff(%ebx) ,%eax" (initial exec, 32-bit pic)

  SDValue TGA =

      DAG.getTargetGlobalAddress(GA->getGlobal(), dl, GA->getValueType(0),

                                 GA->getOffset(), OperandFlags);

  SDValue Offset = DAG.getNode(WrapperKind, dl, PtrVT, TGA);


  if (model == TLSModel::InitialExec) {

    if (isPIC && !is64Bit) {

      Offset = DAG.getNode(ISD::ADD, dl, PtrVT,

                           DAG.getNode(X86ISD::GlobalBaseReg, SDLoc(), PtrVT),

                           Offset);

    }


    Offset = DAG.getLoad(PtrVT, dl, DAG.getEntryNode(), Offset,

                         MachinePointerInfo::getGOT(DAG.getMachineFunction()));

  }


  // The address of the thread local variable is the add of the thread

  // pointer with the offset of the variable.

  return DAG.getNode(ISD::ADD, dl, PtrVT, ThreadPointer, Offset);

}


SDValue

X86TargetLowering::LowerGlobalTLSAddress(SDValue Op, SelectionDAG &DAG) const {


  GlobalAddressSDNode *GA = cast<GlobalAddressSDNode>(Op);


  if (DAG.getTarget().useEmulatedTLS())

    return LowerToTLSEmulatedModel(GA, DAG);


  const GlobalValue *GV = GA->getGlobal();

  EVT PtrVT = Op.getValueType();

  bool PositionIndependent = isPositionIndependent();


  if (Subtarget.isTargetELF()) {

    TLSModel::Model model = DAG.getTarget().getTLSModel(GV);

    switch (model) {

      case TLSModel::GeneralDynamic:

        if (Subtarget.is64Bit()) {

          if (Subtarget.isTarget64BitLP64())

            return LowerToTLSGeneralDynamicModel64(GA, DAG, PtrVT);

          return LowerToTLSGeneralDynamicModelX32(GA, DAG, PtrVT);

        }

        return LowerToTLSGeneralDynamicModel32(GA, DAG, PtrVT);

      case TLSModel::LocalDynamic:

        return LowerToTLSLocalDynamicModel(GA, DAG, PtrVT, Subtarget.is64Bit(),

                                           Subtarget.isTarget64BitLP64());

      case TLSModel::InitialExec:

      case TLSModel::LocalExec:

        return LowerToTLSExecModel(GA, DAG, PtrVT, model, Subtarget.is64Bit(),

                                   PositionIndependent);

    }

    llvm_unreachable("Unknown TLS model.");

  }


  if (Subtarget.isTargetDarwin()) {

    // Darwin only has one model of TLS.  Lower to that.

    unsigned char OpFlag = 0;

    unsigned WrapperKind = 0;


    // In PIC mode (unless we're in RIPRel PIC mode) we add an offset to the

    // global base reg.

    bool PIC32 = PositionIndependent && !Subtarget.is64Bit();

    if (PIC32) {

      OpFlag = X86II::MO_TLVP_PIC_BASE;

      WrapperKind = X86ISD::Wrapper;

    } else {

      OpFlag = X86II::MO_TLVP;

      WrapperKind = X86ISD::WrapperRIP;

    }

    SDLoc DL(Op);

    SDValue Result = DAG.getTargetGlobalAddress(GA->getGlobal(), DL,

                                                GA->getValueType(0),

                                                GA->getOffset(), OpFlag);

    SDValue Offset = DAG.getNode(WrapperKind, DL, PtrVT, Result);


    // With PIC32, the address is actually $g + Offset.

    if (PIC32)

      Offset = DAG.getNode(ISD::ADD, DL, PtrVT,

                           DAG.getNode(X86ISD::GlobalBaseReg, SDLoc(), PtrVT),

                           Offset);


    // Lowering the machine isd will make sure everything is in the right

    // location.

    SDValue Chain = DAG.getEntryNode();

    SDVTList NodeTys = DAG.getVTList(MVT::Other, MVT::Glue);

    Chain = DAG.getCALLSEQ_START(Chain, 0, 0, DL);

    SDValue Args[] = { Chain, Offset };

    Chain = DAG.getNode(X86ISD::TLSCALL, DL, NodeTys, Args);

    Chain = DAG.getCALLSEQ_END(Chain, 0, 0, Chain.getValue(1), DL);


    // TLSCALL will be codegen'ed as call. Inform MFI that function has calls.

    MachineFrameInfo &MFI = DAG.getMachineFunction().getFrameInfo();

    MFI.setAdjustsStack(true);


    // And our return value (tls address) is in the standard call return value

    // location.

    unsigned Reg = Subtarget.is64Bit() ? X86::RAX : X86::EAX;

    return DAG.getCopyFromReg(Chain, DL, Reg, PtrVT, Chain.getValue(1));

  }


  if (Subtarget.isOSWindows()) {

    // Just use the implicit TLS architecture

    // Need to generate something similar to:

    //   mov     rdx, qword [gs:abs 58H]; Load pointer to ThreadLocalStorage

    //                                  ; from TEB

    //   mov     ecx, dword [rel _tls_index]: Load index (from C runtime)

    //   mov     rcx, qword [rdx+rcx*8]

    //   mov     eax, .tls$:tlsvar

    //   [rax+rcx] contains the address

    // Windows 64bit: gs:0x58

    // Windows 32bit: fs:__tls_array


    SDLoc dl(GA);

    SDValue Chain = DAG.getEntryNode();


    // Get the Thread Pointer, which is %fs:__tls_array (32-bit) or

    // %gs:0x58 (64-bit). On MinGW, __tls_array is not available, so directly

    // use its literal value of 0x2C.

    Value *Ptr = Constant::getNullValue(

        Subtarget.is64Bit() ? PointerType::get(*DAG.getContext(), X86AS::GS)

                            : PointerType::get(*DAG.getContext(), X86AS::FS));


    SDValue TlsArray = Subtarget.is64Bit()

                           ? DAG.getIntPtrConstant(0x58, dl)

                           : (Subtarget.isTargetWindowsGNU()

                                  ? DAG.getIntPtrConstant(0x2C, dl)

                                  : DAG.getExternalSymbol("_tls_array", PtrVT));


    SDValue ThreadPointer =

        DAG.getLoad(PtrVT, dl, Chain, TlsArray, MachinePointerInfo(Ptr));


    SDValue res;

    if (GV->getThreadLocalMode() == GlobalVariable::LocalExecTLSModel) {

      res = ThreadPointer;

    } else {

      // Load the _tls_index variable

      SDValue IDX = DAG.getExternalSymbol("_tls_index", PtrVT);

      if (Subtarget.is64Bit())

        IDX = DAG.getExtLoad(ISD::ZEXTLOAD, dl, PtrVT, Chain, IDX,

                             MachinePointerInfo(), MVT::i32);

      else

        IDX = DAG.getLoad(PtrVT, dl, Chain, IDX, MachinePointerInfo());


      const DataLayout &DL = DAG.getDataLayout();

      SDValue Scale =

          DAG.getConstant(Log2_64_Ceil(DL.getPointerSize()), dl, MVT::i8);

      IDX = DAG.getNode(ISD::SHL, dl, PtrVT, IDX, Scale);


      res = DAG.getNode(ISD::ADD, dl, PtrVT, ThreadPointer, IDX);

    }


    res = DAG.getLoad(PtrVT, dl, Chain, res, MachinePointerInfo());


    // Get the offset of start of .tls section

    SDValue TGA = DAG.getTargetGlobalAddress(GA->getGlobal(), dl,

                                             GA->getValueType(0),

                                             GA->getOffset(), X86II::MO_SECREL);

    SDValue Offset = DAG.getNode(X86ISD::Wrapper, dl, PtrVT, TGA);


    // The address of the thread local variable is the add of the thread

    // pointer with the offset of the variable.

    return DAG.getNode(ISD::ADD, dl, PtrVT, res, Offset);

  }


  llvm_unreachable("TLS not implemented for this target.");

}


bool X86TargetLowering::addressingModeSupportsTLS(const GlobalValue &GV) const {

  if (Subtarget.is64Bit() && Subtarget.isTargetELF()) {

    const TargetMachine &TM = getTargetMachine();

    TLSModel::Model Model = TM.getTLSModel(&GV);

    switch (Model) {

    case TLSModel::LocalExec:

    case TLSModel::InitialExec:

      // We can include the %fs segment register in addressing modes.

      return true;

    case TLSModel::LocalDynamic:

    case TLSModel::GeneralDynamic:

      // These models do not result in %fs relative addresses unless

      // TLS descriptior are used.

      //

      // Even in the case of TLS descriptors we currently have no way to model

      // the difference between %fs access and the computations needed for the

      // offset and returning `true` for TLS-desc currently duplicates both

      // which is detrimental :-/

      return false;

    }

  }

  return false;

}


/// Lower SRA_PARTS and friends, which return two i32 values

/// and take a 2 x i32 value to shift plus a shift amount.

/// TODO: Can this be moved to general expansion code?


static SDValue LowerShiftParts(SDValue Op, SelectionDAG &DAG) {

  SDValue Lo, Hi;

  DAG.getTargetLoweringInfo().expandShiftParts(Op.getNode(), Lo, Hi, DAG);

  return DAG.getMergeValues({Lo, Hi}, SDLoc(Op));

}


// Try to use a packed vector operation to handle i64 on 32-bit targets when

// AVX512DQ is enabled.


static SDValue LowerI64IntToFP_AVX512DQ(SDValue Op, const SDLoc &dl,

                                        SelectionDAG &DAG,

                                        const X86Subtarget &Subtarget) {

  assert((Op.getOpcode() == ISD::SINT_TO_FP ||

          Op.getOpcode() == ISD::STRICT_SINT_TO_FP ||

          Op.getOpcode() == ISD::STRICT_UINT_TO_FP ||

          Op.getOpcode() == ISD::UINT_TO_FP) &&

         "Unexpected opcode!");

  bool IsStrict = Op->isStrictFPOpcode();

  unsigned OpNo = IsStrict ? 1 : 0;

  SDValue Src = Op.getOperand(OpNo);

  MVT SrcVT = Src.getSimpleValueType();

  MVT VT = Op.getSimpleValueType();


   if (!Subtarget.hasDQI() || SrcVT != MVT::i64 || Subtarget.is64Bit() ||

       (VT != MVT::f32 && VT != MVT::f64))

    return SDValue();


  // Pack the i64 into a vector, do the operation and extract.


  // Using 256-bit to ensure result is 128-bits for f32 case.

  unsigned NumElts = Subtarget.hasVLX() ? 4 : 8;

  MVT VecInVT = MVT::getVectorVT(MVT::i64, NumElts);

  MVT VecVT = MVT::getVectorVT(VT, NumElts);


  SDValue InVec = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, VecInVT, Src);

  if (IsStrict) {

    SDValue CvtVec = DAG.getNode(Op.getOpcode(), dl, {VecVT, MVT::Other},

                                 {Op.getOperand(0), InVec});

    SDValue Chain = CvtVec.getValue(1);

    SDValue Value = DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, VT, CvtVec,

                                DAG.getVectorIdxConstant(0, dl));

    return DAG.getMergeValues({Value, Chain}, dl);

  }


  SDValue CvtVec = DAG.getNode(Op.getOpcode(), dl, VecVT, InVec);


  return DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, VT, CvtVec,

                     DAG.getVectorIdxConstant(0, dl));

}


// Try to use a packed vector operation to handle i64 on 32-bit targets.


static SDValue LowerI64IntToFP16(SDValue Op, const SDLoc &dl, SelectionDAG &DAG,

                                 const X86Subtarget &Subtarget) {

  assert((Op.getOpcode() == ISD::SINT_TO_FP ||

          Op.getOpcode() == ISD::STRICT_SINT_TO_FP ||

          Op.getOpcode() == ISD::STRICT_UINT_TO_FP ||

          Op.getOpcode() == ISD::UINT_TO_FP) &&

         "Unexpected opcode!");

  bool IsStrict = Op->isStrictFPOpcode();

  SDValue Src = Op.getOperand(IsStrict ? 1 : 0);

  MVT SrcVT = Src.getSimpleValueType();

  MVT VT = Op.getSimpleValueType();


  if (SrcVT != MVT::i64 || Subtarget.is64Bit() || VT != MVT::f16)

    return SDValue();


  // Pack the i64 into a vector, do the operation and extract.


  assert(Subtarget.hasFP16() && "Expected FP16");


  SDValue InVec = DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, MVT::v2i64, Src);

  if (IsStrict) {

    SDValue CvtVec = DAG.getNode(Op.getOpcode(), dl, {MVT::v2f16, MVT::Other},

                                 {Op.getOperand(0), InVec});

    SDValue Chain = CvtVec.getValue(1);

    SDValue Value = DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, VT, CvtVec,

                                DAG.getVectorIdxConstant(0, dl));

    return DAG.getMergeValues({Value, Chain}, dl);

  }


  SDValue CvtVec = DAG.getNode(Op.getOpcode(), dl, MVT::v2f16, InVec);


  return DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, VT, CvtVec,

                     DAG.getVectorIdxConstant(0, dl));

}


static bool useVectorCast(unsigned Opcode, MVT FromVT, MVT ToVT,

                          const X86Subtarget &Subtarget) {

  switch (Opcode) {

    case ISD::SINT_TO_FP:

      // TODO: Handle wider types with AVX/AVX512.

      if (!Subtarget.hasSSE2() || FromVT != MVT::v4i32)

        return false;

      // CVTDQ2PS or (V)CVTDQ2PD

      return ToVT == MVT::v4f32 || (Subtarget.hasAVX() && ToVT == MVT::v4f64);


    case ISD::UINT_TO_FP:

      // TODO: Handle wider types and i64 elements.

      if (!Subtarget.hasAVX512() || FromVT != MVT::v4i32)

        return false;

      // VCVTUDQ2PS or VCVTUDQ2PD

      return ToVT == MVT::v4f32 || ToVT == MVT::v4f64;


    default:

      return false;

  }

}


/// Given a scalar cast operation that is extracted from a vector, try to

/// vectorize the cast op followed by extraction. This will avoid an expensive

/// round-trip between XMM and GPR.


static SDValue vectorizeExtractedCast(SDValue Cast, const SDLoc &DL,

                                      SelectionDAG &DAG,

                                      const X86Subtarget &Subtarget) {

  // TODO: This could be enhanced to handle smaller integer types by peeking

  // through an extend.

  SDValue Extract = Cast.getOperand(0);

  MVT DestVT = Cast.getSimpleValueType();

  if (Extract.getOpcode() != ISD::EXTRACT_VECTOR_ELT ||

      !isa<ConstantSDNode>(Extract.getOperand(1)))

    return SDValue();


  // See if we have a 128-bit vector cast op for this type of cast.

  SDValue VecOp = Extract.getOperand(0);

  EVT FromVT = VecOp.getValueType();

  unsigned NumEltsInXMM = 128 / FromVT.getScalarSizeInBits();

  MVT Vec128VT =

      MVT::getVectorVT(FromVT.getScalarType().getSimpleVT(), NumEltsInXMM);

  MVT ToVT = MVT::getVectorVT(DestVT, NumEltsInXMM);

  if (!useVectorCast(Cast.getOpcode(), Vec128VT, ToVT, Subtarget))

    return SDValue();


  // If we are extracting from a non-zero element, first shuffle the source

  // vector to allow extracting from element zero.

  if (!isNullConstant(Extract.getOperand(1))) {

    SmallVector<int, 16> Mask(FromVT.getVectorNumElements(), -1);

    Mask[0] = Extract.getConstantOperandVal(1);

    VecOp = DAG.getVectorShuffle(FromVT, DL, VecOp, DAG.getUNDEF(FromVT), Mask);

  }

  // If the source vector is wider than 128-bits, extract the low part. Do not

  // create an unnecessarily wide vector cast op.

  if (FromVT != Vec128VT)

    VecOp = extract128BitVector(VecOp, 0, DAG, DL);


  // cast (extelt V, 0) --> extelt (cast (extract_subv V)), 0

  // cast (extelt V, C) --> extelt (cast (extract_subv (shuffle V, [C...]))), 0

  SDValue VCast = DAG.getNode(Cast.getOpcode(), DL, ToVT, VecOp);

  return DAG.getNode(ISD::EXTRACT_VECTOR_ELT, DL, DestVT, VCast,

                     DAG.getVectorIdxConstant(0, DL));

}


/// Given a scalar cast to FP with a cast to integer operand (almost an ftrunc),

/// try to vectorize the cast ops. This will avoid an expensive round-trip

/// between XMM and GPR.


static SDValue lowerFPToIntToFP(SDValue CastToFP, const SDLoc &DL,

                                SelectionDAG &DAG,

                                const X86Subtarget &Subtarget) {

  SDValue CastToInt = CastToFP.getOperand(0);

  MVT VT = CastToFP.getSimpleValueType();

  if ((CastToInt.getOpcode() != ISD::FP_TO_SINT &&

       CastToInt.getOpcode() != ISD::FP_TO_UINT) ||

      VT.isVector())

    return SDValue();


  MVT IntVT = CastToInt.getSimpleValueType();

  SDValue X = CastToInt.getOperand(0);

  MVT SrcVT = X.getSimpleValueType();

  if (SrcVT != MVT::f32 && SrcVT != MVT::f64)

    return SDValue();


  // See if we have 128-bit vector cast instructions for this type of cast.

  // We need cvttps2dq/cvttpd2dq and cvtdq2ps/cvtdq2pd.

  if (!Subtarget.hasSSE2() || (VT != MVT::f32 && VT != MVT::f64) ||

      (IntVT != MVT::i32 && IntVT != MVT::i64))

    return SDValue();


  unsigned SrcSize = SrcVT.getSizeInBits();

  unsigned IntSize = IntVT.getSizeInBits();

  unsigned VTSize = VT.getSizeInBits();

  bool IsUnsigned = CastToInt.getOpcode() == ISD::FP_TO_UINT;

  unsigned ToIntOpcode =

      SrcSize != IntSize ? X86ISD::CVTTP2SI : (unsigned)ISD::FP_TO_SINT;

  unsigned ToFPOpcode =

      IntSize != VTSize ? X86ISD::CVTSI2P : (unsigned)ISD::SINT_TO_FP;

  unsigned Width = 128;


  if (Subtarget.hasVLX() && Subtarget.hasDQI()) {

    // AVX512DQ+VLX

    if (IsUnsigned) {

      ToIntOpcode =

          SrcSize != IntSize ? X86ISD::CVTTP2UI : (unsigned)ISD::FP_TO_UINT;

      ToFPOpcode =

          IntSize != VTSize ? X86ISD::CVTUI2P : (unsigned)ISD::UINT_TO_FP;

    }

  } else {

    if (IsUnsigned || IntVT == MVT::i64) {

      // SSE2 can only perform f64/f32 <-> i32 signed.

      if (!Subtarget.useAVX512Regs() || !Subtarget.hasDQI())

        return SDValue();


      // Need to extend width for AVX512DQ without AVX512VL.

      Width = 512;

      ToIntOpcode = CastToInt.getOpcode();

      ToFPOpcode = IsUnsigned ? ISD::UINT_TO_FP : ISD::SINT_TO_FP;

    }

  }


  MVT VecSrcVT, VecIntVT, VecVT;

  unsigned NumElts;

  unsigned SrcElts, VTElts;

  // Some conversions are only legal with uniform vector sizes on AVX512DQ.

  if (Width == 512) {

    NumElts = std::min(Width / IntSize, Width / SrcSize);

    SrcElts = NumElts;

    VTElts = NumElts;

  } else {

    NumElts = Width / IntSize;

    SrcElts = Width / SrcSize;

    VTElts = Width / VTSize;

  }

  VecIntVT = MVT::getVectorVT(IntVT, NumElts);

  VecSrcVT = MVT::getVectorVT(SrcVT, SrcElts);

  VecVT = MVT::getVectorVT(VT, VTElts);

  // sint_to_fp (fp_to_sint X) --> extelt (sint_to_fp (fp_to_sint (s2v X))), 0

  //

  // We are not defining the high elements (for example, zero them) because

  // that could nullify any performance advantage that we hoped to gain from

  // this vector op hack. We do not expect any adverse effects (like denorm

  // penalties) with cast ops.

  SDValue ZeroIdx = DAG.getVectorIdxConstant(0, DL);

  SDValue VecX = DAG.getNode(ISD::SCALAR_TO_VECTOR, DL, VecSrcVT, X);

  SDValue VCastToInt = DAG.getNode(ToIntOpcode, DL, VecIntVT, VecX);

  SDValue VCastToFP = DAG.getNode(ToFPOpcode, DL, VecVT, VCastToInt);

  return DAG.getNode(ISD::EXTRACT_VECTOR_ELT, DL, VT, VCastToFP, ZeroIdx);

}


static SDValue lowerINT_TO_FP_vXi64(SDValue Op, const SDLoc &DL,

                                    SelectionDAG &DAG,

                                    const X86Subtarget &Subtarget) {

  bool IsStrict = Op->isStrictFPOpcode();

  MVT VT = Op->getSimpleValueType(0);

  SDValue Src = Op->getOperand(IsStrict ? 1 : 0);


  if (Subtarget.hasDQI()) {

    assert(!Subtarget.hasVLX() && "Unexpected features");


    assert((Src.getSimpleValueType() == MVT::v2i64 ||

            Src.getSimpleValueType() == MVT::v4i64) &&

           "Unsupported custom type");


    // With AVX512DQ, but not VLX we need to widen to get a 512-bit result type.

    assert((VT == MVT::v4f32 || VT == MVT::v2f64 || VT == MVT::v4f64) &&

           "Unexpected VT!");

    MVT WideVT = VT == MVT::v4f32 ? MVT::v8f32 : MVT::v8f64;


    // Need to concat with zero vector for strict fp to avoid spurious

    // exceptions.

    SDValue Tmp = IsStrict ? DAG.getConstant(0, DL, MVT::v8i64)

                           : DAG.getUNDEF(MVT::v8i64);

    Src = DAG.getNode(ISD::INSERT_SUBVECTOR, DL, MVT::v8i64, Tmp, Src,

                      DAG.getVectorIdxConstant(0, DL));

    SDValue Res, Chain;

    if (IsStrict) {

      Res = DAG.getNode(Op.getOpcode(), DL, {WideVT, MVT::Other},

                        {Op->getOperand(0), Src});

      Chain = Res.getValue(1);

    } else {

      Res = DAG.getNode(Op.getOpcode(), DL, WideVT, Src);

    }


    Res = DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, VT, Res,

                      DAG.getVectorIdxConstant(0, DL));


    if (IsStrict)

      return DAG.getMergeValues({Res, Chain}, DL);

    return Res;

  }


  bool IsSigned = Op->getOpcode() == ISD::SINT_TO_FP ||

                  Op->getOpcode() == ISD::STRICT_SINT_TO_FP;

  if (VT != MVT::v4f32 || IsSigned)

    return SDValue();


  SDValue Zero = DAG.getConstant(0, DL, MVT::v4i64);

  SDValue One  = DAG.getConstant(1, DL, MVT::v4i64);

  SDValue Sign = DAG.getNode(ISD::OR, DL, MVT::v4i64,

                             DAG.getNode(ISD::SRL, DL, MVT::v4i64, Src, One),

                             DAG.getNode(ISD::AND, DL, MVT::v4i64, Src, One));

  SDValue IsNeg = DAG.getSetCC(DL, MVT::v4i64, Src, Zero, ISD::SETLT);

  SDValue SignSrc = DAG.getSelect(DL, MVT::v4i64, IsNeg, Sign, Src);

  SmallVector<SDValue, 4> SignCvts(4);

  SmallVector<SDValue, 4> Chains(4);

  for (int i = 0; i != 4; ++i) {

    SDValue Elt = DAG.getNode(ISD::EXTRACT_VECTOR_ELT, DL, MVT::i64, SignSrc,

                              DAG.getVectorIdxConstant(i, DL));

    if (IsStrict) {

      SignCvts[i] =

          DAG.getNode(ISD::STRICT_SINT_TO_FP, DL, {MVT::f32, MVT::Other},

                      {Op.getOperand(0), Elt});

      Chains[i] = SignCvts[i].getValue(1);

    } else {

      SignCvts[i] = DAG.getNode(ISD::SINT_TO_FP, DL, MVT::f32, Elt);

    }

  }

  SDValue SignCvt = DAG.getBuildVector(VT, DL, SignCvts);


  SDValue Slow, Chain;

  if (IsStrict) {

    Chain = DAG.getNode(ISD::TokenFactor, DL, MVT::Other, Chains);

    Slow = DAG.getNode(ISD::STRICT_FADD, DL, {MVT::v4f32, MVT::Other},

                       {Chain, SignCvt, SignCvt});

    Chain = Slow.getValue(1);

  } else {

    Slow = DAG.getNode(ISD::FADD, DL, MVT::v4f32, SignCvt, SignCvt);

  }


  IsNeg = DAG.getNode(ISD::TRUNCATE, DL, MVT::v4i32, IsNeg);

  SDValue Cvt = DAG.getSelect(DL, MVT::v4f32, IsNeg, Slow, SignCvt);


  if (IsStrict)

    return DAG.getMergeValues({Cvt, Chain}, DL);


  return Cvt;

}


static SDValue promoteXINT_TO_FP(SDValue Op, const SDLoc &dl,

                                 SelectionDAG &DAG) {

  bool IsStrict = Op->isStrictFPOpcode();

  SDValue Src = Op.getOperand(IsStrict ? 1 : 0);

  SDValue Chain = IsStrict ? Op->getOperand(0) : DAG.getEntryNode();

  MVT VT = Op.getSimpleValueType();

  MVT NVT = VT.isVector() ? VT.changeVectorElementType(MVT::f32) : MVT::f32;


  SDValue Rnd = DAG.getIntPtrConstant(0, dl, /*isTarget=*/true);

  if (IsStrict)

    return DAG.getNode(

        ISD::STRICT_FP_ROUND, dl, {VT, MVT::Other},

        {Chain,

         DAG.getNode(Op.getOpcode(), dl, {NVT, MVT::Other}, {Chain, Src}),

         Rnd});

  return DAG.getNode(ISD::FP_ROUND, dl, VT,

                     DAG.getNode(Op.getOpcode(), dl, NVT, Src), Rnd);

}


static bool isLegalConversion(MVT VT, MVT FloatVT, bool IsSigned,

                              const X86Subtarget &Subtarget) {

  if (FloatVT.getScalarType() != MVT::f16 || Subtarget.hasVLX()) {

    if (VT == MVT::v4i32 && Subtarget.hasSSE2() && IsSigned)

      return true;

    if (VT == MVT::v8i32 && Subtarget.hasAVX() && IsSigned)

      return true;

  }

  if (Subtarget.hasVLX() && (VT == MVT::v4i32 || VT == MVT::v8i32))

    return true;

  if (Subtarget.useAVX512Regs()) {

    if (VT == MVT::v16i32)

      return true;

    if (VT == MVT::v8i64 && FloatVT == MVT::v8f16 && Subtarget.hasFP16())

      return true;

    if (VT == MVT::v8i64 && Subtarget.hasDQI())

      return true;

  }

  if (Subtarget.hasDQI() && Subtarget.hasVLX() &&

      (VT == MVT::v2i64 || VT == MVT::v4i64))

    return true;

  return false;

}


SDValue X86TargetLowering::LowerSINT_TO_FP(SDValue Op,

                                           SelectionDAG &DAG) const {

  bool IsStrict = Op->isStrictFPOpcode();

  unsigned OpNo = IsStrict ? 1 : 0;

  SDValue Src = Op.getOperand(OpNo);

  SDValue Chain = IsStrict ? Op->getOperand(0) : DAG.getEntryNode();

  MVT SrcVT = Src.getSimpleValueType();

  MVT VT = Op.getSimpleValueType();

  SDLoc dl(Op);


  if (isSoftF16(VT, Subtarget))

    return promoteXINT_TO_FP(Op, dl, DAG);

  else if (isLegalConversion(SrcVT, VT, true, Subtarget))

    return Op;


  if (Subtarget.isTargetWin64() && SrcVT == MVT::i128)

    return LowerWin64_INT128_TO_FP(Op, DAG);


  if (SDValue Extract = vectorizeExtractedCast(Op, dl, DAG, Subtarget))

    return Extract;


  if (SDValue R = lowerFPToIntToFP(Op, dl, DAG, Subtarget))

    return R;


  if (SrcVT.isVector()) {

    if (SrcVT == MVT::v2i32 && VT == MVT::v2f64) {

      // Note: Since v2f64 is a legal type. We don't need to zero extend the

      // source for strict FP.

      if (IsStrict)

        return DAG.getNode(

            X86ISD::STRICT_CVTSI2P, dl, {VT, MVT::Other},

            {Chain, DAG.getNode(ISD::CONCAT_VECTORS, dl, MVT::v4i32, Src,

                                DAG.getUNDEF(SrcVT))});

      return DAG.getNode(X86ISD::CVTSI2P, dl, VT,

                         DAG.getNode(ISD::CONCAT_VECTORS, dl, MVT::v4i32, Src,

                                     DAG.getUNDEF(SrcVT)));

    }

    if (SrcVT == MVT::v2i64 || SrcVT == MVT::v4i64)

      return lowerINT_TO_FP_vXi64(Op, dl, DAG, Subtarget);


    return SDValue();

  }


  assert(SrcVT <= MVT::i64 && SrcVT >= MVT::i16 &&

         "Unknown SINT_TO_FP to lower!");


  bool UseSSEReg = isScalarFPTypeInSSEReg(VT);


  // These are really Legal; return the operand so the caller accepts it as

  // Legal.

  if (SrcVT == MVT::i32 && UseSSEReg)

    return Op;

  if (SrcVT == MVT::i64 && UseSSEReg && Subtarget.is64Bit())

    return Op;


  if (SDValue V = LowerI64IntToFP_AVX512DQ(Op, dl, DAG, Subtarget))

    return V;

  if (SDValue V = LowerI64IntToFP16(Op, dl, DAG, Subtarget))

    return V;


  // SSE doesn't have an i16 conversion so we need to promote.

  if (SrcVT == MVT::i16 && (UseSSEReg || VT == MVT::f128)) {

    SDValue Ext = DAG.getNode(ISD::SIGN_EXTEND, dl, MVT::i32, Src);

    if (IsStrict)

      return DAG.getNode(ISD::STRICT_SINT_TO_FP, dl, {VT, MVT::Other},

                         {Chain, Ext});


    return DAG.getNode(ISD::SINT_TO_FP, dl, VT, Ext);

  }


  if (VT == MVT::f128 || !Subtarget.hasX87())

    return SDValue();


  SDValue ValueToStore = Src;

  if (SrcVT == MVT::i64 && Subtarget.hasSSE2() && !Subtarget.is64Bit())

    // Bitcasting to f64 here allows us to do a single 64-bit store from

    // an SSE register, avoiding the store forwarding penalty that would come

    // with two 32-bit stores.

    ValueToStore = DAG.getBitcast(MVT::f64, ValueToStore);


  unsigned Size = SrcVT.getStoreSize();

  Align Alignment(Size);

  MachineFunction &MF = DAG.getMachineFunction();

  auto PtrVT = getPointerTy(MF.getDataLayout());

  int SSFI = MF.getFrameInfo().CreateStackObject(Size, Alignment, false);

  MachinePointerInfo MPI =

      MachinePointerInfo::getFixedStack(DAG.getMachineFunction(), SSFI);

  SDValue StackSlot = DAG.getFrameIndex(SSFI, PtrVT);

  Chain = DAG.getStore(Chain, dl, ValueToStore, StackSlot, MPI, Alignment);

  std::pair<SDValue, SDValue> Tmp =

      BuildFILD(VT, SrcVT, dl, Chain, StackSlot, MPI, Alignment, DAG);


  if (IsStrict)

    return DAG.getMergeValues({Tmp.first, Tmp.second}, dl);


  return Tmp.first;

}


std::pair<SDValue, SDValue> X86TargetLowering::BuildFILD(

    EVT DstVT, EVT SrcVT, const SDLoc &DL, SDValue Chain, SDValue Pointer,

    MachinePointerInfo PtrInfo, Align Alignment, SelectionDAG &DAG) const {

  // Build the FILD

  SDVTList Tys;

  bool useSSE = isScalarFPTypeInSSEReg(DstVT);

  if (useSSE)

    Tys = DAG.getVTList(MVT::f80, MVT::Other);

  else

    Tys = DAG.getVTList(DstVT, MVT::Other);


  SDValue FILDOps[] = {Chain, Pointer};

  SDValue Result =

      DAG.getMemIntrinsicNode(X86ISD::FILD, DL, Tys, FILDOps, SrcVT, PtrInfo,

                              Alignment, MachineMemOperand::MOLoad);

  Chain = Result.getValue(1);


  if (useSSE) {

    MachineFunction &MF = DAG.getMachineFunction();

    unsigned SSFISize = DstVT.getStoreSize();

    int SSFI =

        MF.getFrameInfo().CreateStackObject(SSFISize, Align(SSFISize), false);

    auto PtrVT = getPointerTy(MF.getDataLayout());

    SDValue StackSlot = DAG.getFrameIndex(SSFI, PtrVT);

    Tys = DAG.getVTList(MVT::Other);

    SDValue FSTOps[] = {Chain, Result, StackSlot};

    MachineMemOperand *StoreMMO = DAG.getMachineFunction().getMachineMemOperand(

        MachinePointerInfo::getFixedStack(DAG.getMachineFunction(), SSFI),

        MachineMemOperand::MOStore, SSFISize, Align(SSFISize));


    Chain =

        DAG.getMemIntrinsicNode(X86ISD::FST, DL, Tys, FSTOps, DstVT, StoreMMO);

    Result = DAG.getLoad(

        DstVT, DL, Chain, StackSlot,

        MachinePointerInfo::getFixedStack(DAG.getMachineFunction(), SSFI));

    Chain = Result.getValue(1);

  }


  return { Result, Chain };

}


/// Horizontal vector math instructions may be slower than normal math with

/// shuffles. Limit horizontal op codegen based on size/speed trade-offs, uarch

/// implementation, and likely shuffle complexity of the alternate sequence.


static bool shouldUseHorizontalOp(bool IsSingleSource, SelectionDAG &DAG,

                                  const X86Subtarget &Subtarget) {

  bool IsOptimizingSize = DAG.shouldOptForSize();

  bool HasFastHOps = Subtarget.hasFastHorizontalOps();

  return !IsSingleSource || IsOptimizingSize || HasFastHOps;

}


/// 64-bit unsigned integer to double expansion.


static SDValue LowerUINT_TO_FP_i64(SDValue Op, const SDLoc &dl,

                                   SelectionDAG &DAG,

                                   const X86Subtarget &Subtarget) {

  // We can't use this algorithm for strict fp. It produces -0.0 instead of +0.0

  // when converting 0 when rounding toward negative infinity. Caller will

  // fall back to Expand for when i64 or is legal or use FILD in 32-bit mode.

  assert(!Op->isStrictFPOpcode() && "Expected non-strict uint_to_fp!");

  // This algorithm is not obvious. Here it is what we're trying to output:

  /*

     movq       %rax,  %xmm0

     punpckldq  (c0),  %xmm0  // c0: (uint4){ 0x43300000U, 0x45300000U, 0U, 0U }

     subpd      (c1),  %xmm0  // c1: (double2){ 0x1.0p52, 0x1.0p52 * 0x1.0p32 }

     #ifdef __SSE3__

       haddpd   %xmm0, %xmm0

     #else

       pshufd   $0x4e, %xmm0, %xmm1

       addpd    %xmm1, %xmm0

     #endif

  */


  LLVMContext *Context = DAG.getContext();


  // Build some magic constants.

  static const uint32_t CV0[] = { 0x43300000, 0x45300000, 0, 0 };

  Constant *C0 = ConstantDataVector::get(*Context, CV0);

  auto PtrVT = DAG.getTargetLoweringInfo().getPointerTy(DAG.getDataLayout());

  SDValue CPIdx0 = DAG.getConstantPool(C0, PtrVT, Align(16));


  SmallVector<Constant*,2> CV1;

  CV1.push_back(

    ConstantFP::get(*Context, APFloat(APFloat::IEEEdouble(),

                                      APInt(64, 0x4330000000000000ULL))));

  CV1.push_back(

    ConstantFP::get(*Context, APFloat(APFloat::IEEEdouble(),

                                      APInt(64, 0x4530000000000000ULL))));

  Constant *C1 = ConstantVector::get(CV1);

  SDValue CPIdx1 = DAG.getConstantPool(C1, PtrVT, Align(16));


  // Load the 64-bit value into an XMM register.

  SDValue XR1 =

      DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, MVT::v2i64, Op.getOperand(0));

  SDValue CLod0 = DAG.getLoad(

      MVT::v4i32, dl, DAG.getEntryNode(), CPIdx0,

      MachinePointerInfo::getConstantPool(DAG.getMachineFunction()), Align(16));

  SDValue Unpck1 =

      getUnpackl(DAG, dl, MVT::v4i32, DAG.getBitcast(MVT::v4i32, XR1), CLod0);


  SDValue CLod1 = DAG.getLoad(

      MVT::v2f64, dl, CLod0.getValue(1), CPIdx1,

      MachinePointerInfo::getConstantPool(DAG.getMachineFunction()), Align(16));

  SDValue XR2F = DAG.getBitcast(MVT::v2f64, Unpck1);

  // TODO: Are there any fast-math-flags to propagate here?

  SDValue Sub = DAG.getNode(ISD::FSUB, dl, MVT::v2f64, XR2F, CLod1);

  SDValue Result;


  if (Subtarget.hasSSE3() &&

      shouldUseHorizontalOp(true, DAG, Subtarget)) {

    Result = DAG.getNode(X86ISD::FHADD, dl, MVT::v2f64, Sub, Sub);

  } else {

    SDValue Shuffle = DAG.getVectorShuffle(MVT::v2f64, dl, Sub, Sub, {1,-1});

    Result = DAG.getNode(ISD::FADD, dl, MVT::v2f64, Shuffle, Sub);

  }

  Result = DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, MVT::f64, Result,

                       DAG.getVectorIdxConstant(0, dl));

  return Result;

}


/// 32-bit unsigned integer to float expansion.


static SDValue LowerUINT_TO_FP_i32(SDValue Op, const SDLoc &dl,

                                   SelectionDAG &DAG,

                                   const X86Subtarget &Subtarget) {

  unsigned OpNo = Op.getNode()->isStrictFPOpcode() ? 1 : 0;

  // FP constant to bias correct the final result.

  SDValue Bias = DAG.getConstantFP(

      llvm::bit_cast<double>(0x4330000000000000ULL), dl, MVT::f64);


  // Load the 32-bit value into an XMM register.

  SDValue Load =

      DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, MVT::v4i32, Op.getOperand(OpNo));


  // Zero out the upper parts of the register.

  Load = getShuffleVectorZeroOrUndef(Load, 0, true, Subtarget, DAG);


  // Or the load with the bias.

  SDValue Or = DAG.getNode(

      ISD::OR, dl, MVT::v2i64,

      DAG.getBitcast(MVT::v2i64, Load),

      DAG.getBitcast(MVT::v2i64,

                     DAG.getNode(ISD::SCALAR_TO_VECTOR, dl, MVT::v2f64, Bias)));

  Or = DAG.getNode(ISD::EXTRACT_VECTOR_ELT, dl, MVT::f64,

                   DAG.getBitcast(MVT::v2f64, Or),

                   DAG.getVectorIdxConstant(0, dl));


  if (Op.getNode()->isStrictFPOpcode()) {

    // Subtract the bias.

    // TODO: Are there any fast-math-flags to propagate here?

    SDValue Chain = Op.getOperand(0);

    SDValue Sub = DAG.getNode(ISD::STRICT_FSUB, dl, {MVT::f64, MVT::Other},

                              {Chain, Or, Bias});


    if (Op.getValueType() == Sub.getValueType())

      return Sub;


    // Handle final rounding.

    std::pair<SDValue, SDValue> ResultPair = DAG.getStrictFPExtendOrRound(

        Sub, Sub.getValue(1), dl, Op.getSimpleValueType());


    return DAG.getMergeValues({ResultPair.first, ResultPair.second}, dl);

  }


  // Subtract the bias.

  // TODO: Are there any fast-math-flags to propagate here?

  SDValue Sub = DAG.getNode(ISD::FSUB, dl, MVT::f64, Or, Bias);


  // Handle final rounding.

  return DAG.getFPExtendOrRound(Sub, dl, Op.getSimpleValueType());

}


static SDValue lowerUINT_TO_FP_v2i32(SDValue Op, const SDLoc &DL,

                                     SelectionDAG &DAG,

                                     const X86Subtarget &Subtarget) {

  if (Op.getSimpleValueType() != MVT::v2f64)

    return SDValue();


  bool IsStrict = Op->isStrictFPOpcode();


  SDValue N0 = Op.getOperand(IsStrict ? 1 : 0);

  assert(N0.getSimpleValueType() == MVT::v2i32 && "Unexpected input type");


  if (Subtarget.hasAVX512()) {

    if (!Subtarget.hasVLX()) {

      // Let generic type legalization widen this.

      if (!IsStrict)

        return SDValue();

      // Otherwise pad the integer input with 0s and widen the operation.

      N0 = DAG.getNode(ISD::CONCAT_VECTORS, DL, MVT::v4i32, N0,

                       DAG.getConstant(0, DL, MVT::v2i32));

      SDValue Res = DAG.getNode(Op->getOpcode(), DL, {MVT::v4f64, MVT::Other},

                                {Op.getOperand(0), N0});

      SDValue Chain = Res.getValue(1);

      Res = DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, MVT::v2f64, Res,

                        DAG.getVectorIdxConstant(0, DL));

      return DAG.getMergeValues({Res, Chain}, DL);

    }


    // Legalize to v4i32 type.

    N0 = DAG.getNode(ISD::CONCAT_VECTORS, DL, MVT::v4i32, N0,

                     DAG.getUNDEF(MVT::v2i32));

    if (IsStrict)

      return DAG.getNode(X86ISD::STRICT_CVTUI2P, DL, {MVT::v2f64, MVT::Other},

                         {Op.getOperand(0), N0});

    return DAG.getNode(X86ISD::CVTUI2P, DL, MVT::v2f64, N0);

  }


  // Zero extend to 2i64, OR with the floating point representation of 2^52.

  // This gives us the floating point equivalent of 2^52 + the i32 integer

  // since double has 52-bits of mantissa. Then subtract 2^52 in floating

  // point leaving just our i32 integers in double format.

  SDValue ZExtIn = DAG.getNode(ISD::ZERO_EXTEND, DL, MVT::v2i64, N0);

  SDValue VBias = DAG.getConstantFP(

      llvm::bit_cast<double>(0x4330000000000000ULL), DL, MVT::v2f64);

  SDValue Or = DAG.getNode(ISD::OR, DL, MVT::v2i64, ZExtIn,

                           DAG.getBitcast(MVT::v2i64, VBias));

  Or = DAG.getBitcast(MVT::v2f64, Or);


  if (IsStrict)

    return DAG.getNode(ISD::STRICT_FSUB, DL, {MVT::v2f64, MVT::Other},

                       {Op.getOperand(0), Or, VBias});

  return DAG.getNode(ISD::FSUB, DL, MVT::v2f64, Or, VBias);

}


static SDValue lowerUINT_TO_FP_vXi32(SDValue Op, const SDLoc &DL,

                                     SelectionDAG &DAG,

                                     const X86Subtarget &Subtarget) {

  bool IsStrict = Op->isStrictFPOpcode();

  SDValue V = Op->getOperand(IsStrict ? 1 : 0);

  MVT VecIntVT = V.getSimpleValueType();

  assert((VecIntVT == MVT::v4i32 || VecIntVT == MVT::v8i32) &&

         "Unsupported custom type");


  if (Subtarget.hasAVX512()) {

    // With AVX512, but not VLX we need to widen to get a 512-bit result type.

    assert(!Subtarget.hasVLX() && "Unexpected features");

    MVT VT = Op->getSimpleValueType(0);


    // v8i32->v8f64 is legal with AVX512 so just return it.

    if (VT == MVT::v8f64)

      return Op;


    assert((VT == MVT::v4f32 || VT == MVT::v8f32 || VT == MVT::v4f64 ||

            VT == MVT::v8f16) &&

           "Unexpected VT!");

    MVT WideVT = VT == MVT::v8f16 ? MVT::v16f16 : MVT::v16f32;

    MVT WideIntVT = MVT::v16i32;

    if (VT == MVT::v4f64) {

      WideVT = MVT::v8f64;

      WideIntVT = MVT::v8i32;

    }


    // Need to concat with zero vector for strict fp to avoid spurious

    // exceptions.

    SDValue Tmp =

        IsStrict ? DAG.getConstant(0, DL, WideIntVT) : DAG.getUNDEF(WideIntVT);

    V = DAG.getNode(ISD::INSERT_SUBVECTOR, DL, WideIntVT, Tmp, V,

                    DAG.getVectorIdxConstant(0, DL));

    SDValue Res, Chain;

    if (IsStrict) {

      Res = DAG.getNode(ISD::STRICT_UINT_TO_FP, DL, {WideVT, MVT::Other},

                        {Op->getOperand(0), V});

      Chain = Res.getValue(1);

    } else {

      Res = DAG.getNode(ISD::UINT_TO_FP, DL, WideVT, V);

    }


    Res = DAG.getNode(ISD::EXTRACT_SUBVECTOR, DL, VT, Res,

                      DAG.getVectorIdxConstant(0, DL));


    if (IsStrict)

      return DAG.getMergeValues({Res, Chain}, DL);

    return Res;

  }


  if (Subtarget.hasAVX() && VecIntVT == MVT::v4i32 &&

      Op->getSimpleValueType(0) == MVT::v4f64) {

    SDValue ZExtIn = DAG.getNode(ISD::ZERO_EXTEND, DL, MVT::v4i64, V);

    Constant *Bias = ConstantFP::get(

        *DAG.getContext(),

        APFloat(APFloat::IEEEdouble(), APInt(64, 0x4330000000000000ULL)));

    auto PtrVT = DAG.getTargetLoweringInfo().getPointerTy(DAG.getDataLayout());

    SDValue CPIdx = DAG.getConstantPool(Bias, PtrVT, Align(8));

    SDVTList Tys = DAG.getVTList(MVT::v4f64, MVT::Other);

    SDValue Ops[] = {DAG.getEntryNode(), CPIdx};

    SDValue VBias = DAG.getMemIntrinsicNode(

        X86ISD::VBROADCAST_LOAD, DL, Tys, Ops, MVT::f64,

        MachinePointerInfo::getConstantPool(DAG.getMachineFunction()), Align(8),

        MachineMemOperand::MOLoad);


    SDValue Or = DAG.getNode(ISD::OR, DL, MVT::v4i64, ZExtIn,

                             DAG.getBitcast(MVT::v4i64, VBias));

    Or = DAG.getBitcast(MVT::v4f64, Or);


    if (IsStrict)

      return DAG.getNode(ISD::STRICT_FSUB, DL, {MVT::v4f64, MVT::Other},

                         {Op.getOperand(0), Or, VBias});

    return DAG.getNode(ISD::FSUB, DL, MVT::v4f64, Or, VBias);

  }


  // The algorithm is the following:

  // #ifdef __SSE4_1__

  //     uint4 lo = _mm_blend_epi16( v, (uint4) 0x4b000000, 0xaa);

  //     uint4 hi = _mm_blend_epi16( _mm_srli_epi32(v,16),

  //                                 (uint4) 0x53000000, 0xaa);

  // #else

  //     uint4 lo = (v & (uint4) 0xffff) | (uint4) 0x4b000000;

  //     uint4 hi = (v >> 16) | (uint4) 0x53000000;

  // #endif

  //     float4 fhi = (float4) hi - (0x1.0p39f + 0x1.0p23f);

  //     return (float4) lo + fhi;


  bool Is128 = VecIntVT == MVT::v4i32;

  MVT VecFloatVT = Is128 ? MVT::v4f32 : MVT::v8f32;

  // If we convert to something else than the supported type, e.g., to v4f64,

  // abort early.

  if (VecFloatVT != Op->getSimpleValueType(0))

    return SDValue();


  // In the #idef/#else code, we have in common:

  // - The vector of constants:

  // -- 0x4b000000

  // -- 0x53000000

  // - A shift:

  // -- v >> 16


  // Create the splat vector for 0x4b000000.

  SDValue VecCstLow = DAG.getConstant(0x4b000000, DL, VecIntVT);

  // Create the splat vector for 0x53000000.

  SDValue VecCstHigh = DAG.getConstant(0x53000000, DL, VecIntVT);


  // Create the right shift.

  SDValue VecCstShift = DAG.getConstant(16, DL, VecIntVT);

  SDValue HighShift = DAG.getNode(ISD::SRL, DL, VecIntVT, V, VecCstShift);


  SDValue Low, High;

  if (Subtarget.hasSSE41()) {

    MVT VecI16VT = Is128 ? MVT::v8i16 : MVT::v16i16;

    //     uint4 lo = _mm_blend_epi16( v, (uint4) 0x4b000000, 0xaa);

    SDValue VecCstLowBitcast = DAG.getBitcast(VecI16VT, VecCstLow);

    SDValue VecBitcast = DAG.getBitcast(VecI16VT, V);

    // Low will be bitcasted right away, so do not bother bitcasting back to its

    // original type.

    Low = DAG.getNode(X86ISD::BLENDI, DL, VecI16VT, VecBitcast,

                      VecCstLowBitcast, DAG.getTargetConstant(0xaa, DL, MVT::i8));

    //     uint4 hi = _mm_blend_epi16( _mm_srli_epi32(v,16),

    //                                 (uint4) 0x53000000, 0xaa);

    SDValue VecCstHighBitcast = DAG.getBitcast(VecI16VT, VecCstHigh);

    SDValue VecShiftBitcast = DAG.getBitcast(VecI16VT, HighShift);

    // High will be bitcasted right away, so do not bother bitcasting back to

    // its original type.

    High = DAG.getNode(X86ISD::BLENDI, DL, VecI16VT, VecShiftBitcast,

                       VecCstHighBitcast, DAG.getTargetConstant(0xaa, DL, MVT::i8));

  } else {

    SDValue VecCstMask = DAG.getConstant(0xffff, DL, VecIntVT);

    //     uint4 lo = (v & (uint4) 0xffff) | (uint4) 0x4b000000;

    SDValue LowAnd = DAG.getNode(ISD::AND, DL, VecIntVT, V, VecCstMask);

    Low = DAG.getNode(ISD::OR, DL, VecIntVT, LowAnd, VecCstLow);


    //     uint4 hi = (v >> 16) | (uint4) 0x53000000;

    High = DAG.getNode(ISD::OR, DL, VecIntVT, HighShift, VecCstHigh);

  }


  // Create the vector constant for (0x1.0p39f + 0x1.0p23f).

  SDValue VecCstFSub = DAG.getConstantFP(

      APFloat(APFloat::IEEEsingle(), APInt(32, 0x53000080)), DL, VecFloatVT);


  //     float4 fhi = (float4) hi - (0x1.0p39f + 0x1.0p23f);

  // NOTE: By using fsub of a positive constant instead of fadd of a negative

  // constant, we avoid reassociation in MachineCombiner when reassoc is

  // enabled. See PR24512.

  SDValue HighBitcast = DAG.getBitcast(VecFloatVT, High);

  // TODO: Are there any fast-math-flags to propagate here?

  //     (float4) lo;

  SDValue LowBitcast = DAG.getBitcast(VecFloatVT, Low);

  //     return (float4) lo + fhi;

  if (IsStrict) {

    SDValue FHigh = DAG.getNode(ISD::STRICT_FSUB, DL, {VecFloatVT, MVT::Other},

                                {Op.getOperand(0), HighBitcast, VecCstFSub});

    return DAG.getNode(ISD::STRICT_FADD, DL, {VecFloatVT, MVT::Other},

                       {FHigh.getValue(1), LowBitcast, FHigh});

  }


  SDValue FHigh =

      DAG.getNode(ISD::FSUB, DL, VecFloatVT, HighBitcast, VecCstFSub);

  return DAG.getNode(ISD::FADD, DL, VecFloatVT, LowBitcast, FHigh);

}


static SDValue lowerUINT_TO_FP_vec(SDValue Op, const SDLoc &dl, SelectionDAG &DAG,

                                   const X86Subtarget &Subtarget) {

  unsigned OpNo = Op.getNode()->isStrictFPOpcode() ? 1 : 0;

  SDValue N0 = Op.getOperand(OpNo);

  MVT SrcVT = N0.getSimpleValueType();


  switch (SrcVT.SimpleTy) {

  default:

    llvm_unreachable("Custom UINT_TO_FP is not supported!");

  case MVT::v2i32:

    return lowerUINT_TO_FP_v2i32(Op, dl, DAG, Subtarget);

  case MVT::v4i32:

  case MVT::v8i32:

    return lowerUINT_TO_FP_vXi32(Op, dl, DAG, Subtarget);

  case MVT::v2i64:

  case MVT::v4i64:

    return lowerINT_TO_FP_vXi64(Op, dl, DAG, Subtarget);

  }

}


SDValue X86TargetLowering::LowerUINT_TO_FP(SDValue Op,

                                           SelectionDAG &DAG) const {

  bool IsStrict = Op->isStrictFPOpcode();

  unsigned OpNo = IsStrict ? 1 : 0;

  SDValue Src = Op.getOperand(OpNo);

  SDLoc dl(Op);

  auto PtrVT = getPointerTy(DAG.getDataLayout());

  MVT SrcVT = Src.getSimpleValueType();

  MVT DstVT = Op->getSimpleValueType(0);

  SDValue Chain = IsStrict ? Op.getOperand(0) : DAG.getEntryNode();


  // Bail out when we don't have native conversion instructions.

  if (DstVT == MVT::f128)

    return SDValue();


  if (isSoftF16(DstVT, Subtarget))

    return promoteXINT_TO_FP(Op, dl, DAG);

  else if (isLegalConversion(SrcVT, DstVT, false, Subtarget))

    return Op;


  if (SDValue V = lowerFPToIntToFP(Op, dl, DAG, Subtarget))

    return V;


  if (DstVT.isVector())

    return lowerUINT_TO_FP_vec(Op, dl, DAG, Subtarget);


  if (Subtarget.isTargetWin64() && SrcVT == MVT::i128)

    return LowerWin64_INT128_TO_FP(Op, DAG);


  if (SDValue Extract = vectorizeExtractedCast(Op, dl, DAG, Subtarget))

    return Extract;


  if (Subtarget.hasAVX512() && isScalarFPTypeInSSEReg(DstVT) &&

      (SrcVT == MVT::i32 || (SrcVT == MVT::i64 && Subtarget.is64Bit()))) {

    // Conversions from unsigned i32 to f32/f64 are legal,

    // using VCVTUSI2SS/SD.  Same for i64 in 64-bit mode.

    return Op;

  }


  // Promote i32 to i64 and use a signed conversion on 64-bit targets.

  if (SrcVT == MVT::i32 && Subtarget.is64Bit()) {

    Src = DAG.getNode(ISD::ZERO_EXTEND, dl, MVT::i64, Src);

    if (IsStrict)

      return DAG.getNode(ISD::STRICT_SINT_TO_FP, dl, {DstVT, MVT::Other},

                         {Chain, Src});

    return DAG.getNode(ISD::SINT_TO_FP, dl, DstVT, Src);

  }


  if (SDValue V = LowerI64IntToFP_AVX512DQ(Op, dl, DAG, Subtarget))

    return V;

  if (SDValue V = LowerI64IntToFP16(Op, dl, DAG, Subtarget))

    return V;


  // The transform for i64->f64 isn't correct for 0 when rounding to negative

  // infinity. It produces -0.0, so disable under strictfp.

  if (SrcVT == MVT::i64 && DstVT == MVT::f64 && Subtarget.hasSSE2() &&

      !IsStrict)

    return LowerUINT_TO_FP_i64(Op, dl, DAG, Subtarget);

  // The transform for i32->f64/f32 isn't correct for 0 when rounding to

  // negative infinity. So disable under strictfp. Using FILD instead.

  if (SrcVT == MVT::i32 && Subtarget.hasSSE2() && DstVT != MVT::f80 &&

      !IsStrict)

    return LowerUINT_TO_FP_i32(Op, dl, DAG, Subtarget);

  if (Subtarget.is64Bit() && SrcVT == MVT::i64 &&

      (DstVT == MVT::f32 || DstVT == MVT::f64))

    return SDValue();


  // Make a 64-bit buffer, and use it to build an FILD.

  SDValue StackSlot = DAG.CreateStackTemporary(MVT::i64, 8);

  int SSFI = cast<FrameIndexSDNode>(StackSlot)->getIndex();

  Align SlotAlign(8);

  MachinePointerInfo MPI =

      MachinePointerInfo::getFixedStack(DAG.getMachineFunction(), SSFI);

  if (SrcVT == MVT::i32) {

    SDValue OffsetSlot =

        DAG.getMemBasePlusOffset(StackSlot, TypeSize::getFixed(4), dl);

    SDValue Store1 = DAG.getStore(Chain, dl, Src, StackSlot, MPI, SlotAlign);

    SDValue Store2 = DAG.getStore(Store1, dl, DAG.getConstant(0, dl, MVT::i32),

                                  OffsetSlot, MPI.getWithOffset(4), SlotAlign);

    std::pair<SDValue, SDValue> Tmp =

        BuildFILD(DstVT, MVT::i64, dl, Store2, StackSlot, MPI, SlotAlign, DAG);

    if (IsStrict)

      return DAG.getMergeValues({Tmp.first, Tmp.second}, dl);


    return Tmp.first;

  }


  assert(SrcVT == MVT::i64 && "Unexpected type in UINT_TO_FP");

  SDValue ValueToStore = Src;

  if (isScalarFPTypeInSSEReg(Op.getValueType()) && !Subtarget.is64Bit()) {

    // Bitcasting to f64 here allows us to do a single 64-bit store from

    // an SSE register, avoiding the store forwarding penalty that would come

    // with two 32-bit stores.

    ValueToStore = DAG.getBitcast(MVT::f64, ValueToStore);

  }

  SDValue Store =

      DAG.getStore(Chain, dl, ValueToStore, StackSlot, MPI, SlotAlign);

  // For i64 source, we need to add the appropriate power of 2 if the input

  // was negative. We must be careful to do the computation in x87 extended

  // precision, not in SSE.

  SDVTList Tys = DAG.getVTList(MVT::f80, MVT::Other);

  SDValue Ops[] = {Store, StackSlot};

  SDValue Fild =

      DAG.getMemIntrinsicNode(X86ISD::FILD, dl, Tys, Ops, MVT::i64, MPI,

                              SlotAlign, MachineMemOperand::MOLoad);

  Chain = Fild.getValue(1);


  // Check whether the sign bit is set.

  SDValue SignSet = DAG.getSetCC(

      dl, getSetCCResultType(DAG.getDataLayout(), *DAG.getContext(), MVT::i64),

      Op.getOperand(OpNo), DAG.getConstant(0, dl, MVT::i64), ISD::SETLT);


  // Build a 64 bit pair (FF, 0) in the constant pool, with FF in the hi bits.

  APInt FF(64, 0x5F80000000000000ULL);

  SDValue FudgePtr =

      DAG.getConstantPool(ConstantInt::get(*DAG.getContext(), FF), PtrVT);

  Align CPAlignment = cast<ConstantPoolSDNode>(FudgePtr)->getAlign();


  // Get a pointer to FF if the sign bit was set, or to 0 otherwise.

  SDValue Zero = DAG.getIntPtrConstant(0, dl);

  SDValue Four = DAG.getIntPtrConstant(4, dl);

  SDValue Offset = DAG.getSelect(dl, Zero.getValueType(), SignSet, Four, Zero);

  FudgePtr = DAG.getNode(ISD::ADD, dl, PtrVT, FudgePtr, Offset);


  // Load the value out, extending it from f32 to f80.

  SDValue Fudge = DAG.getExtLoad(

      ISD::EXTLOAD, dl, MVT::f80, Chain, FudgePtr,

      MachinePointerInfo::getConstantPool(DAG.getMachineFunction()), MVT::f32,

      CPAlignment);

  Chain = Fudge.getValue(1);

  // Extend everything to 80 bits to force it to be done on x87.

  // TODO: Are there any fast-math-flags to propagate here?

  if (IsStrict) {

    unsigned Opc = ISD::STRICT_FADD;

    // Windows needs the precision control changed to 80bits around this add.

    if (Subtarget.isOSWindows() && DstVT == MVT::f32)

      Opc = X86ISD::STRICT_FP80_ADD;


    SDValue Add =

        DAG.getNode(Opc, dl, {MVT::f80, MVT::Other}, {Chain, Fild, Fudge});

    // STRICT_FP_ROUND can't handle equal types.

    if (DstVT == MVT::f80)

      return Add;

    return DAG.getNode(ISD::STRICT_FP_ROUND, dl, {DstVT, MVT::Other},

                       {Add.getValue(1), Add,

                        DAG.getIntPtrConstant(0, dl, /*isTarget=*/true)});

  }

  unsigned Opc = ISD::FADD;

  // Windows needs the precision control changed to 80bits around this add.

  if (Subtarget.isOSWindows() && DstVT == MVT::f32)

    Opc = X86ISD::FP80_ADD;


  SDValue Add = DAG.getNode(Opc, dl, MVT::f80, Fild, Fudge);

  return DAG.getNode(ISD::FP_ROUND, dl, DstVT, Add,

                     DAG.getIntPtrConstant(0, dl, /*isTarget=*/true));

}


// If the given FP_TO_SINT (IsSigned) or FP_TO_UINT (!IsSigned) operation

// is legal, or has an fp128 or f16 source (which needs to be promoted to f32),

// just return an SDValue().

// Otherwise it is assumed to be a conversion from one of f32, f64 or f80

// to i16, i32 or i64, and we lower it to a legal sequence and return the

// result.

SDValue X86TargetLowering::FP_TO_INTHelper(SDValue Op, SelectionDAG &DAG,

                                           bool IsSigned,

                                           SDValue &Chain) const {

  bool IsStrict = Op->isStrictFPOpcode();

  SDLoc DL(Op);


  EVT DstTy = Op.getValueType();

  SDValue Value = Op.getOperand(IsStrict ? 1 : 0);

  EVT TheVT = Value.getValueType();

  auto PtrVT = getPointerTy(DAG.getDataLayout());


  if (TheVT != MVT::f32 && TheVT != MVT::f64 && TheVT != MVT::f80) {

    // f16 must be promoted before using the lowering in this routine.

    // fp128 does not use this lowering.

    return SDValue();

  }


  // If using FIST to compute an unsigned i64, we'll need some fixup

  // to handle values above the maximum signed i64.  A FIST is always

  // used for the 32-bit subtarget, but also for f80 on a 64-bit target.

  bool UnsignedFixup = !IsSigned && DstTy == MVT::i64;


  // FIXME: This does not generate an invalid exception if the input does not

  // fit in i32. PR44019

  if (!IsSigned && DstTy != MVT::i64) {

    // Replace the fp-to-uint32 operation with an fp-to-sint64 FIST.

    // The low 32 bits of the fist result will have the correct uint32 result.

    assert(DstTy == MVT::i32 && "Unexpected FP_TO_UINT");

    DstTy = MVT::i64;

  }


  assert(DstTy.getSimpleVT() <= MVT::i64 &&

         DstTy.getSimpleVT() >= MVT::i16 &&

         "Unknown FP_TO_INT to lower!");


  // We lower FP->int64 into FISTP64 followed by a load from a temporary

  // stack slot.

  MachineFunction &MF = DAG.getMachineFunction();

  unsigned MemSize = DstTy.getStoreSize();

  int SSFI =

      MF.getFrameInfo().CreateStackObject(MemSize, Align(MemSize), false);

  SDValue StackSlot = DAG.getFrameIndex(SSFI, PtrVT);


  Chain = IsStrict ? Op.getOperand(0) : DAG.getEntryNode();


  SDValue Adjust; // 0x0 or 0x80000000, for result sign bit adjustment.


  if (UnsignedFixup) {

    //

    // Conversion to unsigned i64 is implemented with a select,

    // depending on whether the source value fits in the range

    // of a signed i64.  Let Thresh be the FP equivalent of

    // 0x8000000000000000ULL.

    //

    //  Adjust = (Value >= Thresh) ? 0x80000000 : 0;

    //  FltOfs = (Value >= Thresh) ? 0x80000000 : 0;

    //  FistSrc = (Value - FltOfs);

    //  Fist-to-mem64 FistSrc

    //  Add 0 or 0x800...0ULL to the 64-bit result, which is equivalent

    //  to XOR'ing the high 32 bits with Adjust.

    //

    // Being a power of 2, Thresh is exactly representable in all FP formats.

    // For X87 we'd like to use the smallest FP type for this constant, but

    // for DAG type consistency we have to match the FP operand type.


    APFloat Thresh(APFloat::IEEEsingle(), APInt(32, 0x5f000000));

    [[maybe_unused]] APFloat::opStatus Status = APFloat::opOK;

    bool LosesInfo = false;

    if (TheVT == MVT::f64)

      // The rounding mode is irrelevant as the conversion should be exact.

      Status = Thresh.convert(APFloat::IEEEdouble(), APFloat::rmNearestTiesToEven,

                              &LosesInfo);

    else if (TheVT == MVT::f80)

      Status = Thresh.convert(APFloat::x87DoubleExtended(),

                              APFloat::rmNearestTiesToEven, &LosesInfo);


    assert(Status == APFloat::opOK && !LosesInfo &&

           "FP conversion should have been exact");


    SDValue ThreshVal = DAG.getConstantFP(Thresh, DL, TheVT);


    EVT ResVT = getSetCCResultType(DAG.getDataLayout(),

                                   *DAG.getContext(), TheVT);

    SDValue Cmp;

    if (IsStrict) {

      Cmp = DAG.getSetCC(DL, ResVT, Value, ThreshVal, ISD::SETGE, Chain,

                         /*IsSignaling*/ true);

      Chain = Cmp.getValue(1);

    } else {

      Cmp = DAG.getSetCC(DL, ResVT, Value, ThreshVal, ISD::SETGE);

    }


    // Our preferred lowering of

    //

    // (Value >= Thresh) ? 0x8000000000000000ULL : 0

    //

    // is

    //

    // (Value >= Thresh) << 63

    //

    // but since we can get here after LegalOperations, DAGCombine might do the

    // wrong thing if we create a select. So, directly create the preferred

    // version.

    SDValue Zext = DAG.getNode(ISD::ZERO_EXTEND, DL, MVT::i64, Cmp);

    SDValue Const63 = DAG.getConstant(63, DL, MVT::i8);

    Adjust = DAG.getNode(ISD::SHL, DL, MVT::i64, Zext, Const63);


    SDValue FltOfs = DAG.getSelect(DL, TheVT, Cmp, ThreshVal,

                                   DAG.getConstantFP(0.0, DL, TheVT));


    if (IsStrict) {

      Value = DAG.getNode(ISD::STRICT_FSUB, DL, { TheVT, MVT::Other},

                          { Chain, Value, FltOfs });

      Chain = Value.getValue(1);

    } else

      Value = DAG.getNode(ISD::FSUB, DL, TheVT, Value, FltOfs);

  }


  MachinePointerInfo MPI = MachinePointerInfo::getFixedStack(MF, SSFI);


  // FIXME This causes a redundant load/store if the SSE-class value is already

  // in memory, such as if it is on the callstack.

  if (isScalarFPTypeInSSEReg(TheVT)) {

    assert(DstTy == MVT::i64 && "Invalid FP_TO_SINT to lower!");

    Chain = DAG.getStore(Chain, DL, Value, StackSlot, MPI);

    SDVTList Tys = DAG.getVTList(MVT::f80, MVT::Other);

    SDValue Ops[] = { Chain, StackSlot };


    unsigned FLDSize = TheVT.getStoreSize();

    assert(FLDSize <= MemSize && "Stack slot not big enough");

    MachineMemOperand *MMO = MF.getMachineMemOperand(

        MPI, MachineMemOperand::MOLoad, FLDSize, Align(FLDSize));

    Value = DAG.getMemIntrinsicNode(X86ISD::FLD, DL, Tys, Ops, TheVT, MMO);

    Chain = Value.getValue(1);

  }


  // Build the FP_TO_INT*_IN_MEM

  MachineMemOperand *MMO = MF.getMachineMemOperand(

      MPI, MachineMemOperand::MOStore, MemSize, Align(MemSize));

  SDValue Ops[] = { Chain, Value, StackSlot };

  SDValue FIST = DAG.getMemIntrinsicNode(X86ISD::FP_TO_INT_IN_MEM, DL,

                                         DAG.getVTList(MVT::Other),

                                         Ops, DstTy, MMO);


  SDValue Res = DAG.getLoad(Op.getValueType(), DL, FIST, StackSlot, MPI);

  Chain = Res.getValue(1);


  // If we need an unsigned fixup, XOR the result with adjust.

  if (UnsignedFixup)

    Res = DAG.getNode(ISD::XOR, DL, MVT::i64, Res, Adjust);


  return Res;

}


static SDValue LowerAVXExtend(SDValue Op, const SDLoc &dl, SelectionDAG &DAG,

                              const X86Subtarget &Subtarget) {

  MVT VT = Op.getSimpleValueType();

  SDValue In = Op.getOperand(0);

  MVT InVT = In.getSimpleValueType();

  unsigned Opc = Op.getOpcode();


  assert(VT.isVector() && InVT.isVector() && "Expected vector type");

  assert((Opc == ISD::ANY_EXTEND || Opc == ISD::ZERO_EXTEND) &&

         "Unexpected extension opcode");

  assert(VT.getVectorNumElements() == InVT.getVectorNumElements() &&

         "Expected same number of elements");

  assert((VT.getVectorElementType() == MVT::i16 ||

          VT.getVectorElementType() == MVT::i32 ||

          VT.getVectorElementType() == MVT::i64) &&

         "Unexpected element type");

  assert((InVT.getVectorElementType() == MVT::i8 ||

          InVT.getVectorElementType() == MVT::i16 ||

          InVT.getVectorElementType() == MVT::i32) &&

         "Unexpected element type");