doxygen/LegalizeTypes_8h_source.html

//===-- LegalizeTypes.h - DAG Type Legalizer class definition ---*- C++ -*-===//

//

// 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 DAGTypeLegalizer class.  This is a private interface

// shared between the code that implements the SelectionDAG::LegalizeTypes

// method.

//

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


#ifndef LLVM_LIB_CODEGEN_SELECTIONDAG_LEGALIZETYPES_H

#define LLVM_LIB_CODEGEN_SELECTIONDAG_LEGALIZETYPES_H


#include "llvm/ADT/DenseMap.h"

#include "llvm/CodeGen/SelectionDAG.h"

#include "llvm/CodeGen/TargetLowering.h"

#include "llvm/Support/Compiler.h"


namespace llvm {


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

/// This takes an arbitrary SelectionDAG as input and hacks on it until only

/// value types the target machine can handle are left. This involves promoting

/// small sizes to large sizes or splitting up large values into small values.

///

class LLVM_LIBRARY_VISIBILITY DAGTypeLegalizer {

  const TargetLowering &TLI;

  SelectionDAG &DAG;

public:

  /// This pass uses the NodeId on the SDNodes to hold information about the

  /// state of the node. The enum has all the values.

  enum NodeIdFlags {

    /// All operands have been processed, so this node is ready to be handled.

    ReadyToProcess = 0,


    /// This is a new node, not before seen, that was created in the process of

    /// legalizing some other node.

    NewNode = -1,


    /// This node's ID needs to be set to the number of its unprocessed

    /// operands.

    Unanalyzed = -2,


    /// This is a node that has already been processed.

    Processed = -3


    // 1+ - This is a node which has this many unprocessed operands.

  };

private:


  /// This is a bitvector that contains two bits for each simple value type,

  /// where the two bits correspond to the LegalizeAction enum from

  /// TargetLowering. This can be queried with "getTypeAction(VT)".

  TargetLowering::ValueTypeActionImpl ValueTypeActions;


  /// Return how we should legalize values of this type.

  TargetLowering::LegalizeTypeAction getTypeAction(EVT VT) const {

    return TLI.getTypeAction(*DAG.getContext(), VT);

  }


  /// Return true if this type is legal on this target.

  bool isTypeLegal(EVT VT) const {

    return TLI.getTypeAction(*DAG.getContext(), VT) == TargetLowering::TypeLegal;

  }


  /// Return true if this is a simple legal type.

  bool isSimpleLegalType(EVT VT) const {

    return VT.isSimple() && TLI.isTypeLegal(VT);

  }


  EVT getSetCCResultType(EVT VT) const {

    return TLI.getSetCCResultType(DAG.getDataLayout(), *DAG.getContext(), VT);

  }


  /// Pretend all of this node's results are legal.

  bool IgnoreNodeResults(SDNode *N) const {

    return N->getOpcode() == ISD::TargetConstant ||

           N->getOpcode() == ISD::Register;

  }


  // Bijection from SDValue to unique id. As each created node gets a

  // new id we do not need to worry about reuse expunging.  Should we

  // run out of ids, we can do a one time expensive compactifcation.

  typedef unsigned TableId;


  TableId NextValueId = 1;


  SmallDenseMap<SDValue, TableId, 8> ValueToIdMap;

  SmallDenseMap<TableId, SDValue, 8> IdToValueMap;


  /// For integer nodes that are below legal width, this map indicates what

  /// promoted value to use.

  SmallDenseMap<TableId, TableId, 8> PromotedIntegers;


  /// For integer nodes that need to be expanded this map indicates which

  /// operands are the expanded version of the input.

  SmallDenseMap<TableId, std::pair<TableId, TableId>, 8> ExpandedIntegers;


  /// For floating-point nodes converted to integers of the same size, this map

  /// indicates the converted value to use.

  SmallDenseMap<TableId, TableId, 8> SoftenedFloats;


  /// For floating-point nodes that have a smaller precision than the smallest

  /// supported precision, this map indicates what promoted value to use.

  SmallDenseMap<TableId, TableId, 8> PromotedFloats;


  /// For floating-point nodes that have a smaller precision than the smallest

  /// supported precision, this map indicates the converted value to use.

  SmallDenseMap<TableId, TableId, 8> SoftPromotedHalfs;


  /// For float nodes that need to be expanded this map indicates which operands

  /// are the expanded version of the input.

  SmallDenseMap<TableId, std::pair<TableId, TableId>, 8> ExpandedFloats;


  /// For nodes that are <1 x ty>, this map indicates the scalar value of type

  /// 'ty' to use.

  SmallDenseMap<TableId, TableId, 8> ScalarizedVectors;


  /// For nodes that need to be split this map indicates which operands are the

  /// expanded version of the input.

  SmallDenseMap<TableId, std::pair<TableId, TableId>, 8> SplitVectors;


  /// For vector nodes that need to be widened, indicates the widened value to

  /// use.

  SmallDenseMap<TableId, TableId, 8> WidenedVectors;


  /// For values that have been replaced with another, indicates the replacement

  /// value to use.

  SmallDenseMap<TableId, TableId, 8> ReplacedValues;


  /// This defines a worklist of nodes to process. In order to be pushed onto

  /// this worklist, all operands of a node must have already been processed.

  SmallVector<SDNode*, 128> Worklist;


  TableId getTableId(SDValue V) {

    assert(V.getNode() && "Getting TableId on SDValue()");


    auto I = ValueToIdMap.find(V);

    if (I != ValueToIdMap.end()) {

      // replace if there's been a shift.

      RemapId(I->second);

      assert(I->second && "All Ids should be nonzero");

      return I->second;

    }

    // Add if it's not there.

    ValueToIdMap.insert(std::make_pair(V, NextValueId));

    IdToValueMap.insert(std::make_pair(NextValueId, V));

    ++NextValueId;

    assert(NextValueId != 0 &&

           "Ran out of Ids. Increase id type size or add compactification");

    return NextValueId - 1;

  }


  const SDValue &getSDValue(TableId &Id) {

    RemapId(Id);

    assert(Id && "TableId should be non-zero");

    auto I = IdToValueMap.find(Id);

    assert(I != IdToValueMap.end() && "cannot find Id in map");

    return I->second;

  }


public:

  explicit DAGTypeLegalizer(SelectionDAG &dag)

    : TLI(dag.getTargetLoweringInfo()), DAG(dag),

    ValueTypeActions(TLI.getValueTypeActions()) {

    static_assert(MVT::LAST_VALUETYPE <= MVT::MAX_ALLOWED_VALUETYPE,

                  "Too many value types for ValueTypeActions to hold!");

  }


  /// This is the main entry point for the type legalizer.  This does a

  /// top-down traversal of the dag, legalizing types as it goes.  Returns

  /// "true" if it made any changes.

  bool run();


  void NoteDeletion(SDNode *Old, SDNode *New) {

    assert(Old != New && "node replaced with self");

    for (unsigned i = 0, e = Old->getNumValues(); i != e; ++i) {

      TableId NewId = getTableId(SDValue(New, i));

      TableId OldId = getTableId(SDValue(Old, i));


      if (OldId != NewId) {

        ReplacedValues[OldId] = NewId;


        // Delete Node from tables.  We cannot do this when OldId == NewId,

        // because NewId can still have table references to it in

        // ReplacedValues.

        IdToValueMap.erase(OldId);

        PromotedIntegers.erase(OldId);

        ExpandedIntegers.erase(OldId);

        SoftenedFloats.erase(OldId);

        PromotedFloats.erase(OldId);

        SoftPromotedHalfs.erase(OldId);

        ExpandedFloats.erase(OldId);

        ScalarizedVectors.erase(OldId);

        SplitVectors.erase(OldId);

        WidenedVectors.erase(OldId);

      }


      ValueToIdMap.erase(SDValue(Old, i));

    }

  }


  SelectionDAG &getDAG() const { return DAG; }


private:

  SDNode *AnalyzeNewNode(SDNode *N);

  void AnalyzeNewValue(SDValue &Val);

  void PerformExpensiveChecks();

  void RemapId(TableId &Id);

  void RemapValue(SDValue &V);


  // Common routines.

  SDValue BitConvertToInteger(SDValue Op);

  SDValue BitConvertVectorToIntegerVector(SDValue Op);

  SDValue CreateStackStoreLoad(SDValue Op, EVT DestVT);

  bool CustomLowerNode(SDNode *N, EVT VT, bool LegalizeResult);

  bool CustomWidenLowerNode(SDNode *N, EVT VT);


  /// Replace each result of the given MERGE_VALUES node with the corresponding

  /// input operand, except for the result 'ResNo', for which the corresponding

  /// input operand is returned.

  SDValue DisintegrateMERGE_VALUES(SDNode *N, unsigned ResNo);


  SDValue JoinIntegers(SDValue Lo, SDValue Hi);


  std::pair<SDValue, SDValue> ExpandAtomic(SDNode *Node);


  SDValue PromoteTargetBoolean(SDValue Bool, EVT ValVT);


  void ReplaceValueWith(SDValue From, SDValue To);

  void SplitInteger(SDValue Op, SDValue &Lo, SDValue &Hi);

  void SplitInteger(SDValue Op, EVT LoVT, EVT HiVT,

                    SDValue &Lo, SDValue &Hi);


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

  // Integer Promotion Support: LegalizeIntegerTypes.cpp

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


  /// Given a processed operand Op which was promoted to a larger integer type,

  /// this returns the promoted value. The low bits of the promoted value

  /// corresponding to the original type are exactly equal to Op.

  /// The extra bits contain rubbish, so the promoted value may need to be zero-

  /// or sign-extended from the original type before it is usable (the helpers

  /// SExtPromotedInteger and ZExtPromotedInteger can do this for you).

  /// For example, if Op is an i16 and was promoted to an i32, then this method

  /// returns an i32, the lower 16 bits of which coincide with Op, and the upper

  /// 16 bits of which contain rubbish.

  SDValue GetPromotedInteger(SDValue Op) {

    TableId &PromotedId = PromotedIntegers[getTableId(Op)];

    SDValue PromotedOp = getSDValue(PromotedId);

    assert(PromotedOp.getNode() && "Operand wasn't promoted?");

    return PromotedOp;

  }

  void SetPromotedInteger(SDValue Op, SDValue Result);


  /// Get a promoted operand and sign extend it to the final size.

  SDValue SExtPromotedInteger(SDValue Op) {

    EVT OldVT = Op.getValueType();

    SDLoc dl(Op);

    Op = GetPromotedInteger(Op);

    return DAG.getNode(ISD::SIGN_EXTEND_INREG, dl, Op.getValueType(), Op,

                       DAG.getValueType(OldVT));

  }


  /// Get a promoted operand and zero extend it to the final size.

  SDValue ZExtPromotedInteger(SDValue Op) {

    EVT OldVT = Op.getValueType();

    SDLoc dl(Op);

    Op = GetPromotedInteger(Op);

    return DAG.getZeroExtendInReg(Op, dl, OldVT);

  }


  // Get a promoted operand and sign or zero extend it to the final size

  // (depending on TargetLoweringInfo::isSExtCheaperThanZExt). For a given

  // subtarget and type, the choice of sign or zero-extension will be

  // consistent.

  SDValue SExtOrZExtPromotedInteger(SDValue Op) {

    EVT OldVT = Op.getValueType();

    SDLoc DL(Op);

    Op = GetPromotedInteger(Op);

    if (TLI.isSExtCheaperThanZExt(OldVT, Op.getValueType()))

      return DAG.getNode(ISD::SIGN_EXTEND_INREG, DL, Op.getValueType(), Op,

                         DAG.getValueType(OldVT));

    return DAG.getZeroExtendInReg(Op, DL, OldVT);

  }


  // Promote the given operand V (vector or scalar) according to N's specific

  // reduction kind. N must be an integer VECREDUCE_* or VP_REDUCE_*. Returns

  // the nominal extension opcode (ISD::(ANY|ZERO|SIGN)_EXTEND) and the

  // promoted value.

  SDValue PromoteIntOpVectorReduction(SDNode *N, SDValue V);


  // Integer Result Promotion.

  void PromoteIntegerResult(SDNode *N, unsigned ResNo);

  SDValue PromoteIntRes_MERGE_VALUES(SDNode *N, unsigned ResNo);

  SDValue PromoteIntRes_AssertSext(SDNode *N);

  SDValue PromoteIntRes_AssertZext(SDNode *N);

  SDValue PromoteIntRes_Atomic0(AtomicSDNode *N);

  SDValue PromoteIntRes_Atomic1(AtomicSDNode *N);

  SDValue PromoteIntRes_AtomicCmpSwap(AtomicSDNode *N, unsigned ResNo);

  SDValue PromoteIntRes_EXTRACT_SUBVECTOR(SDNode *N);

  SDValue PromoteIntRes_INSERT_SUBVECTOR(SDNode *N);

  SDValue PromoteIntRes_VECTOR_REVERSE(SDNode *N);

  SDValue PromoteIntRes_VECTOR_SHUFFLE(SDNode *N);

  SDValue PromoteIntRes_VECTOR_SPLICE(SDNode *N);

  SDValue PromoteIntRes_VECTOR_INTERLEAVE_DEINTERLEAVE(SDNode *N);

  SDValue PromoteIntRes_BUILD_VECTOR(SDNode *N);

  SDValue PromoteIntRes_ScalarOp(SDNode *N);

  SDValue PromoteIntRes_STEP_VECTOR(SDNode *N);

  SDValue PromoteIntRes_EXTEND_VECTOR_INREG(SDNode *N);

  SDValue PromoteIntRes_INSERT_VECTOR_ELT(SDNode *N);

  SDValue PromoteIntRes_CONCAT_VECTORS(SDNode *N);

  SDValue PromoteIntRes_BITCAST(SDNode *N);

  SDValue PromoteIntRes_BSWAP(SDNode *N);

  SDValue PromoteIntRes_BITREVERSE(SDNode *N);

  SDValue PromoteIntRes_BUILD_PAIR(SDNode *N);

  SDValue PromoteIntRes_Constant(SDNode *N);

  SDValue PromoteIntRes_CTLZ(SDNode *N);

  SDValue PromoteIntRes_CTPOP_PARITY(SDNode *N);

  SDValue PromoteIntRes_CTTZ(SDNode *N);

  SDValue PromoteIntRes_EXTRACT_VECTOR_ELT(SDNode *N);

  SDValue PromoteIntRes_FP_TO_XINT(SDNode *N);

  SDValue PromoteIntRes_FP_TO_XINT_SAT(SDNode *N);

  SDValue PromoteIntRes_FP_TO_FP16_BF16(SDNode *N);

  SDValue PromoteIntRes_XRINT(SDNode *N);

  SDValue PromoteIntRes_FREEZE(SDNode *N);

  SDValue PromoteIntRes_INT_EXTEND(SDNode *N);

  SDValue PromoteIntRes_LOAD(LoadSDNode *N);

  SDValue PromoteIntRes_MLOAD(MaskedLoadSDNode *N);

  SDValue PromoteIntRes_MGATHER(MaskedGatherSDNode *N);

  SDValue PromoteIntRes_Overflow(SDNode *N);

  SDValue PromoteIntRes_FFREXP(SDNode *N);

  SDValue PromoteIntRes_SADDSUBO(SDNode *N, unsigned ResNo);

  SDValue PromoteIntRes_Select(SDNode *N);

  SDValue PromoteIntRes_SELECT_CC(SDNode *N);

  SDValue PromoteIntRes_SETCC(SDNode *N);

  SDValue PromoteIntRes_SHL(SDNode *N);

  SDValue PromoteIntRes_SimpleIntBinOp(SDNode *N);

  SDValue PromoteIntRes_ZExtIntBinOp(SDNode *N);

  SDValue PromoteIntRes_SExtIntBinOp(SDNode *N);

  SDValue PromoteIntRes_UMINUMAX(SDNode *N);

  SDValue PromoteIntRes_SIGN_EXTEND_INREG(SDNode *N);

  SDValue PromoteIntRes_SRA(SDNode *N);

  SDValue PromoteIntRes_SRL(SDNode *N);

  SDValue PromoteIntRes_TRUNCATE(SDNode *N);

  SDValue PromoteIntRes_UADDSUBO(SDNode *N, unsigned ResNo);

  SDValue PromoteIntRes_UADDSUBO_CARRY(SDNode *N, unsigned ResNo);

  SDValue PromoteIntRes_SADDSUBO_CARRY(SDNode *N, unsigned ResNo);

  SDValue PromoteIntRes_UNDEF(SDNode *N);

  SDValue PromoteIntRes_VAARG(SDNode *N);

  SDValue PromoteIntRes_VSCALE(SDNode *N);

  SDValue PromoteIntRes_XMULO(SDNode *N, unsigned ResNo);

  SDValue PromoteIntRes_ADDSUBSHLSAT(SDNode *N);

  SDValue PromoteIntRes_MULFIX(SDNode *N);

  SDValue PromoteIntRes_DIVFIX(SDNode *N);

  SDValue PromoteIntRes_GET_ROUNDING(SDNode *N);

  SDValue PromoteIntRes_VECREDUCE(SDNode *N);

  SDValue PromoteIntRes_VP_REDUCE(SDNode *N);

  SDValue PromoteIntRes_ABS(SDNode *N);

  SDValue PromoteIntRes_Rotate(SDNode *N);

  SDValue PromoteIntRes_FunnelShift(SDNode *N);

  SDValue PromoteIntRes_VPFunnelShift(SDNode *N);

  SDValue PromoteIntRes_IS_FPCLASS(SDNode *N);


  // Integer Operand Promotion.

  bool PromoteIntegerOperand(SDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_ANY_EXTEND(SDNode *N);

  SDValue PromoteIntOp_ATOMIC_STORE(AtomicSDNode *N);

  SDValue PromoteIntOp_BITCAST(SDNode *N);

  SDValue PromoteIntOp_BUILD_PAIR(SDNode *N);

  SDValue PromoteIntOp_BR_CC(SDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_BRCOND(SDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_BUILD_VECTOR(SDNode *N);

  SDValue PromoteIntOp_INSERT_VECTOR_ELT(SDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_EXTRACT_VECTOR_ELT(SDNode *N);

  SDValue PromoteIntOp_EXTRACT_SUBVECTOR(SDNode *N);

  SDValue PromoteIntOp_INSERT_SUBVECTOR(SDNode *N);

  SDValue PromoteIntOp_CONCAT_VECTORS(SDNode *N);

  SDValue PromoteIntOp_ScalarOp(SDNode *N);

  SDValue PromoteIntOp_SELECT(SDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_SELECT_CC(SDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_SETCC(SDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_Shift(SDNode *N);

  SDValue PromoteIntOp_FunnelShift(SDNode *N);

  SDValue PromoteIntOp_SIGN_EXTEND(SDNode *N);

  SDValue PromoteIntOp_VP_SIGN_EXTEND(SDNode *N);

  SDValue PromoteIntOp_SINT_TO_FP(SDNode *N);

  SDValue PromoteIntOp_STRICT_SINT_TO_FP(SDNode *N);

  SDValue PromoteIntOp_STORE(StoreSDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_TRUNCATE(SDNode *N);

  SDValue PromoteIntOp_UINT_TO_FP(SDNode *N);

  SDValue PromoteIntOp_STRICT_UINT_TO_FP(SDNode *N);

  SDValue PromoteIntOp_ZERO_EXTEND(SDNode *N);

  SDValue PromoteIntOp_VP_ZERO_EXTEND(SDNode *N);

  SDValue PromoteIntOp_MSTORE(MaskedStoreSDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_MLOAD(MaskedLoadSDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_MSCATTER(MaskedScatterSDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_MGATHER(MaskedGatherSDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_ADDSUBO_CARRY(SDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_FRAMERETURNADDR(SDNode *N);

  SDValue PromoteIntOp_FIX(SDNode *N);

  SDValue PromoteIntOp_ExpOp(SDNode *N);

  SDValue PromoteIntOp_VECREDUCE(SDNode *N);

  SDValue PromoteIntOp_VP_REDUCE(SDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_SET_ROUNDING(SDNode *N);

  SDValue PromoteIntOp_STACKMAP(SDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_PATCHPOINT(SDNode *N, unsigned OpNo);

  SDValue PromoteIntOp_VP_STRIDED(SDNode *N, unsigned OpNo);


  void PromoteSetCCOperands(SDValue &LHS,SDValue &RHS, ISD::CondCode Code);


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

  // Integer Expansion Support: LegalizeIntegerTypes.cpp

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


  /// Given a processed operand Op which was expanded into two integers of half

  /// the size, this returns the two halves. The low bits of Op are exactly

  /// equal to the bits of Lo; the high bits exactly equal Hi.

  /// For example, if Op is an i64 which was expanded into two i32's, then this

  /// method returns the two i32's, with Lo being equal to the lower 32 bits of

  /// Op, and Hi being equal to the upper 32 bits.

  void GetExpandedInteger(SDValue Op, SDValue &Lo, SDValue &Hi);

  void SetExpandedInteger(SDValue Op, SDValue Lo, SDValue Hi);


  // Integer Result Expansion.

  void ExpandIntegerResult(SDNode *N, unsigned ResNo);

  void ExpandIntRes_ANY_EXTEND        (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_AssertSext        (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_AssertZext        (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_Constant          (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_ABS               (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_CTLZ              (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_CTPOP             (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_CTTZ              (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_LOAD          (LoadSDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_READCYCLECOUNTER  (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_SIGN_EXTEND       (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_SIGN_EXTEND_INREG (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_TRUNCATE          (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_ZERO_EXTEND       (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_GET_ROUNDING      (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_FP_TO_XINT        (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_FP_TO_XINT_SAT    (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_XROUND_XRINT      (SDNode *N, SDValue &Lo, SDValue &Hi);


  void ExpandIntRes_Logical           (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_ADDSUB            (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_ADDSUBC           (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_ADDSUBE           (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_UADDSUBO_CARRY    (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_SADDSUBO_CARRY    (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_BITREVERSE        (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_BSWAP             (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_PARITY            (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_MUL               (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_SDIV              (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_SREM              (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_UDIV              (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_UREM              (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_ShiftThroughStack (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_Shift             (SDNode *N, SDValue &Lo, SDValue &Hi);


  void ExpandIntRes_MINMAX            (SDNode *N, SDValue &Lo, SDValue &Hi);


  void ExpandIntRes_SADDSUBO          (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_UADDSUBO          (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_XMULO             (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_ADDSUBSAT         (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_SHLSAT            (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_MULFIX            (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_DIVFIX            (SDNode *N, SDValue &Lo, SDValue &Hi);


  void ExpandIntRes_ATOMIC_LOAD       (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_VECREDUCE         (SDNode *N, SDValue &Lo, SDValue &Hi);


  void ExpandIntRes_Rotate            (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandIntRes_FunnelShift       (SDNode *N, SDValue &Lo, SDValue &Hi);


  void ExpandIntRes_VSCALE            (SDNode *N, SDValue &Lo, SDValue &Hi);


  void ExpandShiftByConstant(SDNode *N, const APInt &Amt,

                             SDValue &Lo, SDValue &Hi);

  bool ExpandShiftWithKnownAmountBit(SDNode *N, SDValue &Lo, SDValue &Hi);

  bool ExpandShiftWithUnknownAmountBit(SDNode *N, SDValue &Lo, SDValue &Hi);


  // Integer Operand Expansion.

  bool ExpandIntegerOperand(SDNode *N, unsigned OpNo);

  SDValue ExpandIntOp_BR_CC(SDNode *N);

  SDValue ExpandIntOp_SELECT_CC(SDNode *N);

  SDValue ExpandIntOp_SETCC(SDNode *N);

  SDValue ExpandIntOp_SETCCCARRY(SDNode *N);

  SDValue ExpandIntOp_Shift(SDNode *N);

  SDValue ExpandIntOp_STORE(StoreSDNode *N, unsigned OpNo);

  SDValue ExpandIntOp_TRUNCATE(SDNode *N);

  SDValue ExpandIntOp_XINT_TO_FP(SDNode *N);

  SDValue ExpandIntOp_RETURNADDR(SDNode *N);

  SDValue ExpandIntOp_ATOMIC_STORE(SDNode *N);

  SDValue ExpandIntOp_SPLAT_VECTOR(SDNode *N);

  SDValue ExpandIntOp_STACKMAP(SDNode *N, unsigned OpNo);

  SDValue ExpandIntOp_PATCHPOINT(SDNode *N, unsigned OpNo);

  SDValue ExpandIntOp_VP_STRIDED(SDNode *N, unsigned OpNo);


  void IntegerExpandSetCCOperands(SDValue &NewLHS, SDValue &NewRHS,

                                  ISD::CondCode &CCCode, const SDLoc &dl);


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

  // Float to Integer Conversion Support: LegalizeFloatTypes.cpp

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


  /// GetSoftenedFloat - Given a processed operand Op which was converted to an

  /// integer of the same size, this returns the integer.  The integer contains

  /// exactly the same bits as Op - only the type changed.  For example, if Op

  /// is an f32 which was softened to an i32, then this method returns an i32,

  /// the bits of which coincide with those of Op

  SDValue GetSoftenedFloat(SDValue Op) {

    TableId Id = getTableId(Op);

    auto Iter = SoftenedFloats.find(Id);

    if (Iter == SoftenedFloats.end()) {

      assert(isSimpleLegalType(Op.getValueType()) &&

             "Operand wasn't converted to integer?");

      return Op;

    }

    SDValue SoftenedOp = getSDValue(Iter->second);

    assert(SoftenedOp.getNode() && "Unconverted op in SoftenedFloats?");

    return SoftenedOp;

  }

  void SetSoftenedFloat(SDValue Op, SDValue Result);


  // Convert Float Results to Integer.

  void SoftenFloatResult(SDNode *N, unsigned ResNo);

  SDValue SoftenFloatRes_Unary(SDNode *N, RTLIB::Libcall LC);

  SDValue SoftenFloatRes_Binary(SDNode *N, RTLIB::Libcall LC);

  SDValue SoftenFloatRes_MERGE_VALUES(SDNode *N, unsigned ResNo);

  SDValue SoftenFloatRes_ARITH_FENCE(SDNode *N);

  SDValue SoftenFloatRes_BITCAST(SDNode *N);

  SDValue SoftenFloatRes_BUILD_PAIR(SDNode *N);

  SDValue SoftenFloatRes_ConstantFP(SDNode *N);

  SDValue SoftenFloatRes_EXTRACT_VECTOR_ELT(SDNode *N, unsigned ResNo);

  SDValue SoftenFloatRes_FABS(SDNode *N);

  SDValue SoftenFloatRes_FMINNUM(SDNode *N);

  SDValue SoftenFloatRes_FMAXNUM(SDNode *N);

  SDValue SoftenFloatRes_FADD(SDNode *N);

  SDValue SoftenFloatRes_FCBRT(SDNode *N);

  SDValue SoftenFloatRes_FCEIL(SDNode *N);

  SDValue SoftenFloatRes_FCOPYSIGN(SDNode *N);

  SDValue SoftenFloatRes_FCOS(SDNode *N);

  SDValue SoftenFloatRes_FDIV(SDNode *N);

  SDValue SoftenFloatRes_FEXP(SDNode *N);

  SDValue SoftenFloatRes_FEXP2(SDNode *N);

  SDValue SoftenFloatRes_FEXP10(SDNode *N);

  SDValue SoftenFloatRes_FFLOOR(SDNode *N);

  SDValue SoftenFloatRes_FLOG(SDNode *N);

  SDValue SoftenFloatRes_FLOG2(SDNode *N);

  SDValue SoftenFloatRes_FLOG10(SDNode *N);

  SDValue SoftenFloatRes_FMA(SDNode *N);

  SDValue SoftenFloatRes_FMUL(SDNode *N);

  SDValue SoftenFloatRes_FNEARBYINT(SDNode *N);

  SDValue SoftenFloatRes_FNEG(SDNode *N);

  SDValue SoftenFloatRes_FP_EXTEND(SDNode *N);

  SDValue SoftenFloatRes_FP16_TO_FP(SDNode *N);

  SDValue SoftenFloatRes_BF16_TO_FP(SDNode *N);

  SDValue SoftenFloatRes_FP_ROUND(SDNode *N);

  SDValue SoftenFloatRes_FPOW(SDNode *N);

  SDValue SoftenFloatRes_ExpOp(SDNode *N);

  SDValue SoftenFloatRes_FFREXP(SDNode *N);

  SDValue SoftenFloatRes_FREEZE(SDNode *N);

  SDValue SoftenFloatRes_FREM(SDNode *N);

  SDValue SoftenFloatRes_FRINT(SDNode *N);

  SDValue SoftenFloatRes_FROUND(SDNode *N);

  SDValue SoftenFloatRes_FROUNDEVEN(SDNode *N);

  SDValue SoftenFloatRes_FSIN(SDNode *N);

  SDValue SoftenFloatRes_FSQRT(SDNode *N);

  SDValue SoftenFloatRes_FSUB(SDNode *N);

  SDValue SoftenFloatRes_FTRUNC(SDNode *N);

  SDValue SoftenFloatRes_LOAD(SDNode *N);

  SDValue SoftenFloatRes_SELECT(SDNode *N);

  SDValue SoftenFloatRes_SELECT_CC(SDNode *N);

  SDValue SoftenFloatRes_UNDEF(SDNode *N);

  SDValue SoftenFloatRes_VAARG(SDNode *N);

  SDValue SoftenFloatRes_XINT_TO_FP(SDNode *N);

  SDValue SoftenFloatRes_VECREDUCE(SDNode *N);

  SDValue SoftenFloatRes_VECREDUCE_SEQ(SDNode *N);


  // Convert Float Operand to Integer.

  bool SoftenFloatOperand(SDNode *N, unsigned OpNo);

  SDValue SoftenFloatOp_Unary(SDNode *N, RTLIB::Libcall LC);

  SDValue SoftenFloatOp_BITCAST(SDNode *N);

  SDValue SoftenFloatOp_BR_CC(SDNode *N);

  SDValue SoftenFloatOp_FP_ROUND(SDNode *N);

  SDValue SoftenFloatOp_FP_TO_XINT(SDNode *N);

  SDValue SoftenFloatOp_FP_TO_XINT_SAT(SDNode *N);

  SDValue SoftenFloatOp_LROUND(SDNode *N);

  SDValue SoftenFloatOp_LLROUND(SDNode *N);

  SDValue SoftenFloatOp_LRINT(SDNode *N);

  SDValue SoftenFloatOp_LLRINT(SDNode *N);

  SDValue SoftenFloatOp_SELECT_CC(SDNode *N);

  SDValue SoftenFloatOp_SETCC(SDNode *N);

  SDValue SoftenFloatOp_STORE(SDNode *N, unsigned OpNo);

  SDValue SoftenFloatOp_FCOPYSIGN(SDNode *N);


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

  // Float Expansion Support: LegalizeFloatTypes.cpp

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


  /// Given a processed operand Op which was expanded into two floating-point

  /// values of half the size, this returns the two halves.

  /// The low bits of Op are exactly equal to the bits of Lo; the high bits

  /// exactly equal Hi.  For example, if Op is a ppcf128 which was expanded

  /// into two f64's, then this method returns the two f64's, with Lo being

  /// equal to the lower 64 bits of Op, and Hi to the upper 64 bits.

  void GetExpandedFloat(SDValue Op, SDValue &Lo, SDValue &Hi);

  void SetExpandedFloat(SDValue Op, SDValue Lo, SDValue Hi);


  // Float Result Expansion.

  void ExpandFloatResult(SDNode *N, unsigned ResNo);

  void ExpandFloatRes_ConstantFP(SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_Unary(SDNode *N, RTLIB::Libcall LC,

                            SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_Binary(SDNode *N, RTLIB::Libcall LC,

                             SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FABS      (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FMINNUM   (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FMAXNUM   (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FADD      (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FCBRT     (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FCEIL     (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FCOPYSIGN (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FCOS      (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FDIV      (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FEXP      (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FEXP2     (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FEXP10    (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FFLOOR    (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FLOG      (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FLOG2     (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FLOG10    (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FMA       (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FMUL      (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FNEARBYINT(SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FNEG      (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FP_EXTEND (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FPOW      (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FPOWI     (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FLDEXP    (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FREEZE    (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FREM      (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FRINT     (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FROUND    (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FROUNDEVEN(SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FSIN      (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FSQRT     (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FSUB      (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_FTRUNC    (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_LOAD      (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandFloatRes_XINT_TO_FP(SDNode *N, SDValue &Lo, SDValue &Hi);


  // Float Operand Expansion.

  bool ExpandFloatOperand(SDNode *N, unsigned OpNo);

  SDValue ExpandFloatOp_BR_CC(SDNode *N);

  SDValue ExpandFloatOp_FCOPYSIGN(SDNode *N);

  SDValue ExpandFloatOp_FP_ROUND(SDNode *N);

  SDValue ExpandFloatOp_FP_TO_XINT(SDNode *N);

  SDValue ExpandFloatOp_LROUND(SDNode *N);

  SDValue ExpandFloatOp_LLROUND(SDNode *N);

  SDValue ExpandFloatOp_LRINT(SDNode *N);

  SDValue ExpandFloatOp_LLRINT(SDNode *N);

  SDValue ExpandFloatOp_SELECT_CC(SDNode *N);

  SDValue ExpandFloatOp_SETCC(SDNode *N);

  SDValue ExpandFloatOp_STORE(SDNode *N, unsigned OpNo);


  void FloatExpandSetCCOperands(SDValue &NewLHS, SDValue &NewRHS,

                                ISD::CondCode &CCCode, const SDLoc &dl,

                                SDValue &Chain, bool IsSignaling = false);


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

  // Float promotion support: LegalizeFloatTypes.cpp

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


  SDValue GetPromotedFloat(SDValue Op) {

    TableId &PromotedId = PromotedFloats[getTableId(Op)];

    SDValue PromotedOp = getSDValue(PromotedId);

    assert(PromotedOp.getNode() && "Operand wasn't promoted?");

    return PromotedOp;

  }

  void SetPromotedFloat(SDValue Op, SDValue Result);


  void PromoteFloatResult(SDNode *N, unsigned ResNo);

  SDValue PromoteFloatRes_BITCAST(SDNode *N);

  SDValue PromoteFloatRes_BinOp(SDNode *N);

  SDValue PromoteFloatRes_ConstantFP(SDNode *N);

  SDValue PromoteFloatRes_EXTRACT_VECTOR_ELT(SDNode *N);

  SDValue PromoteFloatRes_FCOPYSIGN(SDNode *N);

  SDValue PromoteFloatRes_FMAD(SDNode *N);

  SDValue PromoteFloatRes_ExpOp(SDNode *N);

  SDValue PromoteFloatRes_FFREXP(SDNode *N);

  SDValue PromoteFloatRes_FP_ROUND(SDNode *N);

  SDValue PromoteFloatRes_LOAD(SDNode *N);

  SDValue PromoteFloatRes_SELECT(SDNode *N);

  SDValue PromoteFloatRes_SELECT_CC(SDNode *N);

  SDValue PromoteFloatRes_UnaryOp(SDNode *N);

  SDValue PromoteFloatRes_UNDEF(SDNode *N);

  SDValue BitcastToInt_ATOMIC_SWAP(SDNode *N);

  SDValue PromoteFloatRes_XINT_TO_FP(SDNode *N);

  SDValue PromoteFloatRes_VECREDUCE(SDNode *N);

  SDValue PromoteFloatRes_VECREDUCE_SEQ(SDNode *N);


  bool PromoteFloatOperand(SDNode *N, unsigned OpNo);

  SDValue PromoteFloatOp_BITCAST(SDNode *N, unsigned OpNo);

  SDValue PromoteFloatOp_FCOPYSIGN(SDNode *N, unsigned OpNo);

  SDValue PromoteFloatOp_FP_EXTEND(SDNode *N, unsigned OpNo);

  SDValue PromoteFloatOp_UnaryOp(SDNode *N, unsigned OpNo);

  SDValue PromoteFloatOp_FP_TO_XINT_SAT(SDNode *N, unsigned OpNo);

  SDValue PromoteFloatOp_STORE(SDNode *N, unsigned OpNo);

  SDValue PromoteFloatOp_SELECT_CC(SDNode *N, unsigned OpNo);

  SDValue PromoteFloatOp_SETCC(SDNode *N, unsigned OpNo);


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

  // Half soft promotion support: LegalizeFloatTypes.cpp

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


  SDValue GetSoftPromotedHalf(SDValue Op) {

    TableId &PromotedId = SoftPromotedHalfs[getTableId(Op)];

    SDValue PromotedOp = getSDValue(PromotedId);

    assert(PromotedOp.getNode() && "Operand wasn't promoted?");

    return PromotedOp;

  }

  void SetSoftPromotedHalf(SDValue Op, SDValue Result);


  void SoftPromoteHalfResult(SDNode *N, unsigned ResNo);

  SDValue SoftPromoteHalfRes_BinOp(SDNode *N);

  SDValue SoftPromoteHalfRes_BITCAST(SDNode *N);

  SDValue SoftPromoteHalfRes_ConstantFP(SDNode *N);

  SDValue SoftPromoteHalfRes_EXTRACT_VECTOR_ELT(SDNode *N);

  SDValue SoftPromoteHalfRes_FCOPYSIGN(SDNode *N);

  SDValue SoftPromoteHalfRes_FMAD(SDNode *N);

  SDValue SoftPromoteHalfRes_ExpOp(SDNode *N);

  SDValue SoftPromoteHalfRes_FP_ROUND(SDNode *N);

  SDValue SoftPromoteHalfRes_LOAD(SDNode *N);

  SDValue SoftPromoteHalfRes_SELECT(SDNode *N);

  SDValue SoftPromoteHalfRes_SELECT_CC(SDNode *N);

  SDValue SoftPromoteHalfRes_UnaryOp(SDNode *N);

  SDValue SoftPromoteHalfRes_XINT_TO_FP(SDNode *N);

  SDValue SoftPromoteHalfRes_UNDEF(SDNode *N);

  SDValue SoftPromoteHalfRes_VECREDUCE(SDNode *N);

  SDValue SoftPromoteHalfRes_VECREDUCE_SEQ(SDNode *N);


  bool SoftPromoteHalfOperand(SDNode *N, unsigned OpNo);

  SDValue SoftPromoteHalfOp_BITCAST(SDNode *N);

  SDValue SoftPromoteHalfOp_FCOPYSIGN(SDNode *N, unsigned OpNo);

  SDValue SoftPromoteHalfOp_FP_EXTEND(SDNode *N);

  SDValue SoftPromoteHalfOp_FP_TO_XINT(SDNode *N);

  SDValue SoftPromoteHalfOp_FP_TO_XINT_SAT(SDNode *N);

  SDValue SoftPromoteHalfOp_SETCC(SDNode *N);

  SDValue SoftPromoteHalfOp_SELECT_CC(SDNode *N, unsigned OpNo);

  SDValue SoftPromoteHalfOp_STORE(SDNode *N, unsigned OpNo);

  SDValue SoftPromoteHalfOp_STACKMAP(SDNode *N, unsigned OpNo);

  SDValue SoftPromoteHalfOp_PATCHPOINT(SDNode *N, unsigned OpNo);


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

  // Scalarization Support: LegalizeVectorTypes.cpp

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


  /// Given a processed one-element vector Op which was scalarized to its

  /// element type, this returns the element. For example, if Op is a v1i32,

  /// Op = < i32 val >, this method returns val, an i32.

  SDValue GetScalarizedVector(SDValue Op) {

    TableId &ScalarizedId = ScalarizedVectors[getTableId(Op)];

    SDValue ScalarizedOp = getSDValue(ScalarizedId);

    assert(ScalarizedOp.getNode() && "Operand wasn't scalarized?");

    return ScalarizedOp;

  }

  void SetScalarizedVector(SDValue Op, SDValue Result);


  // Vector Result Scalarization: <1 x ty> -> ty.

  void ScalarizeVectorResult(SDNode *N, unsigned ResNo);

  SDValue ScalarizeVecRes_MERGE_VALUES(SDNode *N, unsigned ResNo);

  SDValue ScalarizeVecRes_BinOp(SDNode *N);

  SDValue ScalarizeVecRes_TernaryOp(SDNode *N);

  SDValue ScalarizeVecRes_UnaryOp(SDNode *N);

  SDValue ScalarizeVecRes_StrictFPOp(SDNode *N);

  SDValue ScalarizeVecRes_OverflowOp(SDNode *N, unsigned ResNo);

  SDValue ScalarizeVecRes_InregOp(SDNode *N);

  SDValue ScalarizeVecRes_VecInregOp(SDNode *N);


  SDValue ScalarizeVecRes_BITCAST(SDNode *N);

  SDValue ScalarizeVecRes_BUILD_VECTOR(SDNode *N);

  SDValue ScalarizeVecRes_EXTRACT_SUBVECTOR(SDNode *N);

  SDValue ScalarizeVecRes_FP_ROUND(SDNode *N);

  SDValue ScalarizeVecRes_ExpOp(SDNode *N);

  SDValue ScalarizeVecRes_INSERT_VECTOR_ELT(SDNode *N);

  SDValue ScalarizeVecRes_LOAD(LoadSDNode *N);

  SDValue ScalarizeVecRes_SCALAR_TO_VECTOR(SDNode *N);

  SDValue ScalarizeVecRes_VSELECT(SDNode *N);

  SDValue ScalarizeVecRes_SELECT(SDNode *N);

  SDValue ScalarizeVecRes_SELECT_CC(SDNode *N);

  SDValue ScalarizeVecRes_SETCC(SDNode *N);

  SDValue ScalarizeVecRes_UNDEF(SDNode *N);

  SDValue ScalarizeVecRes_VECTOR_SHUFFLE(SDNode *N);

  SDValue ScalarizeVecRes_FP_TO_XINT_SAT(SDNode *N);

  SDValue ScalarizeVecRes_IS_FPCLASS(SDNode *N);


  SDValue ScalarizeVecRes_FIX(SDNode *N);

  SDValue ScalarizeVecRes_FFREXP(SDNode *N, unsigned ResNo);


  // Vector Operand Scalarization: <1 x ty> -> ty.

  bool ScalarizeVectorOperand(SDNode *N, unsigned OpNo);

  SDValue ScalarizeVecOp_BITCAST(SDNode *N);

  SDValue ScalarizeVecOp_UnaryOp(SDNode *N);

  SDValue ScalarizeVecOp_UnaryOp_StrictFP(SDNode *N);

  SDValue ScalarizeVecOp_CONCAT_VECTORS(SDNode *N);

  SDValue ScalarizeVecOp_EXTRACT_VECTOR_ELT(SDNode *N);

  SDValue ScalarizeVecOp_VSELECT(SDNode *N);

  SDValue ScalarizeVecOp_VSETCC(SDNode *N);

  SDValue ScalarizeVecOp_STORE(StoreSDNode *N, unsigned OpNo);

  SDValue ScalarizeVecOp_FP_ROUND(SDNode *N, unsigned OpNo);

  SDValue ScalarizeVecOp_STRICT_FP_ROUND(SDNode *N, unsigned OpNo);

  SDValue ScalarizeVecOp_FP_EXTEND(SDNode *N);

  SDValue ScalarizeVecOp_STRICT_FP_EXTEND(SDNode *N);

  SDValue ScalarizeVecOp_VECREDUCE(SDNode *N);

  SDValue ScalarizeVecOp_VECREDUCE_SEQ(SDNode *N);


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

  // Vector Splitting Support: LegalizeVectorTypes.cpp

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


  /// Given a processed vector Op which was split into vectors of half the size,

  /// this method returns the halves. The first elements of Op coincide with the

  /// elements of Lo; the remaining elements of Op coincide with the elements of

  /// Hi: Op is what you would get by concatenating Lo and Hi.

  /// For example, if Op is a v8i32 that was split into two v4i32's, then this

  /// method returns the two v4i32's, with Lo corresponding to the first 4

  /// elements of Op, and Hi to the last 4 elements.

  void GetSplitVector(SDValue Op, SDValue &Lo, SDValue &Hi);

  void SetSplitVector(SDValue Op, SDValue Lo, SDValue Hi);


  /// Split mask operator of a VP intrinsic.

  std::pair<SDValue, SDValue> SplitMask(SDValue Mask);


  /// Split mask operator of a VP intrinsic in a given location.

  std::pair<SDValue, SDValue> SplitMask(SDValue Mask, const SDLoc &DL);


  // Helper function for incrementing the pointer when splitting

  // memory operations

  void IncrementPointer(MemSDNode *N, EVT MemVT, MachinePointerInfo &MPI,

                        SDValue &Ptr, uint64_t *ScaledOffset = nullptr);


  // Vector Result Splitting: <128 x ty> -> 2 x <64 x ty>.

  void SplitVectorResult(SDNode *N, unsigned ResNo);

  void SplitVecRes_BinOp(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_TernaryOp(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_UnaryOp(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_FFREXP(SDNode *N, unsigned ResNo, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_ExtendOp(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_InregOp(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_ExtVecInRegOp(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_StrictFPOp(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_OverflowOp(SDNode *N, unsigned ResNo,

                              SDValue &Lo, SDValue &Hi);


  void SplitVecRes_FIX(SDNode *N, SDValue &Lo, SDValue &Hi);


  void SplitVecRes_BITCAST(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_BUILD_VECTOR(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_CONCAT_VECTORS(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_EXTRACT_SUBVECTOR(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_INSERT_SUBVECTOR(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_FPOp_MultiType(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_IS_FPCLASS(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_INSERT_VECTOR_ELT(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_LOAD(LoadSDNode *LD, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_VP_LOAD(VPLoadSDNode *LD, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_VP_STRIDED_LOAD(VPStridedLoadSDNode *SLD, SDValue &Lo,

                                   SDValue &Hi);

  void SplitVecRes_MLOAD(MaskedLoadSDNode *MLD, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_Gather(MemSDNode *VPGT, SDValue &Lo, SDValue &Hi,

                          bool SplitSETCC = false);

  void SplitVecRes_ScalarOp(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_STEP_VECTOR(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_SETCC(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_VECTOR_REVERSE(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_VECTOR_SHUFFLE(ShuffleVectorSDNode *N, SDValue &Lo,

                                  SDValue &Hi);

  void SplitVecRes_VECTOR_SPLICE(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_VECTOR_DEINTERLEAVE(SDNode *N);

  void SplitVecRes_VECTOR_INTERLEAVE(SDNode *N);

  void SplitVecRes_VAARG(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_FP_TO_XINT_SAT(SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitVecRes_VP_REVERSE(SDNode *N, SDValue &Lo, SDValue &Hi);


  // Vector Operand Splitting: <128 x ty> -> 2 x <64 x ty>.

  bool SplitVectorOperand(SDNode *N, unsigned OpNo);

  SDValue SplitVecOp_VSELECT(SDNode *N, unsigned OpNo);

  SDValue SplitVecOp_VECREDUCE(SDNode *N, unsigned OpNo);

  SDValue SplitVecOp_VECREDUCE_SEQ(SDNode *N);

  SDValue SplitVecOp_VP_REDUCE(SDNode *N, unsigned OpNo);

  SDValue SplitVecOp_UnaryOp(SDNode *N);

  SDValue SplitVecOp_TruncateHelper(SDNode *N);


  SDValue SplitVecOp_BITCAST(SDNode *N);

  SDValue SplitVecOp_INSERT_SUBVECTOR(SDNode *N, unsigned OpNo);

  SDValue SplitVecOp_EXTRACT_SUBVECTOR(SDNode *N);

  SDValue SplitVecOp_EXTRACT_VECTOR_ELT(SDNode *N);

  SDValue SplitVecOp_ExtVecInRegOp(SDNode *N);

  SDValue SplitVecOp_STORE(StoreSDNode *N, unsigned OpNo);

  SDValue SplitVecOp_VP_STORE(VPStoreSDNode *N, unsigned OpNo);

  SDValue SplitVecOp_VP_STRIDED_STORE(VPStridedStoreSDNode *N, unsigned OpNo);

  SDValue SplitVecOp_MSTORE(MaskedStoreSDNode *N, unsigned OpNo);

  SDValue SplitVecOp_Scatter(MemSDNode *N, unsigned OpNo);

  SDValue SplitVecOp_Gather(MemSDNode *MGT, unsigned OpNo);

  SDValue SplitVecOp_CONCAT_VECTORS(SDNode *N);

  SDValue SplitVecOp_VSETCC(SDNode *N);

  SDValue SplitVecOp_FP_ROUND(SDNode *N);

  SDValue SplitVecOp_FPOpDifferentTypes(SDNode *N);

  SDValue SplitVecOp_FP_TO_XINT_SAT(SDNode *N);


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

  // Vector Widening Support: LegalizeVectorTypes.cpp

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


  /// Given a processed vector Op which was widened into a larger vector, this

  /// method returns the larger vector. The elements of the returned vector

  /// consist of the elements of Op followed by elements containing rubbish.

  /// For example, if Op is a v2i32 that was widened to a v4i32, then this

  /// method returns a v4i32 for which the first two elements are the same as

  /// those of Op, while the last two elements contain rubbish.

  SDValue GetWidenedVector(SDValue Op) {

    TableId &WidenedId = WidenedVectors[getTableId(Op)];

    SDValue WidenedOp = getSDValue(WidenedId);

    assert(WidenedOp.getNode() && "Operand wasn't widened?");

    return WidenedOp;

  }

  void SetWidenedVector(SDValue Op, SDValue Result);


  /// Given a mask Mask, returns the larger vector into which Mask was widened.

  SDValue GetWidenedMask(SDValue Mask, ElementCount EC) {

    // For VP operations, we must also widen the mask. Note that the mask type

    // may not actually need widening, leading it be split along with the VP

    // operation.

    // FIXME: This could lead to an infinite split/widen loop. We only handle

    // the case where the mask needs widening to an identically-sized type as

    // the vector inputs.

    assert(getTypeAction(Mask.getValueType()) ==

               TargetLowering::TypeWidenVector &&

           "Unable to widen binary VP op");

    Mask = GetWidenedVector(Mask);

    assert(Mask.getValueType().getVectorElementCount() == EC &&

           "Unable to widen binary VP op");

    return Mask;

  }


  // Widen Vector Result Promotion.

  void WidenVectorResult(SDNode *N, unsigned ResNo);

  SDValue WidenVecRes_MERGE_VALUES(SDNode* N, unsigned ResNo);

  SDValue WidenVecRes_AssertZext(SDNode* N);

  SDValue WidenVecRes_BITCAST(SDNode* N);

  SDValue WidenVecRes_BUILD_VECTOR(SDNode* N);

  SDValue WidenVecRes_CONCAT_VECTORS(SDNode* N);

  SDValue WidenVecRes_EXTEND_VECTOR_INREG(SDNode* N);

  SDValue WidenVecRes_EXTRACT_SUBVECTOR(SDNode* N);

  SDValue WidenVecRes_INSERT_SUBVECTOR(SDNode *N);

  SDValue WidenVecRes_INSERT_VECTOR_ELT(SDNode* N);

  SDValue WidenVecRes_LOAD(SDNode* N);

  SDValue WidenVecRes_VP_LOAD(VPLoadSDNode *N);

  SDValue WidenVecRes_VP_STRIDED_LOAD(VPStridedLoadSDNode *N);

  SDValue WidenVecRes_MLOAD(MaskedLoadSDNode* N);

  SDValue WidenVecRes_MGATHER(MaskedGatherSDNode* N);

  SDValue WidenVecRes_VP_GATHER(VPGatherSDNode* N);

  SDValue WidenVecRes_ScalarOp(SDNode* N);

  SDValue WidenVecRes_Select(SDNode *N);

  SDValue WidenVSELECTMask(SDNode *N);

  SDValue WidenVecRes_SELECT_CC(SDNode* N);

  SDValue WidenVecRes_SETCC(SDNode* N);

  SDValue WidenVecRes_STRICT_FSETCC(SDNode* N);

  SDValue WidenVecRes_UNDEF(SDNode *N);

  SDValue WidenVecRes_VECTOR_SHUFFLE(ShuffleVectorSDNode *N);

  SDValue WidenVecRes_VECTOR_REVERSE(SDNode *N);


  SDValue WidenVecRes_Ternary(SDNode *N);

  SDValue WidenVecRes_Binary(SDNode *N);

  SDValue WidenVecRes_BinaryCanTrap(SDNode *N);

  SDValue WidenVecRes_BinaryWithExtraScalarOp(SDNode *N);

  SDValue WidenVecRes_StrictFP(SDNode *N);

  SDValue WidenVecRes_OverflowOp(SDNode *N, unsigned ResNo);

  SDValue WidenVecRes_Convert(SDNode *N);

  SDValue WidenVecRes_Convert_StrictFP(SDNode *N);

  SDValue WidenVecRes_FP_TO_XINT_SAT(SDNode *N);

  SDValue WidenVecRes_XRINT(SDNode *N);

  SDValue WidenVecRes_FCOPYSIGN(SDNode *N);

  SDValue WidenVecRes_IS_FPCLASS(SDNode *N);

  SDValue WidenVecRes_ExpOp(SDNode *N);

  SDValue WidenVecRes_Unary(SDNode *N);

  SDValue WidenVecRes_InregOp(SDNode *N);


  // Widen Vector Operand.

  bool WidenVectorOperand(SDNode *N, unsigned OpNo);

  SDValue WidenVecOp_BITCAST(SDNode *N);

  SDValue WidenVecOp_CONCAT_VECTORS(SDNode *N);

  SDValue WidenVecOp_EXTEND(SDNode *N);

  SDValue WidenVecOp_EXTRACT_VECTOR_ELT(SDNode *N);

  SDValue WidenVecOp_INSERT_SUBVECTOR(SDNode *N);

  SDValue WidenVecOp_EXTRACT_SUBVECTOR(SDNode *N);

  SDValue WidenVecOp_EXTEND_VECTOR_INREG(SDNode *N);

  SDValue WidenVecOp_STORE(SDNode* N);

  SDValue WidenVecOp_VP_STORE(SDNode *N, unsigned OpNo);

  SDValue WidenVecOp_VP_STRIDED_STORE(SDNode *N, unsigned OpNo);

  SDValue WidenVecOp_MSTORE(SDNode* N, unsigned OpNo);

  SDValue WidenVecOp_MGATHER(SDNode* N, unsigned OpNo);

  SDValue WidenVecOp_MSCATTER(SDNode* N, unsigned OpNo);

  SDValue WidenVecOp_VP_SCATTER(SDNode* N, unsigned OpNo);

  SDValue WidenVecOp_SETCC(SDNode* N);

  SDValue WidenVecOp_STRICT_FSETCC(SDNode* N);

  SDValue WidenVecOp_VSELECT(SDNode *N);


  SDValue WidenVecOp_Convert(SDNode *N);

  SDValue WidenVecOp_FP_TO_XINT_SAT(SDNode *N);

  SDValue WidenVecOp_UnrollVectorOp(SDNode *N);

  SDValue WidenVecOp_IS_FPCLASS(SDNode *N);

  SDValue WidenVecOp_VECREDUCE(SDNode *N);

  SDValue WidenVecOp_VECREDUCE_SEQ(SDNode *N);

  SDValue WidenVecOp_VP_REDUCE(SDNode *N);

  SDValue WidenVecOp_ExpOp(SDNode *N);


  /// Helper function to generate a set of operations to perform

  /// a vector operation for a wider type.

  ///

  SDValue UnrollVectorOp_StrictFP(SDNode *N, unsigned ResNE);


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

  // Vector Widening Utilities Support: LegalizeVectorTypes.cpp

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


  /// Helper function to generate a set of loads to load a vector with a

  /// resulting wider type. It takes:

  ///   LdChain: list of chains for the load to be generated.

  ///   Ld:      load to widen

  SDValue GenWidenVectorLoads(SmallVectorImpl<SDValue> &LdChain,

                              LoadSDNode *LD);


  /// Helper function to generate a set of extension loads to load a vector with

  /// a resulting wider type. It takes:

  ///   LdChain: list of chains for the load to be generated.

  ///   Ld:      load to widen

  ///   ExtType: extension element type

  SDValue GenWidenVectorExtLoads(SmallVectorImpl<SDValue> &LdChain,

                                 LoadSDNode *LD, ISD::LoadExtType ExtType);


  /// Helper function to generate a set of stores to store a widen vector into

  /// non-widen memory. Returns true if successful, false otherwise.

  ///   StChain: list of chains for the stores we have generated

  ///   ST:      store of a widen value

  bool GenWidenVectorStores(SmallVectorImpl<SDValue> &StChain, StoreSDNode *ST);


  /// Modifies a vector input (widen or narrows) to a vector of NVT.  The

  /// input vector must have the same element type as NVT.

  /// When FillWithZeroes is "on" the vector will be widened with zeroes.

  /// By default, the vector will be widened with undefined values.

  SDValue ModifyToType(SDValue InOp, EVT NVT, bool FillWithZeroes = false);


  /// Return a mask of vector type MaskVT to replace InMask. Also adjust

  /// MaskVT to ToMaskVT if needed with vector extension or truncation.

  SDValue convertMask(SDValue InMask, EVT MaskVT, EVT ToMaskVT);


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

  // Generic Splitting: LegalizeTypesGeneric.cpp

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


  // Legalization methods which only use that the illegal type is split into two

  // not necessarily identical types.  As such they can be used for splitting

  // vectors and expanding integers and floats.


  void GetSplitOp(SDValue Op, SDValue &Lo, SDValue &Hi) {

    if (Op.getValueType().isVector())

      GetSplitVector(Op, Lo, Hi);

    else if (Op.getValueType().isInteger())

      GetExpandedInteger(Op, Lo, Hi);

    else

      GetExpandedFloat(Op, Lo, Hi);

  }


  /// Use ISD::EXTRACT_ELEMENT nodes to extract the low and high parts of the

  /// given value.

  void GetPairElements(SDValue Pair, SDValue &Lo, SDValue &Hi);


  // Generic Result Splitting.

  void SplitRes_MERGE_VALUES(SDNode *N, unsigned ResNo,

                             SDValue &Lo, SDValue &Hi);

  void SplitVecRes_AssertZext  (SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitRes_ARITH_FENCE (SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitRes_Select      (SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitRes_SELECT_CC   (SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitRes_UNDEF       (SDNode *N, SDValue &Lo, SDValue &Hi);

  void SplitRes_FREEZE      (SDNode *N, SDValue &Lo, SDValue &Hi);


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

  // Generic Expansion: LegalizeTypesGeneric.cpp

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


  // Legalization methods which only use that the illegal type is split into two

  // identical types of half the size, and that the Lo/Hi part is stored first

  // in memory on little/big-endian machines, followed by the Hi/Lo part.  As

  // such they can be used for expanding integers and floats.


  void GetExpandedOp(SDValue Op, SDValue &Lo, SDValue &Hi) {

    if (Op.getValueType().isInteger())

      GetExpandedInteger(Op, Lo, Hi);

    else

      GetExpandedFloat(Op, Lo, Hi);

  }


  /// This function will split the integer \p Op into \p NumElements

  /// operations of type \p EltVT and store them in \p Ops.

  void IntegerToVector(SDValue Op, unsigned NumElements,

                       SmallVectorImpl<SDValue> &Ops, EVT EltVT);


  // Generic Result Expansion.

  void ExpandRes_MERGE_VALUES      (SDNode *N, unsigned ResNo,

                                    SDValue &Lo, SDValue &Hi);

  void ExpandRes_BITCAST           (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandRes_BUILD_PAIR        (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandRes_EXTRACT_ELEMENT   (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandRes_EXTRACT_VECTOR_ELT(SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandRes_NormalLoad        (SDNode *N, SDValue &Lo, SDValue &Hi);

  void ExpandRes_VAARG             (SDNode *N, SDValue &Lo, SDValue &Hi);


  // Generic Operand Expansion.

  SDValue ExpandOp_BITCAST          (SDNode *N);

  SDValue ExpandOp_BUILD_VECTOR     (SDNode *N);

  SDValue ExpandOp_EXTRACT_ELEMENT  (SDNode *N);

  SDValue ExpandOp_INSERT_VECTOR_ELT(SDNode *N);

  SDValue ExpandOp_SCALAR_TO_VECTOR (SDNode *N);

  SDValue ExpandOp_NormalStore      (SDNode *N, unsigned OpNo);

};


} // end namespace llvm.


#endif

DL
MachineBasicBlock MachineBasicBlock::iterator DebugLoc DL
Definition: AArch64SLSHardening.cpp:75

From
BlockVerifier::State From
Definition: BlockVerifier.cpp:55

Compiler.h

LLVM_LIBRARY_VISIBILITY
#define LLVM_LIBRARY_VISIBILITY
Definition: Compiler.h:131

DenseMap.h
This file defines the DenseMap class.

I
#define I(x, y, z)
Definition: MD5.cpp:58

assert
assert(ImpDefSCC.getReg()==AMDGPU::SCC &&ImpDefSCC.isDef())

SelectionDAG.h

Ptr
@ Ptr
Definition: TargetLibraryInfo.cpp:74

Bool
@ Bool
Definition: TargetLibraryInfo.cpp:59

TargetLowering.h
This file describes how to lower LLVM code to machine code.

RHS
Value * RHS
Definition: X86PartialReduction.cpp:76

LHS
Value * LHS
Definition: X86PartialReduction.cpp:75

Lo
support::ulittle16_t & Lo
Definition: aarch32.cpp:205

Hi
support::ulittle16_t & Hi
Definition: aarch32.cpp:204

Node
Definition: ItaniumDemangle.h:162

llvm::DAGTypeLegalizer
This takes an arbitrary SelectionDAG as input and hacks on it until only value types the target machi...
Definition: LegalizeTypes.h:30

llvm::DAGTypeLegalizer::DAGTypeLegalizer
DAGTypeLegalizer(SelectionDAG &dag)
Definition: LegalizeTypes.h:167

llvm::DAGTypeLegalizer::NoteDeletion
void NoteDeletion(SDNode *Old, SDNode *New)
Definition: LegalizeTypes.h:179

llvm::DAGTypeLegalizer::getDAG
SelectionDAG & getDAG() const
Definition: LegalizeTypes.h:207

llvm::DAGTypeLegalizer::NodeIdFlags
NodeIdFlags
This pass uses the NodeId on the SDNodes to hold information about the state of the node.
Definition: LegalizeTypes.h:36

llvm::DWARFExpression::Operation
This class represents an Operation in the Expression.
Definition: DWARFExpression.h:32

llvm::SDNode
Represents one node in the SelectionDAG.
Definition: SelectionDAGNodes.h:472

llvm::SDNode::getNumValues
unsigned getNumValues() const
Return the number of values defined/returned by this operator.
Definition: SelectionDAGNodes.h:992

llvm::SDValue
Unlike LLVM values, Selection DAG nodes may return multiple values as the result of a computation.
Definition: SelectionDAGNodes.h:145

llvm::SDValue::getNode
SDNode * getNode() const
get the SDNode which holds the desired result
Definition: SelectionDAGNodes.h:159

llvm::SelectionDAG
This is used to represent a portion of an LLVM function in a low-level Data Dependence DAG representa...
Definition: SelectionDAG.h:225

llvm::SelectionDAG::getZeroExtendInReg
SDValue getZeroExtendInReg(SDValue Op, const SDLoc &DL, EVT VT)
Return the expression required to zero extend the Op value assuming it was the smaller SrcTy value.
Definition: SelectionDAG.cpp:1522

llvm::SelectionDAG::getDataLayout
const DataLayout & getDataLayout() const
Definition: SelectionDAG.h:472

llvm::SelectionDAG::getValueType
SDValue getValueType(EVT)
Definition: SelectionDAG.cpp:1940

llvm::SelectionDAG::getNode
SDValue getNode(unsigned Opcode, const SDLoc &DL, EVT VT, ArrayRef< SDUse > Ops)
Gets or creates the specified node.
Definition: SelectionDAG.cpp:9699

llvm::SelectionDAG::getContext
LLVMContext * getContext() const
Definition: SelectionDAG.h:485

llvm::TargetLoweringBase::ValueTypeActionImpl
Definition: TargetLowering.h:1037

llvm::TargetLoweringBase::ValueTypeActionImpl::getTypeAction
LegalizeTypeAction getTypeAction(MVT VT) const
Definition: TargetLowering.h:1048

llvm::TargetLoweringBase::LegalizeTypeAction
LegalizeTypeAction
This enum indicates whether a types are legal for a target, and if not, what action should be used to...
Definition: TargetLowering.h:207

llvm::TargetLowering
This class defines information used to lower LLVM code to legal SelectionDAG operators that the targe...
Definition: TargetLowering.h:3653

uint64_t

unsigned

llvm::AMDGPU::SendMsg::Op
Op
Definition: SIDefines.h:394

llvm::AMDGPU::VGPRIndexMode::Id
Id
Definition: SIDefines.h:280

llvm::BitmaskEnumDetail::Mask
constexpr std::underlying_type_t< E > Mask()
Get a bitmask with 1s in all places up to the high-order bit of E's largest value.
Definition: BitmaskEnum.h:121

llvm::M68k::MemAddrModeKind::V
@ V

llvm
This is an optimization pass for GlobalISel generic memory operations.
Definition: AddressRanges.h:18

N
#define N

llvm::EVT
Extended Value Type.
Definition: ValueTypes.h:34