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//===- llvm/CodeGen/MachineInstr.h - MachineInstr class ---------*- C++ -*-===//
//
//                     The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file contains the declaration of the MachineInstr class, which is the
// basic representation for all target dependent machine instructions used by
// the back end.
//
//===----------------------------------------------------------------------===//

#ifndef LLVM_CODEGEN_MACHINEINSTR_H
#define LLVM_CODEGEN_MACHINEINSTR_H

#include "llvm/ADT/DenseMapInfo.h"
#include "llvm/ADT/ilist.h"
#include "llvm/ADT/ilist_node.h"
#include "llvm/ADT/iterator_range.h"
#include "llvm/Analysis/AliasAnalysis.h"
#include "llvm/CodeGen/MachineOperand.h"
#include "llvm/CodeGen/TargetOpcodes.h"
#include "llvm/IR/DebugLoc.h"
#include "llvm/IR/InlineAsm.h"
#include "llvm/MC/MCInstrDesc.h"
#include "llvm/Support/ArrayRecycler.h"
#include <algorithm>
#include <cassert>
#include <cstdint>
#include <utility>

namespace llvm {

template <typename T> class ArrayRef;
class DIExpression;
class DILocalVariable;
class MachineBasicBlock;
class MachineFunction;
class MachineMemOperand;
class MachineRegisterInfo;
class ModuleSlotTracker;
class raw_ostream;
template <typename T> class SmallVectorImpl;
class SmallBitVector;
class StringRef;
class TargetInstrInfo;
class TargetRegisterClass;
class TargetRegisterInfo;

//===----------------------------------------------------------------------===//
/// Representation of each machine instruction.
///
/// This class isn't a POD type, but it must have a trivial destructor. When a
/// MachineFunction is deleted, all the contained MachineInstrs are deallocated
/// without having their destructor called.
///
class MachineInstr
    : public ilist_node_with_parent<MachineInstr, MachineBasicBlock,
                                    ilist_sentinel_tracking<true>> {
public:
  using mmo_iterator = MachineMemOperand **;

  /// Flags to specify different kinds of comments to output in
  /// assembly code.  These flags carry semantic information not
  /// otherwise easily derivable from the IR text.
  ///
  enum CommentFlag {
    ReloadReuse = 0x1,    // higher bits are reserved for target dep comments.
    NoSchedComment = 0x2,
    TAsmComments = 0x4    // Target Asm comments should start from this value.
  };

  enum MIFlag {
    NoFlags      = 0,
    FrameSetup   = 1 << 0,              // Instruction is used as a part of
                                        // function frame setup code.
    FrameDestroy = 1 << 1,              // Instruction is used as a part of
                                        // function frame destruction code.
    BundledPred  = 1 << 2,              // Instruction has bundled predecessors.
    BundledSucc  = 1 << 3               // Instruction has bundled successors.
  };

private:
  const MCInstrDesc *MCID;              // Instruction descriptor.
  MachineBasicBlock *Parent = nullptr;  // Pointer to the owning basic block.

  // Operands are allocated by an ArrayRecycler.
  MachineOperand *Operands = nullptr;   // Pointer to the first operand.
  unsigned NumOperands = 0;             // Number of operands on instruction.
  using OperandCapacity = ArrayRecycler<MachineOperand>::Capacity;
  OperandCapacity CapOperands;          // Capacity of the Operands array.

  uint8_t Flags = 0;                    // Various bits of additional
                                        // information about machine
                                        // instruction.

  uint8_t AsmPrinterFlags = 0;          // Various bits of information used by
                                        // the AsmPrinter to emit helpful
                                        // comments.  This is *not* semantic
                                        // information.  Do not use this for
                                        // anything other than to convey comment
                                        // information to AsmPrinter.

  uint8_t NumMemRefs = 0;               // Information on memory references.
  // Note that MemRefs == nullptr,  means 'don't know', not 'no memory access'.
  // Calling code must treat missing information conservatively.  If the number
  // of memory operands required to be precise exceeds the maximum value of
  // NumMemRefs - currently 256 - we remove the operands entirely. Note also
  // that this is a non-owning reference to a shared copy on write buffer owned
  // by the MachineFunction and created via MF.allocateMemRefsArray.
  mmo_iterator MemRefs = nullptr;

  DebugLoc debugLoc;                    // Source line information.

  // Intrusive list support
  friend struct ilist_traits<MachineInstr>;
  friend struct ilist_callback_traits<MachineBasicBlock>;
  void setParent(MachineBasicBlock *P) { Parent = P; }

  /// This constructor creates a copy of the given
  /// MachineInstr in the given MachineFunction.
  MachineInstr(MachineFunction &, const MachineInstr &);

  /// This constructor create a MachineInstr and add the implicit operands.
  /// It reserves space for number of operands specified by
  /// MCInstrDesc.  An explicit DebugLoc is supplied.
  MachineInstr(MachineFunction &, const MCInstrDesc &MCID, DebugLoc dl,
               bool NoImp = false);

  // MachineInstrs are pool-allocated and owned by MachineFunction.
  friend class MachineFunction;

public:
  MachineInstr(const MachineInstr &) = delete;
  MachineInstr &operator=(const MachineInstr &) = delete;
  // Use MachineFunction::DeleteMachineInstr() instead.
  ~MachineInstr() = delete;

  const MachineBasicBlock* getParent() const { return Parent; }
  MachineBasicBlock* getParent() { return Parent; }

  /// Return the function that contains the basic block that this instruction
  /// belongs to.
  ///
  /// Note: this is undefined behaviour if the instruction does not have a
  /// parent.
  const MachineFunction *getMF() const;
  MachineFunction *getMF() {
    return const_cast<MachineFunction *>(
        static_cast<const MachineInstr *>(this)->getMF());
  }

  /// Return the asm printer flags bitvector.
  uint8_t getAsmPrinterFlags() const { return AsmPrinterFlags; }

  /// Clear the AsmPrinter bitvector.
  void clearAsmPrinterFlags() { AsmPrinterFlags = 0; }

  /// Return whether an AsmPrinter flag is set.
  bool getAsmPrinterFlag(CommentFlag Flag) const {
    return AsmPrinterFlags & Flag;
  }

  /// Set a flag for the AsmPrinter.
  void setAsmPrinterFlag(uint8_t Flag) {
    AsmPrinterFlags |= Flag;
  }

  /// Clear specific AsmPrinter flags.
  void clearAsmPrinterFlag(CommentFlag Flag) {
    AsmPrinterFlags &= ~Flag;
  }

  /// Return the MI flags bitvector.
  uint8_t getFlags() const {
    return Flags;
  }

  /// Return whether an MI flag is set.
  bool getFlag(MIFlag Flag) const {
    return Flags & Flag;
  }

  /// Set a MI flag.
  void setFlag(MIFlag Flag) {
    Flags |= (uint8_t)Flag;
  }

  void setFlags(unsigned flags) {
    // Filter out the automatically maintained flags.
    unsigned Mask = BundledPred | BundledSucc;
    Flags = (Flags & Mask) | (flags & ~Mask);
  }

  /// clearFlag - Clear a MI flag.
  void clearFlag(MIFlag Flag) {
    Flags &= ~((uint8_t)Flag);
  }

  /// Return true if MI is in a bundle (but not the first MI in a bundle).
  ///
  /// A bundle looks like this before it's finalized:
  ///   ----------------
  ///   |      MI      |
  ///   ----------------
  ///          |
  ///   ----------------
  ///   |      MI    * |
  ///   ----------------
  ///          |
  ///   ----------------
  ///   |      MI    * |
  ///   ----------------
  /// In this case, the first MI starts a bundle but is not inside a bundle, the
  /// next 2 MIs are considered "inside" the bundle.
  ///
  /// After a bundle is finalized, it looks like this:
  ///   ----------------
  ///   |    Bundle    |
  ///   ----------------
  ///          |
  ///   ----------------
  ///   |      MI    * |
  ///   ----------------
  ///          |
  ///   ----------------
  ///   |      MI    * |
  ///   ----------------
  ///          |
  ///   ----------------
  ///   |      MI    * |
  ///   ----------------
  /// The first instruction has the special opcode "BUNDLE". It's not "inside"
  /// a bundle, but the next three MIs are.
  bool isInsideBundle() const {
    return getFlag(BundledPred);
  }

  /// Return true if this instruction part of a bundle. This is true
  /// if either itself or its following instruction is marked "InsideBundle".
  bool isBundled() const {
    return isBundledWithPred() || isBundledWithSucc();
  }

  /// Return true if this instruction is part of a bundle, and it is not the
  /// first instruction in the bundle.
  bool isBundledWithPred() const { return getFlag(BundledPred); }

  /// Return true if this instruction is part of a bundle, and it is not the
  /// last instruction in the bundle.
  bool isBundledWithSucc() const { return getFlag(BundledSucc); }

  /// Bundle this instruction with its predecessor. This can be an unbundled
  /// instruction, or it can be the first instruction in a bundle.
  void bundleWithPred();

  /// Bundle this instruction with its successor. This can be an unbundled
  /// instruction, or it can be the last instruction in a bundle.
  void bundleWithSucc();

  /// Break bundle above this instruction.
  void unbundleFromPred();

  /// Break bundle below this instruction.
  void unbundleFromSucc();

  /// Returns the debug location id of this MachineInstr.
  const DebugLoc &getDebugLoc() const { return debugLoc; }

  /// Return the debug variable referenced by
  /// this DBG_VALUE instruction.
  const DILocalVariable *getDebugVariable() const;

  /// Return the complex address expression referenced by
  /// this DBG_VALUE instruction.
  const DIExpression *getDebugExpression() const;

  /// Emit an error referring to the source location of this instruction.
  /// This should only be used for inline assembly that is somehow
  /// impossible to compile. Other errors should have been handled much
  /// earlier.
  ///
  /// If this method returns, the caller should try to recover from the error.
  void emitError(StringRef Msg) const;

  /// Returns the target instruction descriptor of this MachineInstr.
  const MCInstrDesc &getDesc() const { return *MCID; }

  /// Returns the opcode of this MachineInstr.
  unsigned getOpcode() const { return MCID->Opcode; }

  /// Access to explicit operands of the instruction.
  unsigned getNumOperands() const { return NumOperands; }

  const MachineOperand& getOperand(unsigned i) const {
    assert(i < getNumOperands() && "getOperand() out of range!");
    return Operands[i];
  }
  MachineOperand& getOperand(unsigned i) {
    assert(i < getNumOperands() && "getOperand() out of range!");
    return Operands[i];
  }

  /// Return true if operand \p OpIdx is a subregister index.
  bool isOperandSubregIdx(unsigned OpIdx) const {
    assert(getOperand(OpIdx).getType() == MachineOperand::MO_Immediate &&
           "Expected MO_Immediate operand type.");
    if (isExtractSubreg() && OpIdx == 2)
      return true;
    if (isInsertSubreg() && OpIdx == 3)
      return true;
    if (isRegSequence() && OpIdx > 1 && (OpIdx % 2) == 0)
      return true;
    if (isSubregToReg() && OpIdx == 3)
      return true;
    return false;
  }

  /// Returns the number of non-implicit operands.
  unsigned getNumExplicitOperands() const;

  /// iterator/begin/end - Iterate over all operands of a machine instruction.
  using mop_iterator = MachineOperand *;
  using const_mop_iterator = const MachineOperand *;

  mop_iterator operands_begin() { return Operands; }
  mop_iterator operands_end() { return Operands + NumOperands; }

  const_mop_iterator operands_begin() const { return Operands; }
  const_mop_iterator operands_end() const { return Operands + NumOperands; }

  iterator_range<mop_iterator> operands() {
    return make_range(operands_begin(), operands_end());
  }
  iterator_range<const_mop_iterator> operands() const {
    return make_range(operands_begin(), operands_end());
  }
  iterator_range<mop_iterator> explicit_operands() {
    return make_range(operands_begin(),
                      operands_begin() + getNumExplicitOperands());
  }
  iterator_range<const_mop_iterator> explicit_operands() const {
    return make_range(operands_begin(),
                      operands_begin() + getNumExplicitOperands());
  }
  iterator_range<mop_iterator> implicit_operands() {
    return make_range(explicit_operands().end(), operands_end());
  }
  iterator_range<const_mop_iterator> implicit_operands() const {
    return make_range(explicit_operands().end(), operands_end());
  }
  /// Returns a range over all explicit operands that are register definitions.
  /// Implicit definition are not included!
  iterator_range<mop_iterator> defs() {
    return make_range(operands_begin(),
                      operands_begin() + getDesc().getNumDefs());
  }
  /// \copydoc defs()
  iterator_range<const_mop_iterator> defs() const {
    return make_range(operands_begin(),
                      operands_begin() + getDesc().getNumDefs());
  }
  /// Returns a range that includes all operands that are register uses.
  /// This may include unrelated operands which are not register uses.
  iterator_range<mop_iterator> uses() {
    return make_range(operands_begin() + getDesc().getNumDefs(),
                      operands_end());
  }
  /// \copydoc uses()
  iterator_range<const_mop_iterator> uses() const {
    return make_range(operands_begin() + getDesc().getNumDefs(),
                      operands_end());
  }
  iterator_range<mop_iterator> explicit_uses() {
    return make_range(operands_begin() + getDesc().getNumDefs(),
                      operands_begin() + getNumExplicitOperands() );
  }
  iterator_range<const_mop_iterator> explicit_uses() const {
    return make_range(operands_begin() + getDesc().getNumDefs(),
                      operands_begin() + getNumExplicitOperands() );
  }

  /// Returns the number of the operand iterator \p I points to.
  unsigned getOperandNo(const_mop_iterator I) const {
    return I - operands_begin();
  }

  /// Access to memory operands of the instruction
  mmo_iterator memoperands_begin() const { return MemRefs; }
  mmo_iterator memoperands_end() const { return MemRefs + NumMemRefs; }
  /// Return true if we don't have any memory operands which described the
  /// memory access done by this instruction.  If this is true, calling code
  /// must be conservative.
  bool memoperands_empty() const { return NumMemRefs == 0; }

  iterator_range<mmo_iterator>  memoperands() {
    return make_range(memoperands_begin(), memoperands_end());
  }
  iterator_range<mmo_iterator> memoperands() const {
    return make_range(memoperands_begin(), memoperands_end());
  }

  /// Return true if this instruction has exactly one MachineMemOperand.
  bool hasOneMemOperand() const {
    return NumMemRefs == 1;
  }

  /// Return the number of memory operands.
  unsigned getNumMemOperands() const { return NumMemRefs; }

  /// API for querying MachineInstr properties. They are the same as MCInstrDesc
  /// queries but they are bundle aware.

  enum QueryType {
    IgnoreBundle,    // Ignore bundles
    AnyInBundle,     // Return true if any instruction in bundle has property
    AllInBundle      // Return true if all instructions in bundle have property
  };

  /// Return true if the instruction (or in the case of a bundle,
  /// the instructions inside the bundle) has the specified property.
  /// The first argument is the property being queried.
  /// The second argument indicates whether the query should look inside
  /// instruction bundles.
  bool hasProperty(unsigned MCFlag, QueryType Type = AnyInBundle) const {
    // Inline the fast path for unbundled or bundle-internal instructions.
    if (Type == IgnoreBundle || !isBundled() || isBundledWithPred())
      return getDesc().getFlags() & (1ULL << MCFlag);

    // If this is the first instruction in a bundle, take the slow path.
    return hasPropertyInBundle(1ULL << MCFlag, Type);
  }

  /// Return true if this instruction can have a variable number of operands.
  /// In this case, the variable operands will be after the normal
  /// operands but before the implicit definitions and uses (if any are
  /// present).
  bool isVariadic(QueryType Type = IgnoreBundle) const {
    return hasProperty(MCID::Variadic, Type);
  }

  /// Set if this instruction has an optional definition, e.g.
  /// ARM instructions which can set condition code if 's' bit is set.
  bool hasOptionalDef(QueryType Type = IgnoreBundle) const {
    return hasProperty(MCID::HasOptionalDef, Type);
  }

  /// Return true if this is a pseudo instruction that doesn't
  /// correspond to a real machine instruction.
  bool isPseudo(QueryType Type = IgnoreBundle) const {
    return hasProperty(MCID::Pseudo, Type);
  }

  bool isReturn(QueryType Type = AnyInBundle) const {
    return hasProperty(MCID::Return, Type);
  }

  bool isCall(QueryType Type = AnyInBundle) const {
    return hasProperty(MCID::Call, Type);
  }

  /// Returns true if the specified instruction stops control flow
  /// from executing the instruction immediately following it.  Examples include
  /// unconditional branches and return instructions.
  bool isBarrier(QueryType Type = AnyInBundle) const {
    return hasProperty(MCID::Barrier, Type);
  }

  /// Returns true if this instruction part of the terminator for a basic block.
  /// Typically this is things like return and branch instructions.
  ///
  /// Various passes use this to insert code into the bottom of a basic block,
  /// but before control flow occurs.
  bool isTerminator(QueryType Type = AnyInBundle) const {
    return hasProperty(MCID::Terminator, Type);
  }

  /// Returns true if this is a conditional, unconditional, or indirect branch.
  /// Predicates below can be used to discriminate between
  /// these cases, and the TargetInstrInfo::AnalyzeBranch method can be used to
  /// get more information.
  bool isBranch(QueryType Type = AnyInBundle) const {
    return hasProperty(MCID::Branch, Type);
  }

  /// Return true if this is an indirect branch, such as a
  /// branch through a register.
  bool isIndirectBranch(QueryType Type = AnyInBundle) const {
    return hasProperty(MCID::IndirectBranch, Type);
  }

  /// Return true if this is a branch which may fall
  /// through to the next instruction or may transfer control flow to some other
  /// block.  The TargetInstrInfo::AnalyzeBranch method can be used to get more
  /// information about this branch.
  bool isConditionalBranch(QueryType Type = AnyInBundle) const {
    return isBranch(Type) & !isBarrier(Type) & !isIndirectBranch(Type);
  }

  /// Return true if this is a branch which always
  /// transfers control flow to some other block.  The
  /// TargetInstrInfo::AnalyzeBranch method can be used to get more information
  /// about this branch.
  bool isUnconditionalBranch(QueryType Type = AnyInBundle) const {
    return isBranch(Type) & isBarrier(Type) & !isIndirectBranch(Type);
  }

  /// Return true if this instruction has a predicate operand that
  /// controls execution.  It may be set to 'always', or may be set to other
  /// values.   There are various methods in TargetInstrInfo that can be used to
  /// control and modify the predicate in this instruction.
  bool isPredicable(QueryType Type = AllInBundle) const {
    // If it's a bundle than all bundled instructions must be predicable for this
    // to return true.
    return hasProperty(MCID::Predicable, Type);
  }

  /// Return true if this instruction is a comparison.
  bool isCompare(QueryType Type = IgnoreBundle) const {
    return hasProperty(MCID::Compare, Type);
  }

  /// Return true if this instruction is a move immediate
  /// (including conditional moves) instruction.
  bool isMoveImmediate(QueryType Type = IgnoreBundle) const {
    return hasProperty(MCID::MoveImm, Type);
  }

  /// Return true if this instruction is a bitcast instruction.
  bool isBitcast(QueryType Type = IgnoreBundle) const {
    return hasProperty(MCID::Bitcast, Type);
  }

  /// Return true if this instruction is a select instruction.
  bool isSelect(QueryType Type = IgnoreBundle) const {
    return hasProperty(MCID::Select, Type);
  }

  /// Return true if this instruction cannot be safely duplicated.
  /// For example, if the instruction has a unique labels attached
  /// to it, duplicating it would cause multiple definition errors.
  bool isNotDuplicable(QueryType Type = AnyInBundle) const {
    return hasProperty(MCID::NotDuplicable, Type);
  }

  /// Return true if this instruction is convergent.
  /// Convergent instructions can not be made control-dependent on any
  /// additional values.
  bool isConvergent(QueryType Type = AnyInBundle) const {
    if (isInlineAsm()) {
      unsigned ExtraInfo = getOperand(InlineAsm::MIOp_ExtraInfo).getImm();
      if (ExtraInfo & InlineAsm::Extra_IsConvergent)
        return true;
    }
    return hasProperty(MCID::Convergent, Type);
  }

  /// Returns true if the specified instruction has a delay slot
  /// which must be filled by the code generator.
  bool hasDelaySlot(QueryType Type = AnyInBundle) const {
    return hasProperty(MCID::DelaySlot, Type);
  }

  /// Return true for instructions that can be folded as
  /// memory operands in other instructions. The most common use for this
  /// is instructions that are simple loads from memory that don't modify
  /// the loaded value in any way, but it can also be used for instructions
  /// that can be expressed as constant-pool loads, such as V_SETALLONES
  /// on x86, to allow them to be folded when it is beneficial.
  /// This should only be set on instructions that return a value in their
  /// only virtual register definition.
  bool canFoldAsLoad(QueryType Type = IgnoreBundle) const {
    return hasProperty(MCID::FoldableAsLoad, Type);
  }

  /// \brief Return true if this instruction behaves
  /// the same way as the generic REG_SEQUENCE instructions.
  /// E.g., on ARM,
  /// dX VMOVDRR rY, rZ
  /// is equivalent to
  /// dX = REG_SEQUENCE rY, ssub_0, rZ, ssub_1.
  ///
  /// Note that for the optimizers to be able to take advantage of
  /// this property, TargetInstrInfo::getRegSequenceLikeInputs has to be
  /// override accordingly.
  bool isRegSequenceLike(QueryType Type = IgnoreBundle) const {
    return hasProperty(MCID::RegSequence, Type);
  }

  /// \brief Return true if this instruction behaves
  /// the same way as the generic EXTRACT_SUBREG instructions.
  /// E.g., on ARM,
  /// rX, rY VMOVRRD dZ
  /// is equivalent to two EXTRACT_SUBREG:
  /// rX = EXTRACT_SUBREG dZ, ssub_0
  /// rY = EXTRACT_SUBREG dZ, ssub_1
  ///
  /// Note that for the optimizers to be able to take advantage of
  /// this property, TargetInstrInfo::getExtractSubregLikeInputs has to be
  /// override accordingly.
  bool isExtractSubregLike(QueryType Type = IgnoreBundle) const {
    return hasProperty(MCID::ExtractSubreg, Type);
  }

  /// \brief Return true if this instruction behaves
  /// the same way as the generic INSERT_SUBREG instructions.
  /// E.g., on ARM,
  /// dX = VSETLNi32 dY, rZ, Imm
  /// is equivalent to a INSERT_SUBREG:
  /// dX = INSERT_SUBREG dY, rZ, translateImmToSubIdx(Imm)
  ///
  /// Note that for the optimizers to be able to take advantage of
  /// this property, TargetInstrInfo::getInsertSubregLikeInputs has to be
  /// override accordingly.
  bool isInsertSubregLike(QueryType Type = IgnoreBundle) const {
    return hasProperty(MCID::InsertSubreg, Type);
  }

  //===--------------------------------------------------------------------===//
  // Side Effect Analysis
  //===--------------------------------------------------------------------===//

  /// Return true if this instruction could possibly read memory.
  /// Instructions with this flag set are not necessarily simple load
  /// instructions, they may load a value and modify it, for example.
  bool mayLoad(QueryType Type = AnyInBundle) const {
    if (isInlineAsm()) {
      unsigned ExtraInfo = getOperand(InlineAsm::MIOp_ExtraInfo).getImm();
      if (ExtraInfo & InlineAsm::Extra_MayLoad)
        return true;
    }
    return hasProperty(MCID::MayLoad, Type);
  }

  /// Return true if this instruction could possibly modify memory.
  /// Instructions with this flag set are not necessarily simple store
  /// instructions, they may store a modified value based on their operands, or
  /// may not actually modify anything, for example.
  bool mayStore(QueryType Type = AnyInBundle) const {
    if (isInlineAsm()) {
      unsigned ExtraInfo = getOperand(InlineAsm::MIOp_ExtraInfo).getImm();
      if (ExtraInfo & InlineAsm::Extra_MayStore)
        return true;
    }
    return hasProperty(MCID::MayStore, Type);
  }

  /// Return true if this instruction could possibly read or modify memory.
  bool mayLoadOrStore(QueryType Type = AnyInBundle) const {
    return mayLoad(Type) || mayStore(Type);
  }

  //===--------------------------------------------------------------------===//
  // Flags that indicate whether an instruction can be modified by a method.
  //===--------------------------------------------------------------------===//

  /// Return true if this may be a 2- or 3-address
  /// instruction (of the form "X = op Y, Z, ..."), which produces the same
  /// result if Y and Z are exchanged.  If this flag is set, then the
  /// TargetInstrInfo::commuteInstruction method may be used to hack on the
  /// instruction.
  ///
  /// Note that this flag may be set on instructions that are only commutable
  /// sometimes.  In these cases, the call to commuteInstruction will fail.
  /// Also note that some instructions require non-trivial modification to
  /// commute them.
  bool isCommutable(QueryType Type = IgnoreBundle) const {
    return hasProperty(MCID::Commutable, Type);
  }

  /// Return true if this is a 2-address instruction
  /// which can be changed into a 3-address instruction if needed.  Doing this
  /// transformation can be profitable in the register allocator, because it
  /// means that the instruction can use a 2-address form if possible, but
  /// degrade into a less efficient form if the source and dest register cannot
  /// be assigned to the same register.  For example, this allows the x86
  /// backend to turn a "shl reg, 3" instruction into an LEA instruction, which
  /// is the same speed as the shift but has bigger code size.
  ///
  /// If this returns true, then the target must implement the
  /// TargetInstrInfo::convertToThreeAddress method for this instruction, which
  /// is allowed to fail if the transformation isn't valid for this specific
  /// instruction (e.g. shl reg, 4 on x86).
  ///
  bool isConvertibleTo3Addr(QueryType Type = IgnoreBundle) const {
    return hasProperty(MCID::ConvertibleTo3Addr, Type);
  }

  /// Return true if this instruction requires
  /// custom insertion support when the DAG scheduler is inserting it into a
  /// machine basic block.  If this is true for the instruction, it basically
  /// means that it is a pseudo instruction used at SelectionDAG time that is
  /// expanded out into magic code by the target when MachineInstrs are formed.
  ///
  /// If this is true, the TargetLoweringInfo::InsertAtEndOfBasicBlock method
  /// is used to insert this into the MachineBasicBlock.
  bool usesCustomInsertionHook(QueryType Type = IgnoreBundle) const {
    return hasProperty(MCID::UsesCustomInserter, Type);
  }

  /// Return true if this instruction requires *adjustment*
  /// after instruction selection by calling a target hook. For example, this
  /// can be used to fill in ARM 's' optional operand depending on whether
  /// the conditional flag register is used.
  bool hasPostISelHook(QueryType Type = IgnoreBundle) const {
    return hasProperty(MCID::HasPostISelHook, Type);
  }

  /// Returns true if this instruction is a candidate for remat.
  /// This flag is deprecated, please don't use it anymore.  If this
  /// flag is set, the isReallyTriviallyReMaterializable() method is called to
  /// verify the instruction is really rematable.
  bool isRematerializable(QueryType Type = AllInBundle) const {
    // It's only possible to re-mat a bundle if all bundled instructions are
    // re-materializable.
    return hasProperty(MCID::Rematerializable, Type);
  }

  /// Returns true if this instruction has the same cost (or less) than a move
  /// instruction. This is useful during certain types of optimizations
  /// (e.g., remat during two-address conversion or machine licm)
  /// where we would like to remat or hoist the instruction, but not if it costs
  /// more than moving the instruction into the appropriate register. Note, we
  /// are not marking copies from and to the same register class with this flag.
  bool isAsCheapAsAMove(QueryType Type = AllInBundle) const {
    // Only returns true for a bundle if all bundled instructions are cheap.
    return hasProperty(MCID::CheapAsAMove, Type);
  }

  /// Returns true if this instruction source operands
  /// have special register allocation requirements that are not captured by the
  /// operand register classes. e.g. ARM::STRD's two source registers must be an
  /// even / odd pair, ARM::STM registers have to be in ascending order.
  /// Post-register allocation passes should not attempt to change allocations
  /// for sources of instructions with this flag.
  bool hasExtraSrcRegAllocReq(QueryType Type = AnyInBundle) const {
    return hasProperty(MCID::ExtraSrcRegAllocReq, Type);
  }

  /// Returns true if this instruction def operands
  /// have special register allocation requirements that are not captured by the
  /// operand register classes. e.g. ARM::LDRD's two def registers must be an
  /// even / odd pair, ARM::LDM registers have to be in ascending order.
  /// Post-register allocation passes should not attempt to change allocations
  /// for definitions of instructions with this flag.
  bool hasExtraDefRegAllocReq(QueryType Type = AnyInBundle) const {
    return hasProperty(MCID::ExtraDefRegAllocReq, Type);
  }

  enum MICheckType {
    CheckDefs,      // Check all operands for equality
    CheckKillDead,  // Check all operands including kill / dead markers
    IgnoreDefs,     // Ignore all definitions
    IgnoreVRegDefs  // Ignore virtual register definitions
  };

  /// Return true if this instruction is identical to \p Other.
  /// Two instructions are identical if they have the same opcode and all their
  /// operands are identical (with respect to MachineOperand::isIdenticalTo()).
  /// Note that this means liveness related flags (dead, undef, kill) do not
  /// affect the notion of identical.
  bool isIdenticalTo(const MachineInstr &Other,
                     MICheckType Check = CheckDefs) const;

  /// Unlink 'this' from the containing basic block, and return it without
  /// deleting it.
  ///
  /// This function can not be used on bundled instructions, use
  /// removeFromBundle() to remove individual instructions from a bundle.
  MachineInstr *removeFromParent();

  /// Unlink this instruction from its basic block and return it without
  /// deleting it.
  ///
  /// If the instruction is part of a bundle, the other instructions in the
  /// bundle remain bundled.
  MachineInstr *removeFromBundle();

  /// Unlink 'this' from the containing basic block and delete it.
  ///
  /// If this instruction is the header of a bundle, the whole bundle is erased.
  /// This function can not be used for instructions inside a bundle, use
  /// eraseFromBundle() to erase individual bundled instructions.
  void eraseFromParent();

  /// Unlink 'this' from the containing basic block and delete it.
  ///
  /// For all definitions mark their uses in DBG_VALUE nodes
  /// as undefined. Otherwise like eraseFromParent().
  void eraseFromParentAndMarkDBGValuesForRemoval();

  /// Unlink 'this' form its basic block and delete it.
  ///
  /// If the instruction is part of a bundle, the other instructions in the
  /// bundle remain bundled.
  void eraseFromBundle();

  bool isEHLabel() const { return getOpcode() == TargetOpcode::EH_LABEL; }
  bool isGCLabel() const { return getOpcode() == TargetOpcode::GC_LABEL; }
  bool isAnnotationLabel() const {
    return getOpcode() == TargetOpcode::ANNOTATION_LABEL;
  }

  /// Returns true if the MachineInstr represents a label.
  bool isLabel() const {
    return isEHLabel() || isGCLabel() || isAnnotationLabel();
  }

  bool isCFIInstruction() const {
    return getOpcode() == TargetOpcode::CFI_INSTRUCTION;
  }

  // True if the instruction represents a position in the function.
  bool isPosition() const { return isLabel() || isCFIInstruction(); }

  bool isDebugValue() const { return getOpcode() == TargetOpcode::DBG_VALUE; }

  /// A DBG_VALUE is indirect iff the first operand is a register and
  /// the second operand is an immediate.
  bool isIndirectDebugValue() const {
    return isDebugValue()
      && getOperand(0).isReg()
      && getOperand(1).isImm();
  }

  bool isPHI() const {
    return getOpcode() == TargetOpcode::PHI ||
           getOpcode() == TargetOpcode::G_PHI;
  }
  bool isKill() const { return getOpcode() == TargetOpcode::KILL; }
  bool isImplicitDef() const { return getOpcode()==TargetOpcode::IMPLICIT_DEF; }
  bool isInlineAsm() const { return getOpcode() == TargetOpcode::INLINEASM; }

  bool isMSInlineAsm() const {
    return getOpcode() == TargetOpcode::INLINEASM && getInlineAsmDialect();
  }

  bool isStackAligningInlineAsm() const;
  InlineAsm::AsmDialect getInlineAsmDialect() const;

  bool isInsertSubreg() const {
    return getOpcode() == TargetOpcode::INSERT_SUBREG;
  }

  bool isSubregToReg() const {
    return getOpcode() == TargetOpcode::SUBREG_TO_REG;
  }

  bool isRegSequence() const {
    return getOpcode() == TargetOpcode::REG_SEQUENCE;
  }

  bool isBundle() const {
    return getOpcode() == TargetOpcode::BUNDLE;
  }

  bool isCopy() const {
    return getOpcode() == TargetOpcode::COPY;
  }

  bool isFullCopy() const {
    return isCopy() && !getOperand(0).getSubReg() && !getOperand(1).getSubReg();
  }

  bool isExtractSubreg() const {
    return getOpcode() == TargetOpcode::EXTRACT_SUBREG;
  }

  /// Return true if the instruction behaves like a copy.
  /// This does not include native copy instructions.
  bool isCopyLike() const {
    return isCopy() || isSubregToReg();
  }

  /// Return true is the instruction is an identity copy.
  bool isIdentityCopy() const {
    return isCopy() && getOperand(0).getReg() == getOperand(1).getReg() &&
      getOperand(0).getSubReg() == getOperand(1).getSubReg();
  }

  /// Return true if this instruction doesn't produce any output in the form of
  /// executable instructions.
  bool isMetaInstruction() const {
    switch (getOpcode()) {
    default:
      return false;
    case TargetOpcode::IMPLICIT_DEF:
    case TargetOpcode::KILL:
    case TargetOpcode::CFI_INSTRUCTION:
    case TargetOpcode::EH_LABEL:
    case TargetOpcode::GC_LABEL:
    case TargetOpcode::DBG_VALUE:
    case TargetOpcode::LIFETIME_START:
    case TargetOpcode::LIFETIME_END:
      return true;
    }
  }

  /// Return true if this is a transient instruction that is either very likely
  /// to be eliminated during register allocation (such as copy-like
  /// instructions), or if this instruction doesn't have an execution-time cost.
  bool isTransient() const {
    switch (getOpcode()) {
    default:
      return isMetaInstruction();
    // Copy-like instructions are usually eliminated during register allocation.
    case TargetOpcode::PHI:
    case TargetOpcode::G_PHI:
    case TargetOpcode::COPY:
    case TargetOpcode::INSERT_SUBREG:
    case TargetOpcode::SUBREG_TO_REG:
    case TargetOpcode::REG_SEQUENCE:
      return true;
    }
  }

  /// Return the number of instructions inside the MI bundle, excluding the
  /// bundle header.
  ///
  /// This is the number of instructions that MachineBasicBlock::iterator
  /// skips, 0 for unbundled instructions.
  unsigned getBundleSize() const;

  /// Return true if the MachineInstr reads the specified register.
  /// If TargetRegisterInfo is passed, then it also checks if there
  /// is a read of a super-register.
  /// This does not count partial redefines of virtual registers as reads:
  ///   %reg1024:6 = OP.
  bool readsRegister(unsigned Reg,
                     const TargetRegisterInfo *TRI = nullptr) const {
    return findRegisterUseOperandIdx(Reg, false, TRI) != -1;
  }

  /// Return true if the MachineInstr reads the specified virtual register.
  /// Take into account that a partial define is a
  /// read-modify-write operation.
  bool readsVirtualRegister(unsigned Reg) const {
    return readsWritesVirtualRegister(Reg).first;
  }

  /// Return a pair of bools (reads, writes) indicating if this instruction
  /// reads or writes Reg. This also considers partial defines.
  /// If Ops is not null, all operand indices for Reg are added.
  std::pair<bool,bool> readsWritesVirtualRegister(unsigned Reg,
                                SmallVectorImpl<unsigned> *Ops = nullptr) const;

  /// Return true if the MachineInstr kills the specified register.
  /// If TargetRegisterInfo is passed, then it also checks if there is
  /// a kill of a super-register.
  bool killsRegister(unsigned Reg,
                     const TargetRegisterInfo *TRI = nullptr) const {
    return findRegisterUseOperandIdx(Reg, true, TRI) != -1;
  }

  /// Return true if the MachineInstr fully defines the specified register.
  /// If TargetRegisterInfo is passed, then it also checks
  /// if there is a def of a super-register.
  /// NOTE: It's ignoring subreg indices on virtual registers.
  bool definesRegister(unsigned Reg,
                       const TargetRegisterInfo *TRI = nullptr) const {
    return findRegisterDefOperandIdx(Reg, false, false, TRI) != -1;
  }

  /// Return true if the MachineInstr modifies (fully define or partially
  /// define) the specified register.
  /// NOTE: It's ignoring subreg indices on virtual registers.
  bool modifiesRegister(unsigned Reg, const TargetRegisterInfo *TRI) const {
    return findRegisterDefOperandIdx(Reg, false, true, TRI) != -1;
  }

  /// Returns true if the register is dead in this machine instruction.
  /// If TargetRegisterInfo is passed, then it also checks
  /// if there is a dead def of a super-register.
  bool registerDefIsDead(unsigned Reg,
                         const TargetRegisterInfo *TRI = nullptr) const {
    return findRegisterDefOperandIdx(Reg, true, false, TRI) != -1;
  }

  /// Returns true if the MachineInstr has an implicit-use operand of exactly
  /// the given register (not considering sub/super-registers).
  bool hasRegisterImplicitUseOperand(unsigned Reg) const;

  /// Returns the operand index that is a use of the specific register or -1
  /// if it is not found. It further tightens the search criteria to a use
  /// that kills the register if isKill is true.
  int findRegisterUseOperandIdx(unsigned Reg, bool isKill = false,
                                const TargetRegisterInfo *TRI = nullptr) const;

  /// Wrapper for findRegisterUseOperandIdx, it returns
  /// a pointer to the MachineOperand rather than an index.
  MachineOperand *findRegisterUseOperand(unsigned Reg, bool isKill = false,
                                      const TargetRegisterInfo *TRI = nullptr) {
    int Idx = findRegisterUseOperandIdx(Reg, isKill, TRI);
    return (Idx == -1) ? nullptr : &getOperand(Idx);
  }

  const MachineOperand *findRegisterUseOperand(
    unsigned Reg, bool isKill = false,
    const TargetRegisterInfo *TRI = nullptr) const {
    return const_cast<MachineInstr *>(this)->
      findRegisterUseOperand(Reg, isKill, TRI);
  }

  /// Returns the operand index that is a def of the specified register or
  /// -1 if it is not found. If isDead is true, defs that are not dead are
  /// skipped. If Overlap is true, then it also looks for defs that merely
  /// overlap the specified register. If TargetRegisterInfo is non-null,
  /// then it also checks if there is a def of a super-register.
  /// This may also return a register mask operand when Overlap is true.
  int findRegisterDefOperandIdx(unsigned Reg,
                                bool isDead = false, bool Overlap = false,
                                const TargetRegisterInfo *TRI = nullptr) const;

  /// Wrapper for findRegisterDefOperandIdx, it returns
  /// a pointer to the MachineOperand rather than an index.
  MachineOperand *findRegisterDefOperand(unsigned Reg, bool isDead = false,
                                      const TargetRegisterInfo *TRI = nullptr) {
    int Idx = findRegisterDefOperandIdx(Reg, isDead, false, TRI);
    return (Idx == -1) ? nullptr : &getOperand(Idx);
  }

  /// Find the index of the first operand in the
  /// operand list that is used to represent the predicate. It returns -1 if
  /// none is found.
  int findFirstPredOperandIdx() const;

  /// Find the index of the flag word operand that
  /// corresponds to operand OpIdx on an inline asm instruction.  Returns -1 if
  /// getOperand(OpIdx) does not belong to an inline asm operand group.
  ///
  /// If GroupNo is not NULL, it will receive the number of the operand group
  /// containing OpIdx.
  ///
  /// The flag operand is an immediate that can be decoded with methods like
  /// InlineAsm::hasRegClassConstraint().
  int findInlineAsmFlagIdx(unsigned OpIdx, unsigned *GroupNo = nullptr) const;

  /// Compute the static register class constraint for operand OpIdx.
  /// For normal instructions, this is derived from the MCInstrDesc.
  /// For inline assembly it is derived from the flag words.
  ///
  /// Returns NULL if the static register class constraint cannot be
  /// determined.
  const TargetRegisterClass*
  getRegClassConstraint(unsigned OpIdx,
                        const TargetInstrInfo *TII,
                        const TargetRegisterInfo *TRI) const;

  /// \brief Applies the constraints (def/use) implied by this MI on \p Reg to
  /// the given \p CurRC.
  /// If \p ExploreBundle is set and MI is part of a bundle, all the
  /// instructions inside the bundle will be taken into account. In other words,
  /// this method accumulates all the constraints of the operand of this MI and
  /// the related bundle if MI is a bundle or inside a bundle.
  ///
  /// Returns the register class that satisfies both \p CurRC and the
  /// constraints set by MI. Returns NULL if such a register class does not
  /// exist.
  ///
  /// \pre CurRC must not be NULL.
  const TargetRegisterClass *getRegClassConstraintEffectForVReg(
      unsigned Reg, const TargetRegisterClass *CurRC,
      const TargetInstrInfo *TII, const TargetRegisterInfo *TRI,
      bool ExploreBundle = false) const;

  /// \brief Applies the constraints (def/use) implied by the \p OpIdx operand
  /// to the given \p CurRC.
  ///
  /// Returns the register class that satisfies both \p CurRC and the
  /// constraints set by \p OpIdx MI. Returns NULL if such a register class
  /// does not exist.
  ///
  /// \pre CurRC must not be NULL.
  /// \pre The operand at \p OpIdx must be a register.
  const TargetRegisterClass *
  getRegClassConstraintEffect(unsigned OpIdx, const TargetRegisterClass *CurRC,
                              const TargetInstrInfo *TII,
                              const TargetRegisterInfo *TRI) const;

  /// Add a tie between the register operands at DefIdx and UseIdx.
  /// The tie will cause the register allocator to ensure that the two
  /// operands are assigned the same physical register.
  ///
  /// Tied operands are managed automatically for explicit operands in the
  /// MCInstrDesc. This method is for exceptional cases like inline asm.
  void tieOperands(unsigned DefIdx, unsigned UseIdx);

  /// Given the index of a tied register operand, find the
  /// operand it is tied to. Defs are tied to uses and vice versa. Returns the
  /// index of the tied operand which must exist.
  unsigned findTiedOperandIdx(unsigned OpIdx) const;

  /// Given the index of a register def operand,
  /// check if the register def is tied to a source operand, due to either
  /// two-address elimination or inline assembly constraints. Returns the
  /// first tied use operand index by reference if UseOpIdx is not null.
  bool isRegTiedToUseOperand(unsigned DefOpIdx,
                             unsigned *UseOpIdx = nullptr) const {
    const MachineOperand &MO = getOperand(DefOpIdx);
    if (!MO.isReg() || !MO.isDef() || !MO.isTied())
      return false;
    if (UseOpIdx)
      *UseOpIdx = findTiedOperandIdx(DefOpIdx);
    return true;
  }

  /// Return true if the use operand of the specified index is tied to a def
  /// operand. It also returns the def operand index by reference if DefOpIdx
  /// is not null.
  bool isRegTiedToDefOperand(unsigned UseOpIdx,
                             unsigned *DefOpIdx = nullptr) const {
    const MachineOperand &MO = getOperand(UseOpIdx);
    if (!MO.isReg() || !MO.isUse() || !MO.isTied())
      return false;
    if (DefOpIdx)
      *DefOpIdx = findTiedOperandIdx(UseOpIdx);
    return true;
  }

  /// Clears kill flags on all operands.
  void clearKillInfo();

  /// Replace all occurrences of FromReg with ToReg:SubIdx,
  /// properly composing subreg indices where necessary.
  void substituteRegister(unsigned FromReg, unsigned ToReg, unsigned SubIdx,
                          const TargetRegisterInfo &RegInfo);

  /// We have determined MI kills a register. Look for the
  /// operand that uses it and mark it as IsKill. If AddIfNotFound is true,
  /// add a implicit operand if it's not found. Returns true if the operand
  /// exists / is added.
  bool addRegisterKilled(unsigned IncomingReg,
                         const TargetRegisterInfo *RegInfo,
                         bool AddIfNotFound = false);

  /// Clear all kill flags affecting Reg.  If RegInfo is provided, this includes
  /// all aliasing registers.
  void clearRegisterKills(unsigned Reg, const TargetRegisterInfo *RegInfo);

  /// We have determined MI defined a register without a use.
  /// Look for the operand that defines it and mark it as IsDead. If
  /// AddIfNotFound is true, add a implicit operand if it's not found. Returns
  /// true if the operand exists / is added.
  bool addRegisterDead(unsigned Reg, const TargetRegisterInfo *RegInfo,
                       bool AddIfNotFound = false);

  /// Clear all dead flags on operands defining register @p Reg.
  void clearRegisterDeads(unsigned Reg);

  /// Mark all subregister defs of register @p Reg with the undef flag.
  /// This function is used when we determined to have a subregister def in an
  /// otherwise undefined super register.
  void setRegisterDefReadUndef(unsigned Reg, bool IsUndef = true);

  /// We have determined MI defines a register. Make sure there is an operand
  /// defining Reg.
  void addRegisterDefined(unsigned Reg,
                          const TargetRegisterInfo *RegInfo = nullptr);

  /// Mark every physreg used by this instruction as
  /// dead except those in the UsedRegs list.
  ///
  /// On instructions with register mask operands, also add implicit-def
  /// operands for all registers in UsedRegs.
  void setPhysRegsDeadExcept(ArrayRef<unsigned> UsedRegs,
                             const TargetRegisterInfo &TRI);

  /// Return true if it is safe to move this instruction. If
  /// SawStore is set to true, it means that there is a store (or call) between
  /// the instruction's location and its intended destination.
  bool isSafeToMove(AliasAnalysis *AA, bool &SawStore) const;

  /// Returns true if this instruction's memory access aliases the memory
  /// access of Other.
  //
  /// Assumes any physical registers used to compute addresses
  /// have the same value for both instructions.  Returns false if neither
  /// instruction writes to memory.
  ///
  /// @param AA Optional alias analysis, used to compare memory operands.
  /// @param Other MachineInstr to check aliasing against.
  /// @param UseTBAA Whether to pass TBAA information to alias analysis.
  bool mayAlias(AliasAnalysis *AA, MachineInstr &Other, bool UseTBAA);

  /// Return true if this instruction may have an ordered
  /// or volatile memory reference, or if the information describing the memory
  /// reference is not available. Return false if it is known to have no
  /// ordered or volatile memory references.
  bool hasOrderedMemoryRef() const;

  /// Return true if this load instruction never traps and points to a memory
  /// location whose value doesn't change during the execution of this function.
  ///
  /// Examples include loading a value from the constant pool or from the
  /// argument area of a function (if it does not change).  If the instruction
  /// does multiple loads, this returns true only if all of the loads are
  /// dereferenceable and invariant.
  bool isDereferenceableInvariantLoad(AliasAnalysis *AA) const;

  /// If the specified instruction is a PHI that always merges together the
  /// same virtual register, return the register, otherwise return 0.
  unsigned isConstantValuePHI() const;

  /// Return true if this instruction has side effects that are not modeled
  /// by mayLoad / mayStore, etc.
  /// For all instructions, the property is encoded in MCInstrDesc::Flags
  /// (see MCInstrDesc::hasUnmodeledSideEffects(). The only exception is
  /// INLINEASM instruction, in which case the side effect property is encoded
  /// in one of its operands (see InlineAsm::Extra_HasSideEffect).
  ///
  bool hasUnmodeledSideEffects() const;

  /// Returns true if it is illegal to fold a load across this instruction.
  bool isLoadFoldBarrier() const;

  /// Return true if all the defs of this instruction are dead.
  bool allDefsAreDead() const;

  /// Copy implicit register operands from specified
  /// instruction to this instruction.
  void copyImplicitOps(MachineFunction &MF, const MachineInstr &MI);

  /// Debugging support
  /// @{
  /// Determine the generic type to be printed (if needed) on uses and defs.
  LLT getTypeToPrint(unsigned OpIdx, SmallBitVector &PrintedTypes,
                     const MachineRegisterInfo &MRI) const;

  /// Return true when an instruction has tied register that can't be determined
  /// by the instruction's descriptor. This is useful for MIR printing, to
  /// determine whether we need to print the ties or not.
  bool hasComplexRegisterTies() const;

  /// Print this MI to \p OS.
  /// Don't print information that can be inferred from other instructions if
  /// \p IsStandalone is false. It is usually true when only a fragment of the
  /// function is printed.
  /// Only print the defs and the opcode if \p SkipOpers is true.
  /// Otherwise, also print operands if \p SkipDebugLoc is true.
  /// Otherwise, also print the debug loc, with a terminating newline.
  /// \p TII is used to print the opcode name.  If it's not present, but the
  /// MI is in a function, the opcode will be printed using the function's TII.
  void print(raw_ostream &OS, bool IsStandalone = true, bool SkipOpers = false,
             bool SkipDebugLoc = false,
             const TargetInstrInfo *TII = nullptr) const;
  void print(raw_ostream &OS, ModuleSlotTracker &MST, bool IsStandalone = true,
             bool SkipOpers = false, bool SkipDebugLoc = false,
             const TargetInstrInfo *TII = nullptr) const;
  void dump() const;
  /// @}

  //===--------------------------------------------------------------------===//
  // Accessors used to build up machine instructions.

  /// Add the specified operand to the instruction.  If it is an implicit
  /// operand, it is added to the end of the operand list.  If it is an
  /// explicit operand it is added at the end of the explicit operand list
  /// (before the first implicit operand).
  ///
  /// MF must be the machine function that was used to allocate this
  /// instruction.
  ///
  /// MachineInstrBuilder provides a more convenient interface for creating
  /// instructions and adding operands.
  void addOperand(MachineFunction &MF, const MachineOperand &Op);

  /// Add an operand without providing an MF reference. This only works for
  /// instructions that are inserted in a basic block.
  ///
  /// MachineInstrBuilder and the two-argument addOperand(MF, MO) should be
  /// preferred.
  void addOperand(const MachineOperand &Op);

  /// Replace the instruction descriptor (thus opcode) of
  /// the current instruction with a new one.
  void setDesc(const MCInstrDesc &tid) { MCID = &tid; }

  /// Replace current source information with new such.
  /// Avoid using this, the constructor argument is preferable.
  void setDebugLoc(DebugLoc dl) {
    debugLoc = std::move(dl);
    assert(debugLoc.hasTrivialDestructor() && "Expected trivial destructor");
  }

  /// Erase an operand from an instruction, leaving it with one
  /// fewer operand than it started with.
  void RemoveOperand(unsigned i);

  /// Add a MachineMemOperand to the machine instruction.
  /// This function should be used only occasionally. The setMemRefs function
  /// is the primary method for setting up a MachineInstr's MemRefs list.
  void addMemOperand(MachineFunction &MF, MachineMemOperand *MO);

  /// Assign this MachineInstr's memory reference descriptor list.
  /// This does not transfer ownership.
  void setMemRefs(mmo_iterator NewMemRefs, mmo_iterator NewMemRefsEnd) {
    setMemRefs(std::make_pair(NewMemRefs, NewMemRefsEnd-NewMemRefs));
  }

  /// Assign this MachineInstr's memory reference descriptor list.  First
  /// element in the pair is the begin iterator/pointer to the array; the
  /// second is the number of MemoryOperands.  This does not transfer ownership
  /// of the underlying memory.
  void setMemRefs(std::pair<mmo_iterator, unsigned> NewMemRefs) {
    MemRefs = NewMemRefs.first;
    NumMemRefs = uint8_t(NewMemRefs.second);
    assert(NumMemRefs == NewMemRefs.second &&
           "Too many memrefs - must drop memory operands");
  }

  /// Return a set of memrefs (begin iterator, size) which conservatively
  /// describe the memory behavior of both MachineInstrs.  This is appropriate
  /// for use when merging two MachineInstrs into one. This routine does not
  /// modify the memrefs of the this MachineInstr.
  std::pair<mmo_iterator, unsigned> mergeMemRefsWith(const MachineInstr& Other);

  /// Return the MIFlags which represent both MachineInstrs. This
  /// should be used when merging two MachineInstrs into one. This routine does
  /// not modify the MIFlags of this MachineInstr.
  uint8_t mergeFlagsWith(const MachineInstr& Other) const;

  /// Clear this MachineInstr's memory reference descriptor list.  This resets
  /// the memrefs to their most conservative state.  This should be used only
  /// as a last resort since it greatly pessimizes our knowledge of the memory
  /// access performed by the instruction.
  void dropMemRefs() {
    MemRefs = nullptr;
    NumMemRefs = 0;
  }

  /// Break any tie involving OpIdx.
  void untieRegOperand(unsigned OpIdx) {
    MachineOperand &MO = getOperand(OpIdx);
    if (MO.isReg() && MO.isTied()) {
      getOperand(findTiedOperandIdx(OpIdx)).TiedTo = 0;
      MO.TiedTo = 0;
    }
  }

  /// Add all implicit def and use operands to this instruction.
  void addImplicitDefUseOperands(MachineFunction &MF);

private:
  /// If this instruction is embedded into a MachineFunction, return the
  /// MachineRegisterInfo object for the current function, otherwise
  /// return null.
  MachineRegisterInfo *getRegInfo();

  /// Unlink all of the register operands in this instruction from their
  /// respective use lists.  This requires that the operands already be on their
  /// use lists.
  void RemoveRegOperandsFromUseLists(MachineRegisterInfo&);

  /// Add all of the register operands in this instruction from their
  /// respective use lists.  This requires that the operands not be on their
  /// use lists yet.
  void AddRegOperandsToUseLists(MachineRegisterInfo&);

  /// Slow path for hasProperty when we're dealing with a bundle.
  bool hasPropertyInBundle(unsigned Mask, QueryType Type) const;

  /// \brief Implements the logic of getRegClassConstraintEffectForVReg for the
  /// this MI and the given operand index \p OpIdx.
  /// If the related operand does not constrained Reg, this returns CurRC.
  const TargetRegisterClass *getRegClassConstraintEffectForVRegImpl(
      unsigned OpIdx, unsigned Reg, const TargetRegisterClass *CurRC,
      const TargetInstrInfo *TII, const TargetRegisterInfo *TRI) const;
};

/// Special DenseMapInfo traits to compare MachineInstr* by *value* of the
/// instruction rather than by pointer value.
/// The hashing and equality testing functions ignore definitions so this is
/// useful for CSE, etc.
struct MachineInstrExpressionTrait : DenseMapInfo<MachineInstr*> {
  static inline MachineInstr *getEmptyKey() {
    return nullptr;
  }

  static inline MachineInstr *getTombstoneKey() {
    return reinterpret_cast<MachineInstr*>(-1);
  }

  static unsigned getHashValue(const MachineInstr* const &MI);

  static bool isEqual(const MachineInstr* const &LHS,
                      const MachineInstr* const &RHS) {
    if (RHS == getEmptyKey() || RHS == getTombstoneKey() ||
        LHS == getEmptyKey() || LHS == getTombstoneKey())
      return LHS == RHS;
    return LHS->isIdenticalTo(*RHS, MachineInstr::IgnoreVRegDefs);
  }
};

//===----------------------------------------------------------------------===//
// Debugging Support

inline raw_ostream& operator<<(raw_ostream &OS, const MachineInstr &MI) {
  MI.print(OS);
  return OS;
}

} // end namespace llvm

#endif // LLVM_CODEGEN_MACHINEINSTR_H