GlobalISelEmitter.cpp

//===- GlobalISelEmitter.cpp - Generate an instruction selector -----------===//
//
// 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
//
//===----------------------------------------------------------------------===//
//
/// \file
/// This tablegen backend emits code for use by the GlobalISel instruction
/// selector. See include/llvm/CodeGen/TargetGlobalISel.td.
///
/// This file analyzes the patterns recognized by the SelectionDAGISel tablegen
/// backend, filters out the ones that are unsupported, maps
/// SelectionDAG-specific constructs to their GlobalISel counterpart
/// (when applicable: MVT to LLT;  SDNode to generic Instruction).
///
/// Not all patterns are supported: pass the tablegen invocation
/// "-warn-on-skipped-patterns" to emit a warning when a pattern is skipped,
/// as well as why.
///
/// The generated file defines a single method:
///     bool <Target>InstructionSelector::selectImpl(MachineInstr &I) const;
/// intended to be used in InstructionSelector::select as the first-step
/// selector for the patterns that don't require complex C++.
///
/// FIXME: We'll probably want to eventually define a base
/// "TargetGenInstructionSelector" class.
///
//===----------------------------------------------------------------------===//

#include "CodeGenDAGPatterns.h"
#include "SubtargetFeatureInfo.h"
#include "llvm/ADT/Optional.h"
#include "llvm/ADT/SmallSet.h"
#include "llvm/ADT/Statistic.h"
#include "llvm/Support/CodeGenCoverage.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/Error.h"
#include "llvm/Support/LowLevelTypeImpl.h"
#include "llvm/Support/MachineValueType.h"
#include "llvm/Support/ScopedPrinter.h"
#include "llvm/TableGen/Error.h"
#include "llvm/TableGen/Record.h"
#include "llvm/TableGen/TableGenBackend.h"
#include <numeric>
#include <string>
using namespace llvm;

#define DEBUG_TYPE "gisel-emitter"

STATISTIC(NumPatternTotal, "Total number of patterns");
STATISTIC(NumPatternImported, "Number of patterns imported from SelectionDAG");
STATISTIC(NumPatternImportsSkipped, "Number of SelectionDAG imports skipped");
STATISTIC(NumPatternsTested, "Number of patterns executed according to coverage information");
STATISTIC(NumPatternEmitted, "Number of patterns emitted");

cl::OptionCategory GlobalISelEmitterCat("Options for -gen-global-isel");

static cl::opt<bool> WarnOnSkippedPatterns(
    "warn-on-skipped-patterns",
    cl::desc("Explain why a pattern was skipped for inclusion "
             "in the GlobalISel selector"),
    cl::init(false), cl::cat(GlobalISelEmitterCat));

static cl::opt<bool> GenerateCoverage(
    "instrument-gisel-coverage",
    cl::desc("Generate coverage instrumentation for GlobalISel"),
    cl::init(false), cl::cat(GlobalISelEmitterCat));

static cl::opt<std::string> UseCoverageFile(
    "gisel-coverage-file", cl::init(""),
    cl::desc("Specify file to retrieve coverage information from"),
    cl::cat(GlobalISelEmitterCat));

static cl::opt<bool> OptimizeMatchTable(
    "optimize-match-table",
    cl::desc("Generate an optimized version of the match table"),
    cl::init(true), cl::cat(GlobalISelEmitterCat));

namespace {
//===- Helper functions ---------------------------------------------------===//

/// Get the name of the enum value used to number the predicate function.
std::string getEnumNameForPredicate(const TreePredicateFn &Predicate) {
  if (Predicate.hasGISelPredicateCode())
    return "GIPFP_MI_" + Predicate.getFnName();
  return "GIPFP_" + Predicate.getImmTypeIdentifier().str() + "_" +
         Predicate.getFnName();
}

/// Get the opcode used to check this predicate.
std::string getMatchOpcodeForPredicate(const TreePredicateFn &Predicate) {
  return "GIM_Check" + Predicate.getImmTypeIdentifier().str() + "ImmPredicate";
}

/// This class stands in for LLT wherever we want to tablegen-erate an
/// equivalent at compiler run-time.
class LLTCodeGen {
private:
  LLT Ty;

public:
  LLTCodeGen() = default;
  LLTCodeGen(const LLT &Ty) : Ty(Ty) {}

  std::string getCxxEnumValue() const {
    std::string Str;
    raw_string_ostream OS(Str);

    emitCxxEnumValue(OS);
    return OS.str();
  }

  void emitCxxEnumValue(raw_ostream &OS) const {
    if (Ty.isScalar()) {
      OS << "GILLT_s" << Ty.getSizeInBits();
      return;
    }
    if (Ty.isVector()) {
      OS << "GILLT_v" << Ty.getNumElements() << "s" << Ty.getScalarSizeInBits();
      return;
    }
    if (Ty.isPointer()) {
      OS << "GILLT_p" << Ty.getAddressSpace();
      if (Ty.getSizeInBits() > 0)
        OS << "s" << Ty.getSizeInBits();
      return;
    }
    llvm_unreachable("Unhandled LLT");
  }

  void emitCxxConstructorCall(raw_ostream &OS) const {
    if (Ty.isScalar()) {
      OS << "LLT::scalar(" << Ty.getSizeInBits() << ")";
      return;
    }
    if (Ty.isVector()) {
      OS << "LLT::vector(" << Ty.getNumElements() << ", "
         << Ty.getScalarSizeInBits() << ")";
      return;
    }
    if (Ty.isPointer() && Ty.getSizeInBits() > 0) {
      OS << "LLT::pointer(" << Ty.getAddressSpace() << ", "
         << Ty.getSizeInBits() << ")";
      return;
    }
    llvm_unreachable("Unhandled LLT");
  }

  const LLT &get() const { return Ty; }

  /// This ordering is used for std::unique() and llvm::sort(). There's no
  /// particular logic behind the order but either A < B or B < A must be
  /// true if A != B.
  bool operator<(const LLTCodeGen &Other) const {
    if (Ty.isValid() != Other.Ty.isValid())
      return Ty.isValid() < Other.Ty.isValid();
    if (!Ty.isValid())
      return false;

    if (Ty.isVector() != Other.Ty.isVector())
      return Ty.isVector() < Other.Ty.isVector();
    if (Ty.isScalar() != Other.Ty.isScalar())
      return Ty.isScalar() < Other.Ty.isScalar();
    if (Ty.isPointer() != Other.Ty.isPointer())
      return Ty.isPointer() < Other.Ty.isPointer();

    if (Ty.isPointer() && Ty.getAddressSpace() != Other.Ty.getAddressSpace())
      return Ty.getAddressSpace() < Other.Ty.getAddressSpace();

    if (Ty.isVector() && Ty.getNumElements() != Other.Ty.getNumElements())
      return Ty.getNumElements() < Other.Ty.getNumElements();

    return Ty.getSizeInBits() < Other.Ty.getSizeInBits();
  }

  bool operator==(const LLTCodeGen &B) const { return Ty == B.Ty; }
};

// Track all types that are used so we can emit the corresponding enum.
std::set<LLTCodeGen> KnownTypes;

class InstructionMatcher;
/// Convert an MVT to an equivalent LLT if possible, or the invalid LLT() for
/// MVTs that don't map cleanly to an LLT (e.g., iPTR, *any, ...).
static Optional<LLTCodeGen> MVTToLLT(MVT::SimpleValueType SVT) {
  MVT VT(SVT);

  if (VT.isVector() && VT.getVectorNumElements() != 1)
    return LLTCodeGen(
        LLT::vector(VT.getVectorNumElements(), VT.getScalarSizeInBits()));

  if (VT.isInteger() || VT.isFloatingPoint())
    return LLTCodeGen(LLT::scalar(VT.getSizeInBits()));
  return None;
}

static std::string explainPredicates(const TreePatternNode *N) {
  std::string Explanation = "";
  StringRef Separator = "";
  for (const TreePredicateCall &Call : N->getPredicateCalls()) {
    const TreePredicateFn &P = Call.Fn;
    Explanation +=
        (Separator + P.getOrigPatFragRecord()->getRecord()->getName()).str();
    Separator = ", ";

    if (P.isAlwaysTrue())
      Explanation += " always-true";
    if (P.isImmediatePattern())
      Explanation += " immediate";

    if (P.isUnindexed())
      Explanation += " unindexed";

    if (P.isNonExtLoad())
      Explanation += " non-extload";
    if (P.isAnyExtLoad())
      Explanation += " extload";
    if (P.isSignExtLoad())
      Explanation += " sextload";
    if (P.isZeroExtLoad())
      Explanation += " zextload";

    if (P.isNonTruncStore())
      Explanation += " non-truncstore";
    if (P.isTruncStore())
      Explanation += " truncstore";

    if (Record *VT = P.getMemoryVT())
      Explanation += (" MemVT=" + VT->getName()).str();
    if (Record *VT = P.getScalarMemoryVT())
      Explanation += (" ScalarVT(MemVT)=" + VT->getName()).str();

    if (ListInit *AddrSpaces = P.getAddressSpaces()) {
      raw_string_ostream OS(Explanation);
      OS << " AddressSpaces=[";

      StringRef AddrSpaceSeparator;
      for (Init *Val : AddrSpaces->getValues()) {
        IntInit *IntVal = dyn_cast<IntInit>(Val);
        if (!IntVal)
          continue;

        OS << AddrSpaceSeparator << IntVal->getValue();
        AddrSpaceSeparator = ", ";
      }

      OS << ']';
    }

    int64_t MinAlign = P.getMinAlignment();
    if (MinAlign > 0)
      Explanation += " MinAlign=" + utostr(MinAlign);

    if (P.isAtomicOrderingMonotonic())
      Explanation += " monotonic";
    if (P.isAtomicOrderingAcquire())
      Explanation += " acquire";
    if (P.isAtomicOrderingRelease())
      Explanation += " release";
    if (P.isAtomicOrderingAcquireRelease())
      Explanation += " acq_rel";
    if (P.isAtomicOrderingSequentiallyConsistent())
      Explanation += " seq_cst";
    if (P.isAtomicOrderingAcquireOrStronger())
      Explanation += " >=acquire";
    if (P.isAtomicOrderingWeakerThanAcquire())
      Explanation += " <acquire";
    if (P.isAtomicOrderingReleaseOrStronger())
      Explanation += " >=release";
    if (P.isAtomicOrderingWeakerThanRelease())
      Explanation += " <release";
  }
  return Explanation;
}

std::string explainOperator(Record *Operator) {
  if (Operator->isSubClassOf("SDNode"))
    return (" (" + Operator->getValueAsString("Opcode") + ")").str();

  if (Operator->isSubClassOf("Intrinsic"))
    return (" (Operator is an Intrinsic, " + Operator->getName() + ")").str();

  if (Operator->isSubClassOf("ComplexPattern"))
    return (" (Operator is an unmapped ComplexPattern, " + Operator->getName() +
            ")")
        .str();

  if (Operator->isSubClassOf("SDNodeXForm"))
    return (" (Operator is an unmapped SDNodeXForm, " + Operator->getName() +
            ")")
        .str();

  return (" (Operator " + Operator->getName() + " not understood)").str();
}

/// Helper function to let the emitter report skip reason error messages.
static Error failedImport(const Twine &Reason) {
  return make_error<StringError>(Reason, inconvertibleErrorCode());
}

static Error isTrivialOperatorNode(const TreePatternNode *N) {
  std::string Explanation = "";
  std::string Separator = "";

  bool HasUnsupportedPredicate = false;
  for (const TreePredicateCall &Call : N->getPredicateCalls()) {
    const TreePredicateFn &Predicate = Call.Fn;

    if (Predicate.isAlwaysTrue())
      continue;

    if (Predicate.isImmediatePattern())
      continue;

    if (Predicate.isNonExtLoad() || Predicate.isAnyExtLoad() ||
        Predicate.isSignExtLoad() || Predicate.isZeroExtLoad())
      continue;

    if (Predicate.isNonTruncStore() || Predicate.isTruncStore())
      continue;

    if (Predicate.isLoad() && Predicate.getMemoryVT())
      continue;

    if (Predicate.isLoad() || Predicate.isStore()) {
      if (Predicate.isUnindexed())
        continue;
    }

    if (Predicate.isLoad() || Predicate.isStore() || Predicate.isAtomic()) {
      const ListInit *AddrSpaces = Predicate.getAddressSpaces();
      if (AddrSpaces && !AddrSpaces->empty())
        continue;

      if (Predicate.getMinAlignment() > 0)
        continue;
    }

    if (Predicate.isAtomic() && Predicate.getMemoryVT())
      continue;

    if (Predicate.isAtomic() &&
        (Predicate.isAtomicOrderingMonotonic() ||
         Predicate.isAtomicOrderingAcquire() ||
         Predicate.isAtomicOrderingRelease() ||
         Predicate.isAtomicOrderingAcquireRelease() ||
         Predicate.isAtomicOrderingSequentiallyConsistent() ||
         Predicate.isAtomicOrderingAcquireOrStronger() ||
         Predicate.isAtomicOrderingWeakerThanAcquire() ||
         Predicate.isAtomicOrderingReleaseOrStronger() ||
         Predicate.isAtomicOrderingWeakerThanRelease()))
      continue;

    if (Predicate.hasGISelPredicateCode())
      continue;

    HasUnsupportedPredicate = true;
    Explanation = Separator + "Has a predicate (" + explainPredicates(N) + ")";
    Separator = ", ";
    Explanation += (Separator + "first-failing:" +
                    Predicate.getOrigPatFragRecord()->getRecord()->getName())
                       .str();
    break;
  }

  if (!HasUnsupportedPredicate)
    return Error::success();

  return failedImport(Explanation);
}

static Record *getInitValueAsRegClass(Init *V) {
  if (DefInit *VDefInit = dyn_cast<DefInit>(V)) {
    if (VDefInit->getDef()->isSubClassOf("RegisterOperand"))
      return VDefInit->getDef()->getValueAsDef("RegClass");
    if (VDefInit->getDef()->isSubClassOf("RegisterClass"))
      return VDefInit->getDef();
  }
  return nullptr;
}

std::string
getNameForFeatureBitset(const std::vector<Record *> &FeatureBitset) {
  std::string Name = "GIFBS";
  for (const auto &Feature : FeatureBitset)
    Name += ("_" + Feature->getName()).str();
  return Name;
}

//===- MatchTable Helpers -------------------------------------------------===//

class MatchTable;

/// A record to be stored in a MatchTable.
///
/// This class represents any and all output that may be required to emit the
/// MatchTable. Instances  are most often configured to represent an opcode or
/// value that will be emitted to the table with some formatting but it can also
/// represent commas, comments, and other formatting instructions.
struct MatchTableRecord {
  enum RecordFlagsBits {
    MTRF_None = 0x0,
    /// Causes EmitStr to be formatted as comment when emitted.
    MTRF_Comment = 0x1,
    /// Causes the record value to be followed by a comma when emitted.
    MTRF_CommaFollows = 0x2,
    /// Causes the record value to be followed by a line break when emitted.
    MTRF_LineBreakFollows = 0x4,
    /// Indicates that the record defines a label and causes an additional
    /// comment to be emitted containing the index of the label.
    MTRF_Label = 0x8,
    /// Causes the record to be emitted as the index of the label specified by
    /// LabelID along with a comment indicating where that label is.
    MTRF_JumpTarget = 0x10,
    /// Causes the formatter to add a level of indentation before emitting the
    /// record.
    MTRF_Indent = 0x20,
    /// Causes the formatter to remove a level of indentation after emitting the
    /// record.
    MTRF_Outdent = 0x40,
  };

  /// When MTRF_Label or MTRF_JumpTarget is used, indicates a label id to
  /// reference or define.
  unsigned LabelID;
  /// The string to emit. Depending on the MTRF_* flags it may be a comment, a
  /// value, a label name.
  std::string EmitStr;

private:
  /// The number of MatchTable elements described by this record. Comments are 0
  /// while values are typically 1. Values >1 may occur when we need to emit
  /// values that exceed the size of a MatchTable element.
  unsigned NumElements;

public:
  /// A bitfield of RecordFlagsBits flags.
  unsigned Flags;

  /// The actual run-time value, if known
  int64_t RawValue;

  MatchTableRecord(Optional<unsigned> LabelID_, StringRef EmitStr,
                   unsigned NumElements, unsigned Flags,
                   int64_t RawValue = std::numeric_limits<int64_t>::min())
      : LabelID(LabelID_.hasValue() ? LabelID_.getValue() : ~0u),
        EmitStr(EmitStr), NumElements(NumElements), Flags(Flags),
        RawValue(RawValue) {
    assert((!LabelID_.hasValue() || LabelID != ~0u) &&
           "This value is reserved for non-labels");
  }
  MatchTableRecord(const MatchTableRecord &Other) = default;
  MatchTableRecord(MatchTableRecord &&Other) = default;

  /// Useful if a Match Table Record gets optimized out
  void turnIntoComment() {
    Flags |= MTRF_Comment;
    Flags &= ~MTRF_CommaFollows;
    NumElements = 0;
  }

  /// For Jump Table generation purposes
  bool operator<(const MatchTableRecord &Other) const {
    return RawValue < Other.RawValue;
  }
  int64_t getRawValue() const { return RawValue; }

  void emit(raw_ostream &OS, bool LineBreakNextAfterThis,
            const MatchTable &Table) const;
  unsigned size() const { return NumElements; }
};

class Matcher;

/// Holds the contents of a generated MatchTable to enable formatting and the
/// necessary index tracking needed to support GIM_Try.
class MatchTable {
  /// An unique identifier for the table. The generated table will be named
  /// MatchTable${ID}.
  unsigned ID;
  /// The records that make up the table. Also includes comments describing the
  /// values being emitted and line breaks to format it.
  std::vector<MatchTableRecord> Contents;
  /// The currently defined labels.
  DenseMap<unsigned, unsigned> LabelMap;
  /// Tracks the sum of MatchTableRecord::NumElements as the table is built.
  unsigned CurrentSize = 0;
  /// A unique identifier for a MatchTable label.
  unsigned CurrentLabelID = 0;
  /// Determines if the table should be instrumented for rule coverage tracking.
  bool IsWithCoverage;

public:
  static MatchTableRecord LineBreak;
  static MatchTableRecord Comment(StringRef Comment) {
    return MatchTableRecord(None, Comment, 0, MatchTableRecord::MTRF_Comment);
  }
  static MatchTableRecord Opcode(StringRef Opcode, int IndentAdjust = 0) {
    unsigned ExtraFlags = 0;
    if (IndentAdjust > 0)
      ExtraFlags |= MatchTableRecord::MTRF_Indent;
    if (IndentAdjust < 0)
      ExtraFlags |= MatchTableRecord::MTRF_Outdent;

    return MatchTableRecord(None, Opcode, 1,
                            MatchTableRecord::MTRF_CommaFollows | ExtraFlags);
  }
  static MatchTableRecord NamedValue(StringRef NamedValue) {
    return MatchTableRecord(None, NamedValue, 1,
                            MatchTableRecord::MTRF_CommaFollows);
  }
  static MatchTableRecord NamedValue(StringRef NamedValue, int64_t RawValue) {
    return MatchTableRecord(None, NamedValue, 1,
                            MatchTableRecord::MTRF_CommaFollows, RawValue);
  }
  static MatchTableRecord NamedValue(StringRef Namespace,
                                     StringRef NamedValue) {
    return MatchTableRecord(None, (Namespace + "::" + NamedValue).str(), 1,
                            MatchTableRecord::MTRF_CommaFollows);
  }
  static MatchTableRecord NamedValue(StringRef Namespace, StringRef NamedValue,
                                     int64_t RawValue) {
    return MatchTableRecord(None, (Namespace + "::" + NamedValue).str(), 1,
                            MatchTableRecord::MTRF_CommaFollows, RawValue);
  }
  static MatchTableRecord IntValue(int64_t IntValue) {
    return MatchTableRecord(None, llvm::to_string(IntValue), 1,
                            MatchTableRecord::MTRF_CommaFollows);
  }
  static MatchTableRecord Label(unsigned LabelID) {
    return MatchTableRecord(LabelID, "Label " + llvm::to_string(LabelID), 0,
                            MatchTableRecord::MTRF_Label |
                                MatchTableRecord::MTRF_Comment |
                                MatchTableRecord::MTRF_LineBreakFollows);
  }
  static MatchTableRecord JumpTarget(unsigned LabelID) {
    return MatchTableRecord(LabelID, "Label " + llvm::to_string(LabelID), 1,
                            MatchTableRecord::MTRF_JumpTarget |
                                MatchTableRecord::MTRF_Comment |
                                MatchTableRecord::MTRF_CommaFollows);
  }

  static MatchTable buildTable(ArrayRef<Matcher *> Rules, bool WithCoverage);

  MatchTable(bool WithCoverage, unsigned ID = 0)
      : ID(ID), IsWithCoverage(WithCoverage) {}

  bool isWithCoverage() const { return IsWithCoverage; }

  void push_back(const MatchTableRecord &Value) {
    if (Value.Flags & MatchTableRecord::MTRF_Label)
      defineLabel(Value.LabelID);
    Contents.push_back(Value);
    CurrentSize += Value.size();
  }

  unsigned allocateLabelID() { return CurrentLabelID++; }

  void defineLabel(unsigned LabelID) {
    LabelMap.insert(std::make_pair(LabelID, CurrentSize));
  }

  unsigned getLabelIndex(unsigned LabelID) const {
    const auto I = LabelMap.find(LabelID);
    assert(I != LabelMap.end() && "Use of undeclared label");
    return I->second;
  }

  void emitUse(raw_ostream &OS) const { OS << "MatchTable" << ID; }

  void emitDeclaration(raw_ostream &OS) const {
    unsigned Indentation = 4;
    OS << "  constexpr static int64_t MatchTable" << ID << "[] = {";
    LineBreak.emit(OS, true, *this);
    OS << std::string(Indentation, ' ');

    for (auto I = Contents.begin(), E = Contents.end(); I != E;
         ++I) {
      bool LineBreakIsNext = false;
      const auto &NextI = std::next(I);

      if (NextI != E) {
        if (NextI->EmitStr == "" &&
            NextI->Flags == MatchTableRecord::MTRF_LineBreakFollows)
          LineBreakIsNext = true;
      }

      if (I->Flags & MatchTableRecord::MTRF_Indent)
        Indentation += 2;

      I->emit(OS, LineBreakIsNext, *this);
      if (I->Flags & MatchTableRecord::MTRF_LineBreakFollows)
        OS << std::string(Indentation, ' ');

      if (I->Flags & MatchTableRecord::MTRF_Outdent)
        Indentation -= 2;
    }
    OS << "};\n";
  }
};

MatchTableRecord MatchTable::LineBreak = {
    None, "" /* Emit String */, 0 /* Elements */,
    MatchTableRecord::MTRF_LineBreakFollows};

void MatchTableRecord::emit(raw_ostream &OS, bool LineBreakIsNextAfterThis,
                            const MatchTable &Table) const {
  bool UseLineComment =
      LineBreakIsNextAfterThis || (Flags & MTRF_LineBreakFollows);
  if (Flags & (MTRF_JumpTarget | MTRF_CommaFollows))
    UseLineComment = false;

  if (Flags & MTRF_Comment)
    OS << (UseLineComment ? "// " : "/*");

  OS << EmitStr;
  if (Flags & MTRF_Label)
    OS << ": @" << Table.getLabelIndex(LabelID);

  if ((Flags & MTRF_Comment) && !UseLineComment)
    OS << "*/";

  if (Flags & MTRF_JumpTarget) {
    if (Flags & MTRF_Comment)
      OS << " ";
    OS << Table.getLabelIndex(LabelID);
  }

  if (Flags & MTRF_CommaFollows) {
    OS << ",";
    if (!LineBreakIsNextAfterThis && !(Flags & MTRF_LineBreakFollows))
      OS << " ";
  }

  if (Flags & MTRF_LineBreakFollows)
    OS << "\n";
}

MatchTable &operator<<(MatchTable &Table, const MatchTableRecord &Value) {
  Table.push_back(Value);
  return Table;
}

//===- Matchers -----------------------------------------------------------===//

class OperandMatcher;
class MatchAction;
class PredicateMatcher;
class RuleMatcher;

class Matcher {
public:
  virtual ~Matcher() = default;
  virtual void optimize() {}
  virtual void emit(MatchTable &Table) = 0;

  virtual bool hasFirstCondition() const = 0;
  virtual const PredicateMatcher &getFirstCondition() const = 0;
  virtual std::unique_ptr<PredicateMatcher> popFirstCondition() = 0;
};

MatchTable MatchTable::buildTable(ArrayRef<Matcher *> Rules,
                                  bool WithCoverage) {
  MatchTable Table(WithCoverage);
  for (Matcher *Rule : Rules)
    Rule->emit(Table);

  return Table << MatchTable::Opcode("GIM_Reject") << MatchTable::LineBreak;
}

class GroupMatcher final : public Matcher {
  /// Conditions that form a common prefix of all the matchers contained.
  SmallVector<std::unique_ptr<PredicateMatcher>, 1> Conditions;

  /// All the nested matchers, sharing a common prefix.
  std::vector<Matcher *> Matchers;

  /// An owning collection for any auxiliary matchers created while optimizing
  /// nested matchers contained.
  std::vector<std::unique_ptr<Matcher>> MatcherStorage;

public:
  /// Add a matcher to the collection of nested matchers if it meets the
  /// requirements, and return true. If it doesn't, do nothing and return false.
  ///
  /// Expected to preserve its argument, so it could be moved out later on.
  bool addMatcher(Matcher &Candidate);

  /// Mark the matcher as fully-built and ensure any invariants expected by both
  /// optimize() and emit(...) methods. Generally, both sequences of calls
  /// are expected to lead to a sensible result:
  ///
  /// addMatcher(...)*; finalize(); optimize(); emit(...); and
  /// addMatcher(...)*; finalize(); emit(...);
  ///
  /// or generally
  ///
  /// addMatcher(...)*; finalize(); { optimize()*; emit(...); }*
  ///
  /// Multiple calls to optimize() are expected to be handled gracefully, though
  /// optimize() is not expected to be idempotent. Multiple calls to finalize()
  /// aren't generally supported. emit(...) is expected to be non-mutating and
  /// producing the exact same results upon repeated calls.
  ///
  /// addMatcher() calls after the finalize() call are not supported.
  ///
  /// finalize() and optimize() are both allowed to mutate the contained
  /// matchers, so moving them out after finalize() is not supported.
  void finalize();
  void optimize() override;
  void emit(MatchTable &Table) override;

  /// Could be used to move out the matchers added previously, unless finalize()
  /// has been already called. If any of the matchers are moved out, the group
  /// becomes safe to destroy, but not safe to re-use for anything else.
  iterator_range<std::vector<Matcher *>::iterator> matchers() {
    return make_range(Matchers.begin(), Matchers.end());
  }
  size_t size() const { return Matchers.size(); }
  bool empty() const { return Matchers.empty(); }

  std::unique_ptr<PredicateMatcher> popFirstCondition() override {
    assert(!Conditions.empty() &&
           "Trying to pop a condition from a condition-less group");
    std::unique_ptr<PredicateMatcher> P = std::move(Conditions.front());
    Conditions.erase(Conditions.begin());
    return P;
  }
  const PredicateMatcher &getFirstCondition() const override {
    assert(!Conditions.empty() &&
           "Trying to get a condition from a condition-less group");
    return *Conditions.front();
  }
  bool hasFirstCondition() const override { return !Conditions.empty(); }

private:
  /// See if a candidate matcher could be added to this group solely by
  /// analyzing its first condition.
  bool candidateConditionMatches(const PredicateMatcher &Predicate) const;
};

class SwitchMatcher : public Matcher {
  /// All the nested matchers, representing distinct switch-cases. The first
  /// conditions (as Matcher::getFirstCondition() reports) of all the nested
  /// matchers must share the same type and path to a value they check, in other
  /// words, be isIdenticalDownToValue, but have different values they check
  /// against.
  std::vector<Matcher *> Matchers;

  /// The representative condition, with a type and a path (InsnVarID and OpIdx
  /// in most cases)  shared by all the matchers contained.
  std::unique_ptr<PredicateMatcher> Condition = nullptr;

  /// Temporary set used to check that the case values don't repeat within the
  /// same switch.
  std::set<MatchTableRecord> Values;

  /// An owning collection for any auxiliary matchers created while optimizing
  /// nested matchers contained.
  std::vector<std::unique_ptr<Matcher>> MatcherStorage;

public:
  bool addMatcher(Matcher &Candidate);

  void finalize();
  void emit(MatchTable &Table) override;

  iterator_range<std::vector<Matcher *>::iterator> matchers() {
    return make_range(Matchers.begin(), Matchers.end());
  }
  size_t size() const { return Matchers.size(); }
  bool empty() const { return Matchers.empty(); }

  std::unique_ptr<PredicateMatcher> popFirstCondition() override {
    // SwitchMatcher doesn't have a common first condition for its cases, as all
    // the cases only share a kind of a value (a type and a path to it) they
    // match, but deliberately differ in the actual value they match.
    llvm_unreachable("Trying to pop a condition from a condition-less group");
  }
  const PredicateMatcher &getFirstCondition() const override {
    llvm_unreachable("Trying to pop a condition from a condition-less group");
  }
  bool hasFirstCondition() const override { return false; }

private:
  /// See if the predicate type has a Switch-implementation for it.
  static bool isSupportedPredicateType(const PredicateMatcher &Predicate);

  bool candidateConditionMatches(const PredicateMatcher &Predicate) const;

  /// emit()-helper
  static void emitPredicateSpecificOpcodes(const PredicateMatcher &P,
                                           MatchTable &Table);
};

/// Generates code to check that a match rule matches.
class RuleMatcher : public Matcher {
public:
  using ActionList = std::list<std::unique_ptr<MatchAction>>;
  using action_iterator = ActionList::iterator;

protected:
  /// A list of matchers that all need to succeed for the current rule to match.
  /// FIXME: This currently supports a single match position but could be
  /// extended to support multiple positions to support div/rem fusion or
  /// load-multiple instructions.
  using MatchersTy = std::vector<std::unique_ptr<InstructionMatcher>> ;
  MatchersTy Matchers;

  /// A list of actions that need to be taken when all predicates in this rule
  /// have succeeded.
  ActionList Actions;

  using DefinedInsnVariablesMap = std::map<InstructionMatcher *, unsigned>;

  /// A map of instruction matchers to the local variables
  DefinedInsnVariablesMap InsnVariableIDs;

  using MutatableInsnSet = SmallPtrSet<InstructionMatcher *, 4>;

  // The set of instruction matchers that have not yet been claimed for mutation
  // by a BuildMI.
  MutatableInsnSet MutatableInsns;

  /// A map of named operands defined by the matchers that may be referenced by
  /// the renderers.
  StringMap<OperandMatcher *> DefinedOperands;

  /// A map of anonymous physical register operands defined by the matchers that
  /// may be referenced by the renderers.
  DenseMap<Record *, OperandMatcher *> PhysRegOperands;

  /// ID for the next instruction variable defined with implicitlyDefineInsnVar()
  unsigned NextInsnVarID;

  /// ID for the next output instruction allocated with allocateOutputInsnID()
  unsigned NextOutputInsnID;

  /// ID for the next temporary register ID allocated with allocateTempRegID()
  unsigned NextTempRegID;

  std::vector<Record *> RequiredFeatures;
  std::vector<std::unique_ptr<PredicateMatcher>> EpilogueMatchers;

  ArrayRef<SMLoc> SrcLoc;

  typedef std::tuple<Record *, unsigned, unsigned>
      DefinedComplexPatternSubOperand;
  typedef StringMap<DefinedComplexPatternSubOperand>
      DefinedComplexPatternSubOperandMap;
  /// A map of Symbolic Names to ComplexPattern sub-operands.
  DefinedComplexPatternSubOperandMap ComplexSubOperands;

  uint64_t RuleID;
  static uint64_t NextRuleID;

public:
  RuleMatcher(ArrayRef<SMLoc> SrcLoc)
      : Matchers(), Actions(), InsnVariableIDs(), MutatableInsns(),
        DefinedOperands(), NextInsnVarID(0), NextOutputInsnID(0),
        NextTempRegID(0), SrcLoc(SrcLoc), ComplexSubOperands(),
        RuleID(NextRuleID++) {}
  RuleMatcher(RuleMatcher &&Other) = default;
  RuleMatcher &operator=(RuleMatcher &&Other) = default;

  uint64_t getRuleID() const { return RuleID; }

  InstructionMatcher &addInstructionMatcher(StringRef SymbolicName);
  void addRequiredFeature(Record *Feature);
  const std::vector<Record *> &getRequiredFeatures() const;

  template <class Kind, class... Args> Kind &addAction(Args &&... args);
  template <class Kind, class... Args>
  action_iterator insertAction(action_iterator InsertPt, Args &&... args);

  /// Define an instruction without emitting any code to do so.
  unsigned implicitlyDefineInsnVar(InstructionMatcher &Matcher);

  unsigned getInsnVarID(InstructionMatcher &InsnMatcher) const;
  DefinedInsnVariablesMap::const_iterator defined_insn_vars_begin() const {
    return InsnVariableIDs.begin();
  }
  DefinedInsnVariablesMap::const_iterator defined_insn_vars_end() const {
    return InsnVariableIDs.end();
  }
  iterator_range<typename DefinedInsnVariablesMap::const_iterator>
  defined_insn_vars() const {
    return make_range(defined_insn_vars_begin(), defined_insn_vars_end());
  }

  MutatableInsnSet::const_iterator mutatable_insns_begin() const {
    return MutatableInsns.begin();
  }
  MutatableInsnSet::const_iterator mutatable_insns_end() const {
    return MutatableInsns.end();
  }
  iterator_range<typename MutatableInsnSet::const_iterator>
  mutatable_insns() const {
    return make_range(mutatable_insns_begin(), mutatable_insns_end());
  }
  void reserveInsnMatcherForMutation(InstructionMatcher *InsnMatcher) {
    bool R = MutatableInsns.erase(InsnMatcher);
    assert(R && "Reserving a mutatable insn that isn't available");
    (void)R;
  }

  action_iterator actions_begin() { return Actions.begin(); }
  action_iterator actions_end() { return Actions.end(); }
  iterator_range<action_iterator> actions() {
    return make_range(actions_begin(), actions_end());
  }

  void defineOperand(StringRef SymbolicName, OperandMatcher &OM);

  void definePhysRegOperand(Record *Reg, OperandMatcher &OM);

  Error defineComplexSubOperand(StringRef SymbolicName, Record *ComplexPattern,
                                unsigned RendererID, unsigned SubOperandID) {
    if (ComplexSubOperands.count(SymbolicName))
      return failedImport(
          "Complex suboperand referenced more than once (Operand: " +
          SymbolicName + ")");

    ComplexSubOperands[SymbolicName] =
        std::make_tuple(ComplexPattern, RendererID, SubOperandID);

    return Error::success();
  }

  Optional<DefinedComplexPatternSubOperand>
  getComplexSubOperand(StringRef SymbolicName) const {
    const auto &I = ComplexSubOperands.find(SymbolicName);
    if (I == ComplexSubOperands.end())
      return None;
    return I->second;
  }

  InstructionMatcher &getInstructionMatcher(StringRef SymbolicName) const;
  const OperandMatcher &getOperandMatcher(StringRef Name) const;
  const OperandMatcher &getPhysRegOperandMatcher(Record *) const;

  void optimize() override;
  void emit(MatchTable &Table) override;

  /// Compare the priority of this object and B.
  ///
  /// Returns true if this object is more important than B.
  bool isHigherPriorityThan(const RuleMatcher &B) const;

  /// Report the maximum number of temporary operands needed by the rule
  /// matcher.
  unsigned countRendererFns() const;

  std::unique_ptr<PredicateMatcher> popFirstCondition() override;
  const PredicateMatcher &getFirstCondition() const override;
  LLTCodeGen getFirstConditionAsRootType();
  bool hasFirstCondition() const override;
  unsigned getNumOperands() const;
  StringRef getOpcode() const;

  // FIXME: Remove this as soon as possible
  InstructionMatcher &insnmatchers_front() const { return *Matchers.front(); }

  unsigned allocateOutputInsnID() { return NextOutputInsnID++; }
  unsigned allocateTempRegID() { return NextTempRegID++; }

  iterator_range<MatchersTy::iterator> insnmatchers() {
    return make_range(Matchers.begin(), Matchers.end());
  }
  bool insnmatchers_empty() const { return Matchers.empty(); }
  void insnmatchers_pop_front() { Matchers.erase(Matchers.begin()); }
};

uint64_t RuleMatcher::NextRuleID = 0;

using action_iterator = RuleMatcher::action_iterator;

template <class PredicateTy> class PredicateListMatcher {
private:
  /// Template instantiations should specialize this to return a string to use
  /// for the comment emitted when there are no predicates.
  std::string getNoPredicateComment() const;

protected:
  using PredicatesTy = std::deque<std::unique_ptr<PredicateTy>>;
  PredicatesTy Predicates;

  /// Track if the list of predicates was manipulated by one of the optimization
  /// methods.
  bool Optimized = false;

public:
  /// Construct a new predicate and add it to the matcher.
  template <class Kind, class... Args>
  Optional<Kind *> addPredicate(Args &&... args);

  typename PredicatesTy::iterator predicates_begin() {
    return Predicates.begin();
  }
  typename PredicatesTy::iterator predicates_end() {
    return Predicates.end();
  }
  iterator_range<typename PredicatesTy::iterator> predicates() {
    return make_range(predicates_begin(), predicates_end());
  }
  typename PredicatesTy::size_type predicates_size() const {
    return Predicates.size();
  }
  bool predicates_empty() const { return Predicates.empty(); }

  std::unique_ptr<PredicateTy> predicates_pop_front() {
    std::unique_ptr<PredicateTy> Front = std::move(Predicates.front());
    Predicates.pop_front();
    Optimized = true;
    return Front;
  }

  void prependPredicate(std::unique_ptr<PredicateTy> &&Predicate) {
    Predicates.push_front(std::move(Predicate));
  }

  void eraseNullPredicates() {
    const auto NewEnd =
        std::stable_partition(Predicates.begin(), Predicates.end(),
                              std::logical_not<std::unique_ptr<PredicateTy>>());
    if (NewEnd != Predicates.begin()) {
      Predicates.erase(Predicates.begin(), NewEnd);
      Optimized = true;
    }
  }

  /// Emit MatchTable opcodes that tests whether all the predicates are met.
  template <class... Args>
  void emitPredicateListOpcodes(MatchTable &Table, Args &&... args) {
    if (Predicates.empty() && !Optimized) {
      Table << MatchTable::Comment(getNoPredicateComment())
            << MatchTable::LineBreak;
      return;
    }

    for (const auto &Predicate : predicates())
      Predicate->emitPredicateOpcodes(Table, std::forward<Args>(args)...);
  }
};

class PredicateMatcher {
public:
  /// This enum is used for RTTI and also defines the priority that is given to
  /// the predicate when generating the matcher code. Kinds with higher priority
  /// must be tested first.
  ///
  /// The relative priority of OPM_LLT, OPM_RegBank, and OPM_MBB do not matter
  /// but OPM_Int must have priority over OPM_RegBank since constant integers
  /// are represented by a virtual register defined by a G_CONSTANT instruction.
  ///
  /// Note: The relative priority between IPM_ and OPM_ does not matter, they
  /// are currently not compared between each other.
  enum PredicateKind {
    IPM_Opcode,
    IPM_NumOperands,
    IPM_ImmPredicate,
    IPM_Imm,
    IPM_AtomicOrderingMMO,
    IPM_MemoryLLTSize,
    IPM_MemoryVsLLTSize,
    IPM_MemoryAddressSpace,
    IPM_MemoryAlignment,
    IPM_GenericPredicate,
    OPM_SameOperand,
    OPM_ComplexPattern,
    OPM_IntrinsicID,
    OPM_CmpPredicate,
    OPM_Instruction,
    OPM_Int,
    OPM_LiteralInt,
    OPM_LLT,
    OPM_PointerToAny,
    OPM_RegBank,
    OPM_MBB,
  };

protected:
  PredicateKind Kind;
  unsigned InsnVarID;
  unsigned OpIdx;

public:
  PredicateMatcher(PredicateKind Kind, unsigned InsnVarID, unsigned OpIdx = ~0)
      : Kind(Kind), InsnVarID(InsnVarID), OpIdx(OpIdx) {}

  unsigned getInsnVarID() const { return InsnVarID; }
  unsigned getOpIdx() const { return OpIdx; }

  virtual ~PredicateMatcher() = default;
  /// Emit MatchTable opcodes that check the predicate for the given operand.
  virtual void emitPredicateOpcodes(MatchTable &Table,
                                    RuleMatcher &Rule) const = 0;

  PredicateKind getKind() const { return Kind; }

  virtual bool isIdentical(const PredicateMatcher &B) const {
    return B.getKind() == getKind() && InsnVarID == B.InsnVarID &&
           OpIdx == B.OpIdx;
  }

  virtual bool isIdenticalDownToValue(const PredicateMatcher &B) const {
    return hasValue() && PredicateMatcher::isIdentical(B);
  }

  virtual MatchTableRecord getValue() const {
    assert(hasValue() && "Can not get a value of a value-less predicate!");
    llvm_unreachable("Not implemented yet");
  }
  virtual bool hasValue() const { return false; }

  /// Report the maximum number of temporary operands needed by the predicate
  /// matcher.
  virtual unsigned countRendererFns() const { return 0; }
};

/// Generates code to check a predicate of an operand.
///
/// Typical predicates include:
/// * Operand is a particular register.
/// * Operand is assigned a particular register bank.
/// * Operand is an MBB.
class OperandPredicateMatcher : public PredicateMatcher {
public:
  OperandPredicateMatcher(PredicateKind Kind, unsigned InsnVarID,
                          unsigned OpIdx)
      : PredicateMatcher(Kind, InsnVarID, OpIdx) {}
  virtual ~OperandPredicateMatcher() {}

  /// Compare the priority of this object and B.
  ///
  /// Returns true if this object is more important than B.
  virtual bool isHigherPriorityThan(const OperandPredicateMatcher &B) const;
};

template <>
std::string
PredicateListMatcher<OperandPredicateMatcher>::getNoPredicateComment() const {
  return "No operand predicates";
}

/// Generates code to check that a register operand is defined by the same exact
/// one as another.
class SameOperandMatcher : public OperandPredicateMatcher {
  std::string MatchingName;

public:
  SameOperandMatcher(unsigned InsnVarID, unsigned OpIdx, StringRef MatchingName)
      : OperandPredicateMatcher(OPM_SameOperand, InsnVarID, OpIdx),
        MatchingName(MatchingName) {}

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == OPM_SameOperand;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override;

  bool isIdentical(const PredicateMatcher &B) const override {
    return OperandPredicateMatcher::isIdentical(B) &&
           MatchingName == cast<SameOperandMatcher>(&B)->MatchingName;
  }
};

/// Generates code to check that an operand is a particular LLT.
class LLTOperandMatcher : public OperandPredicateMatcher {
protected:
  LLTCodeGen Ty;

public:
  static std::map<LLTCodeGen, unsigned> TypeIDValues;

  static void initTypeIDValuesMap() {
    TypeIDValues.clear();

    unsigned ID = 0;
    for (const LLTCodeGen &LLTy : KnownTypes)
      TypeIDValues[LLTy] = ID++;
  }

  LLTOperandMatcher(unsigned InsnVarID, unsigned OpIdx, const LLTCodeGen &Ty)
      : OperandPredicateMatcher(OPM_LLT, InsnVarID, OpIdx), Ty(Ty) {
    KnownTypes.insert(Ty);
  }

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == OPM_LLT;
  }
  bool isIdentical(const PredicateMatcher &B) const override {
    return OperandPredicateMatcher::isIdentical(B) &&
           Ty == cast<LLTOperandMatcher>(&B)->Ty;
  }
  MatchTableRecord getValue() const override {
    const auto VI = TypeIDValues.find(Ty);
    if (VI == TypeIDValues.end())
      return MatchTable::NamedValue(getTy().getCxxEnumValue());
    return MatchTable::NamedValue(getTy().getCxxEnumValue(), VI->second);
  }
  bool hasValue() const override {
    if (TypeIDValues.size() != KnownTypes.size())
      initTypeIDValuesMap();
    return TypeIDValues.count(Ty);
  }

  LLTCodeGen getTy() const { return Ty; }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIM_CheckType") << MatchTable::Comment("MI")
          << MatchTable::IntValue(InsnVarID) << MatchTable::Comment("Op")
          << MatchTable::IntValue(OpIdx) << MatchTable::Comment("Type")
          << getValue() << MatchTable::LineBreak;
  }
};

std::map<LLTCodeGen, unsigned> LLTOperandMatcher::TypeIDValues;

/// Generates code to check that an operand is a pointer to any address space.
///
/// In SelectionDAG, the types did not describe pointers or address spaces. As a
/// result, iN is used to describe a pointer of N bits to any address space and
/// PatFrag predicates are typically used to constrain the address space. There's
/// no reliable means to derive the missing type information from the pattern so
/// imported rules must test the components of a pointer separately.
///
/// If SizeInBits is zero, then the pointer size will be obtained from the
/// subtarget.
class PointerToAnyOperandMatcher : public OperandPredicateMatcher {
protected:
  unsigned SizeInBits;

public:
  PointerToAnyOperandMatcher(unsigned InsnVarID, unsigned OpIdx,
                             unsigned SizeInBits)
      : OperandPredicateMatcher(OPM_PointerToAny, InsnVarID, OpIdx),
        SizeInBits(SizeInBits) {}

  static bool classof(const OperandPredicateMatcher *P) {
    return P->getKind() == OPM_PointerToAny;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIM_CheckPointerToAny")
          << MatchTable::Comment("MI") << MatchTable::IntValue(InsnVarID)
          << MatchTable::Comment("Op") << MatchTable::IntValue(OpIdx)
          << MatchTable::Comment("SizeInBits")
          << MatchTable::IntValue(SizeInBits) << MatchTable::LineBreak;
  }
};

/// Generates code to check that an operand is a particular target constant.
class ComplexPatternOperandMatcher : public OperandPredicateMatcher {
protected:
  const OperandMatcher &Operand;
  const Record &TheDef;

  unsigned getAllocatedTemporariesBaseID() const;

public:
  bool isIdentical(const PredicateMatcher &B) const override { return false; }

  ComplexPatternOperandMatcher(unsigned InsnVarID, unsigned OpIdx,
                               const OperandMatcher &Operand,
                               const Record &TheDef)
      : OperandPredicateMatcher(OPM_ComplexPattern, InsnVarID, OpIdx),
        Operand(Operand), TheDef(TheDef) {}

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == OPM_ComplexPattern;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    unsigned ID = getAllocatedTemporariesBaseID();
    Table << MatchTable::Opcode("GIM_CheckComplexPattern")
          << MatchTable::Comment("MI") << MatchTable::IntValue(InsnVarID)
          << MatchTable::Comment("Op") << MatchTable::IntValue(OpIdx)
          << MatchTable::Comment("Renderer") << MatchTable::IntValue(ID)
          << MatchTable::NamedValue(("GICP_" + TheDef.getName()).str())
          << MatchTable::LineBreak;
  }

  unsigned countRendererFns() const override {
    return 1;
  }
};

/// Generates code to check that an operand is in a particular register bank.
class RegisterBankOperandMatcher : public OperandPredicateMatcher {
protected:
  const CodeGenRegisterClass &RC;

public:
  RegisterBankOperandMatcher(unsigned InsnVarID, unsigned OpIdx,
                             const CodeGenRegisterClass &RC)
      : OperandPredicateMatcher(OPM_RegBank, InsnVarID, OpIdx), RC(RC) {}

  bool isIdentical(const PredicateMatcher &B) const override {
    return OperandPredicateMatcher::isIdentical(B) &&
           RC.getDef() == cast<RegisterBankOperandMatcher>(&B)->RC.getDef();
  }

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == OPM_RegBank;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIM_CheckRegBankForClass")
          << MatchTable::Comment("MI") << MatchTable::IntValue(InsnVarID)
          << MatchTable::Comment("Op") << MatchTable::IntValue(OpIdx)
          << MatchTable::Comment("RC")
          << MatchTable::NamedValue(RC.getQualifiedName() + "RegClassID")
          << MatchTable::LineBreak;
  }
};

/// Generates code to check that an operand is a basic block.
class MBBOperandMatcher : public OperandPredicateMatcher {
public:
  MBBOperandMatcher(unsigned InsnVarID, unsigned OpIdx)
      : OperandPredicateMatcher(OPM_MBB, InsnVarID, OpIdx) {}

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == OPM_MBB;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIM_CheckIsMBB") << MatchTable::Comment("MI")
          << MatchTable::IntValue(InsnVarID) << MatchTable::Comment("Op")
          << MatchTable::IntValue(OpIdx) << MatchTable::LineBreak;
  }
};

class ImmOperandMatcher : public OperandPredicateMatcher {
public:
  ImmOperandMatcher(unsigned InsnVarID, unsigned OpIdx)
      : OperandPredicateMatcher(IPM_Imm, InsnVarID, OpIdx) {}

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == IPM_Imm;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIM_CheckIsImm") << MatchTable::Comment("MI")
          << MatchTable::IntValue(InsnVarID) << MatchTable::Comment("Op")
          << MatchTable::IntValue(OpIdx) << MatchTable::LineBreak;
  }
};

/// Generates code to check that an operand is a G_CONSTANT with a particular
/// int.
class ConstantIntOperandMatcher : public OperandPredicateMatcher {
protected:
  int64_t Value;

public:
  ConstantIntOperandMatcher(unsigned InsnVarID, unsigned OpIdx, int64_t Value)
      : OperandPredicateMatcher(OPM_Int, InsnVarID, OpIdx), Value(Value) {}

  bool isIdentical(const PredicateMatcher &B) const override {
    return OperandPredicateMatcher::isIdentical(B) &&
           Value == cast<ConstantIntOperandMatcher>(&B)->Value;
  }

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == OPM_Int;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIM_CheckConstantInt")
          << MatchTable::Comment("MI") << MatchTable::IntValue(InsnVarID)
          << MatchTable::Comment("Op") << MatchTable::IntValue(OpIdx)
          << MatchTable::IntValue(Value) << MatchTable::LineBreak;
  }
};

/// Generates code to check that an operand is a raw int (where MO.isImm() or
/// MO.isCImm() is true).
class LiteralIntOperandMatcher : public OperandPredicateMatcher {
protected:
  int64_t Value;

public:
  LiteralIntOperandMatcher(unsigned InsnVarID, unsigned OpIdx, int64_t Value)
      : OperandPredicateMatcher(OPM_LiteralInt, InsnVarID, OpIdx),
        Value(Value) {}

  bool isIdentical(const PredicateMatcher &B) const override {
    return OperandPredicateMatcher::isIdentical(B) &&
           Value == cast<LiteralIntOperandMatcher>(&B)->Value;
  }

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == OPM_LiteralInt;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIM_CheckLiteralInt")
          << MatchTable::Comment("MI") << MatchTable::IntValue(InsnVarID)
          << MatchTable::Comment("Op") << MatchTable::IntValue(OpIdx)
          << MatchTable::IntValue(Value) << MatchTable::LineBreak;
  }
};

/// Generates code to check that an operand is an CmpInst predicate
class CmpPredicateOperandMatcher : public OperandPredicateMatcher {
protected:
  std::string PredName;

public:
  CmpPredicateOperandMatcher(unsigned InsnVarID, unsigned OpIdx,
                             std::string P)
    : OperandPredicateMatcher(OPM_CmpPredicate, InsnVarID, OpIdx), PredName(P) {}

  bool isIdentical(const PredicateMatcher &B) const override {
    return OperandPredicateMatcher::isIdentical(B) &&
           PredName == cast<CmpPredicateOperandMatcher>(&B)->PredName;
  }

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == OPM_CmpPredicate;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIM_CheckCmpPredicate")
          << MatchTable::Comment("MI") << MatchTable::IntValue(InsnVarID)
          << MatchTable::Comment("Op") << MatchTable::IntValue(OpIdx)
          << MatchTable::Comment("Predicate")
          << MatchTable::NamedValue("CmpInst", PredName)
          << MatchTable::LineBreak;
  }
};

/// Generates code to check that an operand is an intrinsic ID.
class IntrinsicIDOperandMatcher : public OperandPredicateMatcher {
protected:
  const CodeGenIntrinsic *II;

public:
  IntrinsicIDOperandMatcher(unsigned InsnVarID, unsigned OpIdx,
                            const CodeGenIntrinsic *II)
      : OperandPredicateMatcher(OPM_IntrinsicID, InsnVarID, OpIdx), II(II) {}

  bool isIdentical(const PredicateMatcher &B) const override {
    return OperandPredicateMatcher::isIdentical(B) &&
           II == cast<IntrinsicIDOperandMatcher>(&B)->II;
  }

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == OPM_IntrinsicID;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIM_CheckIntrinsicID")
          << MatchTable::Comment("MI") << MatchTable::IntValue(InsnVarID)
          << MatchTable::Comment("Op") << MatchTable::IntValue(OpIdx)
          << MatchTable::NamedValue("Intrinsic::" + II->EnumName)
          << MatchTable::LineBreak;
  }
};

/// Generates code to check that a set of predicates match for a particular
/// operand.
class OperandMatcher : public PredicateListMatcher<OperandPredicateMatcher> {
protected:
  InstructionMatcher &Insn;
  unsigned OpIdx;
  std::string SymbolicName;

  /// The index of the first temporary variable allocated to this operand. The
  /// number of allocated temporaries can be found with
  /// countRendererFns().
  unsigned AllocatedTemporariesBaseID;

public:
  OperandMatcher(InstructionMatcher &Insn, unsigned OpIdx,
                 const std::string &SymbolicName,
                 unsigned AllocatedTemporariesBaseID)
      : Insn(Insn), OpIdx(OpIdx), SymbolicName(SymbolicName),
        AllocatedTemporariesBaseID(AllocatedTemporariesBaseID) {}

  bool hasSymbolicName() const { return !SymbolicName.empty(); }
  const StringRef getSymbolicName() const { return SymbolicName; }
  void setSymbolicName(StringRef Name) {
    assert(SymbolicName.empty() && "Operand already has a symbolic name");
    SymbolicName = std::string(Name);
  }

  /// Construct a new operand predicate and add it to the matcher.
  template <class Kind, class... Args>
  Optional<Kind *> addPredicate(Args &&... args) {
    if (isSameAsAnotherOperand())
      return None;
    Predicates.emplace_back(std::make_unique<Kind>(
        getInsnVarID(), getOpIdx(), std::forward<Args>(args)...));
    return static_cast<Kind *>(Predicates.back().get());
  }

  unsigned getOpIdx() const { return OpIdx; }
  unsigned getInsnVarID() const;

  std::string getOperandExpr(unsigned InsnVarID) const {
    return "State.MIs[" + llvm::to_string(InsnVarID) + "]->getOperand(" +
           llvm::to_string(OpIdx) + ")";
  }

  InstructionMatcher &getInstructionMatcher() const { return Insn; }

  Error addTypeCheckPredicate(const TypeSetByHwMode &VTy,
                              bool OperandIsAPointer);

  /// Emit MatchTable opcodes that test whether the instruction named in
  /// InsnVarID matches all the predicates and all the operands.
  void emitPredicateOpcodes(MatchTable &Table, RuleMatcher &Rule) {
    if (!Optimized) {
      std::string Comment;
      raw_string_ostream CommentOS(Comment);
      CommentOS << "MIs[" << getInsnVarID() << "] ";
      if (SymbolicName.empty())
        CommentOS << "Operand " << OpIdx;
      else
        CommentOS << SymbolicName;
      Table << MatchTable::Comment(CommentOS.str()) << MatchTable::LineBreak;
    }

    emitPredicateListOpcodes(Table, Rule);
  }

  /// Compare the priority of this object and B.
  ///
  /// Returns true if this object is more important than B.
  bool isHigherPriorityThan(OperandMatcher &B) {
    // Operand matchers involving more predicates have higher priority.
    if (predicates_size() > B.predicates_size())
      return true;
    if (predicates_size() < B.predicates_size())
      return false;

    // This assumes that predicates are added in a consistent order.
    for (auto &&Predicate : zip(predicates(), B.predicates())) {
      if (std::get<0>(Predicate)->isHigherPriorityThan(*std::get<1>(Predicate)))
        return true;
      if (std::get<1>(Predicate)->isHigherPriorityThan(*std::get<0>(Predicate)))
        return false;
    }

    return false;
  };

  /// Report the maximum number of temporary operands needed by the operand
  /// matcher.
  unsigned countRendererFns() {
    return std::accumulate(
        predicates().begin(), predicates().end(), 0,
        [](unsigned A,
           const std::unique_ptr<OperandPredicateMatcher> &Predicate) {
          return A + Predicate->countRendererFns();
        });
  }

  unsigned getAllocatedTemporariesBaseID() const {
    return AllocatedTemporariesBaseID;
  }

  bool isSameAsAnotherOperand() {
    for (const auto &Predicate : predicates())
      if (isa<SameOperandMatcher>(Predicate))
        return true;
    return false;
  }
};

Error OperandMatcher::addTypeCheckPredicate(const TypeSetByHwMode &VTy,
                                            bool OperandIsAPointer) {
  if (!VTy.isMachineValueType())
    return failedImport("unsupported typeset");

  if (VTy.getMachineValueType() == MVT::iPTR && OperandIsAPointer) {
    addPredicate<PointerToAnyOperandMatcher>(0);
    return Error::success();
  }

  auto OpTyOrNone = MVTToLLT(VTy.getMachineValueType().SimpleTy);
  if (!OpTyOrNone)
    return failedImport("unsupported type");

  if (OperandIsAPointer)
    addPredicate<PointerToAnyOperandMatcher>(OpTyOrNone->get().getSizeInBits());
  else if (VTy.isPointer())
    addPredicate<LLTOperandMatcher>(LLT::pointer(VTy.getPtrAddrSpace(),
                                                 OpTyOrNone->get().getSizeInBits()));
  else
    addPredicate<LLTOperandMatcher>(*OpTyOrNone);
  return Error::success();
}

unsigned ComplexPatternOperandMatcher::getAllocatedTemporariesBaseID() const {
  return Operand.getAllocatedTemporariesBaseID();
}

/// Generates code to check a predicate on an instruction.
///
/// Typical predicates include:
/// * The opcode of the instruction is a particular value.
/// * The nsw/nuw flag is/isn't set.
class InstructionPredicateMatcher : public PredicateMatcher {
public:
  InstructionPredicateMatcher(PredicateKind Kind, unsigned InsnVarID)
      : PredicateMatcher(Kind, InsnVarID) {}
  virtual ~InstructionPredicateMatcher() {}

  /// Compare the priority of this object and B.
  ///
  /// Returns true if this object is more important than B.
  virtual bool
  isHigherPriorityThan(const InstructionPredicateMatcher &B) const {
    return Kind < B.Kind;
  };
};

template <>
std::string
PredicateListMatcher<PredicateMatcher>::getNoPredicateComment() const {
  return "No instruction predicates";
}

/// Generates code to check the opcode of an instruction.
class InstructionOpcodeMatcher : public InstructionPredicateMatcher {
protected:
  const CodeGenInstruction *I;

  static DenseMap<const CodeGenInstruction *, unsigned> OpcodeValues;

public:
  static void initOpcodeValuesMap(const CodeGenTarget &Target) {
    OpcodeValues.clear();

    unsigned OpcodeValue = 0;
    for (const CodeGenInstruction *I : Target.getInstructionsByEnumValue())
      OpcodeValues[I] = OpcodeValue++;
  }

  InstructionOpcodeMatcher(unsigned InsnVarID, const CodeGenInstruction *I)
      : InstructionPredicateMatcher(IPM_Opcode, InsnVarID), I(I) {}

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == IPM_Opcode;
  }

  bool isIdentical(const PredicateMatcher &B) const override {
    return InstructionPredicateMatcher::isIdentical(B) &&
           I == cast<InstructionOpcodeMatcher>(&B)->I;
  }
  MatchTableRecord getValue() const override {
    const auto VI = OpcodeValues.find(I);
    if (VI != OpcodeValues.end())
      return MatchTable::NamedValue(I->Namespace, I->TheDef->getName(),
                                    VI->second);
    return MatchTable::NamedValue(I->Namespace, I->TheDef->getName());
  }
  bool hasValue() const override { return OpcodeValues.count(I); }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIM_CheckOpcode") << MatchTable::Comment("MI")
          << MatchTable::IntValue(InsnVarID) << getValue()
          << MatchTable::LineBreak;
  }

  /// Compare the priority of this object and B.
  ///
  /// Returns true if this object is more important than B.
  bool
  isHigherPriorityThan(const InstructionPredicateMatcher &B) const override {
    if (InstructionPredicateMatcher::isHigherPriorityThan(B))
      return true;
    if (B.InstructionPredicateMatcher::isHigherPriorityThan(*this))
      return false;

    // Prioritize opcodes for cosmetic reasons in the generated source. Although
    // this is cosmetic at the moment, we may want to drive a similar ordering
    // using instruction frequency information to improve compile time.
    if (const InstructionOpcodeMatcher *BO =
            dyn_cast<InstructionOpcodeMatcher>(&B))
      return I->TheDef->getName() < BO->I->TheDef->getName();

    return false;
  };

  bool isConstantInstruction() const {
    return I->TheDef->getName() == "G_CONSTANT";
  }

  StringRef getOpcode() const { return I->TheDef->getName(); }
  bool isVariadicNumOperands() const { return I->Operands.isVariadic; }

  StringRef getOperandType(unsigned OpIdx) const {
    return I->Operands[OpIdx].OperandType;
  }
};

DenseMap<const CodeGenInstruction *, unsigned>
    InstructionOpcodeMatcher::OpcodeValues;

class InstructionNumOperandsMatcher final : public InstructionPredicateMatcher {
  unsigned NumOperands = 0;

public:
  InstructionNumOperandsMatcher(unsigned InsnVarID, unsigned NumOperands)
      : InstructionPredicateMatcher(IPM_NumOperands, InsnVarID),
        NumOperands(NumOperands) {}

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == IPM_NumOperands;
  }

  bool isIdentical(const PredicateMatcher &B) const override {
    return InstructionPredicateMatcher::isIdentical(B) &&
           NumOperands == cast<InstructionNumOperandsMatcher>(&B)->NumOperands;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIM_CheckNumOperands")
          << MatchTable::Comment("MI") << MatchTable::IntValue(InsnVarID)
          << MatchTable::Comment("Expected")
          << MatchTable::IntValue(NumOperands) << MatchTable::LineBreak;
  }
};

/// Generates code to check that this instruction is a constant whose value
/// meets an immediate predicate.
///
/// Immediates are slightly odd since they are typically used like an operand
/// but are represented as an operator internally. We typically write simm8:$src
/// in a tablegen pattern, but this is just syntactic sugar for
/// (imm:i32)<<P:Predicate_simm8>>:$imm which more directly describes the nodes
/// that will be matched and the predicate (which is attached to the imm
/// operator) that will be tested. In SelectionDAG this describes a
/// ConstantSDNode whose internal value will be tested using the simm8 predicate.
///
/// The corresponding GlobalISel representation is %1 = G_CONSTANT iN Value. In
/// this representation, the immediate could be tested with an
/// InstructionMatcher, InstructionOpcodeMatcher, OperandMatcher, and a
/// OperandPredicateMatcher-subclass to check the Value meets the predicate but
/// there are two implementation issues with producing that matcher
/// configuration from the SelectionDAG pattern:
/// * ImmLeaf is a PatFrag whose root is an InstructionMatcher. This means that
///   were we to sink the immediate predicate to the operand we would have to
///   have two partial implementations of PatFrag support, one for immediates
///   and one for non-immediates.
/// * At the point we handle the predicate, the OperandMatcher hasn't been
///   created yet. If we were to sink the predicate to the OperandMatcher we
///   would also have to complicate (or duplicate) the code that descends and
///   creates matchers for the subtree.
/// Overall, it's simpler to handle it in the place it was found.
class InstructionImmPredicateMatcher : public InstructionPredicateMatcher {
protected:
  TreePredicateFn Predicate;

public:
  InstructionImmPredicateMatcher(unsigned InsnVarID,
                                 const TreePredicateFn &Predicate)
      : InstructionPredicateMatcher(IPM_ImmPredicate, InsnVarID),
        Predicate(Predicate) {}

  bool isIdentical(const PredicateMatcher &B) const override {
    return InstructionPredicateMatcher::isIdentical(B) &&
           Predicate.getOrigPatFragRecord() ==
               cast<InstructionImmPredicateMatcher>(&B)
                   ->Predicate.getOrigPatFragRecord();
  }

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == IPM_ImmPredicate;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode(getMatchOpcodeForPredicate(Predicate))
          << MatchTable::Comment("MI") << MatchTable::IntValue(InsnVarID)
          << MatchTable::Comment("Predicate")
          << MatchTable::NamedValue(getEnumNameForPredicate(Predicate))
          << MatchTable::LineBreak;
  }
};

/// Generates code to check that a memory instruction has a atomic ordering
/// MachineMemoryOperand.
class AtomicOrderingMMOPredicateMatcher : public InstructionPredicateMatcher {
public:
  enum AOComparator {
    AO_Exactly,
    AO_OrStronger,
    AO_WeakerThan,
  };

protected:
  StringRef Order;
  AOComparator Comparator;

public:
  AtomicOrderingMMOPredicateMatcher(unsigned InsnVarID, StringRef Order,
                                    AOComparator Comparator = AO_Exactly)
      : InstructionPredicateMatcher(IPM_AtomicOrderingMMO, InsnVarID),
        Order(Order), Comparator(Comparator) {}

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == IPM_AtomicOrderingMMO;
  }

  bool isIdentical(const PredicateMatcher &B) const override {
    if (!InstructionPredicateMatcher::isIdentical(B))
      return false;
    const auto &R = *cast<AtomicOrderingMMOPredicateMatcher>(&B);
    return Order == R.Order && Comparator == R.Comparator;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    StringRef Opcode = "GIM_CheckAtomicOrdering";

    if (Comparator == AO_OrStronger)
      Opcode = "GIM_CheckAtomicOrderingOrStrongerThan";
    if (Comparator == AO_WeakerThan)
      Opcode = "GIM_CheckAtomicOrderingWeakerThan";

    Table << MatchTable::Opcode(Opcode) << MatchTable::Comment("MI")
          << MatchTable::IntValue(InsnVarID) << MatchTable::Comment("Order")
          << MatchTable::NamedValue(("(int64_t)AtomicOrdering::" + Order).str())
          << MatchTable::LineBreak;
  }
};

/// Generates code to check that the size of an MMO is exactly N bytes.
class MemorySizePredicateMatcher : public InstructionPredicateMatcher {
protected:
  unsigned MMOIdx;
  uint64_t Size;

public:
  MemorySizePredicateMatcher(unsigned InsnVarID, unsigned MMOIdx, unsigned Size)
      : InstructionPredicateMatcher(IPM_MemoryLLTSize, InsnVarID),
        MMOIdx(MMOIdx), Size(Size) {}

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == IPM_MemoryLLTSize;
  }
  bool isIdentical(const PredicateMatcher &B) const override {
    return InstructionPredicateMatcher::isIdentical(B) &&
           MMOIdx == cast<MemorySizePredicateMatcher>(&B)->MMOIdx &&
           Size == cast<MemorySizePredicateMatcher>(&B)->Size;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIM_CheckMemorySizeEqualTo")
          << MatchTable::Comment("MI") << MatchTable::IntValue(InsnVarID)
          << MatchTable::Comment("MMO") << MatchTable::IntValue(MMOIdx)
          << MatchTable::Comment("Size") << MatchTable::IntValue(Size)
          << MatchTable::LineBreak;
  }
};

class MemoryAddressSpacePredicateMatcher : public InstructionPredicateMatcher {
protected:
  unsigned MMOIdx;
  SmallVector<unsigned, 4> AddrSpaces;

public:
  MemoryAddressSpacePredicateMatcher(unsigned InsnVarID, unsigned MMOIdx,
                                     ArrayRef<unsigned> AddrSpaces)
      : InstructionPredicateMatcher(IPM_MemoryAddressSpace, InsnVarID),
        MMOIdx(MMOIdx), AddrSpaces(AddrSpaces.begin(), AddrSpaces.end()) {}

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == IPM_MemoryAddressSpace;
  }
  bool isIdentical(const PredicateMatcher &B) const override {
    if (!InstructionPredicateMatcher::isIdentical(B))
      return false;
    auto *Other = cast<MemoryAddressSpacePredicateMatcher>(&B);
    return MMOIdx == Other->MMOIdx && AddrSpaces == Other->AddrSpaces;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIM_CheckMemoryAddressSpace")
          << MatchTable::Comment("MI") << MatchTable::IntValue(InsnVarID)
          << MatchTable::Comment("MMO") << MatchTable::IntValue(MMOIdx)
        // Encode number of address spaces to expect.
          << MatchTable::Comment("NumAddrSpace")
          << MatchTable::IntValue(AddrSpaces.size());
    for (unsigned AS : AddrSpaces)
      Table << MatchTable::Comment("AddrSpace") << MatchTable::IntValue(AS);

    Table << MatchTable::LineBreak;
  }
};

class MemoryAlignmentPredicateMatcher : public InstructionPredicateMatcher {
protected:
  unsigned MMOIdx;
  int MinAlign;

public:
  MemoryAlignmentPredicateMatcher(unsigned InsnVarID, unsigned MMOIdx,
                                  int MinAlign)
      : InstructionPredicateMatcher(IPM_MemoryAlignment, InsnVarID),
        MMOIdx(MMOIdx), MinAlign(MinAlign) {
    assert(MinAlign > 0);
  }

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == IPM_MemoryAlignment;
  }

  bool isIdentical(const PredicateMatcher &B) const override {
    if (!InstructionPredicateMatcher::isIdentical(B))
      return false;
    auto *Other = cast<MemoryAlignmentPredicateMatcher>(&B);
    return MMOIdx == Other->MMOIdx && MinAlign == Other->MinAlign;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIM_CheckMemoryAlignment")
          << MatchTable::Comment("MI") << MatchTable::IntValue(InsnVarID)
          << MatchTable::Comment("MMO") << MatchTable::IntValue(MMOIdx)
          << MatchTable::Comment("MinAlign") << MatchTable::IntValue(MinAlign)
          << MatchTable::LineBreak;
  }
};

/// Generates code to check that the size of an MMO is less-than, equal-to, or
/// greater than a given LLT.
class MemoryVsLLTSizePredicateMatcher : public InstructionPredicateMatcher {
public:
  enum RelationKind {
    GreaterThan,
    EqualTo,
    LessThan,
  };

protected:
  unsigned MMOIdx;
  RelationKind Relation;
  unsigned OpIdx;

public:
  MemoryVsLLTSizePredicateMatcher(unsigned InsnVarID, unsigned MMOIdx,
                                  enum RelationKind Relation,
                                  unsigned OpIdx)
      : InstructionPredicateMatcher(IPM_MemoryVsLLTSize, InsnVarID),
        MMOIdx(MMOIdx), Relation(Relation), OpIdx(OpIdx) {}

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == IPM_MemoryVsLLTSize;
  }
  bool isIdentical(const PredicateMatcher &B) const override {
    return InstructionPredicateMatcher::isIdentical(B) &&
           MMOIdx == cast<MemoryVsLLTSizePredicateMatcher>(&B)->MMOIdx &&
           Relation == cast<MemoryVsLLTSizePredicateMatcher>(&B)->Relation &&
           OpIdx == cast<MemoryVsLLTSizePredicateMatcher>(&B)->OpIdx;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode(Relation == EqualTo
                                    ? "GIM_CheckMemorySizeEqualToLLT"
                                    : Relation == GreaterThan
                                          ? "GIM_CheckMemorySizeGreaterThanLLT"
                                          : "GIM_CheckMemorySizeLessThanLLT")
          << MatchTable::Comment("MI") << MatchTable::IntValue(InsnVarID)
          << MatchTable::Comment("MMO") << MatchTable::IntValue(MMOIdx)
          << MatchTable::Comment("OpIdx") << MatchTable::IntValue(OpIdx)
          << MatchTable::LineBreak;
  }
};

/// Generates code to check an arbitrary C++ instruction predicate.
class GenericInstructionPredicateMatcher : public InstructionPredicateMatcher {
protected:
  TreePredicateFn Predicate;

public:
  GenericInstructionPredicateMatcher(unsigned InsnVarID,
                                     TreePredicateFn Predicate)
      : InstructionPredicateMatcher(IPM_GenericPredicate, InsnVarID),
        Predicate(Predicate) {}

  static bool classof(const InstructionPredicateMatcher *P) {
    return P->getKind() == IPM_GenericPredicate;
  }
  bool isIdentical(const PredicateMatcher &B) const override {
    return InstructionPredicateMatcher::isIdentical(B) &&
           Predicate ==
               static_cast<const GenericInstructionPredicateMatcher &>(B)
                   .Predicate;
  }
  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIM_CheckCxxInsnPredicate")
          << MatchTable::Comment("MI") << MatchTable::IntValue(InsnVarID)
          << MatchTable::Comment("FnId")
          << MatchTable::NamedValue(getEnumNameForPredicate(Predicate))
          << MatchTable::LineBreak;
  }
};

/// Generates code to check that a set of predicates and operands match for a
/// particular instruction.
///
/// Typical predicates include:
/// * Has a specific opcode.
/// * Has an nsw/nuw flag or doesn't.
class InstructionMatcher final : public PredicateListMatcher<PredicateMatcher> {
protected:
  typedef std::vector<std::unique_ptr<OperandMatcher>> OperandVec;

  RuleMatcher &Rule;

  /// The operands to match. All rendered operands must be present even if the
  /// condition is always true.
  OperandVec Operands;
  bool NumOperandsCheck = true;

  std::string SymbolicName;
  unsigned InsnVarID;

  /// PhysRegInputs - List list has an entry for each explicitly specified
  /// physreg input to the pattern.  The first elt is the Register node, the
  /// second is the recorded slot number the input pattern match saved it in.
  SmallVector<std::pair<Record *, unsigned>, 2> PhysRegInputs;

public:
  InstructionMatcher(RuleMatcher &Rule, StringRef SymbolicName)
      : Rule(Rule), SymbolicName(SymbolicName) {
    // We create a new instruction matcher.
    // Get a new ID for that instruction.
    InsnVarID = Rule.implicitlyDefineInsnVar(*this);
  }

  /// Construct a new instruction predicate and add it to the matcher.
  template <class Kind, class... Args>
  Optional<Kind *> addPredicate(Args &&... args) {
    Predicates.emplace_back(
        std::make_unique<Kind>(getInsnVarID(), std::forward<Args>(args)...));
    return static_cast<Kind *>(Predicates.back().get());
  }

  RuleMatcher &getRuleMatcher() const { return Rule; }

  unsigned getInsnVarID() const { return InsnVarID; }

  /// Add an operand to the matcher.
  OperandMatcher &addOperand(unsigned OpIdx, const std::string &SymbolicName,
                             unsigned AllocatedTemporariesBaseID) {
    Operands.emplace_back(new OperandMatcher(*this, OpIdx, SymbolicName,
                                             AllocatedTemporariesBaseID));
    if (!SymbolicName.empty())
      Rule.defineOperand(SymbolicName, *Operands.back());

    return *Operands.back();
  }

  OperandMatcher &getOperand(unsigned OpIdx) {
    auto I = std::find_if(Operands.begin(), Operands.end(),
                          [&OpIdx](const std::unique_ptr<OperandMatcher> &X) {
                            return X->getOpIdx() == OpIdx;
                          });
    if (I != Operands.end())
      return **I;
    llvm_unreachable("Failed to lookup operand");
  }

  OperandMatcher &addPhysRegInput(Record *Reg, unsigned OpIdx,
                                  unsigned TempOpIdx) {
    assert(SymbolicName.empty());
    OperandMatcher *OM = new OperandMatcher(*this, OpIdx, "", TempOpIdx);
    Operands.emplace_back(OM);
    Rule.definePhysRegOperand(Reg, *OM);
    PhysRegInputs.emplace_back(Reg, OpIdx);
    return *OM;
  }

  ArrayRef<std::pair<Record *, unsigned>> getPhysRegInputs() const {
    return PhysRegInputs;
  }

  StringRef getSymbolicName() const { return SymbolicName; }
  unsigned getNumOperands() const { return Operands.size(); }
  OperandVec::iterator operands_begin() { return Operands.begin(); }
  OperandVec::iterator operands_end() { return Operands.end(); }
  iterator_range<OperandVec::iterator> operands() {
    return make_range(operands_begin(), operands_end());
  }
  OperandVec::const_iterator operands_begin() const { return Operands.begin(); }
  OperandVec::const_iterator operands_end() const { return Operands.end(); }
  iterator_range<OperandVec::const_iterator> operands() const {
    return make_range(operands_begin(), operands_end());
  }
  bool operands_empty() const { return Operands.empty(); }

  void pop_front() { Operands.erase(Operands.begin()); }

  void optimize();

  /// Emit MatchTable opcodes that test whether the instruction named in
  /// InsnVarName matches all the predicates and all the operands.
  void emitPredicateOpcodes(MatchTable &Table, RuleMatcher &Rule) {
    if (NumOperandsCheck)
      InstructionNumOperandsMatcher(InsnVarID, getNumOperands())
          .emitPredicateOpcodes(Table, Rule);

    emitPredicateListOpcodes(Table, Rule);

    for (const auto &Operand : Operands)
      Operand->emitPredicateOpcodes(Table, Rule);
  }

  /// Compare the priority of this object and B.
  ///
  /// Returns true if this object is more important than B.
  bool isHigherPriorityThan(InstructionMatcher &B) {
    // Instruction matchers involving more operands have higher priority.
    if (Operands.size() > B.Operands.size())
      return true;
    if (Operands.size() < B.Operands.size())
      return false;

    for (auto &&P : zip(predicates(), B.predicates())) {
      auto L = static_cast<InstructionPredicateMatcher *>(std::get<0>(P).get());
      auto R = static_cast<InstructionPredicateMatcher *>(std::get<1>(P).get());
      if (L->isHigherPriorityThan(*R))
        return true;
      if (R->isHigherPriorityThan(*L))
        return false;
    }

    for (auto Operand : zip(Operands, B.Operands)) {
      if (std::get<0>(Operand)->isHigherPriorityThan(*std::get<1>(Operand)))
        return true;
      if (std::get<1>(Operand)->isHigherPriorityThan(*std::get<0>(Operand)))
        return false;
    }

    return false;
  };

  /// Report the maximum number of temporary operands needed by the instruction
  /// matcher.
  unsigned countRendererFns() {
    return std::accumulate(
               predicates().begin(), predicates().end(), 0,
               [](unsigned A,
                  const std::unique_ptr<PredicateMatcher> &Predicate) {
                 return A + Predicate->countRendererFns();
               }) +
           std::accumulate(
               Operands.begin(), Operands.end(), 0,
               [](unsigned A, const std::unique_ptr<OperandMatcher> &Operand) {
                 return A + Operand->countRendererFns();
               });
  }

  InstructionOpcodeMatcher &getOpcodeMatcher() {
    for (auto &P : predicates())
      if (auto *OpMatcher = dyn_cast<InstructionOpcodeMatcher>(P.get()))
        return *OpMatcher;
    llvm_unreachable("Didn't find an opcode matcher");
  }

  bool isConstantInstruction() {
    return getOpcodeMatcher().isConstantInstruction();
  }

  StringRef getOpcode() { return getOpcodeMatcher().getOpcode(); }
};

StringRef RuleMatcher::getOpcode() const {
  return Matchers.front()->getOpcode();
}

unsigned RuleMatcher::getNumOperands() const {
  return Matchers.front()->getNumOperands();
}

LLTCodeGen RuleMatcher::getFirstConditionAsRootType() {
  InstructionMatcher &InsnMatcher = *Matchers.front();
  if (!InsnMatcher.predicates_empty())
    if (const auto *TM =
            dyn_cast<LLTOperandMatcher>(&**InsnMatcher.predicates_begin()))
      if (TM->getInsnVarID() == 0 && TM->getOpIdx() == 0)
        return TM->getTy();
  return {};
}

/// Generates code to check that the operand is a register defined by an
/// instruction that matches the given instruction matcher.
///
/// For example, the pattern:
///   (set $dst, (G_MUL (G_ADD $src1, $src2), $src3))
/// would use an InstructionOperandMatcher for operand 1 of the G_MUL to match
/// the:
///   (G_ADD $src1, $src2)
/// subpattern.
class InstructionOperandMatcher : public OperandPredicateMatcher {
protected:
  std::unique_ptr<InstructionMatcher> InsnMatcher;

public:
  InstructionOperandMatcher(unsigned InsnVarID, unsigned OpIdx,
                            RuleMatcher &Rule, StringRef SymbolicName)
      : OperandPredicateMatcher(OPM_Instruction, InsnVarID, OpIdx),
        InsnMatcher(new InstructionMatcher(Rule, SymbolicName)) {}

  static bool classof(const PredicateMatcher *P) {
    return P->getKind() == OPM_Instruction;
  }

  InstructionMatcher &getInsnMatcher() const { return *InsnMatcher; }

  void emitCaptureOpcodes(MatchTable &Table, RuleMatcher &Rule) const {
    const unsigned NewInsnVarID = InsnMatcher->getInsnVarID();
    Table << MatchTable::Opcode("GIM_RecordInsn")
          << MatchTable::Comment("DefineMI")
          << MatchTable::IntValue(NewInsnVarID) << MatchTable::Comment("MI")
          << MatchTable::IntValue(getInsnVarID())
          << MatchTable::Comment("OpIdx") << MatchTable::IntValue(getOpIdx())
          << MatchTable::Comment("MIs[" + llvm::to_string(NewInsnVarID) + "]")
          << MatchTable::LineBreak;
  }

  void emitPredicateOpcodes(MatchTable &Table,
                            RuleMatcher &Rule) const override {
    emitCaptureOpcodes(Table, Rule);
    InsnMatcher->emitPredicateOpcodes(Table, Rule);
  }

  bool isHigherPriorityThan(const OperandPredicateMatcher &B) const override {
    if (OperandPredicateMatcher::isHigherPriorityThan(B))
      return true;
    if (B.OperandPredicateMatcher::isHigherPriorityThan(*this))
      return false;

    if (const InstructionOperandMatcher *BP =
            dyn_cast<InstructionOperandMatcher>(&B))
      if (InsnMatcher->isHigherPriorityThan(*BP->InsnMatcher))
        return true;
    return false;
  }
};

void InstructionMatcher::optimize() {
  SmallVector<std::unique_ptr<PredicateMatcher>, 8> Stash;
  const auto &OpcMatcher = getOpcodeMatcher();

  Stash.push_back(predicates_pop_front());
  if (Stash.back().get() == &OpcMatcher) {
    if (NumOperandsCheck && OpcMatcher.isVariadicNumOperands())
      Stash.emplace_back(
          new InstructionNumOperandsMatcher(InsnVarID, getNumOperands()));
    NumOperandsCheck = false;

    for (auto &OM : Operands)
      for (auto &OP : OM->predicates())
        if (isa<IntrinsicIDOperandMatcher>(OP)) {
          Stash.push_back(std::move(OP));
          OM->eraseNullPredicates();
          break;
        }
  }

  if (InsnVarID > 0) {
    assert(!Operands.empty() && "Nested instruction is expected to def a vreg");
    for (auto &OP : Operands[0]->predicates())
      OP.reset();
    Operands[0]->eraseNullPredicates();
  }
  for (auto &OM : Operands) {
    for (auto &OP : OM->predicates())
      if (isa<LLTOperandMatcher>(OP))
        Stash.push_back(std::move(OP));
    OM->eraseNullPredicates();
  }
  while (!Stash.empty())
    prependPredicate(Stash.pop_back_val());
}

//===- Actions ------------------------------------------------------------===//
class OperandRenderer {
public:
  enum RendererKind {
    OR_Copy,
    OR_CopyOrAddZeroReg,
    OR_CopySubReg,
    OR_CopyPhysReg,
    OR_CopyConstantAsImm,
    OR_CopyFConstantAsFPImm,
    OR_Imm,
    OR_SubRegIndex,
    OR_Register,
    OR_TempRegister,
    OR_ComplexPattern,
    OR_Custom,
    OR_CustomOperand
  };

protected:
  RendererKind Kind;

public:
  OperandRenderer(RendererKind Kind) : Kind(Kind) {}
  virtual ~OperandRenderer() {}

  RendererKind getKind() const { return Kind; }

  virtual void emitRenderOpcodes(MatchTable &Table,
                                 RuleMatcher &Rule) const = 0;
};

/// A CopyRenderer emits code to copy a single operand from an existing
/// instruction to the one being built.
class CopyRenderer : public OperandRenderer {
protected:
  unsigned NewInsnID;
  /// The name of the operand.
  const StringRef SymbolicName;

public:
  CopyRenderer(unsigned NewInsnID, StringRef SymbolicName)
      : OperandRenderer(OR_Copy), NewInsnID(NewInsnID),
        SymbolicName(SymbolicName) {
    assert(!SymbolicName.empty() && "Cannot copy from an unspecified source");
  }

  static bool classof(const OperandRenderer *R) {
    return R->getKind() == OR_Copy;
  }

  const StringRef getSymbolicName() const { return SymbolicName; }

  void emitRenderOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    const OperandMatcher &Operand = Rule.getOperandMatcher(SymbolicName);
    unsigned OldInsnVarID = Rule.getInsnVarID(Operand.getInstructionMatcher());
    Table << MatchTable::Opcode("GIR_Copy") << MatchTable::Comment("NewInsnID")
          << MatchTable::IntValue(NewInsnID) << MatchTable::Comment("OldInsnID")
          << MatchTable::IntValue(OldInsnVarID) << MatchTable::Comment("OpIdx")
          << MatchTable::IntValue(Operand.getOpIdx())
          << MatchTable::Comment(SymbolicName) << MatchTable::LineBreak;
  }
};

/// A CopyRenderer emits code to copy a virtual register to a specific physical
/// register.
class CopyPhysRegRenderer : public OperandRenderer {
protected:
  unsigned NewInsnID;
  Record *PhysReg;

public:
  CopyPhysRegRenderer(unsigned NewInsnID, Record *Reg)
      : OperandRenderer(OR_CopyPhysReg), NewInsnID(NewInsnID),
        PhysReg(Reg) {
    assert(PhysReg);
  }

  static bool classof(const OperandRenderer *R) {
    return R->getKind() == OR_CopyPhysReg;
  }

  Record *getPhysReg() const { return PhysReg; }

  void emitRenderOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    const OperandMatcher &Operand = Rule.getPhysRegOperandMatcher(PhysReg);
    unsigned OldInsnVarID = Rule.getInsnVarID(Operand.getInstructionMatcher());
    Table << MatchTable::Opcode("GIR_Copy") << MatchTable::Comment("NewInsnID")
          << MatchTable::IntValue(NewInsnID) << MatchTable::Comment("OldInsnID")
          << MatchTable::IntValue(OldInsnVarID) << MatchTable::Comment("OpIdx")
          << MatchTable::IntValue(Operand.getOpIdx())
          << MatchTable::Comment(PhysReg->getName())
          << MatchTable::LineBreak;
  }
};

/// A CopyOrAddZeroRegRenderer emits code to copy a single operand from an
/// existing instruction to the one being built. If the operand turns out to be
/// a 'G_CONSTANT 0' then it replaces the operand with a zero register.
class CopyOrAddZeroRegRenderer : public OperandRenderer {
protected:
  unsigned NewInsnID;
  /// The name of the operand.
  const StringRef SymbolicName;
  const Record *ZeroRegisterDef;

public:
  CopyOrAddZeroRegRenderer(unsigned NewInsnID,
                           StringRef SymbolicName, Record *ZeroRegisterDef)
      : OperandRenderer(OR_CopyOrAddZeroReg), NewInsnID(NewInsnID),
        SymbolicName(SymbolicName), ZeroRegisterDef(ZeroRegisterDef) {
    assert(!SymbolicName.empty() && "Cannot copy from an unspecified source");
  }

  static bool classof(const OperandRenderer *R) {
    return R->getKind() == OR_CopyOrAddZeroReg;
  }

  const StringRef getSymbolicName() const { return SymbolicName; }

  void emitRenderOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    const OperandMatcher &Operand = Rule.getOperandMatcher(SymbolicName);
    unsigned OldInsnVarID = Rule.getInsnVarID(Operand.getInstructionMatcher());
    Table << MatchTable::Opcode("GIR_CopyOrAddZeroReg")
          << MatchTable::Comment("NewInsnID") << MatchTable::IntValue(NewInsnID)
          << MatchTable::Comment("OldInsnID")
          << MatchTable::IntValue(OldInsnVarID) << MatchTable::Comment("OpIdx")
          << MatchTable::IntValue(Operand.getOpIdx())
          << MatchTable::NamedValue(
                 (ZeroRegisterDef->getValue("Namespace")
                      ? ZeroRegisterDef->getValueAsString("Namespace")
                      : ""),
                 ZeroRegisterDef->getName())
          << MatchTable::Comment(SymbolicName) << MatchTable::LineBreak;
  }
};

/// A CopyConstantAsImmRenderer emits code to render a G_CONSTANT instruction to
/// an extended immediate operand.
class CopyConstantAsImmRenderer : public OperandRenderer {
protected:
  unsigned NewInsnID;
  /// The name of the operand.
  const std::string SymbolicName;
  bool Signed;

public:
  CopyConstantAsImmRenderer(unsigned NewInsnID, StringRef SymbolicName)
      : OperandRenderer(OR_CopyConstantAsImm), NewInsnID(NewInsnID),
        SymbolicName(SymbolicName), Signed(true) {}

  static bool classof(const OperandRenderer *R) {
    return R->getKind() == OR_CopyConstantAsImm;
  }

  const StringRef getSymbolicName() const { return SymbolicName; }

  void emitRenderOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    InstructionMatcher &InsnMatcher = Rule.getInstructionMatcher(SymbolicName);
    unsigned OldInsnVarID = Rule.getInsnVarID(InsnMatcher);
    Table << MatchTable::Opcode(Signed ? "GIR_CopyConstantAsSImm"
                                       : "GIR_CopyConstantAsUImm")
          << MatchTable::Comment("NewInsnID") << MatchTable::IntValue(NewInsnID)
          << MatchTable::Comment("OldInsnID")
          << MatchTable::IntValue(OldInsnVarID)
          << MatchTable::Comment(SymbolicName) << MatchTable::LineBreak;
  }
};

/// A CopyFConstantAsFPImmRenderer emits code to render a G_FCONSTANT
/// instruction to an extended immediate operand.
class CopyFConstantAsFPImmRenderer : public OperandRenderer {
protected:
  unsigned NewInsnID;
  /// The name of the operand.
  const std::string SymbolicName;

public:
  CopyFConstantAsFPImmRenderer(unsigned NewInsnID, StringRef SymbolicName)
      : OperandRenderer(OR_CopyFConstantAsFPImm), NewInsnID(NewInsnID),
        SymbolicName(SymbolicName) {}

  static bool classof(const OperandRenderer *R) {
    return R->getKind() == OR_CopyFConstantAsFPImm;
  }

  const StringRef getSymbolicName() const { return SymbolicName; }

  void emitRenderOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    InstructionMatcher &InsnMatcher = Rule.getInstructionMatcher(SymbolicName);
    unsigned OldInsnVarID = Rule.getInsnVarID(InsnMatcher);
    Table << MatchTable::Opcode("GIR_CopyFConstantAsFPImm")
          << MatchTable::Comment("NewInsnID") << MatchTable::IntValue(NewInsnID)
          << MatchTable::Comment("OldInsnID")
          << MatchTable::IntValue(OldInsnVarID)
          << MatchTable::Comment(SymbolicName) << MatchTable::LineBreak;
  }
};

/// A CopySubRegRenderer emits code to copy a single register operand from an
/// existing instruction to the one being built and indicate that only a
/// subregister should be copied.
class CopySubRegRenderer : public OperandRenderer {
protected:
  unsigned NewInsnID;
  /// The name of the operand.
  const StringRef SymbolicName;
  /// The subregister to extract.
  const CodeGenSubRegIndex *SubReg;

public:
  CopySubRegRenderer(unsigned NewInsnID, StringRef SymbolicName,
                     const CodeGenSubRegIndex *SubReg)
      : OperandRenderer(OR_CopySubReg), NewInsnID(NewInsnID),
        SymbolicName(SymbolicName), SubReg(SubReg) {}

  static bool classof(const OperandRenderer *R) {
    return R->getKind() == OR_CopySubReg;
  }

  const StringRef getSymbolicName() const { return SymbolicName; }

  void emitRenderOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    const OperandMatcher &Operand = Rule.getOperandMatcher(SymbolicName);
    unsigned OldInsnVarID = Rule.getInsnVarID(Operand.getInstructionMatcher());
    Table << MatchTable::Opcode("GIR_CopySubReg")
          << MatchTable::Comment("NewInsnID") << MatchTable::IntValue(NewInsnID)
          << MatchTable::Comment("OldInsnID")
          << MatchTable::IntValue(OldInsnVarID) << MatchTable::Comment("OpIdx")
          << MatchTable::IntValue(Operand.getOpIdx())
          << MatchTable::Comment("SubRegIdx")
          << MatchTable::IntValue(SubReg->EnumValue)
          << MatchTable::Comment(SymbolicName) << MatchTable::LineBreak;
  }
};

/// Adds a specific physical register to the instruction being built.
/// This is typically useful for WZR/XZR on AArch64.
class AddRegisterRenderer : public OperandRenderer {
protected:
  unsigned InsnID;
  const Record *RegisterDef;
  bool IsDef;

public:
  AddRegisterRenderer(unsigned InsnID, const Record *RegisterDef,
                      bool IsDef = false)
      : OperandRenderer(OR_Register), InsnID(InsnID), RegisterDef(RegisterDef),
        IsDef(IsDef) {}

  static bool classof(const OperandRenderer *R) {
    return R->getKind() == OR_Register;
  }

  void emitRenderOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIR_AddRegister")
          << MatchTable::Comment("InsnID") << MatchTable::IntValue(InsnID)
          << MatchTable::NamedValue(
                 (RegisterDef->getValue("Namespace")
                      ? RegisterDef->getValueAsString("Namespace")
                      : ""),
                 RegisterDef->getName())
          << MatchTable::Comment("AddRegisterRegFlags");

    // TODO: This is encoded as a 64-bit element, but only 16 or 32-bits are
    // really needed for a physical register reference. We can pack the
    // register and flags in a single field.
    if (IsDef)
      Table << MatchTable::NamedValue("RegState::Define");
    else
      Table << MatchTable::IntValue(0);
    Table << MatchTable::LineBreak;
  }
};

/// Adds a specific temporary virtual register to the instruction being built.
/// This is used to chain instructions together when emitting multiple
/// instructions.
class TempRegRenderer : public OperandRenderer {
protected:
  unsigned InsnID;
  unsigned TempRegID;
  const CodeGenSubRegIndex *SubRegIdx;
  bool IsDef;

public:
  TempRegRenderer(unsigned InsnID, unsigned TempRegID, bool IsDef = false,
                  const CodeGenSubRegIndex *SubReg = nullptr)
      : OperandRenderer(OR_Register), InsnID(InsnID), TempRegID(TempRegID),
        SubRegIdx(SubReg), IsDef(IsDef) {}

  static bool classof(const OperandRenderer *R) {
    return R->getKind() == OR_TempRegister;
  }

  void emitRenderOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    if (SubRegIdx) {
      assert(!IsDef);
      Table << MatchTable::Opcode("GIR_AddTempSubRegister");
    } else
      Table << MatchTable::Opcode("GIR_AddTempRegister");

    Table << MatchTable::Comment("InsnID") << MatchTable::IntValue(InsnID)
          << MatchTable::Comment("TempRegID") << MatchTable::IntValue(TempRegID)
          << MatchTable::Comment("TempRegFlags");

    if (IsDef)
      Table << MatchTable::NamedValue("RegState::Define");
    else
      Table << MatchTable::IntValue(0);

    if (SubRegIdx)
      Table << MatchTable::NamedValue(SubRegIdx->getQualifiedName());
    Table << MatchTable::LineBreak;
  }
};

/// Adds a specific immediate to the instruction being built.
class ImmRenderer : public OperandRenderer {
protected:
  unsigned InsnID;
  int64_t Imm;

public:
  ImmRenderer(unsigned InsnID, int64_t Imm)
      : OperandRenderer(OR_Imm), InsnID(InsnID), Imm(Imm) {}

  static bool classof(const OperandRenderer *R) {
    return R->getKind() == OR_Imm;
  }

  void emitRenderOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIR_AddImm") << MatchTable::Comment("InsnID")
          << MatchTable::IntValue(InsnID) << MatchTable::Comment("Imm")
          << MatchTable::IntValue(Imm) << MatchTable::LineBreak;
  }
};

/// Adds an enum value for a subreg index to the instruction being built.
class SubRegIndexRenderer : public OperandRenderer {
protected:
  unsigned InsnID;
  const CodeGenSubRegIndex *SubRegIdx;

public:
  SubRegIndexRenderer(unsigned InsnID, const CodeGenSubRegIndex *SRI)
      : OperandRenderer(OR_SubRegIndex), InsnID(InsnID), SubRegIdx(SRI) {}

  static bool classof(const OperandRenderer *R) {
    return R->getKind() == OR_SubRegIndex;
  }

  void emitRenderOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIR_AddImm") << MatchTable::Comment("InsnID")
          << MatchTable::IntValue(InsnID) << MatchTable::Comment("SubRegIndex")
          << MatchTable::IntValue(SubRegIdx->EnumValue)
          << MatchTable::LineBreak;
  }
};

/// Adds operands by calling a renderer function supplied by the ComplexPattern
/// matcher function.
class RenderComplexPatternOperand : public OperandRenderer {
private:
  unsigned InsnID;
  const Record &TheDef;
  /// The name of the operand.
  const StringRef SymbolicName;
  /// The renderer number. This must be unique within a rule since it's used to
  /// identify a temporary variable to hold the renderer function.
  unsigned RendererID;
  /// When provided, this is the suboperand of the ComplexPattern operand to
  /// render. Otherwise all the suboperands will be rendered.
  Optional<unsigned> SubOperand;

  unsigned getNumOperands() const {
    return TheDef.getValueAsDag("Operands")->getNumArgs();
  }

public:
  RenderComplexPatternOperand(unsigned InsnID, const Record &TheDef,
                              StringRef SymbolicName, unsigned RendererID,
                              Optional<unsigned> SubOperand = None)
      : OperandRenderer(OR_ComplexPattern), InsnID(InsnID), TheDef(TheDef),
        SymbolicName(SymbolicName), RendererID(RendererID),
        SubOperand(SubOperand) {}

  static bool classof(const OperandRenderer *R) {
    return R->getKind() == OR_ComplexPattern;
  }

  void emitRenderOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode(SubOperand.hasValue() ? "GIR_ComplexSubOperandRenderer"
                                                      : "GIR_ComplexRenderer")
          << MatchTable::Comment("InsnID") << MatchTable::IntValue(InsnID)
          << MatchTable::Comment("RendererID")
          << MatchTable::IntValue(RendererID);
    if (SubOperand.hasValue())
      Table << MatchTable::Comment("SubOperand")
            << MatchTable::IntValue(SubOperand.getValue());
    Table << MatchTable::Comment(SymbolicName) << MatchTable::LineBreak;
  }
};

class CustomRenderer : public OperandRenderer {
protected:
  unsigned InsnID;
  const Record &Renderer;
  /// The name of the operand.
  const std::string SymbolicName;

public:
  CustomRenderer(unsigned InsnID, const Record &Renderer,
                 StringRef SymbolicName)
      : OperandRenderer(OR_Custom), InsnID(InsnID), Renderer(Renderer),
        SymbolicName(SymbolicName) {}

  static bool classof(const OperandRenderer *R) {
    return R->getKind() == OR_Custom;
  }

  void emitRenderOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    InstructionMatcher &InsnMatcher = Rule.getInstructionMatcher(SymbolicName);
    unsigned OldInsnVarID = Rule.getInsnVarID(InsnMatcher);
    Table << MatchTable::Opcode("GIR_CustomRenderer")
          << MatchTable::Comment("InsnID") << MatchTable::IntValue(InsnID)
          << MatchTable::Comment("OldInsnID")
          << MatchTable::IntValue(OldInsnVarID)
          << MatchTable::Comment("Renderer")
          << MatchTable::NamedValue(
                 "GICR_" + Renderer.getValueAsString("RendererFn").str())
          << MatchTable::Comment(SymbolicName) << MatchTable::LineBreak;
  }
};

class CustomOperandRenderer : public OperandRenderer {
protected:
  unsigned InsnID;
  const Record &Renderer;
  /// The name of the operand.
  const std::string SymbolicName;

public:
  CustomOperandRenderer(unsigned InsnID, const Record &Renderer,
                        StringRef SymbolicName)
      : OperandRenderer(OR_CustomOperand), InsnID(InsnID), Renderer(Renderer),
        SymbolicName(SymbolicName) {}

  static bool classof(const OperandRenderer *R) {
    return R->getKind() == OR_CustomOperand;
  }

  void emitRenderOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    const OperandMatcher &OpdMatcher = Rule.getOperandMatcher(SymbolicName);
    Table << MatchTable::Opcode("GIR_CustomOperandRenderer")
          << MatchTable::Comment("InsnID") << MatchTable::IntValue(InsnID)
          << MatchTable::Comment("OldInsnID")
          << MatchTable::IntValue(OpdMatcher.getInsnVarID())
          << MatchTable::Comment("OpIdx")
          << MatchTable::IntValue(OpdMatcher.getOpIdx())
          << MatchTable::Comment("OperandRenderer")
          << MatchTable::NamedValue(
            "GICR_" + Renderer.getValueAsString("RendererFn").str())
          << MatchTable::Comment(SymbolicName) << MatchTable::LineBreak;
  }
};

/// An action taken when all Matcher predicates succeeded for a parent rule.
///
/// Typical actions include:
/// * Changing the opcode of an instruction.
/// * Adding an operand to an instruction.
class MatchAction {
public:
  virtual ~MatchAction() {}

  /// Emit the MatchTable opcodes to implement the action.
  virtual void emitActionOpcodes(MatchTable &Table,
                                 RuleMatcher &Rule) const = 0;
};

/// Generates a comment describing the matched rule being acted upon.
class DebugCommentAction : public MatchAction {
private:
  std::string S;

public:
  DebugCommentAction(StringRef S) : S(std::string(S)) {}

  void emitActionOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    Table << MatchTable::Comment(S) << MatchTable::LineBreak;
  }
};

/// Generates code to build an instruction or mutate an existing instruction
/// into the desired instruction when this is possible.
class BuildMIAction : public MatchAction {
private:
  unsigned InsnID;
  const CodeGenInstruction *I;
  InstructionMatcher *Matched;
  std::vector<std::unique_ptr<OperandRenderer>> OperandRenderers;

  /// True if the instruction can be built solely by mutating the opcode.
  bool canMutate(RuleMatcher &Rule, const InstructionMatcher *Insn) const {
    if (!Insn)
      return false;

    if (OperandRenderers.size() != Insn->getNumOperands())
      return false;

    for (const auto &Renderer : enumerate(OperandRenderers)) {
      if (const auto *Copy = dyn_cast<CopyRenderer>(&*Renderer.value())) {
        const OperandMatcher &OM = Rule.getOperandMatcher(Copy->getSymbolicName());
        if (Insn != &OM.getInstructionMatcher() ||
            OM.getOpIdx() != Renderer.index())
          return false;
      } else
        return false;
    }

    return true;
  }

public:
  BuildMIAction(unsigned InsnID, const CodeGenInstruction *I)
      : InsnID(InsnID), I(I), Matched(nullptr) {}

  unsigned getInsnID() const { return InsnID; }
  const CodeGenInstruction *getCGI() const { return I; }

  void chooseInsnToMutate(RuleMatcher &Rule) {
    for (auto *MutateCandidate : Rule.mutatable_insns()) {
      if (canMutate(Rule, MutateCandidate)) {
        // Take the first one we're offered that we're able to mutate.
        Rule.reserveInsnMatcherForMutation(MutateCandidate);
        Matched = MutateCandidate;
        return;
      }
    }
  }

  template <class Kind, class... Args>
  Kind &addRenderer(Args&&... args) {
    OperandRenderers.emplace_back(
        std::make_unique<Kind>(InsnID, std::forward<Args>(args)...));
    return *static_cast<Kind *>(OperandRenderers.back().get());
  }

  void emitActionOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    if (Matched) {
      assert(canMutate(Rule, Matched) &&
             "Arranged to mutate an insn that isn't mutatable");

      unsigned RecycleInsnID = Rule.getInsnVarID(*Matched);
      Table << MatchTable::Opcode("GIR_MutateOpcode")
            << MatchTable::Comment("InsnID") << MatchTable::IntValue(InsnID)
            << MatchTable::Comment("RecycleInsnID")
            << MatchTable::IntValue(RecycleInsnID)
            << MatchTable::Comment("Opcode")
            << MatchTable::NamedValue(I->Namespace, I->TheDef->getName())
            << MatchTable::LineBreak;

      if (!I->ImplicitDefs.empty() || !I->ImplicitUses.empty()) {
        for (auto Def : I->ImplicitDefs) {
          auto Namespace = Def->getValue("Namespace")
                               ? Def->getValueAsString("Namespace")
                               : "";
          Table << MatchTable::Opcode("GIR_AddImplicitDef")
                << MatchTable::Comment("InsnID") << MatchTable::IntValue(InsnID)
                << MatchTable::NamedValue(Namespace, Def->getName())
                << MatchTable::LineBreak;
        }
        for (auto Use : I->ImplicitUses) {
          auto Namespace = Use->getValue("Namespace")
                               ? Use->getValueAsString("Namespace")
                               : "";
          Table << MatchTable::Opcode("GIR_AddImplicitUse")
                << MatchTable::Comment("InsnID") << MatchTable::IntValue(InsnID)
                << MatchTable::NamedValue(Namespace, Use->getName())
                << MatchTable::LineBreak;
        }
      }
      return;
    }

    // TODO: Simple permutation looks like it could be almost as common as
    //       mutation due to commutative operations.

    Table << MatchTable::Opcode("GIR_BuildMI") << MatchTable::Comment("InsnID")
          << MatchTable::IntValue(InsnID) << MatchTable::Comment("Opcode")
          << MatchTable::NamedValue(I->Namespace, I->TheDef->getName())
          << MatchTable::LineBreak;
    for (const auto &Renderer : OperandRenderers)
      Renderer->emitRenderOpcodes(Table, Rule);

    if (I->mayLoad || I->mayStore) {
      Table << MatchTable::Opcode("GIR_MergeMemOperands")
            << MatchTable::Comment("InsnID") << MatchTable::IntValue(InsnID)
            << MatchTable::Comment("MergeInsnID's");
      // Emit the ID's for all the instructions that are matched by this rule.
      // TODO: Limit this to matched instructions that mayLoad/mayStore or have
      //       some other means of having a memoperand. Also limit this to
      //       emitted instructions that expect to have a memoperand too. For
      //       example, (G_SEXT (G_LOAD x)) that results in separate load and
      //       sign-extend instructions shouldn't put the memoperand on the
      //       sign-extend since it has no effect there.
      std::vector<unsigned> MergeInsnIDs;
      for (const auto &IDMatcherPair : Rule.defined_insn_vars())
        MergeInsnIDs.push_back(IDMatcherPair.second);
      llvm::sort(MergeInsnIDs);
      for (const auto &MergeInsnID : MergeInsnIDs)
        Table << MatchTable::IntValue(MergeInsnID);
      Table << MatchTable::NamedValue("GIU_MergeMemOperands_EndOfList")
            << MatchTable::LineBreak;
    }

    // FIXME: This is a hack but it's sufficient for ISel. We'll need to do
    //        better for combines. Particularly when there are multiple match
    //        roots.
    if (InsnID == 0)
      Table << MatchTable::Opcode("GIR_EraseFromParent")
            << MatchTable::Comment("InsnID") << MatchTable::IntValue(InsnID)
            << MatchTable::LineBreak;
  }
};

/// Generates code to constrain the operands of an output instruction to the
/// register classes specified by the definition of that instruction.
class ConstrainOperandsToDefinitionAction : public MatchAction {
  unsigned InsnID;

public:
  ConstrainOperandsToDefinitionAction(unsigned InsnID) : InsnID(InsnID) {}

  void emitActionOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIR_ConstrainSelectedInstOperands")
          << MatchTable::Comment("InsnID") << MatchTable::IntValue(InsnID)
          << MatchTable::LineBreak;
  }
};

/// Generates code to constrain the specified operand of an output instruction
/// to the specified register class.
class ConstrainOperandToRegClassAction : public MatchAction {
  unsigned InsnID;
  unsigned OpIdx;
  const CodeGenRegisterClass &RC;

public:
  ConstrainOperandToRegClassAction(unsigned InsnID, unsigned OpIdx,
                                   const CodeGenRegisterClass &RC)
      : InsnID(InsnID), OpIdx(OpIdx), RC(RC) {}

  void emitActionOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIR_ConstrainOperandRC")
          << MatchTable::Comment("InsnID") << MatchTable::IntValue(InsnID)
          << MatchTable::Comment("Op") << MatchTable::IntValue(OpIdx)
          << MatchTable::NamedValue(RC.getQualifiedName() + "RegClassID")
          << MatchTable::LineBreak;
  }
};

/// Generates code to create a temporary register which can be used to chain
/// instructions together.
class MakeTempRegisterAction : public MatchAction {
private:
  LLTCodeGen Ty;
  unsigned TempRegID;

public:
  MakeTempRegisterAction(const LLTCodeGen &Ty, unsigned TempRegID)
      : Ty(Ty), TempRegID(TempRegID) {
    KnownTypes.insert(Ty);
  }

  void emitActionOpcodes(MatchTable &Table, RuleMatcher &Rule) const override {
    Table << MatchTable::Opcode("GIR_MakeTempReg")
          << MatchTable::Comment("TempRegID") << MatchTable::IntValue(TempRegID)
          << MatchTable::Comment("TypeID")
          << MatchTable::NamedValue(Ty.getCxxEnumValue())
          << MatchTable::LineBreak;
  }
};

InstructionMatcher &RuleMatcher::addInstructionMatcher(StringRef SymbolicName) {
  Matchers.emplace_back(new InstructionMatcher(*this, SymbolicName));
  MutatableInsns.insert(Matchers.back().get());
  return *Matchers.back();
}

void RuleMatcher::addRequiredFeature(Record *Feature) {
  RequiredFeatures.push_back(Feature);
}

const std::vector<Record *> &RuleMatcher::getRequiredFeatures() const {
  return RequiredFeatures;
}

// Emplaces an action of the specified Kind at the end of the action list.
//
// Returns a reference to the newly created action.
//
// Like std::vector::emplace_back(), may invalidate all iterators if the new
// size exceeds the capacity. Otherwise, only invalidates the past-the-end
// iterator.
template <class Kind, class... Args>
Kind &RuleMatcher::addAction(Args &&... args) {
  Actions.emplace_back(std::make_unique<Kind>(std::forward<Args>(args)...));
  return *static_cast<Kind *>(Actions.back().get());
}

// Emplaces an action of the specified Kind before the given insertion point.
//
// Returns an iterator pointing at the newly created instruction.
//
// Like std::vector::insert(), may invalidate all iterators if the new size
// exceeds the capacity. Otherwise, only invalidates the iterators from the
// insertion point onwards.
template <class Kind, class... Args>
action_iterator RuleMatcher::insertAction(action_iterator InsertPt,
                                          Args &&... args) {
  return Actions.emplace(InsertPt,
                         std::make_unique<Kind>(std::forward<Args>(args)...));
}

unsigned RuleMatcher::implicitlyDefineInsnVar(InstructionMatcher &Matcher) {
  unsigned NewInsnVarID = NextInsnVarID++;
  InsnVariableIDs[&Matcher] = NewInsnVarID;
  return NewInsnVarID;
}

unsigned RuleMatcher::getInsnVarID(InstructionMatcher &InsnMatcher) const {
  const auto &I = InsnVariableIDs.find(&InsnMatcher);
  if (I != InsnVariableIDs.end())
    return I->second;
  llvm_unreachable("Matched Insn was not captured in a local variable");
}

void RuleMatcher::defineOperand(StringRef SymbolicName, OperandMatcher &OM) {
  if (DefinedOperands.find(SymbolicName) == DefinedOperands.end()) {
    DefinedOperands[SymbolicName] = &OM;
    return;
  }

  // If the operand is already defined, then we must ensure both references in
  // the matcher have the exact same node.
  OM.addPredicate<SameOperandMatcher>(OM.getSymbolicName());
}

void RuleMatcher::definePhysRegOperand(Record *Reg, OperandMatcher &OM) {
  if (PhysRegOperands.find(Reg) == PhysRegOperands.end()) {
    PhysRegOperands[Reg] = &OM;
    return;
  }
}

InstructionMatcher &
RuleMatcher::getInstructionMatcher(StringRef SymbolicName) const {
  for (const auto &I : InsnVariableIDs)
    if (I.first->getSymbolicName() == SymbolicName)
      return *I.first;
  llvm_unreachable(
      ("Failed to lookup instruction " + SymbolicName).str().c_str());
}

const OperandMatcher &
RuleMatcher::getPhysRegOperandMatcher(Record *Reg) const {
  const auto &I = PhysRegOperands.find(Reg);

  if (I == PhysRegOperands.end()) {
    PrintFatalError(SrcLoc, "Register " + Reg->getName() +
                    " was not declared in matcher");
  }

  return *I->second;
}

const OperandMatcher &
RuleMatcher::getOperandMatcher(StringRef Name) const {
  const auto &I = DefinedOperands.find(Name);

  if (I == DefinedOperands.end())
    PrintFatalError(SrcLoc, "Operand " + Name + " was not declared in matcher");

  return *I->second;
}

void RuleMatcher::emit(MatchTable &Table) {
  if (Matchers.empty())
    llvm_unreachable("Unexpected empty matcher!");

  // The representation supports rules that require multiple roots such as:
  //    %ptr(p0) = ...
  //    %elt0(s32) = G_LOAD %ptr
  //    %1(p0) = G_ADD %ptr, 4
  //    %elt1(s32) = G_LOAD p0 %1
  // which could be usefully folded into:
  //    %ptr(p0) = ...
  //    %elt0(s32), %elt1(s32) = TGT_LOAD_PAIR %ptr
  // on some targets but we don't need to make use of that yet.
  assert(Matchers.size() == 1 && "Cannot handle multi-root matchers yet");

  unsigned LabelID = Table.allocateLabelID();
  Table << MatchTable::Opcode("GIM_Try", +1)
        << MatchTable::Comment("On fail goto")
        << MatchTable::JumpTarget(LabelID)
        << MatchTable::Comment(("Rule ID " + Twine(RuleID) + " //").str())
        << MatchTable::LineBreak;

  if (!RequiredFeatures.empty()) {
    Table << MatchTable::Opcode("GIM_CheckFeatures")
          << MatchTable::NamedValue(getNameForFeatureBitset(RequiredFeatures))
          << MatchTable::LineBreak;
  }

  Matchers.front()->emitPredicateOpcodes(Table, *this);

  // We must also check if it's safe to fold the matched instructions.
  if (InsnVariableIDs.size() >= 2) {
    // Invert the map to create stable ordering (by var names)
    SmallVector<unsigned, 2> InsnIDs;
    for (const auto &Pair : InsnVariableIDs) {
      // Skip the root node since it isn't moving anywhere. Everything else is
      // sinking to meet it.
      if (Pair.first == Matchers.front().get())
        continue;

      InsnIDs.push_back(Pair.second);
    }
    llvm::sort(InsnIDs);

    for (const auto &InsnID : InsnIDs) {
      // Reject the difficult cases until we have a more accurate check.
      Table << MatchTable::Opcode("GIM_CheckIsSafeToFold")
            << MatchTable::Comment("InsnID") << MatchTable::IntValue(InsnID)
            << MatchTable::LineBreak;

      // FIXME: Emit checks to determine it's _actually_ safe to fold and/or
      //        account for unsafe cases.
      //
      //        Example:
      //          MI1--> %0 = ...
      //                 %1 = ... %0
      //          MI0--> %2 = ... %0
      //          It's not safe to erase MI1. We currently handle this by not
      //          erasing %0 (even when it's dead).
      //
      //        Example:
      //          MI1--> %0 = load volatile @a
      //                 %1 = load volatile @a
      //          MI0--> %2 = ... %0
      //          It's not safe to sink %0's def past %1. We currently handle
      //          this by rejecting all loads.
      //
      //        Example:
      //          MI1--> %0 = load @a
      //                 %1 = store @a
      //          MI0--> %2 = ... %0
      //          It's not safe to sink %0's def past %1. We currently handle
      //          this by rejecting all loads.
      //
      //        Example:
      //                   G_CONDBR %cond, @BB1
      //                 BB0:
      //          MI1-->   %0 = load @a
      //                   G_BR @BB1
      //                 BB1:
      //          MI0-->   %2 = ... %0
      //          It's not always safe to sink %0 across control flow. In this
      //          case it may introduce a memory fault. We currentl handle this
      //          by rejecting all loads.
    }
  }

  for (const auto &PM : EpilogueMatchers)
    PM->emitPredicateOpcodes(Table, *this);

  for (const auto &MA : Actions)
    MA->emitActionOpcodes(Table, *this);

  if (Table.isWithCoverage())
    Table << MatchTable::Opcode("GIR_Coverage") << MatchTable::IntValue(RuleID)
          << MatchTable::LineBreak;
  else
    Table << MatchTable::Comment(("GIR_Coverage, " + Twine(RuleID) + ",").str())
          << MatchTable::LineBreak;

  Table << MatchTable::Opcode("GIR_Done", -1) << MatchTable::LineBreak
        << MatchTable::Label(LabelID);
  ++NumPatternEmitted;
}

bool RuleMatcher::isHigherPriorityThan(const RuleMatcher &B) const {
  // Rules involving more match roots have higher priority.
  if (Matchers.size() > B.Matchers.size())
    return true;
  if (Matchers.size() < B.Matchers.size())
    return false;

  for (auto Matcher : zip(Matchers, B.Matchers)) {
    if (std::get<0>(Matcher)->isHigherPriorityThan(*std::get<1>(Matcher)))
      return true;
    if (std::get<1>(Matcher)->isHigherPriorityThan(*std::get<0>(Matcher)))
      return false;
  }

  return false;
}

unsigned RuleMatcher::countRendererFns() const {
  return std::accumulate(
      Matchers.begin(), Matchers.end(), 0,
      [](unsigned A, const std::unique_ptr<InstructionMatcher> &Matcher) {
        return A + Matcher->countRendererFns();
      });
}

bool OperandPredicateMatcher::isHigherPriorityThan(
    const OperandPredicateMatcher &B) const {
  // Generally speaking, an instruction is more important than an Int or a
  // LiteralInt because it can cover more nodes but theres an exception to
  // this. G_CONSTANT's are less important than either of those two because they
  // are more permissive.

  const InstructionOperandMatcher *AOM =
      dyn_cast<InstructionOperandMatcher>(this);
  const InstructionOperandMatcher *BOM =
      dyn_cast<InstructionOperandMatcher>(&B);
  bool AIsConstantInsn = AOM && AOM->getInsnMatcher().isConstantInstruction();
  bool BIsConstantInsn = BOM && BOM->getInsnMatcher().isConstantInstruction();

  if (AOM && BOM) {
    // The relative priorities between a G_CONSTANT and any other instruction
    // don't actually matter but this code is needed to ensure a strict weak
    // ordering. This is particularly important on Windows where the rules will
    // be incorrectly sorted without it.
    if (AIsConstantInsn != BIsConstantInsn)
      return AIsConstantInsn < BIsConstantInsn;
    return false;
  }

  if (AOM && AIsConstantInsn && (B.Kind == OPM_Int || B.Kind == OPM_LiteralInt))
    return false;
  if (BOM && BIsConstantInsn && (Kind == OPM_Int || Kind == OPM_LiteralInt))
    return true;

  return Kind < B.Kind;
}

void SameOperandMatcher::emitPredicateOpcodes(MatchTable &Table,
                                              RuleMatcher &Rule) const {
  const OperandMatcher &OtherOM = Rule.getOperandMatcher(MatchingName);
  unsigned OtherInsnVarID = Rule.getInsnVarID(OtherOM.getInstructionMatcher());
  assert(OtherInsnVarID == OtherOM.getInstructionMatcher().getInsnVarID());

  Table << MatchTable::Opcode("GIM_CheckIsSameOperand")
        << MatchTable::Comment("MI") << MatchTable::IntValue(InsnVarID)
        << MatchTable::Comment("OpIdx") << MatchTable::IntValue(OpIdx)
        << MatchTable::Comment("OtherMI")
        << MatchTable::IntValue(OtherInsnVarID)
        << MatchTable::Comment("OtherOpIdx")
        << MatchTable::IntValue(OtherOM.getOpIdx())
        << MatchTable::LineBreak;
}

//===- GlobalISelEmitter class --------------------------------------------===//

static Expected<LLTCodeGen> getInstResultType(const TreePatternNode *Dst) {
  ArrayRef<TypeSetByHwMode> ChildTypes = Dst->getExtTypes();
  if (ChildTypes.size() != 1)
    return failedImport("Dst pattern child has multiple results");

  Optional<LLTCodeGen> MaybeOpTy;
  if (ChildTypes.front().isMachineValueType()) {
    MaybeOpTy =
      MVTToLLT(ChildTypes.front().getMachineValueType().SimpleTy);
  }

  if (!MaybeOpTy)
    return failedImport("Dst operand has an unsupported type");
  return *MaybeOpTy;
}

class GlobalISelEmitter {
public:
  explicit GlobalISelEmitter(RecordKeeper &RK);
  void run(raw_ostream &OS);

private:
  const RecordKeeper &RK;
  const CodeGenDAGPatterns CGP;
  const CodeGenTarget &Target;
  CodeGenRegBank &CGRegs;

  /// Keep track of the equivalence between SDNodes and Instruction by mapping
  /// SDNodes to the GINodeEquiv mapping. We need to map to the GINodeEquiv to
  /// check for attributes on the relation such as CheckMMOIsNonAtomic.
  /// This is defined using 'GINodeEquiv' in the target description.
  DenseMap<Record *, Record *> NodeEquivs;

  /// Keep track of the equivalence between ComplexPattern's and
  /// GIComplexOperandMatcher. Map entries are specified by subclassing
  /// GIComplexPatternEquiv.
  DenseMap<const Record *, const Record *> ComplexPatternEquivs;

  /// Keep track of the equivalence between SDNodeXForm's and
  /// GICustomOperandRenderer. Map entries are specified by subclassing
  /// GISDNodeXFormEquiv.
  DenseMap<const Record *, const Record *> SDNodeXFormEquivs;

  /// Keep track of Scores of PatternsToMatch similar to how the DAG does.
  /// This adds compatibility for RuleMatchers to use this for ordering rules.
  DenseMap<uint64_t, int> RuleMatcherScores;

  // Map of predicates to their subtarget features.
  SubtargetFeatureInfoMap SubtargetFeatures;

  // Rule coverage information.
  Optional<CodeGenCoverage> RuleCoverage;

  void gatherOpcodeValues();
  void gatherTypeIDValues();
  void gatherNodeEquivs();

  Record *findNodeEquiv(Record *N) const;
  const CodeGenInstruction *getEquivNode(Record &Equiv,
                                         const TreePatternNode *N) const;

  Error importRulePredicates(RuleMatcher &M, ArrayRef<Predicate> Predicates);
  Expected<InstructionMatcher &>
  createAndImportSelDAGMatcher(RuleMatcher &Rule,
                               InstructionMatcher &InsnMatcher,
                               const TreePatternNode *Src, unsigned &TempOpIdx);
  Error importComplexPatternOperandMatcher(OperandMatcher &OM, Record *R,
                                           unsigned &TempOpIdx) const;
  Error importChildMatcher(RuleMatcher &Rule, InstructionMatcher &InsnMatcher,
                           const TreePatternNode *SrcChild,
                           bool OperandIsAPointer, bool OperandIsImmArg,
                           unsigned OpIdx, unsigned &TempOpIdx);

  Expected<BuildMIAction &> createAndImportInstructionRenderer(
      RuleMatcher &M, InstructionMatcher &InsnMatcher,
      const TreePatternNode *Src, const TreePatternNode *Dst);
  Expected<action_iterator> createAndImportSubInstructionRenderer(
      action_iterator InsertPt, RuleMatcher &M, const TreePatternNode *Dst,
      unsigned TempReg);
  Expected<action_iterator>
  createInstructionRenderer(action_iterator InsertPt, RuleMatcher &M,
                            const TreePatternNode *Dst);
  void importExplicitDefRenderers(BuildMIAction &DstMIBuilder);

  Expected<action_iterator>
  importExplicitUseRenderers(action_iterator InsertPt, RuleMatcher &M,
                             BuildMIAction &DstMIBuilder,
                             const llvm::TreePatternNode *Dst);
  Expected<action_iterator>
  importExplicitUseRenderer(action_iterator InsertPt, RuleMatcher &Rule,
                            BuildMIAction &DstMIBuilder,
                            TreePatternNode *DstChild);
  Error importDefaultOperandRenderers(action_iterator InsertPt, RuleMatcher &M,
                                      BuildMIAction &DstMIBuilder,
                                      DagInit *DefaultOps) const;
  Error
  importImplicitDefRenderers(BuildMIAction &DstMIBuilder,
                             const std::vector<Record *> &ImplicitDefs) const;

  void emitCxxPredicateFns(raw_ostream &OS, StringRef CodeFieldName,
                           StringRef TypeIdentifier, StringRef ArgType,
                           StringRef ArgName, StringRef AdditionalDeclarations,
                           std::function<bool(const Record *R)> Filter);
  void emitImmPredicateFns(raw_ostream &OS, StringRef TypeIdentifier,
                           StringRef ArgType,
                           std::function<bool(const Record *R)> Filter);
  void emitMIPredicateFns(raw_ostream &OS);

  /// Analyze pattern \p P, returning a matcher for it if possible.
  /// Otherwise, return an Error explaining why we don't support it.
  Expected<RuleMatcher> runOnPattern(const PatternToMatch &P);

  void declareSubtargetFeature(Record *Predicate);

  MatchTable buildMatchTable(MutableArrayRef<RuleMatcher> Rules, bool Optimize,
                             bool WithCoverage);

  /// Infer a CodeGenRegisterClass for the type of \p SuperRegNode. The returned
  /// CodeGenRegisterClass will support the CodeGenRegisterClass of
  /// \p SubRegNode, and the subregister index defined by \p SubRegIdxNode.
  /// If no register class is found, return None.
  Optional<const CodeGenRegisterClass *>
  inferSuperRegisterClassForNode(const TypeSetByHwMode &Ty,
                                 TreePatternNode *SuperRegNode,
                                 TreePatternNode *SubRegIdxNode);
  Optional<CodeGenSubRegIndex *>
  inferSubRegIndexForNode(TreePatternNode *SubRegIdxNode);

  /// Infer a CodeGenRegisterClass which suppoorts \p Ty and \p SubRegIdxNode.
  /// Return None if no such class exists.
  Optional<const CodeGenRegisterClass *>
  inferSuperRegisterClass(const TypeSetByHwMode &Ty,
                          TreePatternNode *SubRegIdxNode);

  /// Return the CodeGenRegisterClass associated with \p Leaf if it has one.
  Optional<const CodeGenRegisterClass *>
  getRegClassFromLeaf(TreePatternNode *Leaf);

  /// Return a CodeGenRegisterClass for \p N if one can be found. Return None
  /// otherwise.
  Optional<const CodeGenRegisterClass *>
  inferRegClassFromPattern(TreePatternNode *N);

public:
  /// Takes a sequence of \p Rules and group them based on the predicates
  /// they share. \p MatcherStorage is used as a memory container
  /// for the group that are created as part of this process.
  ///
  /// What this optimization does looks like if GroupT = GroupMatcher:
  /// Output without optimization:
  /// \verbatim
  /// # R1
  ///  # predicate A
  ///  # predicate B
  ///  ...
  /// # R2
  ///  # predicate A // <-- effectively this is going to be checked twice.
  ///                //     Once in R1 and once in R2.
  ///  # predicate C
  /// \endverbatim
  /// Output with optimization:
  /// \verbatim
  /// # Group1_2
  ///  # predicate A // <-- Check is now shared.
  ///  # R1
  ///   # predicate B
  ///  # R2
  ///   # predicate C
  /// \endverbatim
  template <class GroupT>
  static std::vector<Matcher *> optimizeRules(
      ArrayRef<Matcher *> Rules,
      std::vector<std::unique_ptr<Matcher>> &MatcherStorage);
};

void GlobalISelEmitter::gatherOpcodeValues() {
  InstructionOpcodeMatcher::initOpcodeValuesMap(Target);
}

void GlobalISelEmitter::gatherTypeIDValues() {
  LLTOperandMatcher::initTypeIDValuesMap();
}

void GlobalISelEmitter::gatherNodeEquivs() {
  assert(NodeEquivs.empty());
  for (Record *Equiv : RK.getAllDerivedDefinitions("GINodeEquiv"))
    NodeEquivs[Equiv->getValueAsDef("Node")] = Equiv;

  assert(ComplexPatternEquivs.empty());
  for (Record *Equiv : RK.getAllDerivedDefinitions("GIComplexPatternEquiv")) {
    Record *SelDAGEquiv = Equiv->getValueAsDef("SelDAGEquivalent");
    if (!SelDAGEquiv)
      continue;
    ComplexPatternEquivs[SelDAGEquiv] = Equiv;
 }

 assert(SDNodeXFormEquivs.empty());
 for (Record *Equiv : RK.getAllDerivedDefinitions("GISDNodeXFormEquiv")) {
   Record *SelDAGEquiv = Equiv->getValueAsDef("SelDAGEquivalent");
   if (!SelDAGEquiv)
     continue;
   SDNodeXFormEquivs[SelDAGEquiv] = Equiv;
 }
}

Record *GlobalISelEmitter::findNodeEquiv(Record *N) const {
  return NodeEquivs.lookup(N);
}

const CodeGenInstruction *
GlobalISelEmitter::getEquivNode(Record &Equiv, const TreePatternNode *N) const {
  if (N->getNumChildren() >= 1) {
    // setcc operation maps to two different G_* instructions based on the type.
    if (!Equiv.isValueUnset("IfFloatingPoint") &&
        MVT(N->getChild(0)->getSimpleType(0)).isFloatingPoint())
      return &Target.getInstruction(Equiv.getValueAsDef("IfFloatingPoint"));
  }

  for (const TreePredicateCall &Call : N->getPredicateCalls()) {
    const TreePredicateFn &Predicate = Call.Fn;
    if (!Equiv.isValueUnset("IfSignExtend") && Predicate.isLoad() &&
        Predicate.isSignExtLoad())
      return &Target.getInstruction(Equiv.getValueAsDef("IfSignExtend"));
    if (!Equiv.isValueUnset("IfZeroExtend") && Predicate.isLoad() &&
        Predicate.isZeroExtLoad())
      return &Target.getInstruction(Equiv.getValueAsDef("IfZeroExtend"));
  }

  return &Target.getInstruction(Equiv.getValueAsDef("I"));
}

GlobalISelEmitter::GlobalISelEmitter(RecordKeeper &RK)
    : RK(RK), CGP(RK), Target(CGP.getTargetInfo()),
      CGRegs(Target.getRegBank()) {}

//===- Emitter ------------------------------------------------------------===//

Error
GlobalISelEmitter::importRulePredicates(RuleMatcher &M,
                                        ArrayRef<Predicate> Predicates) {
  for (const Predicate &P : Predicates) {
    if (!P.Def || P.getCondString().empty())
      continue;
    declareSubtargetFeature(P.Def);
    M.addRequiredFeature(P.Def);
  }

  return Error::success();
}

Expected<InstructionMatcher &> GlobalISelEmitter::createAndImportSelDAGMatcher(
    RuleMatcher &Rule, InstructionMatcher &InsnMatcher,
    const TreePatternNode *Src, unsigned &TempOpIdx) {
  Record *SrcGIEquivOrNull = nullptr;
  const CodeGenInstruction *SrcGIOrNull = nullptr;

  // Start with the defined operands (i.e., the results of the root operator).
  if (Src->getExtTypes().size() > 1)
    return failedImport("Src pattern has multiple results");

  if (Src->isLeaf()) {
    Init *SrcInit = Src->getLeafValue();
    if (isa<IntInit>(SrcInit)) {
      InsnMatcher.addPredicate<InstructionOpcodeMatcher>(
          &Target.getInstruction(RK.getDef("G_CONSTANT")));
    } else
      return failedImport(
          "Unable to deduce gMIR opcode to handle Src (which is a leaf)");
  } else {
    SrcGIEquivOrNull = findNodeEquiv(Src->getOperator());
    if (!SrcGIEquivOrNull)
      return failedImport("Pattern operator lacks an equivalent Instruction" +
                          explainOperator(Src->getOperator()));
    SrcGIOrNull = getEquivNode(*SrcGIEquivOrNull, Src);

    // The operators look good: match the opcode
    InsnMatcher.addPredicate<InstructionOpcodeMatcher>(SrcGIOrNull);
  }

  unsigned OpIdx = 0;
  for (const TypeSetByHwMode &VTy : Src->getExtTypes()) {
    // Results don't have a name unless they are the root node. The caller will
    // set the name if appropriate.
    OperandMatcher &OM = InsnMatcher.addOperand(OpIdx++, "", TempOpIdx);
    if (auto Error = OM.addTypeCheckPredicate(VTy, false /* OperandIsAPointer */))
      return failedImport(toString(std::move(Error)) +
                          " for result of Src pattern operator");
  }

  for (const TreePredicateCall &Call : Src->getPredicateCalls()) {
    const TreePredicateFn &Predicate = Call.Fn;
    if (Predicate.isAlwaysTrue())
      continue;

    if (Predicate.isImmediatePattern()) {
      InsnMatcher.addPredicate<InstructionImmPredicateMatcher>(Predicate);
      continue;
    }

    // An address space check is needed in all contexts if there is one.
    if (Predicate.isLoad() || Predicate.isStore() || Predicate.isAtomic()) {
      if (const ListInit *AddrSpaces = Predicate.getAddressSpaces()) {
        SmallVector<unsigned, 4> ParsedAddrSpaces;

        for (Init *Val : AddrSpaces->getValues()) {
          IntInit *IntVal = dyn_cast<IntInit>(Val);
          if (!IntVal)
            return failedImport("Address space is not an integer");
          ParsedAddrSpaces.push_back(IntVal->getValue());
        }

        if (!ParsedAddrSpaces.empty()) {
          InsnMatcher.addPredicate<MemoryAddressSpacePredicateMatcher>(
            0, ParsedAddrSpaces);
        }
      }

      int64_t MinAlign = Predicate.getMinAlignment();
      if (MinAlign > 0)
        InsnMatcher.addPredicate<MemoryAlignmentPredicateMatcher>(0, MinAlign);
    }

    // G_LOAD is used for both non-extending and any-extending loads.
    if (Predicate.isLoad() && Predicate.isNonExtLoad()) {
      InsnMatcher.addPredicate<MemoryVsLLTSizePredicateMatcher>(
          0, MemoryVsLLTSizePredicateMatcher::EqualTo, 0);
      continue;
    }
    if (Predicate.isLoad() && Predicate.isAnyExtLoad()) {
      InsnMatcher.addPredicate<MemoryVsLLTSizePredicateMatcher>(
          0, MemoryVsLLTSizePredicateMatcher::LessThan, 0);
      continue;
    }

    if (Predicate.isStore()) {
      if (Predicate.isTruncStore()) {
        // FIXME: If MemoryVT is set, we end up with 2 checks for the MMO size.
        InsnMatcher.addPredicate<MemoryVsLLTSizePredicateMatcher>(
            0, MemoryVsLLTSizePredicateMatcher::LessThan, 0);
        continue;
      }
      if (Predicate.isNonTruncStore()) {
        // We need to check the sizes match here otherwise we could incorrectly
        // match truncating stores with non-truncating ones.
        InsnMatcher.addPredicate<MemoryVsLLTSizePredicateMatcher>(
            0, MemoryVsLLTSizePredicateMatcher::EqualTo, 0);
      }
    }

    // No check required. We already did it by swapping the opcode.
    if (!SrcGIEquivOrNull->isValueUnset("IfSignExtend") &&
        Predicate.isSignExtLoad())
      continue;

    // No check required. We already did it by swapping the opcode.
    if (!SrcGIEquivOrNull->isValueUnset("IfZeroExtend") &&
        Predicate.isZeroExtLoad())
      continue;

    // No check required. G_STORE by itself is a non-extending store.
    if (Predicate.isNonTruncStore())
      continue;

    if (Predicate.isLoad() || Predicate.isStore() || Predicate.isAtomic()) {
      if (Predicate.getMemoryVT() != nullptr) {
        Optional<LLTCodeGen> MemTyOrNone =
            MVTToLLT(getValueType(Predicate.getMemoryVT()));

        if (!MemTyOrNone)
          return failedImport("MemVT could not be converted to LLT");

        // MMO's work in bytes so we must take care of unusual types like i1
        // don't round down.
        unsigned MemSizeInBits =
            llvm::alignTo(MemTyOrNone->get().getSizeInBits(), 8);

        InsnMatcher.addPredicate<MemorySizePredicateMatcher>(
            0, MemSizeInBits / 8);
        continue;
      }
    }

    if (Predicate.isLoad() || Predicate.isStore()) {
      // No check required. A G_LOAD/G_STORE is an unindexed load.
      if (Predicate.isUnindexed())
        continue;
    }

    if (Predicate.isAtomic()) {
      if (Predicate.isAtomicOrderingMonotonic()) {
        InsnMatcher.addPredicate<AtomicOrderingMMOPredicateMatcher>(
            "Monotonic");
        continue;
      }
      if (Predicate.isAtomicOrderingAcquire()) {
        InsnMatcher.addPredicate<AtomicOrderingMMOPredicateMatcher>("Acquire");
        continue;
      }
      if (Predicate.isAtomicOrderingRelease()) {
        InsnMatcher.addPredicate<AtomicOrderingMMOPredicateMatcher>("Release");
        continue;
      }
      if (Predicate.isAtomicOrderingAcquireRelease()) {
        InsnMatcher.addPredicate<AtomicOrderingMMOPredicateMatcher>(
            "AcquireRelease");
        continue;
      }
      if (Predicate.isAtomicOrderingSequentiallyConsistent()) {
        InsnMatcher.addPredicate<AtomicOrderingMMOPredicateMatcher>(
            "SequentiallyConsistent");
        continue;
      }

      if (Predicate.isAtomicOrderingAcquireOrStronger()) {
        InsnMatcher.addPredicate<AtomicOrderingMMOPredicateMatcher>(
            "Acquire", AtomicOrderingMMOPredicateMatcher::AO_OrStronger);
        continue;
      }
      if (Predicate.isAtomicOrderingWeakerThanAcquire()) {
        InsnMatcher.addPredicate<AtomicOrderingMMOPredicateMatcher>(
            "Acquire", AtomicOrderingMMOPredicateMatcher::AO_WeakerThan);
        continue;
      }

      if (Predicate.isAtomicOrderingReleaseOrStronger()) {
        InsnMatcher.addPredicate<AtomicOrderingMMOPredicateMatcher>(
            "Release", AtomicOrderingMMOPredicateMatcher::AO_OrStronger);
        continue;
      }
      if (Predicate.isAtomicOrderingWeakerThanRelease()) {
        InsnMatcher.addPredicate<AtomicOrderingMMOPredicateMatcher>(
            "Release", AtomicOrderingMMOPredicateMatcher::AO_WeakerThan);
        continue;
      }
    }

    if (Predicate.hasGISelPredicateCode()) {
      InsnMatcher.addPredicate<GenericInstructionPredicateMatcher>(Predicate);
      continue;
    }

    return failedImport("Src pattern child has predicate (" +
                        explainPredicates(Src) + ")");
  }
  if (SrcGIEquivOrNull && SrcGIEquivOrNull->getValueAsBit("CheckMMOIsNonAtomic"))
    InsnMatcher.addPredicate<AtomicOrderingMMOPredicateMatcher>("NotAtomic");
  else if (SrcGIEquivOrNull && SrcGIEquivOrNull->getValueAsBit("CheckMMOIsAtomic")) {
    InsnMatcher.addPredicate<AtomicOrderingMMOPredicateMatcher>(
      "Unordered", AtomicOrderingMMOPredicateMatcher::AO_OrStronger);
  }

  if (Src->isLeaf()) {
    Init *SrcInit = Src->getLeafValue();
    if (IntInit *SrcIntInit = dyn_cast<IntInit>(SrcInit)) {
      OperandMatcher &OM =
          InsnMatcher.addOperand(OpIdx++, Src->getName(), TempOpIdx);
      OM.addPredicate<LiteralIntOperandMatcher>(SrcIntInit->getValue());
    } else
      return failedImport(
          "Unable to deduce gMIR opcode to handle Src (which is a leaf)");
  } else {
    assert(SrcGIOrNull &&
           "Expected to have already found an equivalent Instruction");
    if (SrcGIOrNull->TheDef->getName() == "G_CONSTANT" ||
        SrcGIOrNull->TheDef->getName() == "G_FCONSTANT") {
      // imm/fpimm still have operands but we don't need to do anything with it
      // here since we don't support ImmLeaf predicates yet. However, we still
      // need to note the hidden operand to get GIM_CheckNumOperands correct.
      InsnMatcher.addOperand(OpIdx++, "", TempOpIdx);
      return InsnMatcher;
    }

    // Special case because the operand order is changed from setcc. The
    // predicate operand needs to be swapped from the last operand to the first
    // source.

    unsigned NumChildren = Src->getNumChildren();
    bool IsFCmp = SrcGIOrNull->TheDef->getName() == "G_FCMP";

    if (IsFCmp || SrcGIOrNull->TheDef->getName() == "G_ICMP") {
      TreePatternNode *SrcChild = Src->getChild(NumChildren - 1);
      if (SrcChild->isLeaf()) {
        DefInit *DI = dyn_cast<DefInit>(SrcChild->getLeafValue());
        Record *CCDef = DI ? DI->getDef() : nullptr;
        if (!CCDef || !CCDef->isSubClassOf("CondCode"))
          return failedImport("Unable to handle CondCode");

        OperandMatcher &OM =
          InsnMatcher.addOperand(OpIdx++, SrcChild->getName(), TempOpIdx);
        StringRef PredType = IsFCmp ? CCDef->getValueAsString("FCmpPredicate") :
                                      CCDef->getValueAsString("ICmpPredicate");

        if (!PredType.empty()) {
          OM.addPredicate<CmpPredicateOperandMatcher>(std::string(PredType));
          // Process the other 2 operands normally.
          --NumChildren;
        }
      }
    }

    // Match the used operands (i.e. the children of the operator).
    bool IsIntrinsic =
        SrcGIOrNull->TheDef->getName() == "G_INTRINSIC" ||
        SrcGIOrNull->TheDef->getName() == "G_INTRINSIC_W_SIDE_EFFECTS";
    const CodeGenIntrinsic *II = Src->getIntrinsicInfo(CGP);
    if (IsIntrinsic && !II)
      return failedImport("Expected IntInit containing intrinsic ID)");

    for (unsigned i = 0; i != NumChildren; ++i) {
      TreePatternNode *SrcChild = Src->getChild(i);

      // We need to determine the meaning of a literal integer based on the
      // context. If this is a field required to be an immediate (such as an
      // immarg intrinsic argument), the required predicates are different than
      // a constant which may be materialized in a register. If we have an
      // argument that is required to be an immediate, we should not emit an LLT
      // type check, and should not be looking for a G_CONSTANT defined
      // register.
      bool OperandIsImmArg = SrcGIOrNull->isOperandImmArg(i);

      // SelectionDAG allows pointers to be represented with iN since it doesn't
      // distinguish between pointers and integers but they are different types in GlobalISel.
      // Coerce integers to pointers to address space 0 if the context indicates a pointer.
      //
      bool OperandIsAPointer = SrcGIOrNull->isOperandAPointer(i);

      if (IsIntrinsic) {
        // For G_INTRINSIC/G_INTRINSIC_W_SIDE_EFFECTS, the operand immediately
        // following the defs is an intrinsic ID.
        if (i == 0) {
          OperandMatcher &OM =
              InsnMatcher.addOperand(OpIdx++, SrcChild->getName(), TempOpIdx);
          OM.addPredicate<IntrinsicIDOperandMatcher>(II);
          continue;
        }

        // We have to check intrinsics for llvm_anyptr_ty and immarg parameters.
        //
        // Note that we have to look at the i-1th parameter, because we don't
        // have the intrinsic ID in the intrinsic's parameter list.
        OperandIsAPointer |= II->isParamAPointer(i - 1);
        OperandIsImmArg |= II->isParamImmArg(i - 1);
      }

      if (auto Error =
              importChildMatcher(Rule, InsnMatcher, SrcChild, OperandIsAPointer,
                                 OperandIsImmArg, OpIdx++, TempOpIdx))
        return std::move(Error);
    }
  }

  return InsnMatcher;
}

Error GlobalISelEmitter::importComplexPatternOperandMatcher(
    OperandMatcher &OM, Record *R, unsigned &TempOpIdx) const {
  const auto &ComplexPattern = ComplexPatternEquivs.find(R);
  if (ComplexPattern == ComplexPatternEquivs.end())
    return failedImport("SelectionDAG ComplexPattern (" + R->getName() +
                        ") not mapped to GlobalISel");

  OM.addPredicate<ComplexPatternOperandMatcher>(OM, *ComplexPattern->second);
  TempOpIdx++;
  return Error::success();
}

// Get the name to use for a pattern operand. For an anonymous physical register
// input, this should use the register name.
static StringRef getSrcChildName(const TreePatternNode *SrcChild,
                                 Record *&PhysReg) {
  StringRef SrcChildName = SrcChild->getName();
  if (SrcChildName.empty() && SrcChild->isLeaf()) {
    if (auto *ChildDefInit = dyn_cast<DefInit>(SrcChild->getLeafValue())) {
      auto *ChildRec = ChildDefInit->getDef();
      if (ChildRec->isSubClassOf("Register")) {
        SrcChildName = ChildRec->getName();
        PhysReg = ChildRec;
      }
    }
  }

  return SrcChildName;
}

Error GlobalISelEmitter::importChildMatcher(
    RuleMatcher &Rule, InstructionMatcher &InsnMatcher,
    const TreePatternNode *SrcChild, bool OperandIsAPointer,
    bool OperandIsImmArg, unsigned OpIdx, unsigned &TempOpIdx) {

  Record *PhysReg = nullptr;
  StringRef SrcChildName = getSrcChildName(SrcChild, PhysReg);

  OperandMatcher &OM =
      PhysReg
          ? InsnMatcher.addPhysRegInput(PhysReg, OpIdx, TempOpIdx)
          : InsnMatcher.addOperand(OpIdx, std::string(SrcChildName), TempOpIdx);
  if (OM.isSameAsAnotherOperand())
    return Error::success();

  ArrayRef<TypeSetByHwMode> ChildTypes = SrcChild->getExtTypes();
  if (ChildTypes.size() != 1)
    return failedImport("Src pattern child has multiple results");

  // Check MBB's before the type check since they are not a known type.
  if (!SrcChild->isLeaf()) {
    if (SrcChild->getOperator()->isSubClassOf("SDNode")) {
      auto &ChildSDNI = CGP.getSDNodeInfo(SrcChild->getOperator());
      if (ChildSDNI.getSDClassName() == "BasicBlockSDNode") {
        OM.addPredicate<MBBOperandMatcher>();
        return Error::success();
      }
      if (SrcChild->getOperator()->getName() == "timm") {
        OM.addPredicate<ImmOperandMatcher>();
        return Error::success();
      }
    }
  }

  // Immediate arguments have no meaningful type to check as they don't have
  // registers.
  if (!OperandIsImmArg) {
    if (auto Error =
            OM.addTypeCheckPredicate(ChildTypes.front(), OperandIsAPointer))
      return failedImport(toString(std::move(Error)) + " for Src operand (" +
                          to_string(*SrcChild) + ")");
  }

  // Check for nested instructions.
  if (!SrcChild->isLeaf()) {
    if (SrcChild->getOperator()->isSubClassOf("ComplexPattern")) {
      // When a ComplexPattern is used as an operator, it should do the same
      // thing as when used as a leaf. However, the children of the operator
      // name the sub-operands that make up the complex operand and we must
      // prepare to reference them in the renderer too.
      unsigned RendererID = TempOpIdx;
      if (auto Error = importComplexPatternOperandMatcher(
              OM, SrcChild->getOperator(), TempOpIdx))
        return Error;

      for (unsigned i = 0, e = SrcChild->getNumChildren(); i != e; ++i) {
        auto *SubOperand = SrcChild->getChild(i);
        if (!SubOperand->getName().empty()) {
          if (auto Error = Rule.defineComplexSubOperand(SubOperand->getName(),
                                                        SrcChild->getOperator(),
                                                        RendererID, i))
            return Error;
        }
      }

      return Error::success();
    }

    auto MaybeInsnOperand = OM.addPredicate<InstructionOperandMatcher>(
        InsnMatcher.getRuleMatcher(), SrcChild->getName());
    if (!MaybeInsnOperand.hasValue()) {
      // This isn't strictly true. If the user were to provide exactly the same
      // matchers as the original operand then we could allow it. However, it's
      // simpler to not permit the redundant specification.
      return failedImport("Nested instruction cannot be the same as another operand");
    }

    // Map the node to a gMIR instruction.
    InstructionOperandMatcher &InsnOperand = **MaybeInsnOperand;
    auto InsnMatcherOrError = createAndImportSelDAGMatcher(
        Rule, InsnOperand.getInsnMatcher(), SrcChild, TempOpIdx);
    if (auto Error = InsnMatcherOrError.takeError())
      return Error;

    return Error::success();
  }

  if (SrcChild->hasAnyPredicate())
    return failedImport("Src pattern child has unsupported predicate");

  // Check for constant immediates.
  if (auto *ChildInt = dyn_cast<IntInit>(SrcChild->getLeafValue())) {
    if (OperandIsImmArg) {
      // Checks for argument directly in operand list
      OM.addPredicate<LiteralIntOperandMatcher>(ChildInt->getValue());
    } else {
      // Checks for materialized constant
      OM.addPredicate<ConstantIntOperandMatcher>(ChildInt->getValue());
    }
    return Error::success();
  }

  // Check for def's like register classes or ComplexPattern's.
  if (auto *ChildDefInit = dyn_cast<DefInit>(SrcChild->getLeafValue())) {
    auto *ChildRec = ChildDefInit->getDef();

    // Check for register classes.
    if (ChildRec->isSubClassOf("RegisterClass") ||
        ChildRec->isSubClassOf("RegisterOperand")) {
      OM.addPredicate<RegisterBankOperandMatcher>(
          Target.getRegisterClass(getInitValueAsRegClass(ChildDefInit)));
      return Error::success();
    }

    if (ChildRec->isSubClassOf("Register")) {
      // This just be emitted as a copy to the specific register.
      ValueTypeByHwMode VT = ChildTypes.front().getValueTypeByHwMode();
      const CodeGenRegisterClass *RC
        = CGRegs.getMinimalPhysRegClass(ChildRec, &VT);
      if (!RC) {
        return failedImport(
          "Could not determine physical register class of pattern source");
      }

      OM.addPredicate<RegisterBankOperandMatcher>(*RC);
      return Error::success();
    }

    // Check for ValueType.
    if (ChildRec->isSubClassOf("ValueType")) {
      // We already added a type check as standard practice so this doesn't need
      // to do anything.
      return Error::success();
    }

    // Check for ComplexPattern's.
    if (ChildRec->isSubClassOf("ComplexPattern"))
      return importComplexPatternOperandMatcher(OM, ChildRec, TempOpIdx);

    if (ChildRec->isSubClassOf("ImmLeaf")) {
      return failedImport(
          "Src pattern child def is an unsupported tablegen class (ImmLeaf)");
    }

    // Place holder for SRCVALUE nodes. Nothing to do here.
    if (ChildRec->getName() == "srcvalue")
      return Error::success();

    return failedImport(
        "Src pattern child def is an unsupported tablegen class");
  }

  return failedImport("Src pattern child is an unsupported kind");
}

Expected<action_iterator> GlobalISelEmitter::importExplicitUseRenderer(
    action_iterator InsertPt, RuleMatcher &Rule, BuildMIAction &DstMIBuilder,
    TreePatternNode *DstChild) {

  const auto &SubOperand = Rule.getComplexSubOperand(DstChild->getName());
  if (SubOperand.hasValue()) {
    DstMIBuilder.addRenderer<RenderComplexPatternOperand>(
        *std::get<0>(*SubOperand), DstChild->getName(),
        std::get<1>(*SubOperand), std::get<2>(*SubOperand));
    return InsertPt;
  }

  if (!DstChild->isLeaf()) {
    if (DstChild->getOperator()->isSubClassOf("SDNodeXForm")) {
      auto Child = DstChild->getChild(0);
      auto I = SDNodeXFormEquivs.find(DstChild->getOperator());
      if (I != SDNodeXFormEquivs.end()) {
        Record *XFormOpc = DstChild->getOperator()->getValueAsDef("Opcode");
        if (XFormOpc->getName() == "timm") {
          // If this is a TargetConstant, there won't be a corresponding
          // instruction to transform. Instead, this will refer directly to an
          // operand in an instruction's operand list.
          DstMIBuilder.addRenderer<CustomOperandRenderer>(*I->second,
                                                          Child->getName());
        } else {
          DstMIBuilder.addRenderer<CustomRenderer>(*I->second,
                                                   Child->getName());
        }

        return InsertPt;
      }
      return failedImport("SDNodeXForm " + Child->getName() +
                          " has no custom renderer");
    }

    // We accept 'bb' here. It's an operator because BasicBlockSDNode isn't
    // inline, but in MI it's just another operand.
    if (DstChild->getOperator()->isSubClassOf("SDNode")) {
      auto &ChildSDNI = CGP.getSDNodeInfo(DstChild->getOperator());
      if (ChildSDNI.getSDClassName() == "BasicBlockSDNode") {
        DstMIBuilder.addRenderer<CopyRenderer>(DstChild->getName());
        return InsertPt;
      }
    }

    // Similarly, imm is an operator in TreePatternNode's view but must be
    // rendered as operands.
    // FIXME: The target should be able to choose sign-extended when appropriate
    //        (e.g. on Mips).
    if (DstChild->getOperator()->getName() == "timm") {
      DstMIBuilder.addRenderer<CopyRenderer>(DstChild->getName());
      return InsertPt;
    } else if (DstChild->getOperator()->getName() == "imm") {
      DstMIBuilder.addRenderer<CopyConstantAsImmRenderer>(DstChild->getName());
      return InsertPt;
    } else if (DstChild->getOperator()->getName() == "fpimm") {
      DstMIBuilder.addRenderer<CopyFConstantAsFPImmRenderer>(
          DstChild->getName());
      return InsertPt;
    }

    if (DstChild->getOperator()->isSubClassOf("Instruction")) {
      auto OpTy = getInstResultType(DstChild);
      if (!OpTy)
        return OpTy.takeError();

      unsigned TempRegID = Rule.allocateTempRegID();
      InsertPt = Rule.insertAction<MakeTempRegisterAction>(
          InsertPt, *OpTy, TempRegID);
      DstMIBuilder.addRenderer<TempRegRenderer>(TempRegID);

      auto InsertPtOrError = createAndImportSubInstructionRenderer(
          ++InsertPt, Rule, DstChild, TempRegID);
      if (auto Error = InsertPtOrError.takeError())
        return std::move(Error);
      return InsertPtOrError.get();
    }

    return failedImport("Dst pattern child isn't a leaf node or an MBB" + llvm::to_string(*DstChild));
  }

  // It could be a specific immediate in which case we should just check for
  // that immediate.
  if (const IntInit *ChildIntInit =
          dyn_cast<IntInit>(DstChild->getLeafValue())) {
    DstMIBuilder.addRenderer<ImmRenderer>(ChildIntInit->getValue());
    return InsertPt;
  }

  // Otherwise, we're looking for a bog-standard RegisterClass operand.
  if (auto *ChildDefInit = dyn_cast<DefInit>(DstChild->getLeafValue())) {
    auto *ChildRec = ChildDefInit->getDef();

    ArrayRef<TypeSetByHwMode> ChildTypes = DstChild->getExtTypes();
    if (ChildTypes.size() != 1)
      return failedImport("Dst pattern child has multiple results");

    Optional<LLTCodeGen> OpTyOrNone = None;
    if (ChildTypes.front().isMachineValueType())
      OpTyOrNone = MVTToLLT(ChildTypes.front().getMachineValueType().SimpleTy);
    if (!OpTyOrNone)
      return failedImport("Dst operand has an unsupported type");

    if (ChildRec->isSubClassOf("Register")) {
      DstMIBuilder.addRenderer<AddRegisterRenderer>(ChildRec);
      return InsertPt;
    }

    if (ChildRec->isSubClassOf("RegisterClass") ||
        ChildRec->isSubClassOf("RegisterOperand") ||
        ChildRec->isSubClassOf("ValueType")) {
      if (ChildRec->isSubClassOf("RegisterOperand") &&
          !ChildRec->isValueUnset("GIZeroRegister")) {
        DstMIBuilder.addRenderer<CopyOrAddZeroRegRenderer>(
            DstChild->getName(), ChildRec->getValueAsDef("GIZeroRegister"));
        return InsertPt;
      }

      DstMIBuilder.addRenderer<CopyRenderer>(DstChild->getName());
      return InsertPt;
    }

    if (ChildRec->isSubClassOf("SubRegIndex")) {
      CodeGenSubRegIndex *SubIdx = CGRegs.getSubRegIdx(ChildRec);
      DstMIBuilder.addRenderer<ImmRenderer>(SubIdx->EnumValue);
      return InsertPt;
    }

    if (ChildRec->isSubClassOf("ComplexPattern")) {
      const auto &ComplexPattern = ComplexPatternEquivs.find(ChildRec);
      if (ComplexPattern == ComplexPatternEquivs.end())
        return failedImport(
            "SelectionDAG ComplexPattern not mapped to GlobalISel");

      const OperandMatcher &OM = Rule.getOperandMatcher(DstChild->getName());
      DstMIBuilder.addRenderer<RenderComplexPatternOperand>(
          *ComplexPattern->second, DstChild->getName(),
          OM.getAllocatedTemporariesBaseID());
      return InsertPt;
    }

    return failedImport(
        "Dst pattern child def is an unsupported tablegen class");
  }

  return failedImport("Dst pattern child is an unsupported kind");
}

Expected<BuildMIAction &> GlobalISelEmitter::createAndImportInstructionRenderer(
    RuleMatcher &M, InstructionMatcher &InsnMatcher, const TreePatternNode *Src,
    const TreePatternNode *Dst) {
  auto InsertPtOrError = createInstructionRenderer(M.actions_end(), M, Dst);
  if (auto Error = InsertPtOrError.takeError())
    return std::move(Error);

  action_iterator InsertPt = InsertPtOrError.get();
  BuildMIAction &DstMIBuilder = *static_cast<BuildMIAction *>(InsertPt->get());

  for (auto PhysInput : InsnMatcher.getPhysRegInputs()) {
    InsertPt = M.insertAction<BuildMIAction>(
        InsertPt, M.allocateOutputInsnID(),
        &Target.getInstruction(RK.getDef("COPY")));
    BuildMIAction &CopyToPhysRegMIBuilder =
        *static_cast<BuildMIAction *>(InsertPt->get());
    CopyToPhysRegMIBuilder.addRenderer<AddRegisterRenderer>(PhysInput.first,
                                                            true);
    CopyToPhysRegMIBuilder.addRenderer<CopyPhysRegRenderer>(PhysInput.first);
  }

  importExplicitDefRenderers(DstMIBuilder);

  if (auto Error = importExplicitUseRenderers(InsertPt, M, DstMIBuilder, Dst)
                       .takeError())
    return std::move(Error);

  return DstMIBuilder;
}

Expected<action_iterator>
GlobalISelEmitter::createAndImportSubInstructionRenderer(
    const action_iterator InsertPt, RuleMatcher &M, const TreePatternNode *Dst,
    unsigned TempRegID) {
  auto InsertPtOrError = createInstructionRenderer(InsertPt, M, Dst);

  // TODO: Assert there's exactly one result.

  if (auto Error = InsertPtOrError.takeError())
    return std::move(Error);

  BuildMIAction &DstMIBuilder =
      *static_cast<BuildMIAction *>(InsertPtOrError.get()->get());

  // Assign the result to TempReg.
  DstMIBuilder.addRenderer<TempRegRenderer>(TempRegID, true);

  InsertPtOrError =
      importExplicitUseRenderers(InsertPtOrError.get(), M, DstMIBuilder, Dst);
  if (auto Error = InsertPtOrError.takeError())
    return std::move(Error);

  // We need to make sure that when we import an INSERT_SUBREG as a
  // subinstruction that it ends up being constrained to the correct super
  // register and subregister classes.
  auto OpName = Target.getInstruction(Dst->getOperator()).TheDef->getName();
  if (OpName == "INSERT_SUBREG") {
    auto SubClass = inferRegClassFromPattern(Dst->getChild(1));
    if (!SubClass)
      return failedImport(
          "Cannot infer register class from INSERT_SUBREG operand #1");
    Optional<const CodeGenRegisterClass *> SuperClass =
        inferSuperRegisterClassForNode(Dst->getExtType(0), Dst->getChild(0),
                                       Dst->getChild(2));
    if (!SuperClass)
      return failedImport(
          "Cannot infer register class for INSERT_SUBREG operand #0");
    // The destination and the super register source of an INSERT_SUBREG must
    // be the same register class.
    M.insertAction<ConstrainOperandToRegClassAction>(
        InsertPt, DstMIBuilder.getInsnID(), 0, **SuperClass);
    M.insertAction<ConstrainOperandToRegClassAction>(
        InsertPt, DstMIBuilder.getInsnID(), 1, **SuperClass);
    M.insertAction<ConstrainOperandToRegClassAction>(
        InsertPt, DstMIBuilder.getInsnID(), 2, **SubClass);
    return InsertPtOrError.get();
  }

  if (OpName == "EXTRACT_SUBREG") {
    // EXTRACT_SUBREG selects into a subregister COPY but unlike most
    // instructions, the result register class is controlled by the
    // subregisters of the operand. As a result, we must constrain the result
    // class rather than check that it's already the right one.
    auto SuperClass = inferRegClassFromPattern(Dst->getChild(0));
    if (!SuperClass)
      return failedImport(
        "Cannot infer register class from EXTRACT_SUBREG operand #0");

    auto SubIdx = inferSubRegIndexForNode(Dst->getChild(1));
    if (!SubIdx)
      return failedImport("EXTRACT_SUBREG child #1 is not a subreg index");

    const auto SrcRCDstRCPair =
      (*SuperClass)->getMatchingSubClassWithSubRegs(CGRegs, *SubIdx);
    assert(SrcRCDstRCPair->second && "Couldn't find a matching subclass");
    M.insertAction<ConstrainOperandToRegClassAction>(
      InsertPt, DstMIBuilder.getInsnID(), 0, *SrcRCDstRCPair->second);
    M.insertAction<ConstrainOperandToRegClassAction>(
      InsertPt, DstMIBuilder.getInsnID(), 1, *SrcRCDstRCPair->first);

    // We're done with this pattern!  It's eligible for GISel emission; return
    // it.
    return InsertPtOrError.get();
  }

  // Similar to INSERT_SUBREG, we also have to handle SUBREG_TO_REG as a
  // subinstruction.
  if (OpName == "SUBREG_TO_REG") {
    auto SubClass = inferRegClassFromPattern(Dst->getChild(1));
    if (!SubClass)
      return failedImport(
        "Cannot infer register class from SUBREG_TO_REG child #1");
    auto SuperClass = inferSuperRegisterClass(Dst->getExtType(0),
                                              Dst->getChild(2));
    if (!SuperClass)
      return failedImport(
        "Cannot infer register class for SUBREG_TO_REG operand #0");
    M.insertAction<ConstrainOperandToRegClassAction>(
      InsertPt, DstMIBuilder.getInsnID(), 0, **SuperClass);
    M.insertAction<ConstrainOperandToRegClassAction>(
      InsertPt, DstMIBuilder.getInsnID(), 2, **SubClass);
    return InsertPtOrError.get();
  }

  if (OpName == "REG_SEQUENCE") {
    auto SuperClass = inferRegClassFromPattern(Dst->getChild(0));
    M.insertAction<ConstrainOperandToRegClassAction>(
      InsertPt, DstMIBuilder.getInsnID(), 0, **SuperClass);

    unsigned Num = Dst->getNumChildren();
    for (unsigned I = 1; I != Num; I += 2) {
      TreePatternNode *SubRegChild = Dst->getChild(I + 1);

      auto SubIdx = inferSubRegIndexForNode(SubRegChild);
      if (!SubIdx)
        return failedImport("REG_SEQUENCE child is not a subreg index");

      const auto SrcRCDstRCPair =
        (*SuperClass)->getMatchingSubClassWithSubRegs(CGRegs, *SubIdx);
      assert(SrcRCDstRCPair->second && "Couldn't find a matching subclass");
      M.insertAction<ConstrainOperandToRegClassAction>(
        InsertPt, DstMIBuilder.getInsnID(), I, *SrcRCDstRCPair->second);
    }

    return InsertPtOrError.get();
  }

  M.insertAction<ConstrainOperandsToDefinitionAction>(InsertPt,
                                                      DstMIBuilder.getInsnID());
  return InsertPtOrError.get();
}

Expected<action_iterator> GlobalISelEmitter::createInstructionRenderer(
    action_iterator InsertPt, RuleMatcher &M, const TreePatternNode *Dst) {
  Record *DstOp = Dst->getOperator();
  if (!DstOp->isSubClassOf("Instruction")) {
    if (DstOp->isSubClassOf("ValueType"))
      return failedImport(
          "Pattern operator isn't an instruction (it's a ValueType)");
    return failedImport("Pattern operator isn't an instruction");
  }
  CodeGenInstruction *DstI = &Target.getInstruction(DstOp);

  // COPY_TO_REGCLASS is just a copy with a ConstrainOperandToRegClassAction
  // attached. Similarly for EXTRACT_SUBREG except that's a subregister copy.
  StringRef Name = DstI->TheDef->getName();
  if (Name == "COPY_TO_REGCLASS" || Name == "EXTRACT_SUBREG")
    DstI = &Target.getInstruction(RK.getDef("COPY"));

  return M.insertAction<BuildMIAction>(InsertPt, M.allocateOutputInsnID(),
                                       DstI);
}

void GlobalISelEmitter::importExplicitDefRenderers(
    BuildMIAction &DstMIBuilder) {
  const CodeGenInstruction *DstI = DstMIBuilder.getCGI();
  for (unsigned I = 0; I < DstI->Operands.NumDefs; ++I) {
    const CGIOperandList::OperandInfo &DstIOperand = DstI->Operands[I];
    DstMIBuilder.addRenderer<CopyRenderer>(DstIOperand.Name);
  }
}

Expected<action_iterator> GlobalISelEmitter::importExplicitUseRenderers(
    action_iterator InsertPt, RuleMatcher &M, BuildMIAction &DstMIBuilder,
    const llvm::TreePatternNode *Dst) {
  const CodeGenInstruction *DstI = DstMIBuilder.getCGI();
  CodeGenInstruction *OrigDstI = &Target.getInstruction(Dst->getOperator());

  StringRef Name = OrigDstI->TheDef->getName();
  unsigned ExpectedDstINumUses = Dst->getNumChildren();

  // EXTRACT_SUBREG needs to use a subregister COPY.
  if (Name == "EXTRACT_SUBREG") {
    DefInit *SubRegInit = dyn_cast<DefInit>(Dst->getChild(1)->getLeafValue());
    if (!SubRegInit)
      return failedImport("EXTRACT_SUBREG child #1 is not a subreg index");

    CodeGenSubRegIndex *SubIdx = CGRegs.getSubRegIdx(SubRegInit->getDef());
    TreePatternNode *ValChild = Dst->getChild(0);
    if (!ValChild->isLeaf()) {
      // We really have to handle the source instruction, and then insert a
      // copy from the subregister.
      auto ExtractSrcTy = getInstResultType(ValChild);
      if (!ExtractSrcTy)
        return ExtractSrcTy.takeError();

      unsigned TempRegID = M.allocateTempRegID();
      InsertPt = M.insertAction<MakeTempRegisterAction>(
        InsertPt, *ExtractSrcTy, TempRegID);

      auto InsertPtOrError = createAndImportSubInstructionRenderer(
        ++InsertPt, M, ValChild, TempRegID);
      if (auto Error = InsertPtOrError.takeError())
        return std::move(Error);

      DstMIBuilder.addRenderer<TempRegRenderer>(TempRegID, false, SubIdx);
      return InsertPt;
    }

    // If this is a source operand, this is just a subregister copy.
    Record *RCDef = getInitValueAsRegClass(ValChild->getLeafValue());
    if (!RCDef)
      return failedImport("EXTRACT_SUBREG child #0 could not "
                          "be coerced to a register class");

    CodeGenRegisterClass *RC = CGRegs.getRegClass(RCDef);

    const auto SrcRCDstRCPair =
      RC->getMatchingSubClassWithSubRegs(CGRegs, SubIdx);
    if (SrcRCDstRCPair.hasValue()) {
      assert(SrcRCDstRCPair->second && "Couldn't find a matching subclass");
      if (SrcRCDstRCPair->first != RC)
        return failedImport("EXTRACT_SUBREG requires an additional COPY");
    }

    DstMIBuilder.addRenderer<CopySubRegRenderer>(Dst->getChild(0)->getName(),
                                                 SubIdx);
    return InsertPt;
  }

  if (Name == "REG_SEQUENCE") {
    if (!Dst->getChild(0)->isLeaf())
      return failedImport("REG_SEQUENCE child #0 is not a leaf");

    Record *RCDef = getInitValueAsRegClass(Dst->getChild(0)->getLeafValue());
    if (!RCDef)
      return failedImport("REG_SEQUENCE child #0 could not "
                          "be coerced to a register class");

    if ((ExpectedDstINumUses - 1) % 2 != 0)
      return failedImport("Malformed REG_SEQUENCE");

    for (unsigned I = 1; I != ExpectedDstINumUses; I += 2) {
      TreePatternNode *ValChild = Dst->getChild(I);
      TreePatternNode *SubRegChild = Dst->getChild(I + 1);

      if (DefInit *SubRegInit =
              dyn_cast<DefInit>(SubRegChild->getLeafValue())) {
        CodeGenSubRegIndex *SubIdx = CGRegs.getSubRegIdx(SubRegInit->getDef());

        auto InsertPtOrError =
            importExplicitUseRenderer(InsertPt, M, DstMIBuilder, ValChild);
        if (auto Error = InsertPtOrError.takeError())
          return std::move(Error);
        InsertPt = InsertPtOrError.get();
        DstMIBuilder.addRenderer<SubRegIndexRenderer>(SubIdx);
      }
    }

    return InsertPt;
  }

  // Render the explicit uses.
  unsigned DstINumUses = OrigDstI->Operands.size() - OrigDstI->Operands.NumDefs;
  if (Name == "COPY_TO_REGCLASS") {
    DstINumUses--; // Ignore the class constraint.
    ExpectedDstINumUses--;
  }

  // NumResults - This is the number of results produced by the instruction in
  // the "outs" list.
  unsigned NumResults = OrigDstI->Operands.NumDefs;

  // Number of operands we know the output instruction must have. If it is
  // variadic, we could have more operands.
  unsigned NumFixedOperands = DstI->Operands.size();

  // Loop over all of the fixed operands of the instruction pattern, emitting
  // code to fill them all in. The node 'N' usually has number children equal to
  // the number of input operands of the instruction.  However, in cases where
  // there are predicate operands for an instruction, we need to fill in the
  // 'execute always' values. Match up the node operands to the instruction
  // operands to do this.
  unsigned Child = 0;

  // Similarly to the code in TreePatternNode::ApplyTypeConstraints, count the
  // number of operands at the end of the list which have default values.
  // Those can come from the pattern if it provides enough arguments, or be
  // filled in with the default if the pattern hasn't provided them. But any
  // operand with a default value _before_ the last mandatory one will be
  // filled in with their defaults unconditionally.
  unsigned NonOverridableOperands = NumFixedOperands;
  while (NonOverridableOperands > NumResults &&
         CGP.operandHasDefault(DstI->Operands[NonOverridableOperands - 1].Rec))
    --NonOverridableOperands;

  unsigned NumDefaultOps = 0;
  for (unsigned I = 0; I != DstINumUses; ++I) {
    unsigned InstOpNo = DstI->Operands.NumDefs + I;

    // Determine what to emit for this operand.
    Record *OperandNode = DstI->Operands[InstOpNo].Rec;

    // If the operand has default values, introduce them now.
    if (CGP.operandHasDefault(OperandNode) &&
        (InstOpNo < NonOverridableOperands || Child >= Dst->getNumChildren())) {
      // This is a predicate or optional def operand which the pattern has not
      // overridden, or which we aren't letting it override; emit the 'default
      // ops' operands.

      const CGIOperandList::OperandInfo &DstIOperand = DstI->Operands[InstOpNo];
      DagInit *DefaultOps = DstIOperand.Rec->getValueAsDag("DefaultOps");
      if (auto Error = importDefaultOperandRenderers(
            InsertPt, M, DstMIBuilder, DefaultOps))
        return std::move(Error);
      ++NumDefaultOps;
      continue;
    }

    auto InsertPtOrError = importExplicitUseRenderer(InsertPt, M, DstMIBuilder,
                                                     Dst->getChild(Child));
    if (auto Error = InsertPtOrError.takeError())
      return std::move(Error);
    InsertPt = InsertPtOrError.get();
    ++Child;
  }

  if (NumDefaultOps + ExpectedDstINumUses != DstINumUses)
    return failedImport("Expected " + llvm::to_string(DstINumUses) +
                        " used operands but found " +
                        llvm::to_string(ExpectedDstINumUses) +
                        " explicit ones and " + llvm::to_string(NumDefaultOps) +
                        " default ones");

  return InsertPt;
}

Error GlobalISelEmitter::importDefaultOperandRenderers(
    action_iterator InsertPt, RuleMatcher &M, BuildMIAction &DstMIBuilder,
    DagInit *DefaultOps) const {
  for (const auto *DefaultOp : DefaultOps->getArgs()) {
    Optional<LLTCodeGen> OpTyOrNone = None;

    // Look through ValueType operators.
    if (const DagInit *DefaultDagOp = dyn_cast<DagInit>(DefaultOp)) {
      if (const DefInit *DefaultDagOperator =
              dyn_cast<DefInit>(DefaultDagOp->getOperator())) {
        if (DefaultDagOperator->getDef()->isSubClassOf("ValueType")) {
          OpTyOrNone = MVTToLLT(getValueType(
                                  DefaultDagOperator->getDef()));
          DefaultOp = DefaultDagOp->getArg(0);
        }
      }
    }

    if (const DefInit *DefaultDefOp = dyn_cast<DefInit>(DefaultOp)) {
      auto Def = DefaultDefOp->getDef();
      if (Def->getName() == "undef_tied_input") {
        unsigned TempRegID = M.allocateTempRegID();
        M.insertAction<MakeTempRegisterAction>(
          InsertPt, OpTyOrNone.getValue(), TempRegID);
        InsertPt = M.insertAction<BuildMIAction>(
          InsertPt, M.allocateOutputInsnID(),
          &Target.getInstruction(RK.getDef("IMPLICIT_DEF")));
        BuildMIAction &IDMIBuilder = *static_cast<BuildMIAction *>(
          InsertPt->get());
        IDMIBuilder.addRenderer<TempRegRenderer>(TempRegID);
        DstMIBuilder.addRenderer<TempRegRenderer>(TempRegID);
      } else {
        DstMIBuilder.addRenderer<AddRegisterRenderer>(Def);
      }
      continue;
    }

    if (const IntInit *DefaultIntOp = dyn_cast<IntInit>(DefaultOp)) {
      DstMIBuilder.addRenderer<ImmRenderer>(DefaultIntOp->getValue());
      continue;
    }

    return failedImport("Could not add default op");
  }

  return Error::success();
}

Error GlobalISelEmitter::importImplicitDefRenderers(
    BuildMIAction &DstMIBuilder,
    const std::vector<Record *> &ImplicitDefs) const {
  if (!ImplicitDefs.empty())
    return failedImport("Pattern defines a physical register");
  return Error::success();
}

Optional<const CodeGenRegisterClass *>
GlobalISelEmitter::getRegClassFromLeaf(TreePatternNode *Leaf) {
  assert(Leaf && "Expected node?");
  assert(Leaf->isLeaf() && "Expected leaf?");
  Record *RCRec = getInitValueAsRegClass(Leaf->getLeafValue());
  if (!RCRec)
    return None;
  CodeGenRegisterClass *RC = CGRegs.getRegClass(RCRec);
  if (!RC)
    return None;
  return RC;
}

Optional<const CodeGenRegisterClass *>
GlobalISelEmitter::inferRegClassFromPattern(TreePatternNode *N) {
  if (!N)
    return None;

  if (N->isLeaf())
    return getRegClassFromLeaf(N);

  // We don't have a leaf node, so we have to try and infer something. Check
  // that we have an instruction that we an infer something from.

  // Only handle things that produce a single type.
  if (N->getNumTypes() != 1)
    return None;
  Record *OpRec = N->getOperator();

  // We only want instructions.
  if (!OpRec->isSubClassOf("Instruction"))
    return None;

  // Don't want to try and infer things when there could potentially be more
  // than one candidate register class.
  auto &Inst = Target.getInstruction(OpRec);
  if (Inst.Operands.NumDefs > 1)
    return None;

  // Handle any special-case instructions which we can safely infer register
  // classes from.
  StringRef InstName = Inst.TheDef->getName();
  bool IsRegSequence = InstName == "REG_SEQUENCE";
  if (IsRegSequence || InstName == "COPY_TO_REGCLASS") {
    // If we have a COPY_TO_REGCLASS, then we need to handle it specially. It
    // has the desired register class as the first child.
    TreePatternNode *RCChild = N->getChild(IsRegSequence ? 0 : 1);
    if (!RCChild->isLeaf())
      return None;
    return getRegClassFromLeaf(RCChild);
  }

  // Handle destination record types that we can safely infer a register class
  // from.
  const auto &DstIOperand = Inst.Operands[0];
  Record *DstIOpRec = DstIOperand.Rec;
  if (DstIOpRec->isSubClassOf("RegisterOperand")) {
    DstIOpRec = DstIOpRec->getValueAsDef("RegClass");
    const CodeGenRegisterClass &RC = Target.getRegisterClass(DstIOpRec);
    return &RC;
  }

  if (DstIOpRec->isSubClassOf("RegisterClass")) {
    const CodeGenRegisterClass &RC = Target.getRegisterClass(DstIOpRec);
    return &RC;
  }

  return None;
}

Optional<const CodeGenRegisterClass *>
GlobalISelEmitter::inferSuperRegisterClass(const TypeSetByHwMode &Ty,
                                           TreePatternNode *SubRegIdxNode) {
  assert(SubRegIdxNode && "Expected subregister index node!");
  // We need a ValueTypeByHwMode for getSuperRegForSubReg.
  if (!Ty.isValueTypeByHwMode(false))
    return None;
  if (!SubRegIdxNode->isLeaf())
    return None;
  DefInit *SubRegInit = dyn_cast<DefInit>(SubRegIdxNode->getLeafValue());
  if (!SubRegInit)
    return None;
  CodeGenSubRegIndex *SubIdx = CGRegs.getSubRegIdx(SubRegInit->getDef());

  // Use the information we found above to find a minimal register class which
  // supports the subregister and type we want.
  auto RC =
      Target.getSuperRegForSubReg(Ty.getValueTypeByHwMode(), CGRegs, SubIdx);
  if (!RC)
    return None;
  return *RC;
}

Optional<const CodeGenRegisterClass *>
GlobalISelEmitter::inferSuperRegisterClassForNode(
    const TypeSetByHwMode &Ty, TreePatternNode *SuperRegNode,
    TreePatternNode *SubRegIdxNode) {
  assert(SuperRegNode && "Expected super register node!");
  // Check if we already have a defined register class for the super register
  // node. If we do, then we should preserve that rather than inferring anything
  // from the subregister index node. We can assume that whoever wrote the
  // pattern in the first place made sure that the super register and
  // subregister are compatible.
  if (Optional<const CodeGenRegisterClass *> SuperRegisterClass =
          inferRegClassFromPattern(SuperRegNode))
    return *SuperRegisterClass;
  return inferSuperRegisterClass(Ty, SubRegIdxNode);
}

Optional<CodeGenSubRegIndex *>
GlobalISelEmitter::inferSubRegIndexForNode(TreePatternNode *SubRegIdxNode) {
  if (!SubRegIdxNode->isLeaf())
    return None;

  DefInit *SubRegInit = dyn_cast<DefInit>(SubRegIdxNode->getLeafValue());
  if (!SubRegInit)
    return None;
  return CGRegs.getSubRegIdx(SubRegInit->getDef());
}

Expected<RuleMatcher> GlobalISelEmitter::runOnPattern(const PatternToMatch &P) {
  // Keep track of the matchers and actions to emit.
  int Score = P.getPatternComplexity(CGP);
  RuleMatcher M(P.getSrcRecord()->getLoc());
  RuleMatcherScores[M.getRuleID()] = Score;
  M.addAction<DebugCommentAction>(llvm::to_string(*P.getSrcPattern()) +
                                  "  =>  " +
                                  llvm::to_string(*P.getDstPattern()));

  if (auto Error = importRulePredicates(M, P.getPredicates()))
    return std::move(Error);

  // Next, analyze the pattern operators.
  TreePatternNode *Src = P.getSrcPattern();
  TreePatternNode *Dst = P.getDstPattern();

  // If the root of either pattern isn't a simple operator, ignore it.
  if (auto Err = isTrivialOperatorNode(Dst))
    return failedImport("Dst pattern root isn't a trivial operator (" +
                        toString(std::move(Err)) + ")");
  if (auto Err = isTrivialOperatorNode(Src))
    return failedImport("Src pattern root isn't a trivial operator (" +
                        toString(std::move(Err)) + ")");

  // The different predicates and matchers created during
  // addInstructionMatcher use the RuleMatcher M to set up their
  // instruction ID (InsnVarID) that are going to be used when
  // M is going to be emitted.
  // However, the code doing the emission still relies on the IDs
  // returned during that process by the RuleMatcher when issuing
  // the recordInsn opcodes.
  // Because of that:
  // 1. The order in which we created the predicates
  //    and such must be the same as the order in which we emit them,
  //    and
  // 2. We need to reset the generation of the IDs in M somewhere between
  //    addInstructionMatcher and emit
  //
  // FIXME: Long term, we don't want to have to rely on this implicit
  // naming being the same. One possible solution would be to have
  // explicit operator for operation capture and reference those.
  // The plus side is that it would expose opportunities to share
  // the capture accross rules. The downside is that it would
  // introduce a dependency between predicates (captures must happen
  // before their first use.)
  InstructionMatcher &InsnMatcherTemp = M.addInstructionMatcher(Src->getName());
  unsigned TempOpIdx = 0;
  auto InsnMatcherOrError =
      createAndImportSelDAGMatcher(M, InsnMatcherTemp, Src, TempOpIdx);
  if (auto Error = InsnMatcherOrError.takeError())
    return std::move(Error);
  InstructionMatcher &InsnMatcher = InsnMatcherOrError.get();

  if (Dst->isLeaf()) {
    Record *RCDef = getInitValueAsRegClass(Dst->getLeafValue());

    const CodeGenRegisterClass &RC = Target.getRegisterClass(RCDef);
    if (RCDef) {
      // We need to replace the def and all its uses with the specified
      // operand. However, we must also insert COPY's wherever needed.
      // For now, emit a copy and let the register allocator clean up.
      auto &DstI = Target.getInstruction(RK.getDef("COPY"));
      const auto &DstIOperand = DstI.Operands[0];

      OperandMatcher &OM0 = InsnMatcher.getOperand(0);
      OM0.setSymbolicName(DstIOperand.Name);
      M.defineOperand(OM0.getSymbolicName(), OM0);
      OM0.addPredicate<RegisterBankOperandMatcher>(RC);

      auto &DstMIBuilder =
          M.addAction<BuildMIAction>(M.allocateOutputInsnID(), &DstI);
      DstMIBuilder.addRenderer<CopyRenderer>(DstIOperand.Name);
      DstMIBuilder.addRenderer<CopyRenderer>(Dst->getName());
      M.addAction<ConstrainOperandToRegClassAction>(0, 0, RC);

      // We're done with this pattern!  It's eligible for GISel emission; return
      // it.
      ++NumPatternImported;
      return std::move(M);
    }

    return failedImport("Dst pattern root isn't a known leaf");
  }

  // Start with the defined operands (i.e., the results of the root operator).
  Record *DstOp = Dst->getOperator();
  if (!DstOp->isSubClassOf("Instruction"))
    return failedImport("Pattern operator isn't an instruction");

  auto &DstI = Target.getInstruction(DstOp);
  StringRef DstIName = DstI.TheDef->getName();

  if (DstI.Operands.NumDefs != Src->getExtTypes().size())
    return failedImport("Src pattern results and dst MI defs are different (" +
                        to_string(Src->getExtTypes().size()) + " def(s) vs " +
                        to_string(DstI.Operands.NumDefs) + " def(s))");

  // The root of the match also has constraints on the register bank so that it
  // matches the result instruction.
  unsigned OpIdx = 0;
  for (const TypeSetByHwMode &VTy : Src->getExtTypes()) {
    (void)VTy;

    const auto &DstIOperand = DstI.Operands[OpIdx];
    Record *DstIOpRec = DstIOperand.Rec;
    if (DstIName == "COPY_TO_REGCLASS") {
      DstIOpRec = getInitValueAsRegClass(Dst->getChild(1)->getLeafValue());

      if (DstIOpRec == nullptr)
        return failedImport(
            "COPY_TO_REGCLASS operand #1 isn't a register class");
    } else if (DstIName == "REG_SEQUENCE") {
      DstIOpRec = getInitValueAsRegClass(Dst->getChild(0)->getLeafValue());
      if (DstIOpRec == nullptr)
        return failedImport("REG_SEQUENCE operand #0 isn't a register class");
    } else if (DstIName == "EXTRACT_SUBREG") {
      auto InferredClass = inferRegClassFromPattern(Dst->getChild(0));
      if (!InferredClass)
        return failedImport("Could not infer class for EXTRACT_SUBREG operand #0");

      // We can assume that a subregister is in the same bank as it's super
      // register.
      DstIOpRec = (*InferredClass)->getDef();
    } else if (DstIName == "INSERT_SUBREG") {
      auto MaybeSuperClass = inferSuperRegisterClassForNode(
          VTy, Dst->getChild(0), Dst->getChild(2));
      if (!MaybeSuperClass)
        return failedImport(
            "Cannot infer register class for INSERT_SUBREG operand #0");
      // Move to the next pattern here, because the register class we found
      // doesn't necessarily have a record associated with it. So, we can't
      // set DstIOpRec using this.
      OperandMatcher &OM = InsnMatcher.getOperand(OpIdx);
      OM.setSymbolicName(DstIOperand.Name);
      M.defineOperand(OM.getSymbolicName(), OM);
      OM.addPredicate<RegisterBankOperandMatcher>(**MaybeSuperClass);
      ++OpIdx;
      continue;
    } else if (DstIName == "SUBREG_TO_REG") {
      auto MaybeRegClass = inferSuperRegisterClass(VTy, Dst->getChild(2));
      if (!MaybeRegClass)
        return failedImport(
            "Cannot infer register class for SUBREG_TO_REG operand #0");
      OperandMatcher &OM = InsnMatcher.getOperand(OpIdx);
      OM.setSymbolicName(DstIOperand.Name);
      M.defineOperand(OM.getSymbolicName(), OM);
      OM.addPredicate<RegisterBankOperandMatcher>(**MaybeRegClass);
      ++OpIdx;
      continue;
    } else if (DstIOpRec->isSubClassOf("RegisterOperand"))
      DstIOpRec = DstIOpRec->getValueAsDef("RegClass");
    else if (!DstIOpRec->isSubClassOf("RegisterClass"))
      return failedImport("Dst MI def isn't a register class" +
                          to_string(*Dst));

    OperandMatcher &OM = InsnMatcher.getOperand(OpIdx);
    OM.setSymbolicName(DstIOperand.Name);
    M.defineOperand(OM.getSymbolicName(), OM);
    OM.addPredicate<RegisterBankOperandMatcher>(
        Target.getRegisterClass(DstIOpRec));
    ++OpIdx;
  }

  auto DstMIBuilderOrError =
      createAndImportInstructionRenderer(M, InsnMatcher, Src, Dst);
  if (auto Error = DstMIBuilderOrError.takeError())
    return std::move(Error);
  BuildMIAction &DstMIBuilder = DstMIBuilderOrError.get();

  // Render the implicit defs.
  // These are only added to the root of the result.
  if (auto Error = importImplicitDefRenderers(DstMIBuilder, P.getDstRegs()))
    return std::move(Error);

  DstMIBuilder.chooseInsnToMutate(M);

  // Constrain the registers to classes. This is normally derived from the
  // emitted instruction but a few instructions require special handling.
  if (DstIName == "COPY_TO_REGCLASS") {
    // COPY_TO_REGCLASS does not provide operand constraints itself but the
    // result is constrained to the class given by the second child.
    Record *DstIOpRec =
        getInitValueAsRegClass(Dst->getChild(1)->getLeafValue());

    if (DstIOpRec == nullptr)
      return failedImport("COPY_TO_REGCLASS operand #1 isn't a register class");

    M.addAction<ConstrainOperandToRegClassAction>(
        0, 0, Target.getRegisterClass(DstIOpRec));

    // We're done with this pattern!  It's eligible for GISel emission; return
    // it.
    ++NumPatternImported;
    return std::move(M);
  }

  if (DstIName == "EXTRACT_SUBREG") {
    auto SuperClass = inferRegClassFromPattern(Dst->getChild(0));
    if (!SuperClass)
      return failedImport(
        "Cannot infer register class from EXTRACT_SUBREG operand #0");

    auto SubIdx = inferSubRegIndexForNode(Dst->getChild(1));
    if (!SubIdx)
      return failedImport("EXTRACT_SUBREG child #1 is not a subreg index");

    // It would be nice to leave this constraint implicit but we're required
    // to pick a register class so constrain the result to a register class
    // that can hold the correct MVT.
    //
    // FIXME: This may introduce an extra copy if the chosen class doesn't
    //        actually contain the subregisters.
    assert(Src->getExtTypes().size() == 1 &&
             "Expected Src of EXTRACT_SUBREG to have one result type");

    const auto SrcRCDstRCPair =
      (*SuperClass)->getMatchingSubClassWithSubRegs(CGRegs, *SubIdx);
    if (!SrcRCDstRCPair) {
      return failedImport("subreg index is incompatible "
                          "with inferred reg class");
    }

    assert(SrcRCDstRCPair->second && "Couldn't find a matching subclass");
    M.addAction<ConstrainOperandToRegClassAction>(0, 0, *SrcRCDstRCPair->second);
    M.addAction<ConstrainOperandToRegClassAction>(0, 1, *SrcRCDstRCPair->first);

    // We're done with this pattern!  It's eligible for GISel emission; return
    // it.
    ++NumPatternImported;
    return std::move(M);
  }

  if (DstIName == "INSERT_SUBREG") {
    assert(Src->getExtTypes().size() == 1 &&
           "Expected Src of INSERT_SUBREG to have one result type");
    // We need to constrain the destination, a super regsister source, and a
    // subregister source.
    auto SubClass = inferRegClassFromPattern(Dst->getChild(1));
    if (!SubClass)
      return failedImport(
          "Cannot infer register class from INSERT_SUBREG operand #1");
    auto SuperClass = inferSuperRegisterClassForNode(
        Src->getExtType(0), Dst->getChild(0), Dst->getChild(2));
    if (!SuperClass)
      return failedImport(
          "Cannot infer register class for INSERT_SUBREG operand #0");
    M.addAction<ConstrainOperandToRegClassAction>(0, 0, **SuperClass);
    M.addAction<ConstrainOperandToRegClassAction>(0, 1, **SuperClass);
    M.addAction<ConstrainOperandToRegClassAction>(0, 2, **SubClass);
    ++NumPatternImported;
    return std::move(M);
  }

  if (DstIName == "SUBREG_TO_REG") {
    // We need to constrain the destination and subregister source.
    assert(Src->getExtTypes().size() == 1 &&
           "Expected Src of SUBREG_TO_REG to have one result type");

    // Attempt to infer the subregister source from the first child. If it has
    // an explicitly given register class, we'll use that. Otherwise, we will
    // fail.
    auto SubClass = inferRegClassFromPattern(Dst->getChild(1));
    if (!SubClass)
      return failedImport(
          "Cannot infer register class from SUBREG_TO_REG child #1");
    // We don't have a child to look at that might have a super register node.
    auto SuperClass =
        inferSuperRegisterClass(Src->getExtType(0), Dst->getChild(2));
    if (!SuperClass)
      return failedImport(
          "Cannot infer register class for SUBREG_TO_REG operand #0");
    M.addAction<ConstrainOperandToRegClassAction>(0, 0, **SuperClass);
    M.addAction<ConstrainOperandToRegClassAction>(0, 2, **SubClass);
    ++NumPatternImported;
    return std::move(M);
  }

  if (DstIName == "REG_SEQUENCE") {
    auto SuperClass = inferRegClassFromPattern(Dst->getChild(0));

    M.addAction<ConstrainOperandToRegClassAction>(0, 0, **SuperClass);

    unsigned Num = Dst->getNumChildren();
    for (unsigned I = 1; I != Num; I += 2) {
      TreePatternNode *SubRegChild = Dst->getChild(I + 1);

      auto SubIdx = inferSubRegIndexForNode(SubRegChild);
      if (!SubIdx)
        return failedImport("REG_SEQUENCE child is not a subreg index");

      const auto SrcRCDstRCPair =
        (*SuperClass)->getMatchingSubClassWithSubRegs(CGRegs, *SubIdx);

      M.addAction<ConstrainOperandToRegClassAction>(0, I,
                                                    *SrcRCDstRCPair->second);
    }

    ++NumPatternImported;
    return std::move(M);
  }

  M.addAction<ConstrainOperandsToDefinitionAction>(0);

  // We're done with this pattern!  It's eligible for GISel emission; return it.
  ++NumPatternImported;
  return std::move(M);
}

// Emit imm predicate table and an enum to reference them with.
// The 'Predicate_' part of the name is redundant but eliminating it is more
// trouble than it's worth.
void GlobalISelEmitter::emitCxxPredicateFns(
    raw_ostream &OS, StringRef CodeFieldName, StringRef TypeIdentifier,
    StringRef ArgType, StringRef ArgName, StringRef AdditionalDeclarations,
    std::function<bool(const Record *R)> Filter) {
  std::vector<const Record *> MatchedRecords;
  const auto &Defs = RK.getAllDerivedDefinitions("PatFrag");
  std::copy_if(Defs.begin(), Defs.end(), std::back_inserter(MatchedRecords),
               [&](Record *Record) {
                 return !Record->getValueAsString(CodeFieldName).empty() &&
                        Filter(Record);
               });

  if (!MatchedRecords.empty()) {
    OS << "// PatFrag predicates.\n"
       << "enum {\n";
    std::string EnumeratorSeparator =
        (" = GIPFP_" + TypeIdentifier + "_Invalid + 1,\n").str();
    for (const auto *Record : MatchedRecords) {
      OS << "  GIPFP_" << TypeIdentifier << "_Predicate_" << Record->getName()
         << EnumeratorSeparator;
      EnumeratorSeparator = ",\n";
    }
    OS << "};\n";
  }

  OS << "bool " << Target.getName() << "InstructionSelector::test" << ArgName
     << "Predicate_" << TypeIdentifier << "(unsigned PredicateID, " << ArgType << " "
     << ArgName << ") const {\n"
     << AdditionalDeclarations;
  if (!AdditionalDeclarations.empty())
    OS << "\n";
  if (!MatchedRecords.empty())
    OS << "  switch (PredicateID) {\n";
  for (const auto *Record : MatchedRecords) {
    OS << "  case GIPFP_" << TypeIdentifier << "_Predicate_"
       << Record->getName() << ": {\n"
       << "    " << Record->getValueAsString(CodeFieldName) << "\n"
       << "    llvm_unreachable(\"" << CodeFieldName
       << " should have returned\");\n"
       << "    return false;\n"
       << "  }\n";
  }
  if (!MatchedRecords.empty())
    OS << "  }\n";
  OS << "  llvm_unreachable(\"Unknown predicate\");\n"
     << "  return false;\n"
     << "}\n";
}

void GlobalISelEmitter::emitImmPredicateFns(
    raw_ostream &OS, StringRef TypeIdentifier, StringRef ArgType,
    std::function<bool(const Record *R)> Filter) {
  return emitCxxPredicateFns(OS, "ImmediateCode", TypeIdentifier, ArgType,
                             "Imm", "", Filter);
}

void GlobalISelEmitter::emitMIPredicateFns(raw_ostream &OS) {
  return emitCxxPredicateFns(
      OS, "GISelPredicateCode", "MI", "const MachineInstr &", "MI",
      "  const MachineFunction &MF = *MI.getParent()->getParent();\n"
      "  const MachineRegisterInfo &MRI = MF.getRegInfo();\n"
      "  (void)MRI;",
      [](const Record *R) { return true; });
}

template <class GroupT>
std::vector<Matcher *> GlobalISelEmitter::optimizeRules(
    ArrayRef<Matcher *> Rules,
    std::vector<std::unique_ptr<Matcher>> &MatcherStorage) {

  std::vector<Matcher *> OptRules;
  std::unique_ptr<GroupT> CurrentGroup = std::make_unique<GroupT>();
  assert(CurrentGroup->empty() && "Newly created group isn't empty!");
  unsigned NumGroups = 0;

  auto ProcessCurrentGroup = [&]() {
    if (CurrentGroup->empty())
      // An empty group is good to be reused:
      return;

    // If the group isn't large enough to provide any benefit, move all the
    // added rules out of it and make sure to re-create the group to properly
    // re-initialize it:
    if (CurrentGroup->size() < 2)
      for (Matcher *M : CurrentGroup->matchers())
        OptRules.push_back(M);
    else {
      CurrentGroup->finalize();
      OptRules.push_back(CurrentGroup.get());
      MatcherStorage.emplace_back(std::move(CurrentGroup));
      ++NumGroups;
    }
    CurrentGroup = std::make_unique<GroupT>();
  };
  for (Matcher *Rule : Rules) {
    // Greedily add as many matchers as possible to the current group:
    if (CurrentGroup->addMatcher(*Rule))
      continue;

    ProcessCurrentGroup();
    assert(CurrentGroup->empty() && "A group wasn't properly re-initialized");

    // Try to add the pending matcher to a newly created empty group:
    if (!CurrentGroup->addMatcher(*Rule))
      // If we couldn't add the matcher to an empty group, that group type
      // doesn't support that kind of matchers at all, so just skip it:
      OptRules.push_back(Rule);
  }
  ProcessCurrentGroup();

  LLVM_DEBUG(dbgs() << "NumGroups: " << NumGroups << "\n");
  assert(CurrentGroup->empty() && "The last group wasn't properly processed");
  return OptRules;
}

MatchTable
GlobalISelEmitter::buildMatchTable(MutableArrayRef<RuleMatcher> Rules,
                                   bool Optimize, bool WithCoverage) {
  std::vector<Matcher *> InputRules;
  for (Matcher &Rule : Rules)
    InputRules.push_back(&Rule);

  if (!Optimize)
    return MatchTable::buildTable(InputRules, WithCoverage);

  unsigned CurrentOrdering = 0;
  StringMap<unsigned> OpcodeOrder;
  for (RuleMatcher &Rule : Rules) {
    const StringRef Opcode = Rule.getOpcode();
    assert(!Opcode.empty() && "Didn't expect an undefined opcode");
    if (OpcodeOrder.count(Opcode) == 0)
      OpcodeOrder[Opcode] = CurrentOrdering++;
  }

  std::stable_sort(InputRules.begin(), InputRules.end(),
                   [&OpcodeOrder](const Matcher *A, const Matcher *B) {
                     auto *L = static_cast<const RuleMatcher *>(A);
                     auto *R = static_cast<const RuleMatcher *>(B);
                     return std::make_tuple(OpcodeOrder[L->getOpcode()],
                                            L->getNumOperands()) <
                            std::make_tuple(OpcodeOrder[R->getOpcode()],
                                            R->getNumOperands());
                   });

  for (Matcher *Rule : InputRules)
    Rule->optimize();

  std::vector<std::unique_ptr<Matcher>> MatcherStorage;
  std::vector<Matcher *> OptRules =
      optimizeRules<GroupMatcher>(InputRules, MatcherStorage);

  for (Matcher *Rule : OptRules)
    Rule->optimize();

  OptRules = optimizeRules<SwitchMatcher>(OptRules, MatcherStorage);

  return MatchTable::buildTable(OptRules, WithCoverage);
}

void GroupMatcher::optimize() {
  // Make sure we only sort by a specific predicate within a range of rules that
  // all have that predicate checked against a specific value (not a wildcard):
  auto F = Matchers.begin();
  auto T = F;
  auto E = Matchers.end();
  while (T != E) {
    while (T != E) {
      auto *R = static_cast<RuleMatcher *>(*T);
      if (!R->getFirstConditionAsRootType().get().isValid())
        break;
      ++T;
    }
    std::stable_sort(F, T, [](Matcher *A, Matcher *B) {
      auto *L = static_cast<RuleMatcher *>(A);
      auto *R = static_cast<RuleMatcher *>(B);
      return L->getFirstConditionAsRootType() <
             R->getFirstConditionAsRootType();
    });
    if (T != E)
      F = ++T;
  }
  GlobalISelEmitter::optimizeRules<GroupMatcher>(Matchers, MatcherStorage)
      .swap(Matchers);
  GlobalISelEmitter::optimizeRules<SwitchMatcher>(Matchers, MatcherStorage)
      .swap(Matchers);
}

void GlobalISelEmitter::run(raw_ostream &OS) {
  if (!UseCoverageFile.empty()) {
    RuleCoverage = CodeGenCoverage();
    auto RuleCoverageBufOrErr = MemoryBuffer::getFile(UseCoverageFile);
    if (!RuleCoverageBufOrErr) {
      PrintWarning(SMLoc(), "Missing rule coverage data");
      RuleCoverage = None;
    } else {
      if (!RuleCoverage->parse(*RuleCoverageBufOrErr.get(), Target.getName())) {
        PrintWarning(SMLoc(), "Ignoring invalid or missing rule coverage data");
        RuleCoverage = None;
      }
    }
  }

  // Track the run-time opcode values
  gatherOpcodeValues();
  // Track the run-time LLT ID values
  gatherTypeIDValues();

  // Track the GINodeEquiv definitions.
  gatherNodeEquivs();

  emitSourceFileHeader(("Global Instruction Selector for the " +
                       Target.getName() + " target").str(), OS);
  std::vector<RuleMatcher> Rules;
  // Look through the SelectionDAG patterns we found, possibly emitting some.
  for (const PatternToMatch &Pat : CGP.ptms()) {
    ++NumPatternTotal;

    auto MatcherOrErr = runOnPattern(Pat);

    // The pattern analysis can fail, indicating an unsupported pattern.
    // Report that if we've been asked to do so.
    if (auto Err = MatcherOrErr.takeError()) {
      if (WarnOnSkippedPatterns) {
        PrintWarning(Pat.getSrcRecord()->getLoc(),
                     "Skipped pattern: " + toString(std::move(Err)));
      } else {
        consumeError(std::move(Err));
      }
      ++NumPatternImportsSkipped;
      continue;
    }

    if (RuleCoverage) {
      if (RuleCoverage->isCovered(MatcherOrErr->getRuleID()))
        ++NumPatternsTested;
      else
        PrintWarning(Pat.getSrcRecord()->getLoc(),
                     "Pattern is not covered by a test");
    }
    Rules.push_back(std::move(MatcherOrErr.get()));
  }

  // Comparison function to order records by name.
  auto orderByName = [](const Record *A, const Record *B) {
    return A->getName() < B->getName();
  };

  std::vector<Record *> ComplexPredicates =
      RK.getAllDerivedDefinitions("GIComplexOperandMatcher");
  llvm::sort(ComplexPredicates, orderByName);

  std::vector<Record *> CustomRendererFns =
      RK.getAllDerivedDefinitions("GICustomOperandRenderer");
  llvm::sort(CustomRendererFns, orderByName);

  unsigned MaxTemporaries = 0;
  for (const auto &Rule : Rules)
    MaxTemporaries = std::max(MaxTemporaries, Rule.countRendererFns());

  OS << "#ifdef GET_GLOBALISEL_PREDICATE_BITSET\n"
     << "const unsigned MAX_SUBTARGET_PREDICATES = " << SubtargetFeatures.size()
     << ";\n"
     << "using PredicateBitset = "
        "llvm::PredicateBitsetImpl<MAX_SUBTARGET_PREDICATES>;\n"
     << "#endif // ifdef GET_GLOBALISEL_PREDICATE_BITSET\n\n";

  OS << "#ifdef GET_GLOBALISEL_TEMPORARIES_DECL\n"
     << "  mutable MatcherState State;\n"
     << "  typedef "
        "ComplexRendererFns("
     << Target.getName()
     << "InstructionSelector::*ComplexMatcherMemFn)(MachineOperand &) const;\n"

     << "  typedef void(" << Target.getName()
     << "InstructionSelector::*CustomRendererFn)(MachineInstrBuilder &, const "
        "MachineInstr&, int) "
        "const;\n"
     << "  const ISelInfoTy<PredicateBitset, ComplexMatcherMemFn, "
        "CustomRendererFn> "
        "ISelInfo;\n";
  OS << "  static " << Target.getName()
     << "InstructionSelector::ComplexMatcherMemFn ComplexPredicateFns[];\n"
     << "  static " << Target.getName()
     << "InstructionSelector::CustomRendererFn CustomRenderers[];\n"
     << "  bool testImmPredicate_I64(unsigned PredicateID, int64_t Imm) const "
        "override;\n"
     << "  bool testImmPredicate_APInt(unsigned PredicateID, const APInt &Imm) "
        "const override;\n"
     << "  bool testImmPredicate_APFloat(unsigned PredicateID, const APFloat "
        "&Imm) const override;\n"
     << "  const int64_t *getMatchTable() const override;\n"
     << "  bool testMIPredicate_MI(unsigned PredicateID, const MachineInstr &MI) "
        "const override;\n"
     << "#endif // ifdef GET_GLOBALISEL_TEMPORARIES_DECL\n\n";

  OS << "#ifdef GET_GLOBALISEL_TEMPORARIES_INIT\n"
     << ", State(" << MaxTemporaries << "),\n"
     << "ISelInfo(TypeObjects, NumTypeObjects, FeatureBitsets"
     << ", ComplexPredicateFns, CustomRenderers)\n"
     << "#endif // ifdef GET_GLOBALISEL_TEMPORARIES_INIT\n\n";

  OS << "#ifdef GET_GLOBALISEL_IMPL\n";
  SubtargetFeatureInfo::emitSubtargetFeatureBitEnumeration(SubtargetFeatures,
                                                           OS);

  // Separate subtarget features by how often they must be recomputed.
  SubtargetFeatureInfoMap ModuleFeatures;
  std::copy_if(SubtargetFeatures.begin(), SubtargetFeatures.end(),
               std::inserter(ModuleFeatures, ModuleFeatures.end()),
               [](const SubtargetFeatureInfoMap::value_type &X) {
                 return !X.second.mustRecomputePerFunction();
               });
  SubtargetFeatureInfoMap FunctionFeatures;
  std::copy_if(SubtargetFeatures.begin(), SubtargetFeatures.end(),
               std::inserter(FunctionFeatures, FunctionFeatures.end()),
               [](const SubtargetFeatureInfoMap::value_type &X) {
                 return X.second.mustRecomputePerFunction();
               });

  SubtargetFeatureInfo::emitComputeAvailableFeatures(
    Target.getName(), "InstructionSelector", "computeAvailableModuleFeatures",
      ModuleFeatures, OS);


  OS << "void " << Target.getName() << "InstructionSelector"
    "::setupGeneratedPerFunctionState(MachineFunction &MF) {\n"
    "  AvailableFunctionFeatures = computeAvailableFunctionFeatures("
    "(const " << Target.getName() << "Subtarget*)&MF.getSubtarget(), &MF);\n"
    "}\n";

  if (Target.getName() == "X86" || Target.getName() == "AArch64") {
    // TODO: Implement PGSO.
    OS << "static bool shouldOptForSize(const MachineFunction *MF) {\n";
    OS << "    return MF->getFunction().hasOptSize();\n";
    OS << "}\n\n";
  }

  SubtargetFeatureInfo::emitComputeAvailableFeatures(
      Target.getName(), "InstructionSelector",
      "computeAvailableFunctionFeatures", FunctionFeatures, OS,
      "const MachineFunction *MF");

  // Emit a table containing the LLT objects needed by the matcher and an enum
  // for the matcher to reference them with.
  std::vector<LLTCodeGen> TypeObjects;
  for (const auto &Ty : KnownTypes)
    TypeObjects.push_back(Ty);
  llvm::sort(TypeObjects);
  OS << "// LLT Objects.\n"
     << "enum {\n";
  for (const auto &TypeObject : TypeObjects) {
    OS << "  ";
    TypeObject.emitCxxEnumValue(OS);
    OS << ",\n";
  }
  OS << "};\n";
  OS << "const static size_t NumTypeObjects = " << TypeObjects.size() << ";\n"
     << "const static LLT TypeObjects[] = {\n";
  for (const auto &TypeObject : TypeObjects) {
    OS << "  ";
    TypeObject.emitCxxConstructorCall(OS);
    OS << ",\n";
  }
  OS << "};\n\n";

  // Emit a table containing the PredicateBitsets objects needed by the matcher
  // and an enum for the matcher to reference them with.
  std::vector<std::vector<Record *>> FeatureBitsets;
  for (auto &Rule : Rules)
    FeatureBitsets.push_back(Rule.getRequiredFeatures());
  llvm::sort(FeatureBitsets, [&](const std::vector<Record *> &A,
                                 const std::vector<Record *> &B) {
    if (A.size() < B.size())
      return true;
    if (A.size() > B.size())
      return false;
    for (auto Pair : zip(A, B)) {
      if (std::get<0>(Pair)->getName() < std::get<1>(Pair)->getName())
        return true;
      if (std::get<0>(Pair)->getName() > std::get<1>(Pair)->getName())
        return false;
    }
    return false;
  });
  FeatureBitsets.erase(
      std::unique(FeatureBitsets.begin(), FeatureBitsets.end()),
      FeatureBitsets.end());
  OS << "// Feature bitsets.\n"
     << "enum {\n"
     << "  GIFBS_Invalid,\n";
  for (const auto &FeatureBitset : FeatureBitsets) {
    if (FeatureBitset.empty())
      continue;
    OS << "  " << getNameForFeatureBitset(FeatureBitset) << ",\n";
  }
  OS << "};\n"
     << "const static PredicateBitset FeatureBitsets[] {\n"
     << "  {}, // GIFBS_Invalid\n";
  for (const auto &FeatureBitset : FeatureBitsets) {
    if (FeatureBitset.empty())
      continue;
    OS << "  {";
    for (const auto &Feature : FeatureBitset) {
      const auto &I = SubtargetFeatures.find(Feature);
      assert(I != SubtargetFeatures.end() && "Didn't import predicate?");
      OS << I->second.getEnumBitName() << ", ";
    }
    OS << "},\n";
  }
  OS << "};\n\n";

  // Emit complex predicate table and an enum to reference them with.
  OS << "// ComplexPattern predicates.\n"
     << "enum {\n"
     << "  GICP_Invalid,\n";
  for (const auto &Record : ComplexPredicates)
    OS << "  GICP_" << Record->getName() << ",\n";
  OS << "};\n"
     << "// See constructor for table contents\n\n";

  emitImmPredicateFns(OS, "I64", "int64_t", [](const Record *R) {
    bool Unset;
    return !R->getValueAsBitOrUnset("IsAPFloat", Unset) &&
           !R->getValueAsBit("IsAPInt");
  });
  emitImmPredicateFns(OS, "APFloat", "const APFloat &", [](const Record *R) {
    bool Unset;
    return R->getValueAsBitOrUnset("IsAPFloat", Unset);
  });
  emitImmPredicateFns(OS, "APInt", "const APInt &", [](const Record *R) {
    return R->getValueAsBit("IsAPInt");
  });
  emitMIPredicateFns(OS);
  OS << "\n";

  OS << Target.getName() << "InstructionSelector::ComplexMatcherMemFn\n"
     << Target.getName() << "InstructionSelector::ComplexPredicateFns[] = {\n"
     << "  nullptr, // GICP_Invalid\n";
  for (const auto &Record : ComplexPredicates)
    OS << "  &" << Target.getName()
       << "InstructionSelector::" << Record->getValueAsString("MatcherFn")
       << ", // " << Record->getName() << "\n";
  OS << "};\n\n";

  OS << "// Custom renderers.\n"
     << "enum {\n"
     << "  GICR_Invalid,\n";
  for (const auto &Record : CustomRendererFns)
    OS << "  GICR_" << Record->getValueAsString("RendererFn") << ", \n";
  OS << "};\n";

  OS << Target.getName() << "InstructionSelector::CustomRendererFn\n"
     << Target.getName() << "InstructionSelector::CustomRenderers[] = {\n"
     << "  nullptr, // GICR_Invalid\n";
  for (const auto &Record : CustomRendererFns)
    OS << "  &" << Target.getName()
       << "InstructionSelector::" << Record->getValueAsString("RendererFn")
       << ", // " << Record->getName() << "\n";
  OS << "};\n\n";

  llvm::stable_sort(Rules, [&](const RuleMatcher &A, const RuleMatcher &B) {
    int ScoreA = RuleMatcherScores[A.getRuleID()];
    int ScoreB = RuleMatcherScores[B.getRuleID()];
    if (ScoreA > ScoreB)
      return true;
    if (ScoreB > ScoreA)
      return false;
    if (A.isHigherPriorityThan(B)) {
      assert(!B.isHigherPriorityThan(A) && "Cannot be more important "
                                           "and less important at "
                                           "the same time");
      return true;
    }
    return false;
  });

  OS << "bool " << Target.getName()
     << "InstructionSelector::selectImpl(MachineInstr &I, CodeGenCoverage "
        "&CoverageInfo) const {\n"
     << "  MachineFunction &MF = *I.getParent()->getParent();\n"
     << "  MachineRegisterInfo &MRI = MF.getRegInfo();\n"
     << "  const PredicateBitset AvailableFeatures = getAvailableFeatures();\n"
     << "  NewMIVector OutMIs;\n"
     << "  State.MIs.clear();\n"
     << "  State.MIs.push_back(&I);\n\n"
     << "  if (executeMatchTable(*this, OutMIs, State, ISelInfo"
     << ", getMatchTable(), TII, MRI, TRI, RBI, AvailableFeatures"
     << ", CoverageInfo)) {\n"
     << "    return true;\n"
     << "  }\n\n"
     << "  return false;\n"
     << "}\n\n";

  const MatchTable Table =
      buildMatchTable(Rules, OptimizeMatchTable, GenerateCoverage);
  OS << "const int64_t *" << Target.getName()
     << "InstructionSelector::getMatchTable() const {\n";
  Table.emitDeclaration(OS);
  OS << "  return ";
  Table.emitUse(OS);
  OS << ";\n}\n";
  OS << "#endif // ifdef GET_GLOBALISEL_IMPL\n";

  OS << "#ifdef GET_GLOBALISEL_PREDICATES_DECL\n"
     << "PredicateBitset AvailableModuleFeatures;\n"
     << "mutable PredicateBitset AvailableFunctionFeatures;\n"
     << "PredicateBitset getAvailableFeatures() const {\n"
     << "  return AvailableModuleFeatures | AvailableFunctionFeatures;\n"
     << "}\n"
     << "PredicateBitset\n"
     << "computeAvailableModuleFeatures(const " << Target.getName()
     << "Subtarget *Subtarget) const;\n"
     << "PredicateBitset\n"
     << "computeAvailableFunctionFeatures(const " << Target.getName()
     << "Subtarget *Subtarget,\n"
     << "                                 const MachineFunction *MF) const;\n"
     << "void setupGeneratedPerFunctionState(MachineFunction &MF) override;\n"
     << "#endif // ifdef GET_GLOBALISEL_PREDICATES_DECL\n";

  OS << "#ifdef GET_GLOBALISEL_PREDICATES_INIT\n"
     << "AvailableModuleFeatures(computeAvailableModuleFeatures(&STI)),\n"
     << "AvailableFunctionFeatures()\n"
     << "#endif // ifdef GET_GLOBALISEL_PREDICATES_INIT\n";
}

void GlobalISelEmitter::declareSubtargetFeature(Record *Predicate) {
  if (SubtargetFeatures.count(Predicate) == 0)
    SubtargetFeatures.emplace(
        Predicate, SubtargetFeatureInfo(Predicate, SubtargetFeatures.size()));
}

void RuleMatcher::optimize() {
  for (auto &Item : InsnVariableIDs) {
    InstructionMatcher &InsnMatcher = *Item.first;
    for (auto &OM : InsnMatcher.operands()) {
      // Complex Patterns are usually expensive and they relatively rarely fail
      // on their own: more often we end up throwing away all the work done by a
      // matching part of a complex pattern because some other part of the
      // enclosing pattern didn't match. All of this makes it beneficial to
      // delay complex patterns until the very end of the rule matching,
      // especially for targets having lots of complex patterns.
      for (auto &OP : OM->predicates())
        if (isa<ComplexPatternOperandMatcher>(OP))
          EpilogueMatchers.emplace_back(std::move(OP));
      OM->eraseNullPredicates();
    }
    InsnMatcher.optimize();
  }
  llvm::sort(EpilogueMatchers, [](const std::unique_ptr<PredicateMatcher> &L,
                                  const std::unique_ptr<PredicateMatcher> &R) {
    return std::make_tuple(L->getKind(), L->getInsnVarID(), L->getOpIdx()) <
           std::make_tuple(R->getKind(), R->getInsnVarID(), R->getOpIdx());
  });
}

bool RuleMatcher::hasFirstCondition() const {
  if (insnmatchers_empty())
    return false;
  InstructionMatcher &Matcher = insnmatchers_front();
  if (!Matcher.predicates_empty())
    return true;
  for (auto &OM : Matcher.operands())
    for (auto &OP : OM->predicates())
      if (!isa<InstructionOperandMatcher>(OP))
        return true;
  return false;
}

const PredicateMatcher &RuleMatcher::getFirstCondition() const {
  assert(!insnmatchers_empty() &&
         "Trying to get a condition from an empty RuleMatcher");

  InstructionMatcher &Matcher = insnmatchers_front();
  if (!Matcher.predicates_empty())
    return **Matcher.predicates_begin();
  // If there is no more predicate on the instruction itself, look at its
  // operands.
  for (auto &OM : Matcher.operands())
    for (auto &OP : OM->predicates())
      if (!isa<InstructionOperandMatcher>(OP))
        return *OP;

  llvm_unreachable("Trying to get a condition from an InstructionMatcher with "
                   "no conditions");
}

std::unique_ptr<PredicateMatcher> RuleMatcher::popFirstCondition() {
  assert(!insnmatchers_empty() &&
         "Trying to pop a condition from an empty RuleMatcher");

  InstructionMatcher &Matcher = insnmatchers_front();
  if (!Matcher.predicates_empty())
    return Matcher.predicates_pop_front();
  // If there is no more predicate on the instruction itself, look at its
  // operands.
  for (auto &OM : Matcher.operands())
    for (auto &OP : OM->predicates())
      if (!isa<InstructionOperandMatcher>(OP)) {
        std::unique_ptr<PredicateMatcher> Result = std::move(OP);
        OM->eraseNullPredicates();
        return Result;
      }

  llvm_unreachable("Trying to pop a condition from an InstructionMatcher with "
                   "no conditions");
}

bool GroupMatcher::candidateConditionMatches(
    const PredicateMatcher &Predicate) const {

  if (empty()) {
    // Sharing predicates for nested instructions is not supported yet as we
    // currently don't hoist the GIM_RecordInsn's properly, therefore we can
    // only work on the original root instruction (InsnVarID == 0):
    if (Predicate.getInsnVarID() != 0)
      return false;
    // ... otherwise an empty group can handle any predicate with no specific
    // requirements:
    return true;
  }

  const Matcher &Representative = **Matchers.begin();
  const auto &RepresentativeCondition = Representative.getFirstCondition();
  // ... if not empty, the group can only accomodate matchers with the exact
  // same first condition:
  return Predicate.isIdentical(RepresentativeCondition);
}

bool GroupMatcher::addMatcher(Matcher &Candidate) {
  if (!Candidate.hasFirstCondition())
    return false;

  const PredicateMatcher &Predicate = Candidate.getFirstCondition();
  if (!candidateConditionMatches(Predicate))
    return false;

  Matchers.push_back(&Candidate);
  return true;
}

void GroupMatcher::finalize() {
  assert(Conditions.empty() && "Already finalized?");
  if (empty())
    return;

  Matcher &FirstRule = **Matchers.begin();
  for (;;) {
    // All the checks are expected to succeed during the first iteration:
    for (const auto &Rule : Matchers)
      if (!Rule->hasFirstCondition())
        return;
    const auto &FirstCondition = FirstRule.getFirstCondition();
    for (unsigned I = 1, E = Matchers.size(); I < E; ++I)
      if (!Matchers[I]->getFirstCondition().isIdentical(FirstCondition))
        return;

    Conditions.push_back(FirstRule.popFirstCondition());
    for (unsigned I = 1, E = Matchers.size(); I < E; ++I)
      Matchers[I]->popFirstCondition();
  }
}

void GroupMatcher::emit(MatchTable &Table) {
  unsigned LabelID = ~0U;
  if (!Conditions.empty()) {
    LabelID = Table.allocateLabelID();
    Table << MatchTable::Opcode("GIM_Try", +1)
          << MatchTable::Comment("On fail goto")
          << MatchTable::JumpTarget(LabelID) << MatchTable::LineBreak;
  }
  for (auto &Condition : Conditions)
    Condition->emitPredicateOpcodes(
        Table, *static_cast<RuleMatcher *>(*Matchers.begin()));

  for (const auto &M : Matchers)
    M->emit(Table);

  // Exit the group
  if (!Conditions.empty())
    Table << MatchTable::Opcode("GIM_Reject", -1) << MatchTable::LineBreak
          << MatchTable::Label(LabelID);
}

bool SwitchMatcher::isSupportedPredicateType(const PredicateMatcher &P) {
  return isa<InstructionOpcodeMatcher>(P) || isa<LLTOperandMatcher>(P);
}

bool SwitchMatcher::candidateConditionMatches(
    const PredicateMatcher &Predicate) const {

  if (empty()) {
    // Sharing predicates for nested instructions is not supported yet as we
    // currently don't hoist the GIM_RecordInsn's properly, therefore we can
    // only work on the original root instruction (InsnVarID == 0):
    if (Predicate.getInsnVarID() != 0)
      return false;
    // ... while an attempt to add even a root matcher to an empty SwitchMatcher
    // could fail as not all the types of conditions are supported:
    if (!isSupportedPredicateType(Predicate))
      return false;
    // ... or the condition might not have a proper implementation of
    // getValue() / isIdenticalDownToValue() yet:
    if (!Predicate.hasValue())
      return false;
    // ... otherwise an empty Switch can accomodate the condition with no
    // further requirements:
    return true;
  }

  const Matcher &CaseRepresentative = **Matchers.begin();
  const auto &RepresentativeCondition = CaseRepresentative.getFirstCondition();
  // Switch-cases must share the same kind of condition and path to the value it
  // checks:
  if (!Predicate.isIdenticalDownToValue(RepresentativeCondition))
    return false;

  const auto Value = Predicate.getValue();
  // ... but be unique with respect to the actual value they check:
  return Values.count(Value) == 0;
}

bool SwitchMatcher::addMatcher(Matcher &Candidate) {
  if (!Candidate.hasFirstCondition())
    return false;

  const PredicateMatcher &Predicate = Candidate.getFirstCondition();
  if (!candidateConditionMatches(Predicate))
    return false;
  const auto Value = Predicate.getValue();
  Values.insert(Value);

  Matchers.push_back(&Candidate);
  return true;
}

void SwitchMatcher::finalize() {
  assert(Condition == nullptr && "Already finalized");
  assert(Values.size() == Matchers.size() && "Broken SwitchMatcher");
  if (empty())
    return;

  std::stable_sort(Matchers.begin(), Matchers.end(),
                   [](const Matcher *L, const Matcher *R) {
                     return L->getFirstCondition().getValue() <
                            R->getFirstCondition().getValue();
                   });
  Condition = Matchers[0]->popFirstCondition();
  for (unsigned I = 1, E = Values.size(); I < E; ++I)
    Matchers[I]->popFirstCondition();
}

void SwitchMatcher::emitPredicateSpecificOpcodes(const PredicateMatcher &P,
                                                 MatchTable &Table) {
  assert(isSupportedPredicateType(P) && "Predicate type is not supported");

  if (const auto *Condition = dyn_cast<InstructionOpcodeMatcher>(&P)) {
    Table << MatchTable::Opcode("GIM_SwitchOpcode") << MatchTable::Comment("MI")
          << MatchTable::IntValue(Condition->getInsnVarID());
    return;
  }
  if (const auto *Condition = dyn_cast<LLTOperandMatcher>(&P)) {
    Table << MatchTable::Opcode("GIM_SwitchType") << MatchTable::Comment("MI")
          << MatchTable::IntValue(Condition->getInsnVarID())
          << MatchTable::Comment("Op")
          << MatchTable::IntValue(Condition->getOpIdx());
    return;
  }

  llvm_unreachable("emitPredicateSpecificOpcodes is broken: can not handle a "
                   "predicate type that is claimed to be supported");
}

void SwitchMatcher::emit(MatchTable &Table) {
  assert(Values.size() == Matchers.size() && "Broken SwitchMatcher");
  if (empty())
    return;
  assert(Condition != nullptr &&
         "Broken SwitchMatcher, hasn't been finalized?");

  std::vector<unsigned> LabelIDs(Values.size());
  std::generate(LabelIDs.begin(), LabelIDs.end(),
                [&Table]() { return Table.allocateLabelID(); });
  const unsigned Default = Table.allocateLabelID();

  const int64_t LowerBound = Values.begin()->getRawValue();
  const int64_t UpperBound = Values.rbegin()->getRawValue() + 1;

  emitPredicateSpecificOpcodes(*Condition, Table);

  Table << MatchTable::Comment("[") << MatchTable::IntValue(LowerBound)
        << MatchTable::IntValue(UpperBound) << MatchTable::Comment(")")
        << MatchTable::Comment("default:") << MatchTable::JumpTarget(Default);

  int64_t J = LowerBound;
  auto VI = Values.begin();
  for (unsigned I = 0, E = Values.size(); I < E; ++I) {
    auto V = *VI++;
    while (J++ < V.getRawValue())
      Table << MatchTable::IntValue(0);
    V.turnIntoComment();
    Table << MatchTable::LineBreak << V << MatchTable::JumpTarget(LabelIDs[I]);
  }
  Table << MatchTable::LineBreak;

  for (unsigned I = 0, E = Values.size(); I < E; ++I) {
    Table << MatchTable::Label(LabelIDs[I]);
    Matchers[I]->emit(Table);
    Table << MatchTable::Opcode("GIM_Reject") << MatchTable::LineBreak;
  }
  Table << MatchTable::Label(Default);
}

unsigned OperandMatcher::getInsnVarID() const { return Insn.getInsnVarID(); }

} // end anonymous namespace

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

namespace llvm {
void EmitGlobalISel(RecordKeeper &RK, raw_ostream &OS) {
  GlobalISelEmitter(RK).run(OS);
}
} // End llvm namespace