utils/TableGen/DAGISelMatcher.cpp - llvm - Git at Google

 //===- DAGISelMatcher.cpp - Representation of DAG pattern matcher ---------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #include "DAGISelMatcher.h"
 #include "CodeGenDAGPatterns.h"
 #include "CodeGenTarget.h"
 #include "llvm/Support/raw_ostream.h"
 #include "llvm/TableGen/Record.h"
 using namespace llvm;

 void Matcher::anchor() { }

 void Matcher::dump() const {
   print(errs(), 0);
 }

 void Matcher::print(raw_ostream &OS, unsigned indent) const {
   printImpl(OS, indent);
   if (Next)
     return Next->print(OS, indent);
 }

 void Matcher::printOne(raw_ostream &OS) const {
   printImpl(OS, 0);
 }

 /// unlinkNode - Unlink the specified node from this chain.  If Other == this,
 /// we unlink the next pointer and return it.  Otherwise we unlink Other from
 /// the list and return this.
 Matcher *Matcher::unlinkNode(Matcher *Other) {
   if (this == Other)
     return takeNext();

   // Scan until we find the predecessor of Other.
   Matcher *Cur = this;
   for (; Cur && Cur->getNext() != Other; Cur = Cur->getNext())
     /*empty*/;

   if (!Cur) return nullptr;
   Cur->takeNext();
   Cur->setNext(Other->takeNext());
   return this;
 }

 /// canMoveBefore - Return true if this matcher is the same as Other, or if
 /// we can move this matcher past all of the nodes in-between Other and this
 /// node.  Other must be equal to or before this.
 bool Matcher::canMoveBefore(const Matcher *Other) const {
   for (;; Other = Other->getNext()) {
     assert(Other && "Other didn't come before 'this'?");
     if (this == Other) return true;

     // We have to be able to move this node across the Other node.
     if (!canMoveBeforeNode(Other))
       return false;
   }
 }

 /// canMoveBeforeNode - Return true if it is safe to move the current matcher
 /// across the specified one.
 bool Matcher::canMoveBeforeNode(const Matcher *Other) const {
   // We can move simple predicates before record nodes.
   if (isSimplePredicateNode())
     return Other->isSimplePredicateOrRecordNode();

   // We can move record nodes across simple predicates.
   if (isSimplePredicateOrRecordNode())
     return isSimplePredicateNode();

   // We can't move record nodes across each other etc.
   return false;
 }


 ScopeMatcher::~ScopeMatcher() {
   for (Matcher *C : Children)
     delete C;
 }

 SwitchOpcodeMatcher::~SwitchOpcodeMatcher() {
   for (auto &C : Cases)
     delete C.second;
 }

 SwitchTypeMatcher::~SwitchTypeMatcher() {
   for (auto &C : Cases)
     delete C.second;
 }

 CheckPredicateMatcher::CheckPredicateMatcher(
     const TreePredicateFn &pred, const SmallVectorImpl<unsigned> &Ops)
   : Matcher(CheckPredicate), Pred(pred.getOrigPatFragRecord()),
     Operands(Ops.begin(), Ops.end()) {}

 TreePredicateFn CheckPredicateMatcher::getPredicate() const {
   return TreePredicateFn(Pred);
 }

 unsigned CheckPredicateMatcher::getNumOperands() const {
   return Operands.size();
 }

 unsigned CheckPredicateMatcher::getOperandNo(unsigned i) const {
   assert(i < Operands.size());
   return Operands[i];
 }


 // printImpl methods.

 void ScopeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "Scope\n";
   for (const Matcher *C : Children) {
     if (!C)
       OS.indent(indent+1) << "NULL POINTER\n";
     else
       C->print(OS, indent+2);
   }
 }

 void RecordMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "Record\n";
 }

 void RecordChildMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "RecordChild: " << ChildNo << '\n';
 }

 void RecordMemRefMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "RecordMemRef\n";
 }

 void CaptureGlueInputMatcher::printImpl(raw_ostream &OS, unsigned indent) const{
   OS.indent(indent) << "CaptureGlueInput\n";
 }

 void MoveChildMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "MoveChild " << ChildNo << '\n';
 }

 void MoveParentMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "MoveParent\n";
 }

 void CheckSameMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "CheckSame " << MatchNumber << '\n';
 }

 void CheckChildSameMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "CheckChild" << ChildNo << "Same\n";
 }

 void CheckPatternPredicateMatcher::
 printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "CheckPatternPredicate " << Predicate << '\n';
 }

 void CheckPredicateMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "CheckPredicate " << getPredicate().getFnName() << '\n';
 }

 void CheckOpcodeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "CheckOpcode " << Opcode.getEnumName() << '\n';
 }

 void SwitchOpcodeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "SwitchOpcode: {\n";
   for (const auto &C : Cases) {
     OS.indent(indent) << "case " << C.first->getEnumName() << ":\n";
     C.second->print(OS, indent+2);
   }
   OS.indent(indent) << "}\n";
 }


 void CheckTypeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "CheckType " << getEnumName(Type) << ", ResNo="
     << ResNo << '\n';
 }

 void SwitchTypeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "SwitchType: {\n";
   for (const auto &C : Cases) {
     OS.indent(indent) << "case " << getEnumName(C.first) << ":\n";
     C.second->print(OS, indent+2);
   }
   OS.indent(indent) << "}\n";
 }

 void CheckChildTypeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "CheckChildType " << ChildNo << " "
     << getEnumName(Type) << '\n';
 }


 void CheckIntegerMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "CheckInteger " << Value << '\n';
 }

 void CheckChildIntegerMatcher::printImpl(raw_ostream &OS,
                                          unsigned indent) const {
   OS.indent(indent) << "CheckChildInteger " << ChildNo << " " << Value << '\n';
 }

 void CheckCondCodeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "CheckCondCode ISD::" << CondCodeName << '\n';
 }

 void CheckValueTypeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "CheckValueType MVT::" << TypeName << '\n';
 }

 void CheckComplexPatMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "CheckComplexPat " << Pattern.getSelectFunc() << '\n';
 }

 void CheckAndImmMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "CheckAndImm " << Value << '\n';
 }

 void CheckOrImmMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "CheckOrImm " << Value << '\n';
 }

 void CheckFoldableChainNodeMatcher::printImpl(raw_ostream &OS,
                                               unsigned indent) const {
   OS.indent(indent) << "CheckFoldableChainNode\n";
 }

 void EmitIntegerMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "EmitInteger " << Val << " VT=" << getEnumName(VT)
                     << '\n';
 }

 void EmitStringIntegerMatcher::
 printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "EmitStringInteger " << Val << " VT=" << getEnumName(VT)
                     << '\n';
 }

 void EmitRegisterMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "EmitRegister ";
   if (Reg)
     OS << Reg->getName();
   else
     OS << "zero_reg";
   OS << " VT=" << getEnumName(VT) << '\n';
 }

 void EmitConvertToTargetMatcher::
 printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "EmitConvertToTarget " << Slot << '\n';
 }

 void EmitMergeInputChainsMatcher::
 printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "EmitMergeInputChains <todo: args>\n";
 }

 void EmitCopyToRegMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "EmitCopyToReg <todo: args>\n";
 }

 void EmitNodeXFormMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "EmitNodeXForm " << NodeXForm->getName()
      << " Slot=" << Slot << '\n';
 }


 void EmitNodeMatcherCommon::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent);
   OS << (isa<MorphNodeToMatcher>(this) ? "MorphNodeTo: " : "EmitNode: ")
      << OpcodeName << ": <todo flags> ";

   for (unsigned i = 0, e = VTs.size(); i != e; ++i)
     OS << ' ' << getEnumName(VTs[i]);
   OS << '(';
   for (unsigned i = 0, e = Operands.size(); i != e; ++i)
     OS << Operands[i] << ' ';
   OS << ")\n";
 }

 void CompleteMatchMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
   OS.indent(indent) << "CompleteMatch <todo args>\n";
   OS.indent(indent) << "Src = " << *Pattern.getSrcPattern() << "\n";
   OS.indent(indent) << "Dst = " << *Pattern.getDstPattern() << "\n";
 }

 bool CheckOpcodeMatcher::isEqualImpl(const Matcher *M) const {
   // Note: pointer equality isn't enough here, we have to check the enum names
   // to ensure that the nodes are for the same opcode.
   return cast<CheckOpcodeMatcher>(M)->Opcode.getEnumName() ==
           Opcode.getEnumName();
 }

 bool EmitNodeMatcherCommon::isEqualImpl(const Matcher *m) const {
   const EmitNodeMatcherCommon *M = cast<EmitNodeMatcherCommon>(m);
   return M->OpcodeName == OpcodeName && M->VTs == VTs &&
          M->Operands == Operands && M->HasChain == HasChain &&
          M->HasInGlue == HasInGlue && M->HasOutGlue == HasOutGlue &&
          M->HasMemRefs == HasMemRefs &&
          M->NumFixedArityOperands == NumFixedArityOperands;
 }

 void EmitNodeMatcher::anchor() { }

 void MorphNodeToMatcher::anchor() { }

 // isContradictoryImpl Implementations.

 static bool TypesAreContradictory(MVT::SimpleValueType T1,
                                   MVT::SimpleValueType T2) {
   // If the two types are the same, then they are the same, so they don't
   // contradict.
   if (T1 == T2) return false;

   // If either type is about iPtr, then they don't conflict unless the other
   // one is not a scalar integer type.
   if (T1 == MVT::iPTR)
     return !MVT(T2).isInteger() || MVT(T2).isVector();

   if (T2 == MVT::iPTR)
     return !MVT(T1).isInteger() || MVT(T1).isVector();

   // Otherwise, they are two different non-iPTR types, they conflict.
   return true;
 }

 bool CheckOpcodeMatcher::isContradictoryImpl(const Matcher *M) const {
   if (const CheckOpcodeMatcher *COM = dyn_cast<CheckOpcodeMatcher>(M)) {
     // One node can't have two different opcodes!
     // Note: pointer equality isn't enough here, we have to check the enum names
     // to ensure that the nodes are for the same opcode.
     return COM->getOpcode().getEnumName() != getOpcode().getEnumName();
   }

   // If the node has a known type, and if the type we're checking for is
   // different, then we know they contradict.  For example, a check for
   // ISD::STORE will never be true at the same time a check for Type i32 is.
   if (const CheckTypeMatcher *CT = dyn_cast<CheckTypeMatcher>(M)) {
     // If checking for a result the opcode doesn't have, it can't match.
     if (CT->getResNo() >= getOpcode().getNumResults())
       return true;

     MVT::SimpleValueType NodeType = getOpcode().getKnownType(CT->getResNo());
     if (NodeType != MVT::Other)
       return TypesAreContradictory(NodeType, CT->getType());
   }

   return false;
 }

 bool CheckTypeMatcher::isContradictoryImpl(const Matcher *M) const {
   if (const CheckTypeMatcher *CT = dyn_cast<CheckTypeMatcher>(M))
     return TypesAreContradictory(getType(), CT->getType());
   return false;
 }

 bool CheckChildTypeMatcher::isContradictoryImpl(const Matcher *M) const {
   if (const CheckChildTypeMatcher *CC = dyn_cast<CheckChildTypeMatcher>(M)) {
     // If the two checks are about different nodes, we don't know if they
     // conflict!
     if (CC->getChildNo() != getChildNo())
       return false;

     return TypesAreContradictory(getType(), CC->getType());
   }
   return false;
 }

 bool CheckIntegerMatcher::isContradictoryImpl(const Matcher *M) const {
   if (const CheckIntegerMatcher *CIM = dyn_cast<CheckIntegerMatcher>(M))
     return CIM->getValue() != getValue();
   return false;
 }

 bool CheckChildIntegerMatcher::isContradictoryImpl(const Matcher *M) const {
   if (const CheckChildIntegerMatcher *CCIM = dyn_cast<CheckChildIntegerMatcher>(M)) {
     // If the two checks are about different nodes, we don't know if they
     // conflict!
     if (CCIM->getChildNo() != getChildNo())
       return false;

     return CCIM->getValue() != getValue();
   }
   return false;
 }

 bool CheckValueTypeMatcher::isContradictoryImpl(const Matcher *M) const {
   if (const CheckValueTypeMatcher *CVT = dyn_cast<CheckValueTypeMatcher>(M))
     return CVT->getTypeName() != getTypeName();
   return false;
 }
	//===- DAGISelMatcher.cpp - Representation of DAG pattern matcher ---------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#include "DAGISelMatcher.h"
	#include "CodeGenDAGPatterns.h"
	#include "CodeGenTarget.h"
	#include "llvm/Support/raw_ostream.h"
	#include "llvm/TableGen/Record.h"
	using namespace llvm;

	void Matcher::anchor() { }

	void Matcher::dump() const {
	print(errs(), 0);
	}

	void Matcher::print(raw_ostream &OS, unsigned indent) const {
	printImpl(OS, indent);
	if (Next)
	return Next->print(OS, indent);
	}

	void Matcher::printOne(raw_ostream &OS) const {
	printImpl(OS, 0);
	}

	/// unlinkNode - Unlink the specified node from this chain. If Other == this,
	/// we unlink the next pointer and return it. Otherwise we unlink Other from
	/// the list and return this.
	Matcher Matcher::unlinkNode(Matcher Other) {
	if (this == Other)
	return takeNext();

	// Scan until we find the predecessor of Other.
	Matcher *Cur = this;
	for (; Cur && Cur->getNext() != Other; Cur = Cur->getNext())
	/empty/;

	if (!Cur) return nullptr;
	Cur->takeNext();
	Cur->setNext(Other->takeNext());
	return this;
	}

	/// canMoveBefore - Return true if this matcher is the same as Other, or if
	/// we can move this matcher past all of the nodes in-between Other and this
	/// node. Other must be equal to or before this.
	bool Matcher::canMoveBefore(const Matcher *Other) const {
	for (;; Other = Other->getNext()) {
	assert(Other && "Other didn't come before 'this'?");
	if (this == Other) return true;

	// We have to be able to move this node across the Other node.
	if (!canMoveBeforeNode(Other))
	return false;
	}
	}

	/// canMoveBeforeNode - Return true if it is safe to move the current matcher
	/// across the specified one.
	bool Matcher::canMoveBeforeNode(const Matcher *Other) const {
	// We can move simple predicates before record nodes.
	if (isSimplePredicateNode())
	return Other->isSimplePredicateOrRecordNode();

	// We can move record nodes across simple predicates.
	if (isSimplePredicateOrRecordNode())
	return isSimplePredicateNode();

	// We can't move record nodes across each other etc.
	return false;
	}


	ScopeMatcher::~ScopeMatcher() {
	for (Matcher *C : Children)
	delete C;
	}

	SwitchOpcodeMatcher::~SwitchOpcodeMatcher() {
	for (auto &C : Cases)
	delete C.second;
	}

	SwitchTypeMatcher::~SwitchTypeMatcher() {
	for (auto &C : Cases)
	delete C.second;
	}

	CheckPredicateMatcher::CheckPredicateMatcher(
	const TreePredicateFn &pred, const SmallVectorImpl<unsigned> &Ops)
	: Matcher(CheckPredicate), Pred(pred.getOrigPatFragRecord()),
	Operands(Ops.begin(), Ops.end()) {}

	TreePredicateFn CheckPredicateMatcher::getPredicate() const {
	return TreePredicateFn(Pred);
	}

	unsigned CheckPredicateMatcher::getNumOperands() const {
	return Operands.size();
	}

	unsigned CheckPredicateMatcher::getOperandNo(unsigned i) const {
	assert(i < Operands.size());
	return Operands[i];
	}


	// printImpl methods.

	void ScopeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "Scope\n";
	for (const Matcher *C : Children) {
	if (!C)
	OS.indent(indent+1) << "NULL POINTER\n";
	else
	C->print(OS, indent+2);
	}
	}

	void RecordMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "Record\n";
	}

	void RecordChildMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "RecordChild: " << ChildNo << '\n';
	}

	void RecordMemRefMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "RecordMemRef\n";
	}

	void CaptureGlueInputMatcher::printImpl(raw_ostream &OS, unsigned indent) const{
	OS.indent(indent) << "CaptureGlueInput\n";
	}

	void MoveChildMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "MoveChild " << ChildNo << '\n';
	}

	void MoveParentMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "MoveParent\n";
	}

	void CheckSameMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "CheckSame " << MatchNumber << '\n';
	}

	void CheckChildSameMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "CheckChild" << ChildNo << "Same\n";
	}

	void CheckPatternPredicateMatcher::
	printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "CheckPatternPredicate " << Predicate << '\n';
	}

	void CheckPredicateMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "CheckPredicate " << getPredicate().getFnName() << '\n';
	}

	void CheckOpcodeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "CheckOpcode " << Opcode.getEnumName() << '\n';
	}

	void SwitchOpcodeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "SwitchOpcode: {\n";
	for (const auto &C : Cases) {
	OS.indent(indent) << "case " << C.first->getEnumName() << ":\n";
	C.second->print(OS, indent+2);
	}
	OS.indent(indent) << "}\n";
	}


	void CheckTypeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "CheckType " << getEnumName(Type) << ", ResNo="
	<< ResNo << '\n';
	}

	void SwitchTypeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "SwitchType: {\n";
	for (const auto &C : Cases) {
	OS.indent(indent) << "case " << getEnumName(C.first) << ":\n";
	C.second->print(OS, indent+2);
	}
	OS.indent(indent) << "}\n";
	}

	void CheckChildTypeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "CheckChildType " << ChildNo << " "
	<< getEnumName(Type) << '\n';
	}


	void CheckIntegerMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "CheckInteger " << Value << '\n';
	}

	void CheckChildIntegerMatcher::printImpl(raw_ostream &OS,
	unsigned indent) const {
	OS.indent(indent) << "CheckChildInteger " << ChildNo << " " << Value << '\n';
	}

	void CheckCondCodeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "CheckCondCode ISD::" << CondCodeName << '\n';
	}

	void CheckValueTypeMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "CheckValueType MVT::" << TypeName << '\n';
	}

	void CheckComplexPatMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "CheckComplexPat " << Pattern.getSelectFunc() << '\n';
	}

	void CheckAndImmMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "CheckAndImm " << Value << '\n';
	}

	void CheckOrImmMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "CheckOrImm " << Value << '\n';
	}

	void CheckFoldableChainNodeMatcher::printImpl(raw_ostream &OS,
	unsigned indent) const {
	OS.indent(indent) << "CheckFoldableChainNode\n";
	}

	void EmitIntegerMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "EmitInteger " << Val << " VT=" << getEnumName(VT)
	<< '\n';
	}

	void EmitStringIntegerMatcher::
	printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "EmitStringInteger " << Val << " VT=" << getEnumName(VT)
	<< '\n';
	}

	void EmitRegisterMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "EmitRegister ";
	if (Reg)
	OS << Reg->getName();
	else
	OS << "zero_reg";
	OS << " VT=" << getEnumName(VT) << '\n';
	}

	void EmitConvertToTargetMatcher::
	printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "EmitConvertToTarget " << Slot << '\n';
	}

	void EmitMergeInputChainsMatcher::
	printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "EmitMergeInputChains <todo: args>\n";
	}

	void EmitCopyToRegMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "EmitCopyToReg <todo: args>\n";
	}

	void EmitNodeXFormMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "EmitNodeXForm " << NodeXForm->getName()
	<< " Slot=" << Slot << '\n';
	}


	void EmitNodeMatcherCommon::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent);
	OS << (isa<MorphNodeToMatcher>(this) ? "MorphNodeTo: " : "EmitNode: ")
	<< OpcodeName << ": <todo flags> ";

	for (unsigned i = 0, e = VTs.size(); i != e; ++i)
	OS << ' ' << getEnumName(VTs[i]);
	OS << '(';
	for (unsigned i = 0, e = Operands.size(); i != e; ++i)
	OS << Operands[i] << ' ';
	OS << ")\n";
	}

	void CompleteMatchMatcher::printImpl(raw_ostream &OS, unsigned indent) const {
	OS.indent(indent) << "CompleteMatch <todo args>\n";
	OS.indent(indent) << "Src = " << *Pattern.getSrcPattern() << "\n";
	OS.indent(indent) << "Dst = " << *Pattern.getDstPattern() << "\n";
	}

	bool CheckOpcodeMatcher::isEqualImpl(const Matcher *M) const {
	// Note: pointer equality isn't enough here, we have to check the enum names
	// to ensure that the nodes are for the same opcode.
	return cast<CheckOpcodeMatcher>(M)->Opcode.getEnumName() ==
	Opcode.getEnumName();
	}

	bool EmitNodeMatcherCommon::isEqualImpl(const Matcher *m) const {
	const EmitNodeMatcherCommon *M = cast<EmitNodeMatcherCommon>(m);
	return M->OpcodeName == OpcodeName && M->VTs == VTs &&
	M->Operands == Operands && M->HasChain == HasChain &&
	M->HasInGlue == HasInGlue && M->HasOutGlue == HasOutGlue &&
	M->HasMemRefs == HasMemRefs &&
	M->NumFixedArityOperands == NumFixedArityOperands;
	}

	void EmitNodeMatcher::anchor() { }

	void MorphNodeToMatcher::anchor() { }

	// isContradictoryImpl Implementations.

	static bool TypesAreContradictory(MVT::SimpleValueType T1,
	MVT::SimpleValueType T2) {
	// If the two types are the same, then they are the same, so they don't
	// contradict.
	if (T1 == T2) return false;

	// If either type is about iPtr, then they don't conflict unless the other
	// one is not a scalar integer type.
	if (T1 == MVT::iPTR)
	return !MVT(T2).isInteger() \|\| MVT(T2).isVector();

	if (T2 == MVT::iPTR)
	return !MVT(T1).isInteger() \|\| MVT(T1).isVector();

	// Otherwise, they are two different non-iPTR types, they conflict.
	return true;
	}

	bool CheckOpcodeMatcher::isContradictoryImpl(const Matcher *M) const {
	if (const CheckOpcodeMatcher *COM = dyn_cast<CheckOpcodeMatcher>(M)) {
	// One node can't have two different opcodes!
	// Note: pointer equality isn't enough here, we have to check the enum names
	// to ensure that the nodes are for the same opcode.
	return COM->getOpcode().getEnumName() != getOpcode().getEnumName();
	}

	// If the node has a known type, and if the type we're checking for is
	// different, then we know they contradict. For example, a check for
	// ISD::STORE will never be true at the same time a check for Type i32 is.
	if (const CheckTypeMatcher *CT = dyn_cast<CheckTypeMatcher>(M)) {
	// If checking for a result the opcode doesn't have, it can't match.
	if (CT->getResNo() >= getOpcode().getNumResults())
	return true;

	MVT::SimpleValueType NodeType = getOpcode().getKnownType(CT->getResNo());
	if (NodeType != MVT::Other)
	return TypesAreContradictory(NodeType, CT->getType());
	}

	return false;
	}

	bool CheckTypeMatcher::isContradictoryImpl(const Matcher *M) const {
	if (const CheckTypeMatcher *CT = dyn_cast<CheckTypeMatcher>(M))
	return TypesAreContradictory(getType(), CT->getType());
	return false;
	}

	bool CheckChildTypeMatcher::isContradictoryImpl(const Matcher *M) const {
	if (const CheckChildTypeMatcher *CC = dyn_cast<CheckChildTypeMatcher>(M)) {
	// If the two checks are about different nodes, we don't know if they
	// conflict!
	if (CC->getChildNo() != getChildNo())
	return false;

	return TypesAreContradictory(getType(), CC->getType());
	}
	return false;
	}

	bool CheckIntegerMatcher::isContradictoryImpl(const Matcher *M) const {
	if (const CheckIntegerMatcher *CIM = dyn_cast<CheckIntegerMatcher>(M))
	return CIM->getValue() != getValue();
	return false;
	}

	bool CheckChildIntegerMatcher::isContradictoryImpl(const Matcher *M) const {
	if (const CheckChildIntegerMatcher *CCIM = dyn_cast<CheckChildIntegerMatcher>(M)) {
	// If the two checks are about different nodes, we don't know if they
	// conflict!
	if (CCIM->getChildNo() != getChildNo())
	return false;

	return CCIM->getValue() != getValue();
	}
	return false;
	}

	bool CheckValueTypeMatcher::isContradictoryImpl(const Matcher *M) const {
	if (const CheckValueTypeMatcher *CVT = dyn_cast<CheckValueTypeMatcher>(M))
	return CVT->getTypeName() != getTypeName();
	return false;
	}