lib/Analysis/RValues.cpp - fp2-dev/platform/external/clang - Gitiles

 //= RValues.cpp - Abstract RValues for Path-Sens. Value Tracking -*- C++ -*-==//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 //  This file defines RVal, LVal, and NonLVal, classes that represent
 //  abstract r-values for use with path-sensitive value tracking.
 //
 //===----------------------------------------------------------------------===//

 #include "clang/Analysis/PathSensitive/RValues.h"
 #include "llvm/Support/Streams.h"

 using namespace clang;
 using llvm::dyn_cast;
 using llvm::cast;
 using llvm::APSInt;

 //===----------------------------------------------------------------------===//
 // Symbol Iteration.
 //===----------------------------------------------------------------------===//

 RVal::symbol_iterator RVal::symbol_begin() const {
   if (isa<lval::SymbolVal>(this))
     return (symbol_iterator) (&Data);
   else if (isa<nonlval::SymbolVal>(this))
     return (symbol_iterator) (&Data);
   else if (isa<nonlval::SymIntConstraintVal>(this)) {
     const SymIntConstraint& C =
       cast<nonlval::SymIntConstraintVal>(this)->getConstraint();

     return (symbol_iterator) &C.getSymbol();
   }
   else if (isa<nonlval::LValAsInteger>(this)) {
     const nonlval::LValAsInteger& V = cast<nonlval::LValAsInteger>(*this);
     return  V.getPersistentLVal().symbol_begin();
   }

   return NULL;
 }

 RVal::symbol_iterator RVal::symbol_end() const {
   symbol_iterator X = symbol_begin();
   return X ? X+1 : NULL;
 }

 //===----------------------------------------------------------------------===//
 // Transfer function dispatch for Non-LVals.
 //===----------------------------------------------------------------------===//

 RVal
 nonlval::ConcreteInt::EvalBinOp(BasicValueFactory& BasicVals, BinaryOperator::Opcode Op,
                                 const nonlval::ConcreteInt& R) const {

   const llvm::APSInt* X = BasicVals.EvaluateAPSInt(Op, getValue(), R.getValue());

   if (X)
     return nonlval::ConcreteInt(*X);
   else
     return UndefinedVal();
 }


   // Bitwise-Complement.

 nonlval::ConcreteInt
 nonlval::ConcreteInt::EvalComplement(BasicValueFactory& BasicVals) const {
   return BasicVals.getValue(~getValue());
 }

   // Unary Minus.

 nonlval::ConcreteInt
 nonlval::ConcreteInt::EvalMinus(BasicValueFactory& BasicVals, UnaryOperator* U) const {
   assert (U->getType() == U->getSubExpr()->getType());
   assert (U->getType()->isIntegerType());
   return BasicVals.getValue(-getValue());
 }

 //===----------------------------------------------------------------------===//
 // Transfer function dispatch for LVals.
 //===----------------------------------------------------------------------===//

 RVal
 lval::ConcreteInt::EvalBinOp(BasicValueFactory& BasicVals, BinaryOperator::Opcode Op,
                              const lval::ConcreteInt& R) const {

   assert (Op == BinaryOperator::Add || Op == BinaryOperator::Sub ||
           (Op >= BinaryOperator::LT && Op <= BinaryOperator::NE));

   const llvm::APSInt* X = BasicVals.EvaluateAPSInt(Op, getValue(), R.getValue());

   if (X)
     return lval::ConcreteInt(*X);
   else
     return UndefinedVal();
 }

 NonLVal LVal::EQ(BasicValueFactory& BasicVals, const LVal& R) const {

   switch (getSubKind()) {
     default:
       assert(false && "EQ not implemented for this LVal.");
       break;

     case lval::ConcreteIntKind:
       if (isa<lval::ConcreteInt>(R)) {
         bool b = cast<lval::ConcreteInt>(this)->getValue() ==
                  cast<lval::ConcreteInt>(R).getValue();

         return NonLVal::MakeIntTruthVal(BasicVals, b);
       }
       else if (isa<lval::SymbolVal>(R)) {

         const SymIntConstraint& C =
           BasicVals.getConstraint(cast<lval::SymbolVal>(R).getSymbol(),
                                BinaryOperator::EQ,
                                cast<lval::ConcreteInt>(this)->getValue());

         return nonlval::SymIntConstraintVal(C);
       }

       break;

       case lval::SymbolValKind: {
         if (isa<lval::ConcreteInt>(R)) {

           const SymIntConstraint& C =
             BasicVals.getConstraint(cast<lval::SymbolVal>(this)->getSymbol(),
                                  BinaryOperator::EQ,
                                  cast<lval::ConcreteInt>(R).getValue());

           return nonlval::SymIntConstraintVal(C);
         }

         assert (!isa<lval::SymbolVal>(R) && "FIXME: Implement unification.");

         break;
       }

       case lval::DeclValKind:
       if (isa<lval::DeclVal>(R)) {
         bool b = cast<lval::DeclVal>(*this) == cast<lval::DeclVal>(R);
         return NonLVal::MakeIntTruthVal(BasicVals, b);
       }

       break;
   }

   return NonLVal::MakeIntTruthVal(BasicVals, false);
 }

 NonLVal LVal::NE(BasicValueFactory& BasicVals, const LVal& R) const {
   switch (getSubKind()) {
     default:
       assert(false && "NE not implemented for this LVal.");
       break;

     case lval::ConcreteIntKind:
       if (isa<lval::ConcreteInt>(R)) {
         bool b = cast<lval::ConcreteInt>(this)->getValue() !=
                  cast<lval::ConcreteInt>(R).getValue();

         return NonLVal::MakeIntTruthVal(BasicVals, b);
       }
       else if (isa<lval::SymbolVal>(R)) {

         const SymIntConstraint& C =
         BasicVals.getConstraint(cast<lval::SymbolVal>(R).getSymbol(),
                              BinaryOperator::NE,
                              cast<lval::ConcreteInt>(this)->getValue());

         return nonlval::SymIntConstraintVal(C);
       }

       break;

       case lval::SymbolValKind: {
         if (isa<lval::ConcreteInt>(R)) {

           const SymIntConstraint& C =
           BasicVals.getConstraint(cast<lval::SymbolVal>(this)->getSymbol(),
                                BinaryOperator::NE,
                                cast<lval::ConcreteInt>(R).getValue());

           return nonlval::SymIntConstraintVal(C);
         }

         assert (!isa<lval::SymbolVal>(R) && "FIXME: Implement sym !=.");

         break;
       }

       case lval::DeclValKind:
         if (isa<lval::DeclVal>(R)) {
           bool b = cast<lval::DeclVal>(*this) == cast<lval::DeclVal>(R);
           return NonLVal::MakeIntTruthVal(BasicVals, b);
         }

         break;
   }

   return NonLVal::MakeIntTruthVal(BasicVals, true);
 }

 //===----------------------------------------------------------------------===//
 // Utility methods for constructing Non-LVals.
 //===----------------------------------------------------------------------===//

 NonLVal NonLVal::MakeVal(BasicValueFactory& BasicVals, uint64_t X, QualType T) {
   return nonlval::ConcreteInt(BasicVals.getValue(X, T));
 }

 NonLVal NonLVal::MakeVal(BasicValueFactory& BasicVals, IntegerLiteral* I) {

   return nonlval::ConcreteInt(BasicVals.getValue(APSInt(I->getValue(),
                               I->getType()->isUnsignedIntegerType())));
 }

 NonLVal NonLVal::MakeIntTruthVal(BasicValueFactory& BasicVals, bool b) {
   return nonlval::ConcreteInt(BasicVals.getTruthValue(b));
 }

 RVal RVal::GetSymbolValue(SymbolManager& SymMgr, VarDecl* D) {

   QualType T = D->getType();

   if (T->isPointerLikeType())
     return lval::SymbolVal(SymMgr.getSymbol(D));
   return nonlval::SymbolVal(SymMgr.getSymbol(D));
 }

 //===----------------------------------------------------------------------===//
 // Utility methods for constructing LVals.
 //===----------------------------------------------------------------------===//

 LVal LVal::MakeVal(AddrLabelExpr* E) { return lval::GotoLabel(E->getLabel()); }

 LVal LVal::MakeVal(StringLiteral* S) {
   return lval::StringLiteralVal(S);
 }

 //===----------------------------------------------------------------------===//
 // Utility methods for constructing RVals (both NonLVals and LVals).
 //===----------------------------------------------------------------------===//

 RVal RVal::MakeVal(BasicValueFactory& BasicVals, DeclRefExpr* E) {

   ValueDecl* D = cast<DeclRefExpr>(E)->getDecl();

   if (VarDecl* VD = dyn_cast<VarDecl>(D)) {
     return lval::DeclVal(VD);
   }
   else if (EnumConstantDecl* ED = dyn_cast<EnumConstantDecl>(D)) {

     // FIXME: Do we need to cache a copy of this enum, since it
     // already has persistent storage?  We do this because we
     // are comparing states using pointer equality.  Perhaps there is
     // a better way, since APInts are fairly lightweight.

     return nonlval::ConcreteInt(BasicVals.getValue(ED->getInitVal()));
   }
   else if (FunctionDecl* FD = dyn_cast<FunctionDecl>(D)) {
     return lval::FuncVal(FD);
   }

   assert (false &&
           "ValueDecl support for this ValueDecl not implemented.");

   return UnknownVal();
 }

 //===----------------------------------------------------------------------===//
 // Pretty-Printing.
 //===----------------------------------------------------------------------===//

 void RVal::printStdErr() const { print(*llvm::cerr.stream()); }

 void RVal::print(std::ostream& Out) const {

   switch (getBaseKind()) {

     case UnknownKind:
       Out << "Invalid"; break;

     case NonLValKind:
       cast<NonLVal>(this)->print(Out); break;

     case LValKind:
       cast<LVal>(this)->print(Out); break;

     case UndefinedKind:
       Out << "Undefined"; break;

     default:
       assert (false && "Invalid RVal.");
   }
 }

 static void printOpcode(std::ostream& Out, BinaryOperator::Opcode Op) {

   switch (Op) {
     case BinaryOperator::Mul: Out << '*'  ; break;
     case BinaryOperator::Div: Out << '/'  ; break;
     case BinaryOperator::Rem: Out << '%'  ; break;
     case BinaryOperator::Add: Out << '+'  ; break;
     case BinaryOperator::Sub: Out << '-'  ; break;
     case BinaryOperator::Shl: Out << "<<" ; break;
     case BinaryOperator::Shr: Out << ">>" ; break;
     case BinaryOperator::LT:  Out << "<"  ; break;
     case BinaryOperator::GT:  Out << '>'  ; break;
     case BinaryOperator::LE:  Out << "<=" ; break;
     case BinaryOperator::GE:  Out << ">=" ; break;
     case BinaryOperator::EQ:  Out << "==" ; break;
     case BinaryOperator::NE:  Out << "!=" ; break;
     case BinaryOperator::And: Out << '&'  ; break;
     case BinaryOperator::Xor: Out << '^'  ; break;
     case BinaryOperator::Or:  Out << '|'  ; break;

     default: assert(false && "Not yet implemented.");
   }
 }

 void NonLVal::print(std::ostream& Out) const {

   switch (getSubKind()) {

     case nonlval::ConcreteIntKind:
       Out << cast<nonlval::ConcreteInt>(this)->getValue().toString();

       if (cast<nonlval::ConcreteInt>(this)->getValue().isUnsigned())
         Out << 'U';

       break;

     case nonlval::SymbolValKind:
       Out << '$' << cast<nonlval::SymbolVal>(this)->getSymbol();
       break;

     case nonlval::SymIntConstraintValKind: {
       const nonlval::SymIntConstraintVal& C =
         *cast<nonlval::SymIntConstraintVal>(this);

       Out << '$' << C.getConstraint().getSymbol() << ' ';
       printOpcode(Out, C.getConstraint().getOpcode());
       Out << ' ' << C.getConstraint().getInt().toString();

       if (C.getConstraint().getInt().isUnsigned())
         Out << 'U';

       break;
     }

     case nonlval::LValAsIntegerKind: {
       const nonlval::LValAsInteger& C = *cast<nonlval::LValAsInteger>(this);
       C.getLVal().print(Out);
       Out << " [as " << C.getNumBits() << " bit integer]";
       break;
     }

     default:
       assert (false && "Pretty-printed not implemented for this NonLVal.");
       break;
   }
 }

 void LVal::print(std::ostream& Out) const {

   switch (getSubKind()) {

     case lval::ConcreteIntKind:
       Out << cast<lval::ConcreteInt>(this)->getValue().toString()
           << " (LVal)";
       break;

     case lval::SymbolValKind:
       Out << '$' << cast<lval::SymbolVal>(this)->getSymbol();
       break;

     case lval::GotoLabelKind:
       Out << "&&"
           << cast<lval::GotoLabel>(this)->getLabel()->getID()->getName();
       break;

     case lval::DeclValKind:
       Out << '&'
           << cast<lval::DeclVal>(this)->getDecl()->getIdentifier()->getName();
       break;

     case lval::FuncValKind:
       Out << "function "
           << cast<lval::FuncVal>(this)->getDecl()->getIdentifier()->getName();
       break;

     case lval::StringLiteralValKind:
       Out << "literal \""
           << cast<lval::StringLiteralVal>(this)->getLiteral()->getStrData()
           << "\"";
       break;

     default:
       assert (false && "Pretty-printing not implemented for this LVal.");
       break;
   }
 }
	//= RValues.cpp - Abstract RValues for Path-Sens. Value Tracking -- C++ --==//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines RVal, LVal, and NonLVal, classes that represent
	// abstract r-values for use with path-sensitive value tracking.
	//
	//===----------------------------------------------------------------------===//

	#include "clang/Analysis/PathSensitive/RValues.h"
	#include "llvm/Support/Streams.h"

	using namespace clang;
	using llvm::dyn_cast;
	using llvm::cast;
	using llvm::APSInt;

	//===----------------------------------------------------------------------===//
	// Symbol Iteration.
	//===----------------------------------------------------------------------===//

	RVal::symbol_iterator RVal::symbol_begin() const {
	if (isa<lval::SymbolVal>(this))
	return (symbol_iterator) (&Data);
	else if (isa<nonlval::SymbolVal>(this))
	return (symbol_iterator) (&Data);
	else if (isa<nonlval::SymIntConstraintVal>(this)) {
	const SymIntConstraint& C =
	cast<nonlval::SymIntConstraintVal>(this)->getConstraint();

	return (symbol_iterator) &C.getSymbol();
	}
	else if (isa<nonlval::LValAsInteger>(this)) {
	const nonlval::LValAsInteger& V = cast<nonlval::LValAsInteger>(*this);
	return V.getPersistentLVal().symbol_begin();
	}

	return NULL;
	}

	RVal::symbol_iterator RVal::symbol_end() const {
	symbol_iterator X = symbol_begin();
	return X ? X+1 : NULL;
	}

	//===----------------------------------------------------------------------===//
	// Transfer function dispatch for Non-LVals.
	//===----------------------------------------------------------------------===//

	RVal
	nonlval::ConcreteInt::EvalBinOp(BasicValueFactory& BasicVals, BinaryOperator::Opcode Op,
	const nonlval::ConcreteInt& R) const {

	const llvm::APSInt* X = BasicVals.EvaluateAPSInt(Op, getValue(), R.getValue());

	if (X)
	return nonlval::ConcreteInt(*X);
	else
	return UndefinedVal();
	}


	// Bitwise-Complement.

	nonlval::ConcreteInt
	nonlval::ConcreteInt::EvalComplement(BasicValueFactory& BasicVals) const {
	return BasicVals.getValue(~getValue());
	}

	// Unary Minus.

	nonlval::ConcreteInt
	nonlval::ConcreteInt::EvalMinus(BasicValueFactory& BasicVals, UnaryOperator* U) const {
	assert (U->getType() == U->getSubExpr()->getType());
	assert (U->getType()->isIntegerType());
	return BasicVals.getValue(-getValue());
	}

	//===----------------------------------------------------------------------===//
	// Transfer function dispatch for LVals.
	//===----------------------------------------------------------------------===//

	RVal
	lval::ConcreteInt::EvalBinOp(BasicValueFactory& BasicVals, BinaryOperator::Opcode Op,
	const lval::ConcreteInt& R) const {

	assert (Op == BinaryOperator::Add \|\| Op == BinaryOperator::Sub \|\|
	(Op >= BinaryOperator::LT && Op <= BinaryOperator::NE));

	const llvm::APSInt* X = BasicVals.EvaluateAPSInt(Op, getValue(), R.getValue());

	if (X)
	return lval::ConcreteInt(*X);
	else
	return UndefinedVal();
	}

	NonLVal LVal::EQ(BasicValueFactory& BasicVals, const LVal& R) const {

	switch (getSubKind()) {
	default:
	assert(false && "EQ not implemented for this LVal.");
	break;

	case lval::ConcreteIntKind:
	if (isa<lval::ConcreteInt>(R)) {
	bool b = cast<lval::ConcreteInt>(this)->getValue() ==
	cast<lval::ConcreteInt>(R).getValue();

	return NonLVal::MakeIntTruthVal(BasicVals, b);
	}
	else if (isa<lval::SymbolVal>(R)) {

	const SymIntConstraint& C =
	BasicVals.getConstraint(cast<lval::SymbolVal>(R).getSymbol(),
	BinaryOperator::EQ,
	cast<lval::ConcreteInt>(this)->getValue());

	return nonlval::SymIntConstraintVal(C);
	}

	break;

	case lval::SymbolValKind: {
	if (isa<lval::ConcreteInt>(R)) {

	const SymIntConstraint& C =
	BasicVals.getConstraint(cast<lval::SymbolVal>(this)->getSymbol(),
	BinaryOperator::EQ,
	cast<lval::ConcreteInt>(R).getValue());

	return nonlval::SymIntConstraintVal(C);
	}

	assert (!isa<lval::SymbolVal>(R) && "FIXME: Implement unification.");

	break;
	}

	case lval::DeclValKind:
	if (isa<lval::DeclVal>(R)) {
	bool b = cast<lval::DeclVal>(*this) == cast<lval::DeclVal>(R);
	return NonLVal::MakeIntTruthVal(BasicVals, b);
	}

	break;
	}

	return NonLVal::MakeIntTruthVal(BasicVals, false);
	}

	NonLVal LVal::NE(BasicValueFactory& BasicVals, const LVal& R) const {
	switch (getSubKind()) {
	default:
	assert(false && "NE not implemented for this LVal.");
	break;

	case lval::ConcreteIntKind:
	if (isa<lval::ConcreteInt>(R)) {
	bool b = cast<lval::ConcreteInt>(this)->getValue() !=
	cast<lval::ConcreteInt>(R).getValue();

	return NonLVal::MakeIntTruthVal(BasicVals, b);
	}
	else if (isa<lval::SymbolVal>(R)) {

	const SymIntConstraint& C =
	BasicVals.getConstraint(cast<lval::SymbolVal>(R).getSymbol(),
	BinaryOperator::NE,
	cast<lval::ConcreteInt>(this)->getValue());

	return nonlval::SymIntConstraintVal(C);
	}

	break;

	case lval::SymbolValKind: {
	if (isa<lval::ConcreteInt>(R)) {

	const SymIntConstraint& C =
	BasicVals.getConstraint(cast<lval::SymbolVal>(this)->getSymbol(),
	BinaryOperator::NE,
	cast<lval::ConcreteInt>(R).getValue());

	return nonlval::SymIntConstraintVal(C);
	}

	assert (!isa<lval::SymbolVal>(R) && "FIXME: Implement sym !=.");

	break;
	}

	case lval::DeclValKind:
	if (isa<lval::DeclVal>(R)) {
	bool b = cast<lval::DeclVal>(*this) == cast<lval::DeclVal>(R);
	return NonLVal::MakeIntTruthVal(BasicVals, b);
	}

	break;
	}

	return NonLVal::MakeIntTruthVal(BasicVals, true);
	}

	//===----------------------------------------------------------------------===//
	// Utility methods for constructing Non-LVals.
	//===----------------------------------------------------------------------===//

	NonLVal NonLVal::MakeVal(BasicValueFactory& BasicVals, uint64_t X, QualType T) {
	return nonlval::ConcreteInt(BasicVals.getValue(X, T));
	}

	NonLVal NonLVal::MakeVal(BasicValueFactory& BasicVals, IntegerLiteral* I) {

	return nonlval::ConcreteInt(BasicVals.getValue(APSInt(I->getValue(),
	I->getType()->isUnsignedIntegerType())));
	}

	NonLVal NonLVal::MakeIntTruthVal(BasicValueFactory& BasicVals, bool b) {
	return nonlval::ConcreteInt(BasicVals.getTruthValue(b));
	}

	RVal RVal::GetSymbolValue(SymbolManager& SymMgr, VarDecl* D) {

	QualType T = D->getType();

	if (T->isPointerLikeType())
	return lval::SymbolVal(SymMgr.getSymbol(D));
	return nonlval::SymbolVal(SymMgr.getSymbol(D));
	}

	//===----------------------------------------------------------------------===//
	// Utility methods for constructing LVals.
	//===----------------------------------------------------------------------===//

	LVal LVal::MakeVal(AddrLabelExpr* E) { return lval::GotoLabel(E->getLabel()); }

	LVal LVal::MakeVal(StringLiteral* S) {
	return lval::StringLiteralVal(S);
	}

	//===----------------------------------------------------------------------===//
	// Utility methods for constructing RVals (both NonLVals and LVals).
	//===----------------------------------------------------------------------===//

	RVal RVal::MakeVal(BasicValueFactory& BasicVals, DeclRefExpr* E) {

	ValueDecl* D = cast<DeclRefExpr>(E)->getDecl();

	if (VarDecl* VD = dyn_cast<VarDecl>(D)) {
	return lval::DeclVal(VD);
	}
	else if (EnumConstantDecl* ED = dyn_cast<EnumConstantDecl>(D)) {

	// FIXME: Do we need to cache a copy of this enum, since it
	// already has persistent storage? We do this because we
	// are comparing states using pointer equality. Perhaps there is
	// a better way, since APInts are fairly lightweight.

	return nonlval::ConcreteInt(BasicVals.getValue(ED->getInitVal()));
	}
	else if (FunctionDecl* FD = dyn_cast<FunctionDecl>(D)) {
	return lval::FuncVal(FD);
	}

	assert (false &&
	"ValueDecl support for this ValueDecl not implemented.");

	return UnknownVal();
	}

	//===----------------------------------------------------------------------===//
	// Pretty-Printing.
	//===----------------------------------------------------------------------===//

	void RVal::printStdErr() const { print(*llvm::cerr.stream()); }

	void RVal::print(std::ostream& Out) const {

	switch (getBaseKind()) {

	case UnknownKind:
	Out << "Invalid"; break;

	case NonLValKind:
	cast<NonLVal>(this)->print(Out); break;

	case LValKind:
	cast<LVal>(this)->print(Out); break;

	case UndefinedKind:
	Out << "Undefined"; break;

	default:
	assert (false && "Invalid RVal.");
	}
	}

	static void printOpcode(std::ostream& Out, BinaryOperator::Opcode Op) {

	switch (Op) {
	case BinaryOperator::Mul: Out << '*' ; break;
	case BinaryOperator::Div: Out << '/' ; break;
	case BinaryOperator::Rem: Out << '%' ; break;
	case BinaryOperator::Add: Out << '+' ; break;
	case BinaryOperator::Sub: Out << '-' ; break;
	case BinaryOperator::Shl: Out << "<<" ; break;
	case BinaryOperator::Shr: Out << ">>" ; break;
	case BinaryOperator::LT: Out << "<" ; break;
	case BinaryOperator::GT: Out << '>' ; break;
	case BinaryOperator::LE: Out << "<=" ; break;
	case BinaryOperator::GE: Out << ">=" ; break;
	case BinaryOperator::EQ: Out << "==" ; break;
	case BinaryOperator::NE: Out << "!=" ; break;
	case BinaryOperator::And: Out << '&' ; break;
	case BinaryOperator::Xor: Out << '^' ; break;
	case BinaryOperator::Or: Out << '\|' ; break;

	default: assert(false && "Not yet implemented.");
	}
	}

	void NonLVal::print(std::ostream& Out) const {

	switch (getSubKind()) {

	case nonlval::ConcreteIntKind:
	Out << cast<nonlval::ConcreteInt>(this)->getValue().toString();

	if (cast<nonlval::ConcreteInt>(this)->getValue().isUnsigned())
	Out << 'U';

	break;

	case nonlval::SymbolValKind:
	Out << '$' << cast<nonlval::SymbolVal>(this)->getSymbol();
	break;

	case nonlval::SymIntConstraintValKind: {
	const nonlval::SymIntConstraintVal& C =
	*cast<nonlval::SymIntConstraintVal>(this);

	Out << '$' << C.getConstraint().getSymbol() << ' ';
	printOpcode(Out, C.getConstraint().getOpcode());
	Out << ' ' << C.getConstraint().getInt().toString();

	if (C.getConstraint().getInt().isUnsigned())
	Out << 'U';

	break;
	}

	case nonlval::LValAsIntegerKind: {
	const nonlval::LValAsInteger& C = *cast<nonlval::LValAsInteger>(this);
	C.getLVal().print(Out);
	Out << " [as " << C.getNumBits() << " bit integer]";
	break;
	}

	default:
	assert (false && "Pretty-printed not implemented for this NonLVal.");
	break;
	}
	}

	void LVal::print(std::ostream& Out) const {

	switch (getSubKind()) {

	case lval::ConcreteIntKind:
	Out << cast<lval::ConcreteInt>(this)->getValue().toString()
	<< " (LVal)";
	break;

	case lval::SymbolValKind:
	Out << '$' << cast<lval::SymbolVal>(this)->getSymbol();
	break;

	case lval::GotoLabelKind:
	Out << "&&"
	<< cast<lval::GotoLabel>(this)->getLabel()->getID()->getName();
	break;

	case lval::DeclValKind:
	Out << '&'
	<< cast<lval::DeclVal>(this)->getDecl()->getIdentifier()->getName();
	break;

	case lval::FuncValKind:
	Out << "function "
	<< cast<lval::FuncVal>(this)->getDecl()->getIdentifier()->getName();
	break;

	case lval::StringLiteralValKind:
	Out << "literal \""
	<< cast<lval::StringLiteralVal>(this)->getLiteral()->getStrData()
	<< "\"";
	break;

	default:
	assert (false && "Pretty-printing not implemented for this LVal.");
	break;
	}
	}