lib/Checker/SimpleConstraintManager.cpp - clang - Git at Google

 //== SimpleConstraintManager.cpp --------------------------------*- 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 SimpleConstraintManager, a class that holds code shared
 //  between BasicConstraintManager and RangeConstraintManager.
 //
 //===----------------------------------------------------------------------===//

 #include "SimpleConstraintManager.h"
 #include "clang/Checker/PathSensitive/GRExprEngine.h"
 #include "clang/Checker/PathSensitive/GRState.h"
 #include "clang/Checker/PathSensitive/Checker.h"

 namespace clang {

 SimpleConstraintManager::~SimpleConstraintManager() {}

 bool SimpleConstraintManager::canReasonAbout(SVal X) const {
   if (nonloc::SymExprVal *SymVal = dyn_cast<nonloc::SymExprVal>(&X)) {
     const SymExpr *SE = SymVal->getSymbolicExpression();

     if (isa<SymbolData>(SE))
       return true;

     if (const SymIntExpr *SIE = dyn_cast<SymIntExpr>(SE)) {
       switch (SIE->getOpcode()) {
           // We don't reason yet about bitwise-constraints on symbolic values.
         case BinaryOperator::And:
         case BinaryOperator::Or:
         case BinaryOperator::Xor:
           return false;
         // We don't reason yet about arithmetic constraints on symbolic values.
         case BinaryOperator::Mul:
         case BinaryOperator::Div:
         case BinaryOperator::Rem:
         case BinaryOperator::Add:
         case BinaryOperator::Sub:
         case BinaryOperator::Shl:
         case BinaryOperator::Shr:
           return false;
         // All other cases.
         default:
           return true;
       }
     }

     return false;
   }

   return true;
 }

 const GRState *SimpleConstraintManager::Assume(const GRState *state,
                                                DefinedSVal Cond,
                                                bool Assumption) {
   if (isa<NonLoc>(Cond))
     return Assume(state, cast<NonLoc>(Cond), Assumption);
   else
     return Assume(state, cast<Loc>(Cond), Assumption);
 }

 const GRState *SimpleConstraintManager::Assume(const GRState *state, Loc cond,
                                                bool assumption) {
   state = AssumeAux(state, cond, assumption);
   return SU.ProcessAssume(state, cond, assumption);
 }

 const GRState *SimpleConstraintManager::AssumeAux(const GRState *state,
                                                   Loc Cond, bool Assumption) {

   BasicValueFactory &BasicVals = state->getBasicVals();

   switch (Cond.getSubKind()) {
   default:
     assert (false && "'Assume' not implemented for this Loc.");
     return state;

   case loc::MemRegionKind: {
     // FIXME: Should this go into the storemanager?

     const MemRegion *R = cast<loc::MemRegionVal>(Cond).getRegion();
     const SubRegion *SubR = dyn_cast<SubRegion>(R);

     while (SubR) {
       // FIXME: now we only find the first symbolic region.
       if (const SymbolicRegion *SymR = dyn_cast<SymbolicRegion>(SubR)) {
         if (Assumption)
           return AssumeSymNE(state, SymR->getSymbol(),
                              BasicVals.getZeroWithPtrWidth());
         else
           return AssumeSymEQ(state, SymR->getSymbol(),
                              BasicVals.getZeroWithPtrWidth());
       }
       SubR = dyn_cast<SubRegion>(SubR->getSuperRegion());
     }

     // FALL-THROUGH.
   }

   case loc::GotoLabelKind:
     return Assumption ? state : NULL;

   case loc::ConcreteIntKind: {
     bool b = cast<loc::ConcreteInt>(Cond).getValue() != 0;
     bool isFeasible = b ? Assumption : !Assumption;
     return isFeasible ? state : NULL;
   }
   } // end switch
 }

 const GRState *SimpleConstraintManager::Assume(const GRState *state,
                                                NonLoc cond,
                                                bool assumption) {
   state = AssumeAux(state, cond, assumption);
   return SU.ProcessAssume(state, cond, assumption);
 }

 const GRState *SimpleConstraintManager::AssumeAux(const GRState *state,
                                                   NonLoc Cond,
                                                   bool Assumption) {

   // We cannot reason about SymIntExpr and SymSymExpr.
   if (!canReasonAbout(Cond)) {
     // Just return the current state indicating that the path is feasible.
     // This may be an over-approximation of what is possible.
     return state;
   }

   BasicValueFactory &BasicVals = state->getBasicVals();
   SymbolManager &SymMgr = state->getSymbolManager();

   switch (Cond.getSubKind()) {
   default:
     assert(false && "'Assume' not implemented for this NonLoc");

   case nonloc::SymbolValKind: {
     nonloc::SymbolVal& SV = cast<nonloc::SymbolVal>(Cond);
     SymbolRef sym = SV.getSymbol();
     QualType T =  SymMgr.getType(sym);
     const llvm::APSInt &zero = BasicVals.getValue(0, T);

     return Assumption ? AssumeSymNE(state, sym, zero)
                       : AssumeSymEQ(state, sym, zero);
   }

   case nonloc::SymExprValKind: {
     nonloc::SymExprVal V = cast<nonloc::SymExprVal>(Cond);
     if (const SymIntExpr *SE = dyn_cast<SymIntExpr>(V.getSymbolicExpression())){
       // FIXME: This is a hack.  It silently converts the RHS integer to be
       // of the same type as on the left side.  This should be removed once
       // we support truncation/extension of symbolic values.
       GRStateManager &StateMgr = state->getStateManager();
       ASTContext &Ctx = StateMgr.getContext();
       QualType LHSType = SE->getLHS()->getType(Ctx);
       BasicValueFactory &BasicVals = StateMgr.getBasicVals();
       const llvm::APSInt &RHS = BasicVals.Convert(LHSType, SE->getRHS());
       SymIntExpr SENew(SE->getLHS(), SE->getOpcode(), RHS, SE->getType(Ctx));

       return AssumeSymInt(state, Assumption, &SENew);
     }

     // For all other symbolic expressions, over-approximate and consider
     // the constraint feasible.
     return state;
   }

   case nonloc::ConcreteIntKind: {
     bool b = cast<nonloc::ConcreteInt>(Cond).getValue() != 0;
     bool isFeasible = b ? Assumption : !Assumption;
     return isFeasible ? state : NULL;
   }

   case nonloc::LocAsIntegerKind:
     return AssumeAux(state, cast<nonloc::LocAsInteger>(Cond).getLoc(),
                      Assumption);
   } // end switch
 }

 const GRState *SimpleConstraintManager::AssumeSymInt(const GRState *state,
                                                      bool Assumption,
                                                      const SymIntExpr *SE) {


   // Here we assume that LHS is a symbol.  This is consistent with the
   // rest of the constraint manager logic.
   SymbolRef Sym = cast<SymbolData>(SE->getLHS());
   const llvm::APSInt &Int = SE->getRHS();

   switch (SE->getOpcode()) {
   default:
     // No logic yet for other operators.  Assume the constraint is feasible.
     return state;

   case BinaryOperator::EQ:
     return Assumption ? AssumeSymEQ(state, Sym, Int)
                       : AssumeSymNE(state, Sym, Int);

   case BinaryOperator::NE:
     return Assumption ? AssumeSymNE(state, Sym, Int)
                       : AssumeSymEQ(state, Sym, Int);
   case BinaryOperator::GT:
     return Assumption ? AssumeSymGT(state, Sym, Int)
                       : AssumeSymLE(state, Sym, Int);

   case BinaryOperator::GE:
     return Assumption ? AssumeSymGE(state, Sym, Int)
                       : AssumeSymLT(state, Sym, Int);

   case BinaryOperator::LT:
     return Assumption ? AssumeSymLT(state, Sym, Int)
                       : AssumeSymGE(state, Sym, Int);

   case BinaryOperator::LE:
     return Assumption ? AssumeSymLE(state, Sym, Int)
                       : AssumeSymGT(state, Sym, Int);
   } // end switch
 }

 const GRState *SimpleConstraintManager::AssumeInBound(const GRState *state,
                                                       DefinedSVal Idx,
                                                       DefinedSVal UpperBound,
                                                       bool Assumption) {

   // Only support ConcreteInt for now.
   if (!(isa<nonloc::ConcreteInt>(Idx) && isa<nonloc::ConcreteInt>(UpperBound)))
     return state;

   const llvm::APSInt& Zero = state->getBasicVals().getZeroWithPtrWidth(false);
   llvm::APSInt IdxV = cast<nonloc::ConcreteInt>(Idx).getValue();
   // IdxV might be too narrow.
   if (IdxV.getBitWidth() < Zero.getBitWidth())
     IdxV.extend(Zero.getBitWidth());
   // UBV might be too narrow, too.
   llvm::APSInt UBV = cast<nonloc::ConcreteInt>(UpperBound).getValue();
   if (UBV.getBitWidth() < Zero.getBitWidth())
     UBV.extend(Zero.getBitWidth());

   bool InBound = (Zero <= IdxV) && (IdxV < UBV);
   bool isFeasible = Assumption ? InBound : !InBound;
   return isFeasible ? state : NULL;
 }

 }  // end of namespace clang
	//== SimpleConstraintManager.cpp --------------------------------- 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 SimpleConstraintManager, a class that holds code shared
	// between BasicConstraintManager and RangeConstraintManager.
	//
	//===----------------------------------------------------------------------===//

	#include "SimpleConstraintManager.h"
	#include "clang/Checker/PathSensitive/GRExprEngine.h"
	#include "clang/Checker/PathSensitive/GRState.h"
	#include "clang/Checker/PathSensitive/Checker.h"

	namespace clang {

	SimpleConstraintManager::~SimpleConstraintManager() {}

	bool SimpleConstraintManager::canReasonAbout(SVal X) const {
	if (nonloc::SymExprVal *SymVal = dyn_cast<nonloc::SymExprVal>(&X)) {
	const SymExpr *SE = SymVal->getSymbolicExpression();

	if (isa<SymbolData>(SE))
	return true;

	if (const SymIntExpr *SIE = dyn_cast<SymIntExpr>(SE)) {
	switch (SIE->getOpcode()) {
	// We don't reason yet about bitwise-constraints on symbolic values.
	case BinaryOperator::And:
	case BinaryOperator::Or:
	case BinaryOperator::Xor:
	return false;
	// We don't reason yet about arithmetic constraints on symbolic values.
	case BinaryOperator::Mul:
	case BinaryOperator::Div:
	case BinaryOperator::Rem:
	case BinaryOperator::Add:
	case BinaryOperator::Sub:
	case BinaryOperator::Shl:
	case BinaryOperator::Shr:
	return false;
	// All other cases.
	default:
	return true;
	}
	}

	return false;
	}

	return true;
	}

	const GRState SimpleConstraintManager::Assume(const GRState state,
	DefinedSVal Cond,
	bool Assumption) {
	if (isa<NonLoc>(Cond))
	return Assume(state, cast<NonLoc>(Cond), Assumption);
	else
	return Assume(state, cast<Loc>(Cond), Assumption);
	}

	const GRState SimpleConstraintManager::Assume(const GRState state, Loc cond,
	bool assumption) {
	state = AssumeAux(state, cond, assumption);
	return SU.ProcessAssume(state, cond, assumption);
	}

	const GRState SimpleConstraintManager::AssumeAux(const GRState state,
	Loc Cond, bool Assumption) {

	BasicValueFactory &BasicVals = state->getBasicVals();

	switch (Cond.getSubKind()) {
	default:
	assert (false && "'Assume' not implemented for this Loc.");
	return state;

	case loc::MemRegionKind: {
	// FIXME: Should this go into the storemanager?

	const MemRegion *R = cast<loc::MemRegionVal>(Cond).getRegion();
	const SubRegion *SubR = dyn_cast<SubRegion>(R);

	while (SubR) {
	// FIXME: now we only find the first symbolic region.
	if (const SymbolicRegion *SymR = dyn_cast<SymbolicRegion>(SubR)) {
	if (Assumption)
	return AssumeSymNE(state, SymR->getSymbol(),
	BasicVals.getZeroWithPtrWidth());
	else
	return AssumeSymEQ(state, SymR->getSymbol(),
	BasicVals.getZeroWithPtrWidth());
	}
	SubR = dyn_cast<SubRegion>(SubR->getSuperRegion());
	}

	// FALL-THROUGH.
	}

	case loc::GotoLabelKind:
	return Assumption ? state : NULL;

	case loc::ConcreteIntKind: {
	bool b = cast<loc::ConcreteInt>(Cond).getValue() != 0;
	bool isFeasible = b ? Assumption : !Assumption;
	return isFeasible ? state : NULL;
	}
	} // end switch
	}

	const GRState SimpleConstraintManager::Assume(const GRState state,
	NonLoc cond,
	bool assumption) {
	state = AssumeAux(state, cond, assumption);
	return SU.ProcessAssume(state, cond, assumption);
	}

	const GRState SimpleConstraintManager::AssumeAux(const GRState state,
	NonLoc Cond,
	bool Assumption) {

	// We cannot reason about SymIntExpr and SymSymExpr.
	if (!canReasonAbout(Cond)) {
	// Just return the current state indicating that the path is feasible.
	// This may be an over-approximation of what is possible.
	return state;
	}

	BasicValueFactory &BasicVals = state->getBasicVals();
	SymbolManager &SymMgr = state->getSymbolManager();

	switch (Cond.getSubKind()) {
	default:
	assert(false && "'Assume' not implemented for this NonLoc");

	case nonloc::SymbolValKind: {
	nonloc::SymbolVal& SV = cast<nonloc::SymbolVal>(Cond);
	SymbolRef sym = SV.getSymbol();
	QualType T = SymMgr.getType(sym);
	const llvm::APSInt &zero = BasicVals.getValue(0, T);

	return Assumption ? AssumeSymNE(state, sym, zero)
	: AssumeSymEQ(state, sym, zero);
	}

	case nonloc::SymExprValKind: {
	nonloc::SymExprVal V = cast<nonloc::SymExprVal>(Cond);
	if (const SymIntExpr *SE = dyn_cast<SymIntExpr>(V.getSymbolicExpression())){
	// FIXME: This is a hack. It silently converts the RHS integer to be
	// of the same type as on the left side. This should be removed once
	// we support truncation/extension of symbolic values.
	GRStateManager &StateMgr = state->getStateManager();
	ASTContext &Ctx = StateMgr.getContext();
	QualType LHSType = SE->getLHS()->getType(Ctx);
	BasicValueFactory &BasicVals = StateMgr.getBasicVals();
	const llvm::APSInt &RHS = BasicVals.Convert(LHSType, SE->getRHS());
	SymIntExpr SENew(SE->getLHS(), SE->getOpcode(), RHS, SE->getType(Ctx));

	return AssumeSymInt(state, Assumption, &SENew);
	}

	// For all other symbolic expressions, over-approximate and consider
	// the constraint feasible.
	return state;
	}

	case nonloc::ConcreteIntKind: {
	bool b = cast<nonloc::ConcreteInt>(Cond).getValue() != 0;
	bool isFeasible = b ? Assumption : !Assumption;
	return isFeasible ? state : NULL;
	}

	case nonloc::LocAsIntegerKind:
	return AssumeAux(state, cast<nonloc::LocAsInteger>(Cond).getLoc(),
	Assumption);
	} // end switch
	}

	const GRState SimpleConstraintManager::AssumeSymInt(const GRState state,
	bool Assumption,
	const SymIntExpr *SE) {


	// Here we assume that LHS is a symbol. This is consistent with the
	// rest of the constraint manager logic.
	SymbolRef Sym = cast<SymbolData>(SE->getLHS());
	const llvm::APSInt &Int = SE->getRHS();

	switch (SE->getOpcode()) {
	default:
	// No logic yet for other operators. Assume the constraint is feasible.
	return state;

	case BinaryOperator::EQ:
	return Assumption ? AssumeSymEQ(state, Sym, Int)
	: AssumeSymNE(state, Sym, Int);

	case BinaryOperator::NE:
	return Assumption ? AssumeSymNE(state, Sym, Int)
	: AssumeSymEQ(state, Sym, Int);
	case BinaryOperator::GT:
	return Assumption ? AssumeSymGT(state, Sym, Int)
	: AssumeSymLE(state, Sym, Int);

	case BinaryOperator::GE:
	return Assumption ? AssumeSymGE(state, Sym, Int)
	: AssumeSymLT(state, Sym, Int);

	case BinaryOperator::LT:
	return Assumption ? AssumeSymLT(state, Sym, Int)
	: AssumeSymGE(state, Sym, Int);

	case BinaryOperator::LE:
	return Assumption ? AssumeSymLE(state, Sym, Int)
	: AssumeSymGT(state, Sym, Int);
	} // end switch
	}

	const GRState SimpleConstraintManager::AssumeInBound(const GRState state,
	DefinedSVal Idx,
	DefinedSVal UpperBound,
	bool Assumption) {

	// Only support ConcreteInt for now.
	if (!(isa<nonloc::ConcreteInt>(Idx) && isa<nonloc::ConcreteInt>(UpperBound)))
	return state;

	const llvm::APSInt& Zero = state->getBasicVals().getZeroWithPtrWidth(false);
	llvm::APSInt IdxV = cast<nonloc::ConcreteInt>(Idx).getValue();
	// IdxV might be too narrow.
	if (IdxV.getBitWidth() < Zero.getBitWidth())
	IdxV.extend(Zero.getBitWidth());
	// UBV might be too narrow, too.
	llvm::APSInt UBV = cast<nonloc::ConcreteInt>(UpperBound).getValue();
	if (UBV.getBitWidth() < Zero.getBitWidth())
	UBV.extend(Zero.getBitWidth());

	bool InBound = (Zero <= IdxV) && (IdxV < UBV);
	bool isFeasible = Assumption ? InBound : !InBound;
	return isFeasible ? state : NULL;
	}

	} // end of namespace clang