lib/StaticAnalyzer/Core/Store.cpp - third_party/swift-clang - Git at Google

 //== Store.cpp - Interface for maps from Locations to Values ----*- C++ -*--==//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 //  This file defined the types Store and StoreManager.
 //
 //===----------------------------------------------------------------------===//

 #include "clang/StaticAnalyzer/Core/PathSensitive/Store.h"
 #include "clang/AST/CXXInheritance.h"
 #include "clang/AST/CharUnits.h"
 #include "clang/AST/DeclObjC.h"
 #include "clang/StaticAnalyzer/Core/PathSensitive/CallEvent.h"
 #include "clang/StaticAnalyzer/Core/PathSensitive/ProgramState.h"

 using namespace clang;
 using namespace ento;

 StoreManager::StoreManager(ProgramStateManager &stateMgr)
   : svalBuilder(stateMgr.getSValBuilder()), StateMgr(stateMgr),
     MRMgr(svalBuilder.getRegionManager()), Ctx(stateMgr.getContext()) {}

 StoreRef StoreManager::enterStackFrame(Store OldStore,
                                        const CallEvent &Call,
                                        const StackFrameContext *LCtx) {
   StoreRef Store = StoreRef(OldStore, *this);

   SmallVector<CallEvent::FrameBindingTy, 16> InitialBindings;
   Call.getInitialStackFrameContents(LCtx, InitialBindings);

   for (CallEvent::BindingsTy::iterator I = InitialBindings.begin(),
                                        E = InitialBindings.end();
        I != E; ++I) {
     Store = Bind(Store.getStore(), I->first, I->second);
   }

   return Store;
 }

 const MemRegion *StoreManager::MakeElementRegion(const MemRegion *Base,
                                               QualType EleTy, uint64_t index) {
   NonLoc idx = svalBuilder.makeArrayIndex(index);
   return MRMgr.getElementRegion(EleTy, idx, Base, svalBuilder.getContext());
 }

 StoreRef StoreManager::BindDefault(Store store, const MemRegion *R, SVal V) {
   return StoreRef(store, *this);
 }

 const ElementRegion *StoreManager::GetElementZeroRegion(const MemRegion *R,
                                                         QualType T) {
   NonLoc idx = svalBuilder.makeZeroArrayIndex();
   assert(!T.isNull());
   return MRMgr.getElementRegion(T, idx, R, Ctx);
 }

 const MemRegion *StoreManager::castRegion(const MemRegion *R, QualType CastToTy) {

   ASTContext &Ctx = StateMgr.getContext();

   // Handle casts to Objective-C objects.
   if (CastToTy->isObjCObjectPointerType())
     return R->StripCasts();

   if (CastToTy->isBlockPointerType()) {
     // FIXME: We may need different solutions, depending on the symbol
     // involved.  Blocks can be casted to/from 'id', as they can be treated
     // as Objective-C objects.  This could possibly be handled by enhancing
     // our reasoning of downcasts of symbolic objects.
     if (isa<CodeTextRegion>(R) || isa<SymbolicRegion>(R))
       return R;

     // We don't know what to make of it.  Return a NULL region, which
     // will be interpretted as UnknownVal.
     return nullptr;
   }

   // Now assume we are casting from pointer to pointer. Other cases should
   // already be handled.
   QualType PointeeTy = CastToTy->getPointeeType();
   QualType CanonPointeeTy = Ctx.getCanonicalType(PointeeTy);

   // Handle casts to void*.  We just pass the region through.
   if (CanonPointeeTy.getLocalUnqualifiedType() == Ctx.VoidTy)
     return R;

   // Handle casts from compatible types.
   if (R->isBoundable())
     if (const TypedValueRegion *TR = dyn_cast<TypedValueRegion>(R)) {
       QualType ObjTy = Ctx.getCanonicalType(TR->getValueType());
       if (CanonPointeeTy == ObjTy)
         return R;
     }

   // Process region cast according to the kind of the region being cast.
   switch (R->getKind()) {
     case MemRegion::CXXThisRegionKind:
     case MemRegion::GenericMemSpaceRegionKind:
     case MemRegion::StackLocalsSpaceRegionKind:
     case MemRegion::StackArgumentsSpaceRegionKind:
     case MemRegion::HeapSpaceRegionKind:
     case MemRegion::UnknownSpaceRegionKind:
     case MemRegion::StaticGlobalSpaceRegionKind:
     case MemRegion::GlobalInternalSpaceRegionKind:
     case MemRegion::GlobalSystemSpaceRegionKind:
     case MemRegion::GlobalImmutableSpaceRegionKind: {
       llvm_unreachable("Invalid region cast");
     }

     case MemRegion::FunctionTextRegionKind:
     case MemRegion::BlockTextRegionKind:
     case MemRegion::BlockDataRegionKind:
     case MemRegion::StringRegionKind:
       // FIXME: Need to handle arbitrary downcasts.
     case MemRegion::SymbolicRegionKind:
     case MemRegion::AllocaRegionKind:
     case MemRegion::CompoundLiteralRegionKind:
     case MemRegion::FieldRegionKind:
     case MemRegion::ObjCIvarRegionKind:
     case MemRegion::ObjCStringRegionKind:
     case MemRegion::VarRegionKind:
     case MemRegion::CXXTempObjectRegionKind:
     case MemRegion::CXXBaseObjectRegionKind:
       return MakeElementRegion(R, PointeeTy);

     case MemRegion::ElementRegionKind: {
       // If we are casting from an ElementRegion to another type, the
       // algorithm is as follows:
       //
       // (1) Compute the "raw offset" of the ElementRegion from the
       //     base region.  This is done by calling 'getAsRawOffset()'.
       //
       // (2a) If we get a 'RegionRawOffset' after calling
       //      'getAsRawOffset()', determine if the absolute offset
       //      can be exactly divided into chunks of the size of the
       //      casted-pointee type.  If so, create a new ElementRegion with
       //      the pointee-cast type as the new ElementType and the index
       //      being the offset divded by the chunk size.  If not, create
       //      a new ElementRegion at offset 0 off the raw offset region.
       //
       // (2b) If we don't a get a 'RegionRawOffset' after calling
       //      'getAsRawOffset()', it means that we are at offset 0.
       //
       // FIXME: Handle symbolic raw offsets.

       const ElementRegion *elementR = cast<ElementRegion>(R);
       const RegionRawOffset &rawOff = elementR->getAsArrayOffset();
       const MemRegion *baseR = rawOff.getRegion();

       // If we cannot compute a raw offset, throw up our hands and return
       // a NULL MemRegion*.
       if (!baseR)
         return nullptr;

       CharUnits off = rawOff.getOffset();

       if (off.isZero()) {
         // Edge case: we are at 0 bytes off the beginning of baseR.  We
         // check to see if type we are casting to is the same as the base
         // region.  If so, just return the base region.
         if (const TypedValueRegion *TR = dyn_cast<TypedValueRegion>(baseR)) {
           QualType ObjTy = Ctx.getCanonicalType(TR->getValueType());
           QualType CanonPointeeTy = Ctx.getCanonicalType(PointeeTy);
           if (CanonPointeeTy == ObjTy)
             return baseR;
         }

         // Otherwise, create a new ElementRegion at offset 0.
         return MakeElementRegion(baseR, PointeeTy);
       }

       // We have a non-zero offset from the base region.  We want to determine
       // if the offset can be evenly divided by sizeof(PointeeTy).  If so,
       // we create an ElementRegion whose index is that value.  Otherwise, we
       // create two ElementRegions, one that reflects a raw offset and the other
       // that reflects the cast.

       // Compute the index for the new ElementRegion.
       int64_t newIndex = 0;
       const MemRegion *newSuperR = nullptr;

       // We can only compute sizeof(PointeeTy) if it is a complete type.
       if (!PointeeTy->isIncompleteType()) {
         // Compute the size in **bytes**.
         CharUnits pointeeTySize = Ctx.getTypeSizeInChars(PointeeTy);
         if (!pointeeTySize.isZero()) {
           // Is the offset a multiple of the size?  If so, we can layer the
           // ElementRegion (with elementType == PointeeTy) directly on top of
           // the base region.
           if (off % pointeeTySize == 0) {
             newIndex = off / pointeeTySize;
             newSuperR = baseR;
           }
         }
       }

       if (!newSuperR) {
         // Create an intermediate ElementRegion to represent the raw byte.
         // This will be the super region of the final ElementRegion.
         newSuperR = MakeElementRegion(baseR, Ctx.CharTy, off.getQuantity());
       }

       return MakeElementRegion(newSuperR, PointeeTy, newIndex);
     }
   }

   llvm_unreachable("unreachable");
 }

 static bool regionMatchesCXXRecordType(SVal V, QualType Ty) {
   const MemRegion *MR = V.getAsRegion();
   if (!MR)
     return true;

   const TypedValueRegion *TVR = dyn_cast<TypedValueRegion>(MR);
   if (!TVR)
     return true;

   const CXXRecordDecl *RD = TVR->getValueType()->getAsCXXRecordDecl();
   if (!RD)
     return true;

   const CXXRecordDecl *Expected = Ty->getPointeeCXXRecordDecl();
   if (!Expected)
     Expected = Ty->getAsCXXRecordDecl();

   return Expected->getCanonicalDecl() == RD->getCanonicalDecl();
 }

 SVal StoreManager::evalDerivedToBase(SVal Derived, const CastExpr *Cast) {
   // Sanity check to avoid doing the wrong thing in the face of
   // reinterpret_cast.
   if (!regionMatchesCXXRecordType(Derived, Cast->getSubExpr()->getType()))
     return UnknownVal();

   // Walk through the cast path to create nested CXXBaseRegions.
   SVal Result = Derived;
   for (CastExpr::path_const_iterator I = Cast->path_begin(),
                                      E = Cast->path_end();
        I != E; ++I) {
     Result = evalDerivedToBase(Result, (*I)->getType(), (*I)->isVirtual());
   }
   return Result;
 }

 SVal StoreManager::evalDerivedToBase(SVal Derived, const CXXBasePath &Path) {
   // Walk through the path to create nested CXXBaseRegions.
   SVal Result = Derived;
   for (CXXBasePath::const_iterator I = Path.begin(), E = Path.end();
        I != E; ++I) {
     Result = evalDerivedToBase(Result, I->Base->getType(),
                                I->Base->isVirtual());
   }
   return Result;
 }

 SVal StoreManager::evalDerivedToBase(SVal Derived, QualType BaseType,
                                      bool IsVirtual) {
   Optional<loc::MemRegionVal> DerivedRegVal =
       Derived.getAs<loc::MemRegionVal>();
   if (!DerivedRegVal)
     return Derived;

   const CXXRecordDecl *BaseDecl = BaseType->getPointeeCXXRecordDecl();
   if (!BaseDecl)
     BaseDecl = BaseType->getAsCXXRecordDecl();
   assert(BaseDecl && "not a C++ object?");

   const MemRegion *BaseReg =
     MRMgr.getCXXBaseObjectRegion(BaseDecl, DerivedRegVal->getRegion(),
                                  IsVirtual);

   return loc::MemRegionVal(BaseReg);
 }

 /// Returns the static type of the given region, if it represents a C++ class
 /// object.
 ///
 /// This handles both fully-typed regions, where the dynamic type is known, and
 /// symbolic regions, where the dynamic type is merely bounded (and even then,
 /// only ostensibly!), but does not take advantage of any dynamic type info.
 static const CXXRecordDecl *getCXXRecordType(const MemRegion *MR) {
   if (const TypedValueRegion *TVR = dyn_cast<TypedValueRegion>(MR))
     return TVR->getValueType()->getAsCXXRecordDecl();
   if (const SymbolicRegion *SR = dyn_cast<SymbolicRegion>(MR))
     return SR->getSymbol()->getType()->getPointeeCXXRecordDecl();
   return nullptr;
 }

 SVal StoreManager::evalDynamicCast(SVal Base, QualType TargetType,
                                    bool &Failed) {
   Failed = false;

   const MemRegion *MR = Base.getAsRegion();
   if (!MR)
     return UnknownVal();

   // Assume the derived class is a pointer or a reference to a CXX record.
   TargetType = TargetType->getPointeeType();
   assert(!TargetType.isNull());
   const CXXRecordDecl *TargetClass = TargetType->getAsCXXRecordDecl();
   if (!TargetClass && !TargetType->isVoidType())
     return UnknownVal();

   // Drill down the CXXBaseObject chains, which represent upcasts (casts from
   // derived to base).
   while (const CXXRecordDecl *MRClass = getCXXRecordType(MR)) {
     // If found the derived class, the cast succeeds.
     if (MRClass == TargetClass)
       return loc::MemRegionVal(MR);

     // We skip over incomplete types. They must be the result of an earlier
     // reinterpret_cast, as one can only dynamic_cast between types in the same
     // class hierarchy.
     if (!TargetType->isVoidType() && MRClass->hasDefinition()) {
       // Static upcasts are marked as DerivedToBase casts by Sema, so this will
       // only happen when multiple or virtual inheritance is involved.
       CXXBasePaths Paths(/*FindAmbiguities=*/false, /*RecordPaths=*/true,
                          /*DetectVirtual=*/false);
       if (MRClass->isDerivedFrom(TargetClass, Paths))
         return evalDerivedToBase(loc::MemRegionVal(MR), Paths.front());
     }

     if (const CXXBaseObjectRegion *BaseR = dyn_cast<CXXBaseObjectRegion>(MR)) {
       // Drill down the chain to get the derived classes.
       MR = BaseR->getSuperRegion();
       continue;
     }

     // If this is a cast to void*, return the region.
     if (TargetType->isVoidType())
       return loc::MemRegionVal(MR);

     // Strange use of reinterpret_cast can give us paths we don't reason
     // about well, by putting in ElementRegions where we'd expect
     // CXXBaseObjectRegions. If it's a valid reinterpret_cast (i.e. if the
     // derived class has a zero offset from the base class), then it's safe
     // to strip the cast; if it's invalid, -Wreinterpret-base-class should
     // catch it. In the interest of performance, the analyzer will silently
     // do the wrong thing in the invalid case (because offsets for subregions
     // will be wrong).
     const MemRegion *Uncasted = MR->StripCasts(/*IncludeBaseCasts=*/false);
     if (Uncasted == MR) {
       // We reached the bottom of the hierarchy and did not find the derived
       // class. We we must be casting the base to derived, so the cast should
       // fail.
       break;
     }

     MR = Uncasted;
   }

   // We failed if the region we ended up with has perfect type info.
   Failed = isa<TypedValueRegion>(MR);
   return UnknownVal();
 }


 /// CastRetrievedVal - Used by subclasses of StoreManager to implement
 ///  implicit casts that arise from loads from regions that are reinterpreted
 ///  as another region.
 SVal StoreManager::CastRetrievedVal(SVal V, const TypedValueRegion *R,
                                     QualType castTy, bool performTestOnly) {

   if (castTy.isNull() || V.isUnknownOrUndef())
     return V;

   ASTContext &Ctx = svalBuilder.getContext();

   if (performTestOnly) {
     // Automatically translate references to pointers.
     QualType T = R->getValueType();
     if (const ReferenceType *RT = T->getAs<ReferenceType>())
       T = Ctx.getPointerType(RT->getPointeeType());

     assert(svalBuilder.getContext().hasSameUnqualifiedType(castTy, T));
     return V;
   }

   return svalBuilder.dispatchCast(V, castTy);
 }

 SVal StoreManager::getLValueFieldOrIvar(const Decl *D, SVal Base) {
   if (Base.isUnknownOrUndef())
     return Base;

   Loc BaseL = Base.castAs<Loc>();
   const MemRegion* BaseR = nullptr;

   switch (BaseL.getSubKind()) {
   case loc::MemRegionKind:
     BaseR = BaseL.castAs<loc::MemRegionVal>().getRegion();
     break;

   case loc::GotoLabelKind:
     // These are anormal cases. Flag an undefined value.
     return UndefinedVal();

   case loc::ConcreteIntKind:
     // While these seem funny, this can happen through casts.
     // FIXME: What we should return is the field offset.  For example,
     //  add the field offset to the integer value.  That way funny things
     //  like this work properly:  &(((struct foo *) 0xa)->f)
     return Base;

   default:
     llvm_unreachable("Unhandled Base.");
   }

   // NOTE: We must have this check first because ObjCIvarDecl is a subclass
   // of FieldDecl.
   if (const ObjCIvarDecl *ID = dyn_cast<ObjCIvarDecl>(D))
     return loc::MemRegionVal(MRMgr.getObjCIvarRegion(ID, BaseR));

   return loc::MemRegionVal(MRMgr.getFieldRegion(cast<FieldDecl>(D), BaseR));
 }

 SVal StoreManager::getLValueIvar(const ObjCIvarDecl *decl, SVal base) {
   return getLValueFieldOrIvar(decl, base);
 }

 SVal StoreManager::getLValueElement(QualType elementType, NonLoc Offset,
                                     SVal Base) {

   // If the base is an unknown or undefined value, just return it back.
   // FIXME: For absolute pointer addresses, we just return that value back as
   //  well, although in reality we should return the offset added to that
   //  value.
   if (Base.isUnknownOrUndef() || Base.getAs<loc::ConcreteInt>())
     return Base;

   const MemRegion* BaseRegion = Base.castAs<loc::MemRegionVal>().getRegion();

   // Pointer of any type can be cast and used as array base.
   const ElementRegion *ElemR = dyn_cast<ElementRegion>(BaseRegion);

   // Convert the offset to the appropriate size and signedness.
   Offset = svalBuilder.convertToArrayIndex(Offset).castAs<NonLoc>();

   if (!ElemR) {
     //
     // If the base region is not an ElementRegion, create one.
     // This can happen in the following example:
     //
     //   char *p = __builtin_alloc(10);
     //   p[1] = 8;
     //
     //  Observe that 'p' binds to an AllocaRegion.
     //
     return loc::MemRegionVal(MRMgr.getElementRegion(elementType, Offset,
                                                     BaseRegion, Ctx));
   }

   SVal BaseIdx = ElemR->getIndex();

   if (!BaseIdx.getAs<nonloc::ConcreteInt>())
     return UnknownVal();

   const llvm::APSInt &BaseIdxI =
       BaseIdx.castAs<nonloc::ConcreteInt>().getValue();

   // Only allow non-integer offsets if the base region has no offset itself.
   // FIXME: This is a somewhat arbitrary restriction. We should be using
   // SValBuilder here to add the two offsets without checking their types.
   if (!Offset.getAs<nonloc::ConcreteInt>()) {
     if (isa<ElementRegion>(BaseRegion->StripCasts()))
       return UnknownVal();

     return loc::MemRegionVal(MRMgr.getElementRegion(elementType, Offset,
                                                     ElemR->getSuperRegion(),
                                                     Ctx));
   }

   const llvm::APSInt& OffI = Offset.castAs<nonloc::ConcreteInt>().getValue();
   assert(BaseIdxI.isSigned());

   // Compute the new index.
   nonloc::ConcreteInt NewIdx(svalBuilder.getBasicValueFactory().getValue(BaseIdxI +
                                                                     OffI));

   // Construct the new ElementRegion.
   const MemRegion *ArrayR = ElemR->getSuperRegion();
   return loc::MemRegionVal(MRMgr.getElementRegion(elementType, NewIdx, ArrayR,
                                                   Ctx));
 }

 StoreManager::BindingsHandler::~BindingsHandler() {}

 bool StoreManager::FindUniqueBinding::HandleBinding(StoreManager& SMgr,
                                                     Store store,
                                                     const MemRegion* R,
                                                     SVal val) {
   SymbolRef SymV = val.getAsLocSymbol();
   if (!SymV || SymV != Sym)
     return true;

   if (Binding) {
     First = false;
     return false;
   }
   else
     Binding = R;

   return true;
 }
	//== Store.cpp - Interface for maps from Locations to Values ----- C++ ---==//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defined the types Store and StoreManager.
	//
	//===----------------------------------------------------------------------===//

	#include "clang/StaticAnalyzer/Core/PathSensitive/Store.h"
	#include "clang/AST/CXXInheritance.h"
	#include "clang/AST/CharUnits.h"
	#include "clang/AST/DeclObjC.h"
	#include "clang/StaticAnalyzer/Core/PathSensitive/CallEvent.h"
	#include "clang/StaticAnalyzer/Core/PathSensitive/ProgramState.h"

	using namespace clang;
	using namespace ento;

	StoreManager::StoreManager(ProgramStateManager &stateMgr)
	: svalBuilder(stateMgr.getSValBuilder()), StateMgr(stateMgr),
	MRMgr(svalBuilder.getRegionManager()), Ctx(stateMgr.getContext()) {}

	StoreRef StoreManager::enterStackFrame(Store OldStore,
	const CallEvent &Call,
	const StackFrameContext *LCtx) {
	StoreRef Store = StoreRef(OldStore, *this);

	SmallVector<CallEvent::FrameBindingTy, 16> InitialBindings;
	Call.getInitialStackFrameContents(LCtx, InitialBindings);

	for (CallEvent::BindingsTy::iterator I = InitialBindings.begin(),
	E = InitialBindings.end();
	I != E; ++I) {
	Store = Bind(Store.getStore(), I->first, I->second);
	}

	return Store;
	}

	const MemRegion StoreManager::MakeElementRegion(const MemRegion Base,
	QualType EleTy, uint64_t index) {
	NonLoc idx = svalBuilder.makeArrayIndex(index);
	return MRMgr.getElementRegion(EleTy, idx, Base, svalBuilder.getContext());
	}

	StoreRef StoreManager::BindDefault(Store store, const MemRegion *R, SVal V) {
	return StoreRef(store, *this);
	}

	const ElementRegion StoreManager::GetElementZeroRegion(const MemRegion R,
	QualType T) {
	NonLoc idx = svalBuilder.makeZeroArrayIndex();
	assert(!T.isNull());
	return MRMgr.getElementRegion(T, idx, R, Ctx);
	}

	const MemRegion StoreManager::castRegion(const MemRegion R, QualType CastToTy) {

	ASTContext &Ctx = StateMgr.getContext();

	// Handle casts to Objective-C objects.
	if (CastToTy->isObjCObjectPointerType())
	return R->StripCasts();

	if (CastToTy->isBlockPointerType()) {
	// FIXME: We may need different solutions, depending on the symbol
	// involved. Blocks can be casted to/from 'id', as they can be treated
	// as Objective-C objects. This could possibly be handled by enhancing
	// our reasoning of downcasts of symbolic objects.
	if (isa<CodeTextRegion>(R) \|\| isa<SymbolicRegion>(R))
	return R;

	// We don't know what to make of it. Return a NULL region, which
	// will be interpretted as UnknownVal.
	return nullptr;
	}

	// Now assume we are casting from pointer to pointer. Other cases should
	// already be handled.
	QualType PointeeTy = CastToTy->getPointeeType();
	QualType CanonPointeeTy = Ctx.getCanonicalType(PointeeTy);

	// Handle casts to void*. We just pass the region through.
	if (CanonPointeeTy.getLocalUnqualifiedType() == Ctx.VoidTy)
	return R;

	// Handle casts from compatible types.
	if (R->isBoundable())
	if (const TypedValueRegion *TR = dyn_cast<TypedValueRegion>(R)) {
	QualType ObjTy = Ctx.getCanonicalType(TR->getValueType());
	if (CanonPointeeTy == ObjTy)
	return R;
	}

	// Process region cast according to the kind of the region being cast.
	switch (R->getKind()) {
	case MemRegion::CXXThisRegionKind:
	case MemRegion::GenericMemSpaceRegionKind:
	case MemRegion::StackLocalsSpaceRegionKind:
	case MemRegion::StackArgumentsSpaceRegionKind:
	case MemRegion::HeapSpaceRegionKind:
	case MemRegion::UnknownSpaceRegionKind:
	case MemRegion::StaticGlobalSpaceRegionKind:
	case MemRegion::GlobalInternalSpaceRegionKind:
	case MemRegion::GlobalSystemSpaceRegionKind:
	case MemRegion::GlobalImmutableSpaceRegionKind: {
	llvm_unreachable("Invalid region cast");
	}

	case MemRegion::FunctionTextRegionKind:
	case MemRegion::BlockTextRegionKind:
	case MemRegion::BlockDataRegionKind:
	case MemRegion::StringRegionKind:
	// FIXME: Need to handle arbitrary downcasts.
	case MemRegion::SymbolicRegionKind:
	case MemRegion::AllocaRegionKind:
	case MemRegion::CompoundLiteralRegionKind:
	case MemRegion::FieldRegionKind:
	case MemRegion::ObjCIvarRegionKind:
	case MemRegion::ObjCStringRegionKind:
	case MemRegion::VarRegionKind:
	case MemRegion::CXXTempObjectRegionKind:
	case MemRegion::CXXBaseObjectRegionKind:
	return MakeElementRegion(R, PointeeTy);

	case MemRegion::ElementRegionKind: {
	// If we are casting from an ElementRegion to another type, the
	// algorithm is as follows:
	//
	// (1) Compute the "raw offset" of the ElementRegion from the
	// base region. This is done by calling 'getAsRawOffset()'.
	//
	// (2a) If we get a 'RegionRawOffset' after calling
	// 'getAsRawOffset()', determine if the absolute offset
	// can be exactly divided into chunks of the size of the
	// casted-pointee type. If so, create a new ElementRegion with
	// the pointee-cast type as the new ElementType and the index
	// being the offset divded by the chunk size. If not, create
	// a new ElementRegion at offset 0 off the raw offset region.
	//
	// (2b) If we don't a get a 'RegionRawOffset' after calling
	// 'getAsRawOffset()', it means that we are at offset 0.
	//
	// FIXME: Handle symbolic raw offsets.

	const ElementRegion *elementR = cast<ElementRegion>(R);
	const RegionRawOffset &rawOff = elementR->getAsArrayOffset();
	const MemRegion *baseR = rawOff.getRegion();

	// If we cannot compute a raw offset, throw up our hands and return
	// a NULL MemRegion*.
	if (!baseR)
	return nullptr;

	CharUnits off = rawOff.getOffset();

	if (off.isZero()) {
	// Edge case: we are at 0 bytes off the beginning of baseR. We
	// check to see if type we are casting to is the same as the base
	// region. If so, just return the base region.
	if (const TypedValueRegion *TR = dyn_cast<TypedValueRegion>(baseR)) {
	QualType ObjTy = Ctx.getCanonicalType(TR->getValueType());
	QualType CanonPointeeTy = Ctx.getCanonicalType(PointeeTy);
	if (CanonPointeeTy == ObjTy)
	return baseR;
	}

	// Otherwise, create a new ElementRegion at offset 0.
	return MakeElementRegion(baseR, PointeeTy);
	}

	// We have a non-zero offset from the base region. We want to determine
	// if the offset can be evenly divided by sizeof(PointeeTy). If so,
	// we create an ElementRegion whose index is that value. Otherwise, we
	// create two ElementRegions, one that reflects a raw offset and the other
	// that reflects the cast.

	// Compute the index for the new ElementRegion.
	int64_t newIndex = 0;
	const MemRegion *newSuperR = nullptr;

	// We can only compute sizeof(PointeeTy) if it is a complete type.
	if (!PointeeTy->isIncompleteType()) {
	// Compute the size in bytes.
	CharUnits pointeeTySize = Ctx.getTypeSizeInChars(PointeeTy);
	if (!pointeeTySize.isZero()) {
	// Is the offset a multiple of the size? If so, we can layer the
	// ElementRegion (with elementType == PointeeTy) directly on top of
	// the base region.
	if (off % pointeeTySize == 0) {
	newIndex = off / pointeeTySize;
	newSuperR = baseR;
	}
	}
	}

	if (!newSuperR) {
	// Create an intermediate ElementRegion to represent the raw byte.
	// This will be the super region of the final ElementRegion.
	newSuperR = MakeElementRegion(baseR, Ctx.CharTy, off.getQuantity());
	}

	return MakeElementRegion(newSuperR, PointeeTy, newIndex);
	}
	}

	llvm_unreachable("unreachable");
	}

	static bool regionMatchesCXXRecordType(SVal V, QualType Ty) {
	const MemRegion *MR = V.getAsRegion();
	if (!MR)
	return true;

	const TypedValueRegion *TVR = dyn_cast<TypedValueRegion>(MR);
	if (!TVR)
	return true;

	const CXXRecordDecl *RD = TVR->getValueType()->getAsCXXRecordDecl();
	if (!RD)
	return true;

	const CXXRecordDecl *Expected = Ty->getPointeeCXXRecordDecl();
	if (!Expected)
	Expected = Ty->getAsCXXRecordDecl();

	return Expected->getCanonicalDecl() == RD->getCanonicalDecl();
	}

	SVal StoreManager::evalDerivedToBase(SVal Derived, const CastExpr *Cast) {
	// Sanity check to avoid doing the wrong thing in the face of
	// reinterpret_cast.
	if (!regionMatchesCXXRecordType(Derived, Cast->getSubExpr()->getType()))
	return UnknownVal();

	// Walk through the cast path to create nested CXXBaseRegions.
	SVal Result = Derived;
	for (CastExpr::path_const_iterator I = Cast->path_begin(),
	E = Cast->path_end();
	I != E; ++I) {
	Result = evalDerivedToBase(Result, (I)->getType(), (I)->isVirtual());
	}
	return Result;
	}

	SVal StoreManager::evalDerivedToBase(SVal Derived, const CXXBasePath &Path) {
	// Walk through the path to create nested CXXBaseRegions.
	SVal Result = Derived;
	for (CXXBasePath::const_iterator I = Path.begin(), E = Path.end();
	I != E; ++I) {
	Result = evalDerivedToBase(Result, I->Base->getType(),
	I->Base->isVirtual());
	}
	return Result;
	}

	SVal StoreManager::evalDerivedToBase(SVal Derived, QualType BaseType,
	bool IsVirtual) {
	Optional<loc::MemRegionVal> DerivedRegVal =
	Derived.getAs<loc::MemRegionVal>();
	if (!DerivedRegVal)
	return Derived;

	const CXXRecordDecl *BaseDecl = BaseType->getPointeeCXXRecordDecl();
	if (!BaseDecl)
	BaseDecl = BaseType->getAsCXXRecordDecl();
	assert(BaseDecl && "not a C++ object?");

	const MemRegion *BaseReg =
	MRMgr.getCXXBaseObjectRegion(BaseDecl, DerivedRegVal->getRegion(),
	IsVirtual);

	return loc::MemRegionVal(BaseReg);
	}

	/// Returns the static type of the given region, if it represents a C++ class
	/// object.
	///
	/// This handles both fully-typed regions, where the dynamic type is known, and
	/// symbolic regions, where the dynamic type is merely bounded (and even then,
	/// only ostensibly!), but does not take advantage of any dynamic type info.
	static const CXXRecordDecl getCXXRecordType(const MemRegion MR) {
	if (const TypedValueRegion *TVR = dyn_cast<TypedValueRegion>(MR))
	return TVR->getValueType()->getAsCXXRecordDecl();
	if (const SymbolicRegion *SR = dyn_cast<SymbolicRegion>(MR))
	return SR->getSymbol()->getType()->getPointeeCXXRecordDecl();
	return nullptr;
	}

	SVal StoreManager::evalDynamicCast(SVal Base, QualType TargetType,
	bool &Failed) {
	Failed = false;

	const MemRegion *MR = Base.getAsRegion();
	if (!MR)
	return UnknownVal();

	// Assume the derived class is a pointer or a reference to a CXX record.
	TargetType = TargetType->getPointeeType();
	assert(!TargetType.isNull());
	const CXXRecordDecl *TargetClass = TargetType->getAsCXXRecordDecl();
	if (!TargetClass && !TargetType->isVoidType())
	return UnknownVal();

	// Drill down the CXXBaseObject chains, which represent upcasts (casts from
	// derived to base).
	while (const CXXRecordDecl *MRClass = getCXXRecordType(MR)) {
	// If found the derived class, the cast succeeds.
	if (MRClass == TargetClass)
	return loc::MemRegionVal(MR);

	// We skip over incomplete types. They must be the result of an earlier
	// reinterpret_cast, as one can only dynamic_cast between types in the same
	// class hierarchy.
	if (!TargetType->isVoidType() && MRClass->hasDefinition()) {
	// Static upcasts are marked as DerivedToBase casts by Sema, so this will
	// only happen when multiple or virtual inheritance is involved.
	CXXBasePaths Paths(/FindAmbiguities=/false, /RecordPaths=/true,
	/DetectVirtual=/false);
	if (MRClass->isDerivedFrom(TargetClass, Paths))
	return evalDerivedToBase(loc::MemRegionVal(MR), Paths.front());
	}

	if (const CXXBaseObjectRegion *BaseR = dyn_cast<CXXBaseObjectRegion>(MR)) {
	// Drill down the chain to get the derived classes.
	MR = BaseR->getSuperRegion();
	continue;
	}

	// If this is a cast to void*, return the region.
	if (TargetType->isVoidType())
	return loc::MemRegionVal(MR);

	// Strange use of reinterpret_cast can give us paths we don't reason
	// about well, by putting in ElementRegions where we'd expect
	// CXXBaseObjectRegions. If it's a valid reinterpret_cast (i.e. if the
	// derived class has a zero offset from the base class), then it's safe
	// to strip the cast; if it's invalid, -Wreinterpret-base-class should
	// catch it. In the interest of performance, the analyzer will silently
	// do the wrong thing in the invalid case (because offsets for subregions
	// will be wrong).
	const MemRegion Uncasted = MR->StripCasts(/IncludeBaseCasts=*/false);
	if (Uncasted == MR) {
	// We reached the bottom of the hierarchy and did not find the derived
	// class. We we must be casting the base to derived, so the cast should
	// fail.
	break;
	}

	MR = Uncasted;
	}

	// We failed if the region we ended up with has perfect type info.
	Failed = isa<TypedValueRegion>(MR);
	return UnknownVal();
	}


	/// CastRetrievedVal - Used by subclasses of StoreManager to implement
	/// implicit casts that arise from loads from regions that are reinterpreted
	/// as another region.
	SVal StoreManager::CastRetrievedVal(SVal V, const TypedValueRegion *R,
	QualType castTy, bool performTestOnly) {

	if (castTy.isNull() \|\| V.isUnknownOrUndef())
	return V;

	ASTContext &Ctx = svalBuilder.getContext();

	if (performTestOnly) {
	// Automatically translate references to pointers.
	QualType T = R->getValueType();
	if (const ReferenceType *RT = T->getAs<ReferenceType>())
	T = Ctx.getPointerType(RT->getPointeeType());

	assert(svalBuilder.getContext().hasSameUnqualifiedType(castTy, T));
	return V;
	}

	return svalBuilder.dispatchCast(V, castTy);
	}

	SVal StoreManager::getLValueFieldOrIvar(const Decl *D, SVal Base) {
	if (Base.isUnknownOrUndef())
	return Base;

	Loc BaseL = Base.castAs<Loc>();
	const MemRegion* BaseR = nullptr;

	switch (BaseL.getSubKind()) {
	case loc::MemRegionKind:
	BaseR = BaseL.castAs<loc::MemRegionVal>().getRegion();
	break;

	case loc::GotoLabelKind:
	// These are anormal cases. Flag an undefined value.
	return UndefinedVal();

	case loc::ConcreteIntKind:
	// While these seem funny, this can happen through casts.
	// FIXME: What we should return is the field offset. For example,
	// add the field offset to the integer value. That way funny things
	// like this work properly: &(((struct foo *) 0xa)->f)
	return Base;

	default:
	llvm_unreachable("Unhandled Base.");
	}

	// NOTE: We must have this check first because ObjCIvarDecl is a subclass
	// of FieldDecl.
	if (const ObjCIvarDecl *ID = dyn_cast<ObjCIvarDecl>(D))
	return loc::MemRegionVal(MRMgr.getObjCIvarRegion(ID, BaseR));

	return loc::MemRegionVal(MRMgr.getFieldRegion(cast<FieldDecl>(D), BaseR));
	}

	SVal StoreManager::getLValueIvar(const ObjCIvarDecl *decl, SVal base) {
	return getLValueFieldOrIvar(decl, base);
	}

	SVal StoreManager::getLValueElement(QualType elementType, NonLoc Offset,
	SVal Base) {

	// If the base is an unknown or undefined value, just return it back.
	// FIXME: For absolute pointer addresses, we just return that value back as
	// well, although in reality we should return the offset added to that
	// value.
	if (Base.isUnknownOrUndef() \|\| Base.getAs<loc::ConcreteInt>())
	return Base;

	const MemRegion* BaseRegion = Base.castAs<loc::MemRegionVal>().getRegion();

	// Pointer of any type can be cast and used as array base.
	const ElementRegion *ElemR = dyn_cast<ElementRegion>(BaseRegion);

	// Convert the offset to the appropriate size and signedness.
	Offset = svalBuilder.convertToArrayIndex(Offset).castAs<NonLoc>();

	if (!ElemR) {
	//
	// If the base region is not an ElementRegion, create one.
	// This can happen in the following example:
	//
	// char *p = __builtin_alloc(10);
	// p[1] = 8;
	//
	// Observe that 'p' binds to an AllocaRegion.
	//
	return loc::MemRegionVal(MRMgr.getElementRegion(elementType, Offset,
	BaseRegion, Ctx));
	}

	SVal BaseIdx = ElemR->getIndex();

	if (!BaseIdx.getAs<nonloc::ConcreteInt>())
	return UnknownVal();

	const llvm::APSInt &BaseIdxI =
	BaseIdx.castAs<nonloc::ConcreteInt>().getValue();

	// Only allow non-integer offsets if the base region has no offset itself.
	// FIXME: This is a somewhat arbitrary restriction. We should be using
	// SValBuilder here to add the two offsets without checking their types.
	if (!Offset.getAs<nonloc::ConcreteInt>()) {
	if (isa<ElementRegion>(BaseRegion->StripCasts()))
	return UnknownVal();

	return loc::MemRegionVal(MRMgr.getElementRegion(elementType, Offset,
	ElemR->getSuperRegion(),
	Ctx));
	}

	const llvm::APSInt& OffI = Offset.castAs<nonloc::ConcreteInt>().getValue();
	assert(BaseIdxI.isSigned());

	// Compute the new index.
	nonloc::ConcreteInt NewIdx(svalBuilder.getBasicValueFactory().getValue(BaseIdxI +
	OffI));

	// Construct the new ElementRegion.
	const MemRegion *ArrayR = ElemR->getSuperRegion();
	return loc::MemRegionVal(MRMgr.getElementRegion(elementType, NewIdx, ArrayR,
	Ctx));
	}

	StoreManager::BindingsHandler::~BindingsHandler() {}

	bool StoreManager::FindUniqueBinding::HandleBinding(StoreManager& SMgr,
	Store store,
	const MemRegion* R,
	SVal val) {
	SymbolRef SymV = val.getAsLocSymbol();
	if (!SymV \|\| SymV != Sym)
	return true;

	if (Binding) {
	First = false;
	return false;
	}
	else
	Binding = R;

	return true;
	}