include/clang/Analysis/ProgramPoint.h - third_party/swift-clang - Git at Google

 //==- ProgramPoint.h - Program Points for Path-Sensitive Analysis --*- 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 the interface ProgramPoint, which identifies a
 //  distinct location in a function.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CLANG_ANALYSIS_PROGRAMPOINT_H
 #define LLVM_CLANG_ANALYSIS_PROGRAMPOINT_H

 #include "clang/Analysis/AnalysisContext.h"
 #include "clang/Analysis/CFG.h"
 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/FoldingSet.h"
 #include "llvm/ADT/Optional.h"
 #include "llvm/ADT/PointerIntPair.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/Support/Casting.h"
 #include "llvm/Support/DataTypes.h"
 #include <cassert>
 #include <string>
 #include <utility>

 namespace clang {

 class AnalysisDeclContext;
 class FunctionDecl;
 class LocationContext;

 /// ProgramPoints can be "tagged" as representing points specific to a given
 /// analysis entity.  Tags are abstract annotations, with an associated
 /// description and potentially other information.
 class ProgramPointTag {
 public:
   ProgramPointTag(void *tagKind = nullptr) : TagKind(tagKind) {}
   virtual ~ProgramPointTag();
   virtual StringRef getTagDescription() const = 0;

 protected:
   /// Used to implement 'isKind' in subclasses.
   const void *getTagKind() { return TagKind; }

 private:
   const void *TagKind;
 };

 class SimpleProgramPointTag : public ProgramPointTag {
   std::string Desc;
 public:
   SimpleProgramPointTag(StringRef MsgProvider, StringRef Msg);
   StringRef getTagDescription() const override;
 };

 class ProgramPoint {
 public:
   enum Kind { BlockEdgeKind,
               BlockEntranceKind,
               BlockExitKind,
               PreStmtKind,
               PreStmtPurgeDeadSymbolsKind,
               PostStmtPurgeDeadSymbolsKind,
               PostStmtKind,
               PreLoadKind,
               PostLoadKind,
               PreStoreKind,
               PostStoreKind,
               PostConditionKind,
               PostLValueKind,
               MinPostStmtKind = PostStmtKind,
               MaxPostStmtKind = PostLValueKind,
               PostInitializerKind,
               CallEnterKind,
               CallExitBeginKind,
               CallExitEndKind,
               PreImplicitCallKind,
               PostImplicitCallKind,
               MinImplicitCallKind = PreImplicitCallKind,
               MaxImplicitCallKind = PostImplicitCallKind,
               EpsilonKind};

 private:
   const void *Data1;
   llvm::PointerIntPair<const void *, 2, unsigned> Data2;

   // The LocationContext could be NULL to allow ProgramPoint to be used in
   // context insensitive analysis.
   llvm::PointerIntPair<const LocationContext *, 2, unsigned> L;

   llvm::PointerIntPair<const ProgramPointTag *, 2, unsigned> Tag;

 protected:
   ProgramPoint() {}
   ProgramPoint(const void *P,
                Kind k,
                const LocationContext *l,
                const ProgramPointTag *tag = nullptr)
     : Data1(P),
       Data2(nullptr, (((unsigned) k) >> 0) & 0x3),
       L(l, (((unsigned) k) >> 2) & 0x3),
       Tag(tag, (((unsigned) k) >> 4) & 0x3) {
         assert(getKind() == k);
         assert(getLocationContext() == l);
         assert(getData1() == P);
       }

   ProgramPoint(const void *P1,
                const void *P2,
                Kind k,
                const LocationContext *l,
                const ProgramPointTag *tag = nullptr)
     : Data1(P1),
       Data2(P2, (((unsigned) k) >> 0) & 0x3),
       L(l, (((unsigned) k) >> 2) & 0x3),
       Tag(tag, (((unsigned) k) >> 4) & 0x3) {}

 protected:
   const void *getData1() const { return Data1; }
   const void *getData2() const { return Data2.getPointer(); }
   void setData2(const void *d) { Data2.setPointer(d); }

 public:
   /// Create a new ProgramPoint object that is the same as the original
   /// except for using the specified tag value.
   ProgramPoint withTag(const ProgramPointTag *tag) const {
     return ProgramPoint(getData1(), getData2(), getKind(),
                         getLocationContext(), tag);
   }

   /// \brief Convert to the specified ProgramPoint type, asserting that this
   /// ProgramPoint is of the desired type.
   template<typename T>
   T castAs() const {
     assert(T::isKind(*this));
     T t;
     ProgramPoint& PP = t;
     PP = *this;
     return t;
   }

   /// \brief Convert to the specified ProgramPoint type, returning None if this
   /// ProgramPoint is not of the desired type.
   template<typename T>
   Optional<T> getAs() const {
     if (!T::isKind(*this))
       return None;
     T t;
     ProgramPoint& PP = t;
     PP = *this;
     return t;
   }

   Kind getKind() const {
     unsigned x = Tag.getInt();
     x <<= 2;
     x |= L.getInt();
     x <<= 2;
     x |= Data2.getInt();
     return (Kind) x;
   }

   /// \brief Is this a program point corresponding to purge/removal of dead
   /// symbols and bindings.
   bool isPurgeKind() {
     Kind K = getKind();
     return (K == PostStmtPurgeDeadSymbolsKind ||
             K == PreStmtPurgeDeadSymbolsKind);
   }

   const ProgramPointTag *getTag() const { return Tag.getPointer(); }

   const LocationContext *getLocationContext() const {
     return L.getPointer();
   }

   // For use with DenseMap.  This hash is probably slow.
   unsigned getHashValue() const {
     llvm::FoldingSetNodeID ID;
     Profile(ID);
     return ID.ComputeHash();
   }

   bool operator==(const ProgramPoint & RHS) const {
     return Data1 == RHS.Data1 &&
            Data2 == RHS.Data2 &&
            L == RHS.L &&
            Tag == RHS.Tag;
   }

   bool operator!=(const ProgramPoint &RHS) const {
     return Data1 != RHS.Data1 ||
            Data2 != RHS.Data2 ||
            L != RHS.L ||
            Tag != RHS.Tag;
   }

   void Profile(llvm::FoldingSetNodeID& ID) const {
     ID.AddInteger((unsigned) getKind());
     ID.AddPointer(getData1());
     ID.AddPointer(getData2());
     ID.AddPointer(getLocationContext());
     ID.AddPointer(getTag());
   }

   static ProgramPoint getProgramPoint(const Stmt *S, ProgramPoint::Kind K,
                                       const LocationContext *LC,
                                       const ProgramPointTag *tag);
 };

 class BlockEntrance : public ProgramPoint {
 public:
   BlockEntrance(const CFGBlock *B, const LocationContext *L,
                 const ProgramPointTag *tag = nullptr)
     : ProgramPoint(B, BlockEntranceKind, L, tag) {
     assert(B && "BlockEntrance requires non-null block");
   }

   const CFGBlock *getBlock() const {
     return reinterpret_cast<const CFGBlock*>(getData1());
   }

   Optional<CFGElement> getFirstElement() const {
     const CFGBlock *B = getBlock();
     return B->empty() ? Optional<CFGElement>() : B->front();
   }

 private:
   friend class ProgramPoint;
   BlockEntrance() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == BlockEntranceKind;
   }
 };

 class BlockExit : public ProgramPoint {
 public:
   BlockExit(const CFGBlock *B, const LocationContext *L)
     : ProgramPoint(B, BlockExitKind, L) {}

   const CFGBlock *getBlock() const {
     return reinterpret_cast<const CFGBlock*>(getData1());
   }

   const Stmt *getTerminator() const {
     return getBlock()->getTerminator();
   }

 private:
   friend class ProgramPoint;
   BlockExit() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == BlockExitKind;
   }
 };

 class StmtPoint : public ProgramPoint {
 public:
   StmtPoint(const Stmt *S, const void *p2, Kind k, const LocationContext *L,
             const ProgramPointTag *tag)
     : ProgramPoint(S, p2, k, L, tag) {
     assert(S);
   }

   const Stmt *getStmt() const { return (const Stmt*) getData1(); }

   template <typename T>
   const T* getStmtAs() const { return dyn_cast<T>(getStmt()); }

 protected:
   StmtPoint() {}
 private:
   friend class ProgramPoint;
   static bool isKind(const ProgramPoint &Location) {
     unsigned k = Location.getKind();
     return k >= PreStmtKind && k <= MaxPostStmtKind;
   }
 };


 class PreStmt : public StmtPoint {
 public:
   PreStmt(const Stmt *S, const LocationContext *L, const ProgramPointTag *tag,
           const Stmt *SubStmt = nullptr)
     : StmtPoint(S, SubStmt, PreStmtKind, L, tag) {}

   const Stmt *getSubStmt() const { return (const Stmt*) getData2(); }

 private:
   friend class ProgramPoint;
   PreStmt() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == PreStmtKind;
   }
 };

 class PostStmt : public StmtPoint {
 protected:
   PostStmt() {}
   PostStmt(const Stmt *S, const void *data, Kind k, const LocationContext *L,
            const ProgramPointTag *tag = nullptr)
     : StmtPoint(S, data, k, L, tag) {}

 public:
   explicit PostStmt(const Stmt *S, Kind k, const LocationContext *L,
                     const ProgramPointTag *tag = nullptr)
     : StmtPoint(S, nullptr, k, L, tag) {}

   explicit PostStmt(const Stmt *S, const LocationContext *L,
                     const ProgramPointTag *tag = nullptr)
     : StmtPoint(S, nullptr, PostStmtKind, L, tag) {}

 private:
   friend class ProgramPoint;
   static bool isKind(const ProgramPoint &Location) {
     unsigned k = Location.getKind();
     return k >= MinPostStmtKind && k <= MaxPostStmtKind;
   }
 };

 // PostCondition represents the post program point of a branch condition.
 class PostCondition : public PostStmt {
 public:
   PostCondition(const Stmt *S, const LocationContext *L,
                 const ProgramPointTag *tag = nullptr)
     : PostStmt(S, PostConditionKind, L, tag) {}

 private:
   friend class ProgramPoint;
   PostCondition() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == PostConditionKind;
   }
 };

 class LocationCheck : public StmtPoint {
 protected:
   LocationCheck() {}
   LocationCheck(const Stmt *S, const LocationContext *L,
                 ProgramPoint::Kind K, const ProgramPointTag *tag)
     : StmtPoint(S, nullptr, K, L, tag) {}

 private:
   friend class ProgramPoint;
   static bool isKind(const ProgramPoint &location) {
     unsigned k = location.getKind();
     return k == PreLoadKind || k == PreStoreKind;
   }
 };

 class PreLoad : public LocationCheck {
 public:
   PreLoad(const Stmt *S, const LocationContext *L,
           const ProgramPointTag *tag = nullptr)
     : LocationCheck(S, L, PreLoadKind, tag) {}

 private:
   friend class ProgramPoint;
   PreLoad() {}
   static bool isKind(const ProgramPoint &location) {
     return location.getKind() == PreLoadKind;
   }
 };

 class PreStore : public LocationCheck {
 public:
   PreStore(const Stmt *S, const LocationContext *L,
            const ProgramPointTag *tag = nullptr)
   : LocationCheck(S, L, PreStoreKind, tag) {}

 private:
   friend class ProgramPoint;
   PreStore() {}
   static bool isKind(const ProgramPoint &location) {
     return location.getKind() == PreStoreKind;
   }
 };

 class PostLoad : public PostStmt {
 public:
   PostLoad(const Stmt *S, const LocationContext *L,
            const ProgramPointTag *tag = nullptr)
     : PostStmt(S, PostLoadKind, L, tag) {}

 private:
   friend class ProgramPoint;
   PostLoad() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == PostLoadKind;
   }
 };

 /// \brief Represents a program point after a store evaluation.
 class PostStore : public PostStmt {
 public:
   /// Construct the post store point.
   /// \param Loc can be used to store the information about the location
   /// used in the form it was uttered in the code.
   PostStore(const Stmt *S, const LocationContext *L, const void *Loc,
             const ProgramPointTag *tag = nullptr)
     : PostStmt(S, PostStoreKind, L, tag) {
     assert(getData2() == nullptr);
     setData2(Loc);
   }

   /// \brief Returns the information about the location used in the store,
   /// how it was uttered in the code.
   const void *getLocationValue() const {
     return getData2();
   }

 private:
   friend class ProgramPoint;
   PostStore() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == PostStoreKind;
   }
 };

 class PostLValue : public PostStmt {
 public:
   PostLValue(const Stmt *S, const LocationContext *L,
              const ProgramPointTag *tag = nullptr)
     : PostStmt(S, PostLValueKind, L, tag) {}

 private:
   friend class ProgramPoint;
   PostLValue() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == PostLValueKind;
   }
 };

 /// Represents a point after we ran remove dead bindings BEFORE
 /// processing the given statement.
 class PreStmtPurgeDeadSymbols : public StmtPoint {
 public:
   PreStmtPurgeDeadSymbols(const Stmt *S, const LocationContext *L,
                        const ProgramPointTag *tag = nullptr)
     : StmtPoint(S, nullptr, PreStmtPurgeDeadSymbolsKind, L, tag) { }

 private:
   friend class ProgramPoint;
   PreStmtPurgeDeadSymbols() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == PreStmtPurgeDeadSymbolsKind;
   }
 };

 /// Represents a point after we ran remove dead bindings AFTER
 /// processing the  given statement.
 class PostStmtPurgeDeadSymbols : public StmtPoint {
 public:
   PostStmtPurgeDeadSymbols(const Stmt *S, const LocationContext *L,
                        const ProgramPointTag *tag = nullptr)
     : StmtPoint(S, nullptr, PostStmtPurgeDeadSymbolsKind, L, tag) { }

 private:
   friend class ProgramPoint;
   PostStmtPurgeDeadSymbols() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == PostStmtPurgeDeadSymbolsKind;
   }
 };

 class BlockEdge : public ProgramPoint {
 public:
   BlockEdge(const CFGBlock *B1, const CFGBlock *B2, const LocationContext *L)
     : ProgramPoint(B1, B2, BlockEdgeKind, L) {
     assert(B1 && "BlockEdge: source block must be non-null");
     assert(B2 && "BlockEdge: destination block must be non-null");
   }

   const CFGBlock *getSrc() const {
     return static_cast<const CFGBlock*>(getData1());
   }

   const CFGBlock *getDst() const {
     return static_cast<const CFGBlock*>(getData2());
   }

 private:
   friend class ProgramPoint;
   BlockEdge() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == BlockEdgeKind;
   }
 };

 class PostInitializer : public ProgramPoint {
 public:
   /// \brief Construct a PostInitializer point that represents a location after
   ///   CXXCtorInitializer expression evaluation.
   ///
   /// \param I The initializer.
   /// \param Loc The location of the field being initialized.
   PostInitializer(const CXXCtorInitializer *I,
                   const void *Loc,
                   const LocationContext *L)
     : ProgramPoint(I, Loc, PostInitializerKind, L) {}

   const CXXCtorInitializer *getInitializer() const {
     return static_cast<const CXXCtorInitializer *>(getData1());
   }

   /// \brief Returns the location of the field.
   const void *getLocationValue() const {
     return getData2();
   }

 private:
   friend class ProgramPoint;
   PostInitializer() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == PostInitializerKind;
   }
 };

 /// Represents an implicit call event.
 ///
 /// The nearest statement is provided for diagnostic purposes.
 class ImplicitCallPoint : public ProgramPoint {
 public:
   ImplicitCallPoint(const Decl *D, SourceLocation Loc, Kind K,
                     const LocationContext *L, const ProgramPointTag *Tag)
     : ProgramPoint(Loc.getPtrEncoding(), D, K, L, Tag) {}

   const Decl *getDecl() const { return static_cast<const Decl *>(getData2()); }
   SourceLocation getLocation() const {
     return SourceLocation::getFromPtrEncoding(getData1());
   }

 protected:
   ImplicitCallPoint() {}
 private:
   friend class ProgramPoint;
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() >= MinImplicitCallKind &&
            Location.getKind() <= MaxImplicitCallKind;
   }
 };

 /// Represents a program point just before an implicit call event.
 ///
 /// Explicit calls will appear as PreStmt program points.
 class PreImplicitCall : public ImplicitCallPoint {
 public:
   PreImplicitCall(const Decl *D, SourceLocation Loc, const LocationContext *L,
                   const ProgramPointTag *Tag = nullptr)
     : ImplicitCallPoint(D, Loc, PreImplicitCallKind, L, Tag) {}

 private:
   friend class ProgramPoint;
   PreImplicitCall() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == PreImplicitCallKind;
   }
 };

 /// Represents a program point just after an implicit call event.
 ///
 /// Explicit calls will appear as PostStmt program points.
 class PostImplicitCall : public ImplicitCallPoint {
 public:
   PostImplicitCall(const Decl *D, SourceLocation Loc, const LocationContext *L,
                    const ProgramPointTag *Tag = nullptr)
     : ImplicitCallPoint(D, Loc, PostImplicitCallKind, L, Tag) {}

 private:
   friend class ProgramPoint;
   PostImplicitCall() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == PostImplicitCallKind;
   }
 };

 /// Represents a point when we begin processing an inlined call.
 /// CallEnter uses the caller's location context.
 class CallEnter : public ProgramPoint {
 public:
   CallEnter(const Stmt *stmt, const StackFrameContext *calleeCtx,
             const LocationContext *callerCtx)
     : ProgramPoint(stmt, calleeCtx, CallEnterKind, callerCtx, nullptr) {}

   const Stmt *getCallExpr() const {
     return static_cast<const Stmt *>(getData1());
   }

   const StackFrameContext *getCalleeContext() const {
     return static_cast<const StackFrameContext *>(getData2());
   }

   /// Returns the entry block in the CFG for the entered function.
   const CFGBlock *getEntry() const {
     const StackFrameContext *CalleeCtx = getCalleeContext();
     const CFG *CalleeCFG = CalleeCtx->getCFG();
     return &(CalleeCFG->getEntry());
   }

 private:
   friend class ProgramPoint;
   CallEnter() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == CallEnterKind;
   }
 };

 /// Represents a point when we start the call exit sequence (for inlined call).
 ///
 /// The call exit is simulated with a sequence of nodes, which occur between
 /// CallExitBegin and CallExitEnd. The following operations occur between the
 /// two program points:
 /// - CallExitBegin
 /// - Bind the return value
 /// - Run Remove dead bindings (to clean up the dead symbols from the callee).
 /// - CallExitEnd
 class CallExitBegin : public ProgramPoint {
 public:
   // CallExitBegin uses the callee's location context.
   CallExitBegin(const StackFrameContext *L, const ReturnStmt *RS)
     : ProgramPoint(RS, CallExitBeginKind, L, nullptr) { }

 private:
   friend class ProgramPoint;
   CallExitBegin() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == CallExitBeginKind;
   }
 };

 /// Represents a point when we finish the call exit sequence (for inlined call).
 /// \sa CallExitBegin
 class CallExitEnd : public ProgramPoint {
 public:
   // CallExitEnd uses the caller's location context.
   CallExitEnd(const StackFrameContext *CalleeCtx,
               const LocationContext *CallerCtx)
     : ProgramPoint(CalleeCtx, CallExitEndKind, CallerCtx, nullptr) {}

   const StackFrameContext *getCalleeContext() const {
     return static_cast<const StackFrameContext *>(getData1());
   }

 private:
   friend class ProgramPoint;
   CallExitEnd() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == CallExitEndKind;
   }
 };

 /// This is a meta program point, which should be skipped by all the diagnostic
 /// reasoning etc.
 class EpsilonPoint : public ProgramPoint {
 public:
   EpsilonPoint(const LocationContext *L, const void *Data1,
                const void *Data2 = nullptr,
                const ProgramPointTag *tag = nullptr)
     : ProgramPoint(Data1, Data2, EpsilonKind, L, tag) {}

   const void *getData() const { return getData1(); }

 private:
   friend class ProgramPoint;
   EpsilonPoint() {}
   static bool isKind(const ProgramPoint &Location) {
     return Location.getKind() == EpsilonKind;
   }
 };

 } // end namespace clang


 namespace llvm { // Traits specialization for DenseMap

 template <> struct DenseMapInfo<clang::ProgramPoint> {

 static inline clang::ProgramPoint getEmptyKey() {
   uintptr_t x =
    reinterpret_cast<uintptr_t>(DenseMapInfo<void*>::getEmptyKey()) & ~0x7;
   return clang::BlockEntrance(reinterpret_cast<clang::CFGBlock*>(x), nullptr);
 }

 static inline clang::ProgramPoint getTombstoneKey() {
   uintptr_t x =
    reinterpret_cast<uintptr_t>(DenseMapInfo<void*>::getTombstoneKey()) & ~0x7;
   return clang::BlockEntrance(reinterpret_cast<clang::CFGBlock*>(x), nullptr);
 }

 static unsigned getHashValue(const clang::ProgramPoint &Loc) {
   return Loc.getHashValue();
 }

 static bool isEqual(const clang::ProgramPoint &L,
                     const clang::ProgramPoint &R) {
   return L == R;
 }

 };

 template <>
 struct isPodLike<clang::ProgramPoint> { static const bool value = true; };

 } // end namespace llvm

 #endif
	//==- ProgramPoint.h - Program Points for Path-Sensitive Analysis --- 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 the interface ProgramPoint, which identifies a
	// distinct location in a function.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CLANG_ANALYSIS_PROGRAMPOINT_H
	#define LLVM_CLANG_ANALYSIS_PROGRAMPOINT_H

	#include "clang/Analysis/AnalysisContext.h"
	#include "clang/Analysis/CFG.h"
	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/FoldingSet.h"
	#include "llvm/ADT/Optional.h"
	#include "llvm/ADT/PointerIntPair.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/Support/Casting.h"
	#include "llvm/Support/DataTypes.h"
	#include <cassert>
	#include <string>
	#include <utility>

	namespace clang {

	class AnalysisDeclContext;
	class FunctionDecl;
	class LocationContext;

	/// ProgramPoints can be "tagged" as representing points specific to a given
	/// analysis entity. Tags are abstract annotations, with an associated
	/// description and potentially other information.
	class ProgramPointTag {
	public:
	ProgramPointTag(void *tagKind = nullptr) : TagKind(tagKind) {}
	virtual ~ProgramPointTag();
	virtual StringRef getTagDescription() const = 0;

	protected:
	/// Used to implement 'isKind' in subclasses.
	const void *getTagKind() { return TagKind; }

	private:
	const void *TagKind;
	};

	class SimpleProgramPointTag : public ProgramPointTag {
	std::string Desc;
	public:
	SimpleProgramPointTag(StringRef MsgProvider, StringRef Msg);
	StringRef getTagDescription() const override;
	};

	class ProgramPoint {
	public:
	enum Kind { BlockEdgeKind,
	BlockEntranceKind,
	BlockExitKind,
	PreStmtKind,
	PreStmtPurgeDeadSymbolsKind,
	PostStmtPurgeDeadSymbolsKind,
	PostStmtKind,
	PreLoadKind,
	PostLoadKind,
	PreStoreKind,
	PostStoreKind,
	PostConditionKind,
	PostLValueKind,
	MinPostStmtKind = PostStmtKind,
	MaxPostStmtKind = PostLValueKind,
	PostInitializerKind,
	CallEnterKind,
	CallExitBeginKind,
	CallExitEndKind,
	PreImplicitCallKind,
	PostImplicitCallKind,
	MinImplicitCallKind = PreImplicitCallKind,
	MaxImplicitCallKind = PostImplicitCallKind,
	EpsilonKind};

	private:
	const void *Data1;
	llvm::PointerIntPair<const void *, 2, unsigned> Data2;

	// The LocationContext could be NULL to allow ProgramPoint to be used in
	// context insensitive analysis.
	llvm::PointerIntPair<const LocationContext *, 2, unsigned> L;

	llvm::PointerIntPair<const ProgramPointTag *, 2, unsigned> Tag;

	protected:
	ProgramPoint() {}
	ProgramPoint(const void *P,
	Kind k,
	const LocationContext *l,
	const ProgramPointTag *tag = nullptr)
	: Data1(P),
	Data2(nullptr, (((unsigned) k) >> 0) & 0x3),
	L(l, (((unsigned) k) >> 2) & 0x3),
	Tag(tag, (((unsigned) k) >> 4) & 0x3) {
	assert(getKind() == k);
	assert(getLocationContext() == l);
	assert(getData1() == P);
	}

	ProgramPoint(const void *P1,
	const void *P2,
	Kind k,
	const LocationContext *l,
	const ProgramPointTag *tag = nullptr)
	: Data1(P1),
	Data2(P2, (((unsigned) k) >> 0) & 0x3),
	L(l, (((unsigned) k) >> 2) & 0x3),
	Tag(tag, (((unsigned) k) >> 4) & 0x3) {}

	protected:
	const void *getData1() const { return Data1; }
	const void *getData2() const { return Data2.getPointer(); }
	void setData2(const void *d) { Data2.setPointer(d); }

	public:
	/// Create a new ProgramPoint object that is the same as the original
	/// except for using the specified tag value.
	ProgramPoint withTag(const ProgramPointTag *tag) const {
	return ProgramPoint(getData1(), getData2(), getKind(),
	getLocationContext(), tag);
	}

	/// \brief Convert to the specified ProgramPoint type, asserting that this
	/// ProgramPoint is of the desired type.
	template<typename T>
	T castAs() const {
	assert(T::isKind(*this));
	T t;
	ProgramPoint& PP = t;
	PP = *this;
	return t;
	}

	/// \brief Convert to the specified ProgramPoint type, returning None if this
	/// ProgramPoint is not of the desired type.
	template<typename T>
	Optional<T> getAs() const {
	if (!T::isKind(*this))
	return None;
	T t;
	ProgramPoint& PP = t;
	PP = *this;
	return t;
	}

	Kind getKind() const {
	unsigned x = Tag.getInt();
	x <<= 2;
	x \|= L.getInt();
	x <<= 2;
	x \|= Data2.getInt();
	return (Kind) x;
	}

	/// \brief Is this a program point corresponding to purge/removal of dead
	/// symbols and bindings.
	bool isPurgeKind() {
	Kind K = getKind();
	return (K == PostStmtPurgeDeadSymbolsKind \|\|
	K == PreStmtPurgeDeadSymbolsKind);
	}

	const ProgramPointTag *getTag() const { return Tag.getPointer(); }

	const LocationContext *getLocationContext() const {
	return L.getPointer();
	}

	// For use with DenseMap. This hash is probably slow.
	unsigned getHashValue() const {
	llvm::FoldingSetNodeID ID;
	Profile(ID);
	return ID.ComputeHash();
	}

	bool operator==(const ProgramPoint & RHS) const {
	return Data1 == RHS.Data1 &&
	Data2 == RHS.Data2 &&
	L == RHS.L &&
	Tag == RHS.Tag;
	}

	bool operator!=(const ProgramPoint &RHS) const {
	return Data1 != RHS.Data1 \|\|
	Data2 != RHS.Data2 \|\|
	L != RHS.L \|\|
	Tag != RHS.Tag;
	}

	void Profile(llvm::FoldingSetNodeID& ID) const {
	ID.AddInteger((unsigned) getKind());
	ID.AddPointer(getData1());
	ID.AddPointer(getData2());
	ID.AddPointer(getLocationContext());
	ID.AddPointer(getTag());
	}

	static ProgramPoint getProgramPoint(const Stmt *S, ProgramPoint::Kind K,
	const LocationContext *LC,
	const ProgramPointTag *tag);
	};

	class BlockEntrance : public ProgramPoint {
	public:
	BlockEntrance(const CFGBlock B, const LocationContext L,
	const ProgramPointTag *tag = nullptr)
	: ProgramPoint(B, BlockEntranceKind, L, tag) {
	assert(B && "BlockEntrance requires non-null block");
	}

	const CFGBlock *getBlock() const {
	return reinterpret_cast<const CFGBlock*>(getData1());
	}

	Optional<CFGElement> getFirstElement() const {
	const CFGBlock *B = getBlock();
	return B->empty() ? Optional<CFGElement>() : B->front();
	}

	private:
	friend class ProgramPoint;
	BlockEntrance() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == BlockEntranceKind;
	}
	};

	class BlockExit : public ProgramPoint {
	public:
	BlockExit(const CFGBlock B, const LocationContext L)
	: ProgramPoint(B, BlockExitKind, L) {}

	const CFGBlock *getBlock() const {
	return reinterpret_cast<const CFGBlock*>(getData1());
	}

	const Stmt *getTerminator() const {
	return getBlock()->getTerminator();
	}

	private:
	friend class ProgramPoint;
	BlockExit() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == BlockExitKind;
	}
	};

	class StmtPoint : public ProgramPoint {
	public:
	StmtPoint(const Stmt S, const void p2, Kind k, const LocationContext *L,
	const ProgramPointTag *tag)
	: ProgramPoint(S, p2, k, L, tag) {
	assert(S);
	}

	const Stmt getStmt() const { return (const Stmt) getData1(); }

	template <typename T>
	const T* getStmtAs() const { return dyn_cast<T>(getStmt()); }

	protected:
	StmtPoint() {}
	private:
	friend class ProgramPoint;
	static bool isKind(const ProgramPoint &Location) {
	unsigned k = Location.getKind();
	return k >= PreStmtKind && k <= MaxPostStmtKind;
	}
	};


	class PreStmt : public StmtPoint {
	public:
	PreStmt(const Stmt S, const LocationContext L, const ProgramPointTag *tag,
	const Stmt *SubStmt = nullptr)
	: StmtPoint(S, SubStmt, PreStmtKind, L, tag) {}

	const Stmt getSubStmt() const { return (const Stmt) getData2(); }

	private:
	friend class ProgramPoint;
	PreStmt() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == PreStmtKind;
	}
	};

	class PostStmt : public StmtPoint {
	protected:
	PostStmt() {}
	PostStmt(const Stmt S, const void data, Kind k, const LocationContext *L,
	const ProgramPointTag *tag = nullptr)
	: StmtPoint(S, data, k, L, tag) {}

	public:
	explicit PostStmt(const Stmt S, Kind k, const LocationContext L,
	const ProgramPointTag *tag = nullptr)
	: StmtPoint(S, nullptr, k, L, tag) {}

	explicit PostStmt(const Stmt S, const LocationContext L,
	const ProgramPointTag *tag = nullptr)
	: StmtPoint(S, nullptr, PostStmtKind, L, tag) {}

	private:
	friend class ProgramPoint;
	static bool isKind(const ProgramPoint &Location) {
	unsigned k = Location.getKind();
	return k >= MinPostStmtKind && k <= MaxPostStmtKind;
	}
	};

	// PostCondition represents the post program point of a branch condition.
	class PostCondition : public PostStmt {
	public:
	PostCondition(const Stmt S, const LocationContext L,
	const ProgramPointTag *tag = nullptr)
	: PostStmt(S, PostConditionKind, L, tag) {}

	private:
	friend class ProgramPoint;
	PostCondition() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == PostConditionKind;
	}
	};

	class LocationCheck : public StmtPoint {
	protected:
	LocationCheck() {}
	LocationCheck(const Stmt S, const LocationContext L,
	ProgramPoint::Kind K, const ProgramPointTag *tag)
	: StmtPoint(S, nullptr, K, L, tag) {}

	private:
	friend class ProgramPoint;
	static bool isKind(const ProgramPoint &location) {
	unsigned k = location.getKind();
	return k == PreLoadKind \|\| k == PreStoreKind;
	}
	};

	class PreLoad : public LocationCheck {
	public:
	PreLoad(const Stmt S, const LocationContext L,
	const ProgramPointTag *tag = nullptr)
	: LocationCheck(S, L, PreLoadKind, tag) {}

	private:
	friend class ProgramPoint;
	PreLoad() {}
	static bool isKind(const ProgramPoint &location) {
	return location.getKind() == PreLoadKind;
	}
	};

	class PreStore : public LocationCheck {
	public:
	PreStore(const Stmt S, const LocationContext L,
	const ProgramPointTag *tag = nullptr)
	: LocationCheck(S, L, PreStoreKind, tag) {}

	private:
	friend class ProgramPoint;
	PreStore() {}
	static bool isKind(const ProgramPoint &location) {
	return location.getKind() == PreStoreKind;
	}
	};

	class PostLoad : public PostStmt {
	public:
	PostLoad(const Stmt S, const LocationContext L,
	const ProgramPointTag *tag = nullptr)
	: PostStmt(S, PostLoadKind, L, tag) {}

	private:
	friend class ProgramPoint;
	PostLoad() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == PostLoadKind;
	}
	};

	/// \brief Represents a program point after a store evaluation.
	class PostStore : public PostStmt {
	public:
	/// Construct the post store point.
	/// \param Loc can be used to store the information about the location
	/// used in the form it was uttered in the code.
	PostStore(const Stmt S, const LocationContext L, const void *Loc,
	const ProgramPointTag *tag = nullptr)
	: PostStmt(S, PostStoreKind, L, tag) {
	assert(getData2() == nullptr);
	setData2(Loc);
	}

	/// \brief Returns the information about the location used in the store,
	/// how it was uttered in the code.
	const void *getLocationValue() const {
	return getData2();
	}

	private:
	friend class ProgramPoint;
	PostStore() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == PostStoreKind;
	}
	};

	class PostLValue : public PostStmt {
	public:
	PostLValue(const Stmt S, const LocationContext L,
	const ProgramPointTag *tag = nullptr)
	: PostStmt(S, PostLValueKind, L, tag) {}

	private:
	friend class ProgramPoint;
	PostLValue() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == PostLValueKind;
	}
	};

	/// Represents a point after we ran remove dead bindings BEFORE
	/// processing the given statement.
	class PreStmtPurgeDeadSymbols : public StmtPoint {
	public:
	PreStmtPurgeDeadSymbols(const Stmt S, const LocationContext L,
	const ProgramPointTag *tag = nullptr)
	: StmtPoint(S, nullptr, PreStmtPurgeDeadSymbolsKind, L, tag) { }

	private:
	friend class ProgramPoint;
	PreStmtPurgeDeadSymbols() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == PreStmtPurgeDeadSymbolsKind;
	}
	};

	/// Represents a point after we ran remove dead bindings AFTER
	/// processing the given statement.
	class PostStmtPurgeDeadSymbols : public StmtPoint {
	public:
	PostStmtPurgeDeadSymbols(const Stmt S, const LocationContext L,
	const ProgramPointTag *tag = nullptr)
	: StmtPoint(S, nullptr, PostStmtPurgeDeadSymbolsKind, L, tag) { }

	private:
	friend class ProgramPoint;
	PostStmtPurgeDeadSymbols() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == PostStmtPurgeDeadSymbolsKind;
	}
	};

	class BlockEdge : public ProgramPoint {
	public:
	BlockEdge(const CFGBlock B1, const CFGBlock B2, const LocationContext *L)
	: ProgramPoint(B1, B2, BlockEdgeKind, L) {
	assert(B1 && "BlockEdge: source block must be non-null");
	assert(B2 && "BlockEdge: destination block must be non-null");
	}

	const CFGBlock *getSrc() const {
	return static_cast<const CFGBlock*>(getData1());
	}

	const CFGBlock *getDst() const {
	return static_cast<const CFGBlock*>(getData2());
	}

	private:
	friend class ProgramPoint;
	BlockEdge() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == BlockEdgeKind;
	}
	};

	class PostInitializer : public ProgramPoint {
	public:
	/// \brief Construct a PostInitializer point that represents a location after
	/// CXXCtorInitializer expression evaluation.
	///
	/// \param I The initializer.
	/// \param Loc The location of the field being initialized.
	PostInitializer(const CXXCtorInitializer *I,
	const void *Loc,
	const LocationContext *L)
	: ProgramPoint(I, Loc, PostInitializerKind, L) {}

	const CXXCtorInitializer *getInitializer() const {
	return static_cast<const CXXCtorInitializer *>(getData1());
	}

	/// \brief Returns the location of the field.
	const void *getLocationValue() const {
	return getData2();
	}

	private:
	friend class ProgramPoint;
	PostInitializer() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == PostInitializerKind;
	}
	};

	/// Represents an implicit call event.
	///
	/// The nearest statement is provided for diagnostic purposes.
	class ImplicitCallPoint : public ProgramPoint {
	public:
	ImplicitCallPoint(const Decl *D, SourceLocation Loc, Kind K,
	const LocationContext L, const ProgramPointTag Tag)
	: ProgramPoint(Loc.getPtrEncoding(), D, K, L, Tag) {}

	const Decl getDecl() const { return static_cast<const Decl >(getData2()); }
	SourceLocation getLocation() const {
	return SourceLocation::getFromPtrEncoding(getData1());
	}

	protected:
	ImplicitCallPoint() {}
	private:
	friend class ProgramPoint;
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() >= MinImplicitCallKind &&
	Location.getKind() <= MaxImplicitCallKind;
	}
	};

	/// Represents a program point just before an implicit call event.
	///
	/// Explicit calls will appear as PreStmt program points.
	class PreImplicitCall : public ImplicitCallPoint {
	public:
	PreImplicitCall(const Decl D, SourceLocation Loc, const LocationContext L,
	const ProgramPointTag *Tag = nullptr)
	: ImplicitCallPoint(D, Loc, PreImplicitCallKind, L, Tag) {}

	private:
	friend class ProgramPoint;
	PreImplicitCall() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == PreImplicitCallKind;
	}
	};

	/// Represents a program point just after an implicit call event.
	///
	/// Explicit calls will appear as PostStmt program points.
	class PostImplicitCall : public ImplicitCallPoint {
	public:
	PostImplicitCall(const Decl D, SourceLocation Loc, const LocationContext L,
	const ProgramPointTag *Tag = nullptr)
	: ImplicitCallPoint(D, Loc, PostImplicitCallKind, L, Tag) {}

	private:
	friend class ProgramPoint;
	PostImplicitCall() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == PostImplicitCallKind;
	}
	};

	/// Represents a point when we begin processing an inlined call.
	/// CallEnter uses the caller's location context.
	class CallEnter : public ProgramPoint {
	public:
	CallEnter(const Stmt stmt, const StackFrameContext calleeCtx,
	const LocationContext *callerCtx)
	: ProgramPoint(stmt, calleeCtx, CallEnterKind, callerCtx, nullptr) {}

	const Stmt *getCallExpr() const {
	return static_cast<const Stmt *>(getData1());
	}

	const StackFrameContext *getCalleeContext() const {
	return static_cast<const StackFrameContext *>(getData2());
	}

	/// Returns the entry block in the CFG for the entered function.
	const CFGBlock *getEntry() const {
	const StackFrameContext *CalleeCtx = getCalleeContext();
	const CFG *CalleeCFG = CalleeCtx->getCFG();
	return &(CalleeCFG->getEntry());
	}

	private:
	friend class ProgramPoint;
	CallEnter() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == CallEnterKind;
	}
	};

	/// Represents a point when we start the call exit sequence (for inlined call).
	///
	/// The call exit is simulated with a sequence of nodes, which occur between
	/// CallExitBegin and CallExitEnd. The following operations occur between the
	/// two program points:
	/// - CallExitBegin
	/// - Bind the return value
	/// - Run Remove dead bindings (to clean up the dead symbols from the callee).
	/// - CallExitEnd
	class CallExitBegin : public ProgramPoint {
	public:
	// CallExitBegin uses the callee's location context.
	CallExitBegin(const StackFrameContext L, const ReturnStmt RS)
	: ProgramPoint(RS, CallExitBeginKind, L, nullptr) { }

	private:
	friend class ProgramPoint;
	CallExitBegin() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == CallExitBeginKind;
	}
	};

	/// Represents a point when we finish the call exit sequence (for inlined call).
	/// \sa CallExitBegin
	class CallExitEnd : public ProgramPoint {
	public:
	// CallExitEnd uses the caller's location context.
	CallExitEnd(const StackFrameContext *CalleeCtx,
	const LocationContext *CallerCtx)
	: ProgramPoint(CalleeCtx, CallExitEndKind, CallerCtx, nullptr) {}

	const StackFrameContext *getCalleeContext() const {
	return static_cast<const StackFrameContext *>(getData1());
	}

	private:
	friend class ProgramPoint;
	CallExitEnd() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == CallExitEndKind;
	}
	};

	/// This is a meta program point, which should be skipped by all the diagnostic
	/// reasoning etc.
	class EpsilonPoint : public ProgramPoint {
	public:
	EpsilonPoint(const LocationContext L, const void Data1,
	const void *Data2 = nullptr,
	const ProgramPointTag *tag = nullptr)
	: ProgramPoint(Data1, Data2, EpsilonKind, L, tag) {}

	const void *getData() const { return getData1(); }

	private:
	friend class ProgramPoint;
	EpsilonPoint() {}
	static bool isKind(const ProgramPoint &Location) {
	return Location.getKind() == EpsilonKind;
	}
	};

	} // end namespace clang


	namespace llvm { // Traits specialization for DenseMap

	template <> struct DenseMapInfo<clang::ProgramPoint> {

	static inline clang::ProgramPoint getEmptyKey() {
	uintptr_t x =
	reinterpret_cast<uintptr_t>(DenseMapInfo<void*>::getEmptyKey()) & ~0x7;
	return clang::BlockEntrance(reinterpret_cast<clang::CFGBlock*>(x), nullptr);
	}

	static inline clang::ProgramPoint getTombstoneKey() {
	uintptr_t x =
	reinterpret_cast<uintptr_t>(DenseMapInfo<void*>::getTombstoneKey()) & ~0x7;
	return clang::BlockEntrance(reinterpret_cast<clang::CFGBlock*>(x), nullptr);
	}

	static unsigned getHashValue(const clang::ProgramPoint &Loc) {
	return Loc.getHashValue();
	}

	static bool isEqual(const clang::ProgramPoint &L,
	const clang::ProgramPoint &R) {
	return L == R;
	}

	};

	template <>
	struct isPodLike<clang::ProgramPoint> { static const bool value = true; };

	} // end namespace llvm

	#endif