clang/lib/StaticAnalyzer/Core/CFRefCount.cpp

// CFRefCount.cpp - Transfer functions for tracking simple 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 defines the methods for CFRefCount, which implements
//  a reference count checker for Core Foundation (Mac OS X).
//
//===----------------------------------------------------------------------===//

#include "clang/StaticAnalyzer/Core/Checker.h"
#include "clang/StaticAnalyzer/Core/CheckerManager.h"
#include "clang/StaticAnalyzer/Core/PathSensitive/CheckerContext.h"
#include "clang/AST/DeclObjC.h"
#include "clang/AST/DeclCXX.h"
#include "clang/AST/StmtVisitor.h"
#include "clang/Basic/LangOptions.h"
#include "clang/Basic/SourceManager.h"
#include "clang/StaticAnalyzer/Core/BugReporter/BugType.h"
#include "clang/StaticAnalyzer/Core/BugReporter/PathDiagnostic.h"
#include "clang/StaticAnalyzer/Checkers/LocalCheckers.h"
#include "clang/Analysis/DomainSpecific/CocoaConventions.h"
#include "clang/StaticAnalyzer/Core/PathSensitive/ExprEngineBuilders.h"
#include "clang/StaticAnalyzer/Core/PathSensitive/GRStateTrait.h"
#include "clang/StaticAnalyzer/Core/PathSensitive/TransferFuncs.h"
#include "clang/StaticAnalyzer/Core/PathSensitive/SymbolManager.h"
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/FoldingSet.h"
#include "llvm/ADT/ImmutableList.h"
#include "llvm/ADT/ImmutableMap.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/StringExtras.h"
#include <cstdarg>

using namespace clang;
using namespace ento;
using llvm::StrInStrNoCase;

namespace {
class InstanceReceiver {
  ObjCMessage Msg;
  const LocationContext *LC;
public:
  InstanceReceiver() : LC(0) { }
  InstanceReceiver(const ObjCMessage &msg,
                   const LocationContext *lc = 0) : Msg(msg), LC(lc) {}

  bool isValid() const {
    return Msg.isValid() && Msg.isInstanceMessage();
  }
  operator bool() const {
    return isValid();
  }

  SVal getSValAsScalarOrLoc(const GRState *state) {
    assert(isValid());
    // We have an expression for the receiver?  Fetch the value
    // of that expression.
    if (const Expr *Ex = Msg.getInstanceReceiver())
      return state->getSValAsScalarOrLoc(Ex);

    // Otherwise we are sending a message to super.  In this case the
    // object reference is the same as 'self'.
    if (const ImplicitParamDecl *SelfDecl = LC->getSelfDecl())
      return state->getSVal(state->getRegion(SelfDecl, LC));

    return UnknownVal();
  }

  SourceRange getSourceRange() const {
    assert(isValid());
    if (const Expr *Ex = Msg.getInstanceReceiver())
      return Ex->getSourceRange();

    // Otherwise we are sending a message to super.
    SourceLocation L = Msg.getSuperLoc();
    assert(L.isValid());
    return SourceRange(L, L);
  }
};
}

namespace {
class GenericNodeBuilderRefCount {
  StmtNodeBuilder *SNB;
  const Stmt *S;
  const ProgramPointTag *tag;
  EndOfFunctionNodeBuilder *ENB;
public:
  GenericNodeBuilderRefCount(StmtNodeBuilder &snb, const Stmt *s,
                     const ProgramPointTag *t)
  : SNB(&snb), S(s), tag(t), ENB(0) {}

  GenericNodeBuilderRefCount(EndOfFunctionNodeBuilder &enb)
  : SNB(0), S(0), tag(0), ENB(&enb) {}

  ExplodedNode *MakeNode(const GRState *state, ExplodedNode *Pred) {
    if (SNB)
      return SNB->generateNode(PostStmt(S, Pred->getLocationContext(), tag),
                               state, Pred);

    assert(ENB);
    return ENB->generateNode(state, Pred);
  }
};
} // end anonymous namespace

//===----------------------------------------------------------------------===//
// Primitives used for constructing summaries for function/method calls.
//===----------------------------------------------------------------------===//

/// ArgEffect is used to summarize a function/method call's effect on a
/// particular argument.
enum ArgEffect { Autorelease, Dealloc, DecRef, DecRefMsg, DoNothing,
                 DecRefBridgedTransfered,
                 DoNothingByRef, IncRefMsg, IncRef, MakeCollectable, MayEscape,
                 NewAutoreleasePool, SelfOwn, StopTracking };

namespace llvm {
template <> struct FoldingSetTrait<ArgEffect> {
static inline void Profile(const ArgEffect X, FoldingSetNodeID& ID) {
  ID.AddInteger((unsigned) X);
}
};
} // end llvm namespace

/// ArgEffects summarizes the effects of a function/method call on all of
/// its arguments.
typedef llvm::ImmutableMap<unsigned,ArgEffect> ArgEffects;

namespace {

///  RetEffect is used to summarize a function/method call's behavior with
///  respect to its return value.
class RetEffect {
public:
  enum Kind { NoRet, Alias, OwnedSymbol, OwnedAllocatedSymbol,
              NotOwnedSymbol, GCNotOwnedSymbol, ARCNotOwnedSymbol,
              ReceiverAlias,
              OwnedWhenTrackedReceiver };

  enum ObjKind { CF, ObjC, AnyObj };

private:
  Kind K;
  ObjKind O;
  unsigned index;

  RetEffect(Kind k, unsigned idx = 0) : K(k), O(AnyObj), index(idx) {}
  RetEffect(Kind k, ObjKind o) : K(k), O(o), index(0) {}

public:
  Kind getKind() const { return K; }

  ObjKind getObjKind() const { return O; }

  unsigned getIndex() const {
    assert(getKind() == Alias);
    return index;
  }

  bool isOwned() const {
    return K == OwnedSymbol || K == OwnedAllocatedSymbol ||
           K == OwnedWhenTrackedReceiver;
  }

  static RetEffect MakeOwnedWhenTrackedReceiver() {
    return RetEffect(OwnedWhenTrackedReceiver, ObjC);
  }

  static RetEffect MakeAlias(unsigned Idx) {
    return RetEffect(Alias, Idx);
  }
  static RetEffect MakeReceiverAlias() {
    return RetEffect(ReceiverAlias);
  }
  static RetEffect MakeOwned(ObjKind o, bool isAllocated = false) {
    return RetEffect(isAllocated ? OwnedAllocatedSymbol : OwnedSymbol, o);
  }
  static RetEffect MakeNotOwned(ObjKind o) {
    return RetEffect(NotOwnedSymbol, o);
  }
  static RetEffect MakeGCNotOwned() {
    return RetEffect(GCNotOwnedSymbol, ObjC);
  }
  static RetEffect MakeARCNotOwned() {
    return RetEffect(ARCNotOwnedSymbol, ObjC);
  }
  static RetEffect MakeNoRet() {
    return RetEffect(NoRet);
  }
};

//===----------------------------------------------------------------------===//
// Reference-counting logic (typestate + counts).
//===----------------------------------------------------------------------===//

class RefVal {
public:
  enum Kind {
    Owned = 0, // Owning reference.
    NotOwned,  // Reference is not owned by still valid (not freed).
    Released,  // Object has been released.
    ReturnedOwned, // Returned object passes ownership to caller.
    ReturnedNotOwned, // Return object does not pass ownership to caller.
    ERROR_START,
    ErrorDeallocNotOwned, // -dealloc called on non-owned object.
    ErrorDeallocGC, // Calling -dealloc with GC enabled.
    ErrorUseAfterRelease, // Object used after released.
    ErrorReleaseNotOwned, // Release of an object that was not owned.
    ERROR_LEAK_START,
    ErrorLeak,  // A memory leak due to excessive reference counts.
    ErrorLeakReturned, // A memory leak due to the returning method not having
                       // the correct naming conventions.
    ErrorGCLeakReturned,
    ErrorOverAutorelease,
    ErrorReturnedNotOwned
  };

private:
  Kind kind;
  RetEffect::ObjKind okind;
  unsigned Cnt;
  unsigned ACnt;
  QualType T;

  RefVal(Kind k, RetEffect::ObjKind o, unsigned cnt, unsigned acnt, QualType t)
  : kind(k), okind(o), Cnt(cnt), ACnt(acnt), T(t) {}

public:
  Kind getKind() const { return kind; }

  RetEffect::ObjKind getObjKind() const { return okind; }

  unsigned getCount() const { return Cnt; }
  unsigned getAutoreleaseCount() const { return ACnt; }
  unsigned getCombinedCounts() const { return Cnt + ACnt; }
  void clearCounts() { Cnt = 0; ACnt = 0; }
  void setCount(unsigned i) { Cnt = i; }
  void setAutoreleaseCount(unsigned i) { ACnt = i; }

  QualType getType() const { return T; }

  bool isOwned() const {
    return getKind() == Owned;
  }

  bool isNotOwned() const {
    return getKind() == NotOwned;
  }

  bool isReturnedOwned() const {
    return getKind() == ReturnedOwned;
  }

  bool isReturnedNotOwned() const {
    return getKind() == ReturnedNotOwned;
  }

  static RefVal makeOwned(RetEffect::ObjKind o, QualType t,
                          unsigned Count = 1) {
    return RefVal(Owned, o, Count, 0, t);
  }

  static RefVal makeNotOwned(RetEffect::ObjKind o, QualType t,
                             unsigned Count = 0) {
    return RefVal(NotOwned, o, Count, 0, t);
  }

  // Comparison, profiling, and pretty-printing.

  bool operator==(const RefVal& X) const {
    return kind == X.kind && Cnt == X.Cnt && T == X.T && ACnt == X.ACnt;
  }

  RefVal operator-(size_t i) const {
    return RefVal(getKind(), getObjKind(), getCount() - i,
                  getAutoreleaseCount(), getType());
  }

  RefVal operator+(size_t i) const {
    return RefVal(getKind(), getObjKind(), getCount() + i,
                  getAutoreleaseCount(), getType());
  }

  RefVal operator^(Kind k) const {
    return RefVal(k, getObjKind(), getCount(), getAutoreleaseCount(),
                  getType());
  }

  RefVal autorelease() const {
    return RefVal(getKind(), getObjKind(), getCount(), getAutoreleaseCount()+1,
                  getType());
  }

  void Profile(llvm::FoldingSetNodeID& ID) const {
    ID.AddInteger((unsigned) kind);
    ID.AddInteger(Cnt);
    ID.AddInteger(ACnt);
    ID.Add(T);
  }

  void print(raw_ostream& Out) const;
};

void RefVal::print(raw_ostream& Out) const {
  if (!T.isNull())
    Out << "Tracked Type:" << T.getAsString() << '\n';

  switch (getKind()) {
    default: assert(false);
    case Owned: {
      Out << "Owned";
      unsigned cnt = getCount();
      if (cnt) Out << " (+ " << cnt << ")";
      break;
    }

    case NotOwned: {
      Out << "NotOwned";
      unsigned cnt = getCount();
      if (cnt) Out << " (+ " << cnt << ")";
      break;
    }

    case ReturnedOwned: {
      Out << "ReturnedOwned";
      unsigned cnt = getCount();
      if (cnt) Out << " (+ " << cnt << ")";
      break;
    }

    case ReturnedNotOwned: {
      Out << "ReturnedNotOwned";
      unsigned cnt = getCount();
      if (cnt) Out << " (+ " << cnt << ")";
      break;
    }

    case Released:
      Out << "Released";
      break;

    case ErrorDeallocGC:
      Out << "-dealloc (GC)";
      break;

    case ErrorDeallocNotOwned:
      Out << "-dealloc (not-owned)";
      break;

    case ErrorLeak:
      Out << "Leaked";
      break;

    case ErrorLeakReturned:
      Out << "Leaked (Bad naming)";
      break;

    case ErrorGCLeakReturned:
      Out << "Leaked (GC-ed at return)";
      break;

    case ErrorUseAfterRelease:
      Out << "Use-After-Release [ERROR]";
      break;

    case ErrorReleaseNotOwned:
      Out << "Release of Not-Owned [ERROR]";
      break;

    case RefVal::ErrorOverAutorelease:
      Out << "Over autoreleased";
      break;

    case RefVal::ErrorReturnedNotOwned:
      Out << "Non-owned object returned instead of owned";
      break;
  }

  if (ACnt) {
    Out << " [ARC +" << ACnt << ']';
  }
}
} //end anonymous namespace

//===----------------------------------------------------------------------===//
// RefBindings - State used to track object reference counts.
//===----------------------------------------------------------------------===//

typedef llvm::ImmutableMap<SymbolRef, RefVal> RefBindings;

namespace clang {
namespace ento {
  template<>
  struct GRStateTrait<RefBindings> : public GRStatePartialTrait<RefBindings> {
    static void* GDMIndex() {
      static int RefBIndex = 0;
      return &RefBIndex;
    }
  };
}
}

//===----------------------------------------------------------------------===//
// Summaries
//===----------------------------------------------------------------------===//

namespace {
class RetainSummary {
  /// Args - an ordered vector of (index, ArgEffect) pairs, where index
  ///  specifies the argument (starting from 0).  This can be sparsely
  ///  populated; arguments with no entry in Args use 'DefaultArgEffect'.
  ArgEffects Args;

  /// DefaultArgEffect - The default ArgEffect to apply to arguments that
  ///  do not have an entry in Args.
  ArgEffect   DefaultArgEffect;

  /// Receiver - If this summary applies to an Objective-C message expression,
  ///  this is the effect applied to the state of the receiver.
  ArgEffect   Receiver;

  /// Ret - The effect on the return value.  Used to indicate if the
  ///  function/method call returns a new tracked symbol, returns an
  ///  alias of one of the arguments in the call, and so on.
  RetEffect   Ret;

  /// EndPath - Indicates that execution of this method/function should
  ///  terminate the simulation of a path.
  bool EndPath;

public:
  RetainSummary(ArgEffects A, RetEffect R, ArgEffect defaultEff,
                ArgEffect ReceiverEff, bool endpath = false)
    : Args(A), DefaultArgEffect(defaultEff), Receiver(ReceiverEff), Ret(R),
      EndPath(endpath) {}

  /// getArg - Return the argument effect on the argument specified by
  ///  idx (starting from 0).
  ArgEffect getArg(unsigned idx) const {
    if (const ArgEffect *AE = Args.lookup(idx))
      return *AE;

    return DefaultArgEffect;
  }
  
  void addArg(ArgEffects::Factory &af, unsigned idx, ArgEffect e) {
    Args = af.add(Args, idx, e);
  }

  /// setDefaultArgEffect - Set the default argument effect.
  void setDefaultArgEffect(ArgEffect E) {
    DefaultArgEffect = E;
  }

  /// getRetEffect - Returns the effect on the return value of the call.
  RetEffect getRetEffect() const { return Ret; }

  /// setRetEffect - Set the effect of the return value of the call.
  void setRetEffect(RetEffect E) { Ret = E; }

  /// isEndPath - Returns true if executing the given method/function should
  ///  terminate the path.
  bool isEndPath() const { return EndPath; }

  
  /// Sets the effect on the receiver of the message.
  void setReceiverEffect(ArgEffect e) { Receiver = e; }
  
  /// getReceiverEffect - Returns the effect on the receiver of the call.
  ///  This is only meaningful if the summary applies to an ObjCMessageExpr*.
  ArgEffect getReceiverEffect() const { return Receiver; }
};
} // end anonymous namespace

//===----------------------------------------------------------------------===//
// Data structures for constructing summaries.
//===----------------------------------------------------------------------===//

namespace {
class ObjCSummaryKey {
  IdentifierInfo* II;
  Selector S;
public:
  ObjCSummaryKey(IdentifierInfo* ii, Selector s)
    : II(ii), S(s) {}

  ObjCSummaryKey(const ObjCInterfaceDecl* d, Selector s)
    : II(d ? d->getIdentifier() : 0), S(s) {}

  ObjCSummaryKey(const ObjCInterfaceDecl* d, IdentifierInfo *ii, Selector s)
    : II(d ? d->getIdentifier() : ii), S(s) {}

  ObjCSummaryKey(Selector s)
    : II(0), S(s) {}

  IdentifierInfo* getIdentifier() const { return II; }
  Selector getSelector() const { return S; }
};
}

namespace llvm {
template <> struct DenseMapInfo<ObjCSummaryKey> {
  static inline ObjCSummaryKey getEmptyKey() {
    return ObjCSummaryKey(DenseMapInfo<IdentifierInfo*>::getEmptyKey(),
                          DenseMapInfo<Selector>::getEmptyKey());
  }

  static inline ObjCSummaryKey getTombstoneKey() {
    return ObjCSummaryKey(DenseMapInfo<IdentifierInfo*>::getTombstoneKey(),
                          DenseMapInfo<Selector>::getTombstoneKey());
  }

  static unsigned getHashValue(const ObjCSummaryKey &V) {
    return (DenseMapInfo<IdentifierInfo*>::getHashValue(V.getIdentifier())
            & 0x88888888)
        | (DenseMapInfo<Selector>::getHashValue(V.getSelector())
            & 0x55555555);
  }

  static bool isEqual(const ObjCSummaryKey& LHS, const ObjCSummaryKey& RHS) {
    return DenseMapInfo<IdentifierInfo*>::isEqual(LHS.getIdentifier(),
                                                  RHS.getIdentifier()) &&
           DenseMapInfo<Selector>::isEqual(LHS.getSelector(),
                                           RHS.getSelector());
  }

};
template <>
struct isPodLike<ObjCSummaryKey> { static const bool value = true; };
} // end llvm namespace

namespace {
class ObjCSummaryCache {
  typedef llvm::DenseMap<ObjCSummaryKey, RetainSummary*> MapTy;
  MapTy M;
public:
  ObjCSummaryCache() {}

  RetainSummary* find(const ObjCInterfaceDecl* D, IdentifierInfo *ClsName,
                Selector S) {
    // Lookup the method using the decl for the class @interface.  If we
    // have no decl, lookup using the class name.
    return D ? find(D, S) : find(ClsName, S);
  }

  RetainSummary* find(const ObjCInterfaceDecl* D, Selector S) {
    // Do a lookup with the (D,S) pair.  If we find a match return
    // the iterator.
    ObjCSummaryKey K(D, S);
    MapTy::iterator I = M.find(K);

    if (I != M.end() || !D)
      return I->second;

    // Walk the super chain.  If we find a hit with a parent, we'll end
    // up returning that summary.  We actually allow that key (null,S), as
    // we cache summaries for the null ObjCInterfaceDecl* to allow us to
    // generate initial summaries without having to worry about NSObject
    // being declared.
    // FIXME: We may change this at some point.
    for (ObjCInterfaceDecl* C=D->getSuperClass() ;; C=C->getSuperClass()) {
      if ((I = M.find(ObjCSummaryKey(C, S))) != M.end())
        break;

      if (!C)
        return NULL;
    }

    // Cache the summary with original key to make the next lookup faster
    // and return the iterator.
    RetainSummary *Summ = I->second;
    M[K] = Summ;
    return Summ;
  }

  RetainSummary* find(IdentifierInfo* II, Selector S) {
    // FIXME: Class method lookup.  Right now we dont' have a good way
    // of going between IdentifierInfo* and the class hierarchy.
    MapTy::iterator I = M.find(ObjCSummaryKey(II, S));

    if (I == M.end())
      I = M.find(ObjCSummaryKey(S));

    return I == M.end() ? NULL : I->second;
  }

  RetainSummary*& operator[](ObjCSummaryKey K) {
    return M[K];
  }

  RetainSummary*& operator[](Selector S) {
    return M[ ObjCSummaryKey(S) ];
  }
};
} // end anonymous namespace

//===----------------------------------------------------------------------===//
// Data structures for managing collections of summaries.
//===----------------------------------------------------------------------===//

namespace {
class RetainSummaryManager {

  //==-----------------------------------------------------------------==//
  //  Typedefs.
  //==-----------------------------------------------------------------==//

  typedef llvm::DenseMap<const FunctionDecl*, RetainSummary*>
          FuncSummariesTy;

  typedef ObjCSummaryCache ObjCMethodSummariesTy;

  //==-----------------------------------------------------------------==//
  //  Data.
  //==-----------------------------------------------------------------==//

  /// Ctx - The ASTContext object for the analyzed ASTs.
  ASTContext& Ctx;

  /// CFDictionaryCreateII - An IdentifierInfo* representing the indentifier
  ///  "CFDictionaryCreate".
  IdentifierInfo* CFDictionaryCreateII;

  /// GCEnabled - Records whether or not the analyzed code runs in GC mode.
  const bool GCEnabled;

  /// Records whether or not the analyzed code runs in ARC mode.
  const bool ARCEnabled;

  /// FuncSummaries - A map from FunctionDecls to summaries.
  FuncSummariesTy FuncSummaries;

  /// ObjCClassMethodSummaries - A map from selectors (for instance methods)
  ///  to summaries.
  ObjCMethodSummariesTy ObjCClassMethodSummaries;

  /// ObjCMethodSummaries - A map from selectors to summaries.
  ObjCMethodSummariesTy ObjCMethodSummaries;

  /// BPAlloc - A BumpPtrAllocator used for allocating summaries, ArgEffects,
  ///  and all other data used by the checker.
  llvm::BumpPtrAllocator BPAlloc;

  /// AF - A factory for ArgEffects objects.
  ArgEffects::Factory AF;

  /// ScratchArgs - A holding buffer for construct ArgEffects.
  ArgEffects ScratchArgs;

  /// ObjCAllocRetE - Default return effect for methods returning Objective-C
  ///  objects.
  RetEffect ObjCAllocRetE;

  /// ObjCInitRetE - Default return effect for init methods returning
  ///   Objective-C objects.
  RetEffect ObjCInitRetE;

  RetainSummary DefaultSummary;
  RetainSummary* StopSummary;

  //==-----------------------------------------------------------------==//
  //  Methods.
  //==-----------------------------------------------------------------==//

  /// getArgEffects - Returns a persistent ArgEffects object based on the
  ///  data in ScratchArgs.
  ArgEffects getArgEffects();

  enum UnaryFuncKind { cfretain, cfrelease, cfmakecollectable };

public:
  RetEffect getObjAllocRetEffect() const { return ObjCAllocRetE; }

  RetainSummary *getDefaultSummary() {
    RetainSummary *Summ = (RetainSummary*) BPAlloc.Allocate<RetainSummary>();
    return new (Summ) RetainSummary(DefaultSummary);
  }

  RetainSummary* getUnarySummary(const FunctionType* FT, UnaryFuncKind func);

  RetainSummary* getCFSummaryCreateRule(const FunctionDecl* FD);
  RetainSummary* getCFSummaryGetRule(const FunctionDecl* FD);
  RetainSummary* getCFCreateGetRuleSummary(const FunctionDecl* FD, 
                                           StringRef FName);

  RetainSummary* getPersistentSummary(ArgEffects AE, RetEffect RetEff,
                                      ArgEffect ReceiverEff = DoNothing,
                                      ArgEffect DefaultEff = MayEscape,
                                      bool isEndPath = false);

  RetainSummary* getPersistentSummary(RetEffect RE,
                                      ArgEffect ReceiverEff = DoNothing,
                                      ArgEffect DefaultEff = MayEscape) {
    return getPersistentSummary(getArgEffects(), RE, ReceiverEff, DefaultEff);
  }

  RetainSummary *getPersistentStopSummary() {
    if (StopSummary)
      return StopSummary;

    StopSummary = getPersistentSummary(RetEffect::MakeNoRet(),
                                       StopTracking, StopTracking);

    return StopSummary;
  }

  RetainSummary *getInitMethodSummary(QualType RetTy);

  void InitializeClassMethodSummaries();
  void InitializeMethodSummaries();
private:
  void addNSObjectClsMethSummary(Selector S, RetainSummary *Summ) {
    ObjCClassMethodSummaries[S] = Summ;
  }

  void addNSObjectMethSummary(Selector S, RetainSummary *Summ) {
    ObjCMethodSummaries[S] = Summ;
  }

  void addClassMethSummary(const char* Cls, const char* nullaryName,
                           RetainSummary *Summ) {
    IdentifierInfo* ClsII = &Ctx.Idents.get(Cls);
    Selector S = GetNullarySelector(nullaryName, Ctx);
    ObjCClassMethodSummaries[ObjCSummaryKey(ClsII, S)]  = Summ;
  }

  void addInstMethSummary(const char* Cls, const char* nullaryName,
                          RetainSummary *Summ) {
    IdentifierInfo* ClsII = &Ctx.Idents.get(Cls);
    Selector S = GetNullarySelector(nullaryName, Ctx);
    ObjCMethodSummaries[ObjCSummaryKey(ClsII, S)]  = Summ;
  }

  Selector generateSelector(va_list argp) {
    SmallVector<IdentifierInfo*, 10> II;

    while (const char* s = va_arg(argp, const char*))
      II.push_back(&Ctx.Idents.get(s));

    return Ctx.Selectors.getSelector(II.size(), &II[0]);
  }

  void addMethodSummary(IdentifierInfo *ClsII, ObjCMethodSummariesTy& Summaries,
                        RetainSummary* Summ, va_list argp) {
    Selector S = generateSelector(argp);
    Summaries[ObjCSummaryKey(ClsII, S)] = Summ;
  }

  void addInstMethSummary(const char* Cls, RetainSummary* Summ, ...) {
    va_list argp;
    va_start(argp, Summ);
    addMethodSummary(&Ctx.Idents.get(Cls), ObjCMethodSummaries, Summ, argp);
    va_end(argp);
  }

  void addClsMethSummary(const char* Cls, RetainSummary* Summ, ...) {
    va_list argp;
    va_start(argp, Summ);
    addMethodSummary(&Ctx.Idents.get(Cls),ObjCClassMethodSummaries, Summ, argp);
    va_end(argp);
  }

  void addClsMethSummary(IdentifierInfo *II, RetainSummary* Summ, ...) {
    va_list argp;
    va_start(argp, Summ);
    addMethodSummary(II, ObjCClassMethodSummaries, Summ, argp);
    va_end(argp);
  }

  void addPanicSummary(const char* Cls, ...) {
    RetainSummary* Summ = getPersistentSummary(AF.getEmptyMap(),
                                               RetEffect::MakeNoRet(),
                                               DoNothing,  DoNothing, true);
    va_list argp;
    va_start (argp, Cls);
    addMethodSummary(&Ctx.Idents.get(Cls), ObjCMethodSummaries, Summ, argp);
    va_end(argp);
  }

public:

  RetainSummaryManager(ASTContext& ctx, bool gcenabled, bool usesARC)
   : Ctx(ctx),
     CFDictionaryCreateII(&ctx.Idents.get("CFDictionaryCreate")),
     GCEnabled(gcenabled),
     ARCEnabled(usesARC),
     AF(BPAlloc), ScratchArgs(AF.getEmptyMap()),
     ObjCAllocRetE(gcenabled
                    ? RetEffect::MakeGCNotOwned()
                    : (usesARC ? RetEffect::MakeARCNotOwned()
                               : RetEffect::MakeOwned(RetEffect::ObjC, true))),
     ObjCInitRetE(gcenabled 
                    ? RetEffect::MakeGCNotOwned()
                    : (usesARC ? RetEffect::MakeARCNotOwned()
                               : RetEffect::MakeOwnedWhenTrackedReceiver())),
     DefaultSummary(AF.getEmptyMap() /* per-argument effects (none) */,
                    RetEffect::MakeNoRet() /* return effect */,
                    MayEscape, /* default argument effect */
                    DoNothing /* receiver effect */),
     StopSummary(0) {

    InitializeClassMethodSummaries();
    InitializeMethodSummaries();
  }

  ~RetainSummaryManager();

  RetainSummary* getSummary(const FunctionDecl* FD);

  RetainSummary *getInstanceMethodSummary(const ObjCMessage &msg,
                                          const GRState *state,
                                          const LocationContext *LC);

  RetainSummary* getInstanceMethodSummary(const ObjCMessage &msg,
                                          const ObjCInterfaceDecl* ID) {
    return getInstanceMethodSummary(msg.getSelector(), 0,
                            ID, msg.getMethodDecl(), msg.getType(Ctx));
  }

  RetainSummary* getInstanceMethodSummary(Selector S, IdentifierInfo *ClsName,
                                          const ObjCInterfaceDecl* ID,
                                          const ObjCMethodDecl *MD,
                                          QualType RetTy);

  RetainSummary *getClassMethodSummary(Selector S, IdentifierInfo *ClsName,
                                       const ObjCInterfaceDecl *ID,
                                       const ObjCMethodDecl *MD,
                                       QualType RetTy);

  RetainSummary *getClassMethodSummary(const ObjCMessage &msg) {
    const ObjCInterfaceDecl *Class = 0;
    if (!msg.isInstanceMessage())
      Class = msg.getReceiverInterface();

    return getClassMethodSummary(msg.getSelector(),
                                 Class? Class->getIdentifier() : 0,
                                 Class,
                                 msg.getMethodDecl(), msg.getType(Ctx));
  }

  /// getMethodSummary - This version of getMethodSummary is used to query
  ///  the summary for the current method being analyzed.
  RetainSummary *getMethodSummary(const ObjCMethodDecl *MD) {
    // FIXME: Eventually this should be unneeded.
    const ObjCInterfaceDecl *ID = MD->getClassInterface();
    Selector S = MD->getSelector();
    IdentifierInfo *ClsName = ID->getIdentifier();
    QualType ResultTy = MD->getResultType();

    if (MD->isInstanceMethod())
      return getInstanceMethodSummary(S, ClsName, ID, MD, ResultTy);
    else
      return getClassMethodSummary(S, ClsName, ID, MD, ResultTy);
  }

  RetainSummary* getCommonMethodSummary(const ObjCMethodDecl* MD,
                                        Selector S, QualType RetTy);

  void updateSummaryFromAnnotations(RetainSummary &Summ,
                                    const ObjCMethodDecl *MD);

  void updateSummaryFromAnnotations(RetainSummary &Summ,
                                    const FunctionDecl *FD);

  bool isGCEnabled() const { return GCEnabled; }

  bool isARCEnabled() const { return ARCEnabled; }
  
  bool isARCorGCEnabled() const { return GCEnabled || ARCEnabled; }

  RetainSummary *copySummary(RetainSummary *OldSumm) {
    RetainSummary *Summ = (RetainSummary*) BPAlloc.Allocate<RetainSummary>();
    new (Summ) RetainSummary(*OldSumm);
    return Summ;
  }
};

} // end anonymous namespace

//===----------------------------------------------------------------------===//
// Implementation of checker data structures.
//===----------------------------------------------------------------------===//

RetainSummaryManager::~RetainSummaryManager() {}

ArgEffects RetainSummaryManager::getArgEffects() {
  ArgEffects AE = ScratchArgs;
  ScratchArgs = AF.getEmptyMap();
  return AE;
}

RetainSummary*
RetainSummaryManager::getPersistentSummary(ArgEffects AE, RetEffect RetEff,
                                           ArgEffect ReceiverEff,
                                           ArgEffect DefaultEff,
                                           bool isEndPath) {
  // Create the summary and return it.
  RetainSummary *Summ = (RetainSummary*) BPAlloc.Allocate<RetainSummary>();
  new (Summ) RetainSummary(AE, RetEff, DefaultEff, ReceiverEff, isEndPath);
  return Summ;
}

//===----------------------------------------------------------------------===//
// Summary creation for functions (largely uses of Core Foundation).
//===----------------------------------------------------------------------===//

static bool isRetain(const FunctionDecl* FD, StringRef FName) {
  return FName.endswith("Retain");
}

static bool isRelease(const FunctionDecl* FD, StringRef FName) {
  return FName.endswith("Release");
}

RetainSummary* RetainSummaryManager::getSummary(const FunctionDecl* FD) {
  // Look up a summary in our cache of FunctionDecls -> Summaries.
  FuncSummariesTy::iterator I = FuncSummaries.find(FD);
  if (I != FuncSummaries.end())
    return I->second;

  // No summary?  Generate one.
  RetainSummary *S = 0;

  do {
    // We generate "stop" summaries for implicitly defined functions.
    if (FD->isImplicit()) {
      S = getPersistentStopSummary();
      break;
    }
    // For C++ methods, generate an implicit "stop" summary as well.  We
    // can relax this once we have a clear policy for C++ methods and
    // ownership attributes.
    if (isa<CXXMethodDecl>(FD)) {
      S = getPersistentStopSummary();
      break;
    }

    // [PR 3337] Use 'getAs<FunctionType>' to strip away any typedefs on the
    // function's type.
    const FunctionType* FT = FD->getType()->getAs<FunctionType>();
    const IdentifierInfo *II = FD->getIdentifier();
    if (!II)
      break;

    StringRef FName = II->getName();

    // Strip away preceding '_'.  Doing this here will effect all the checks
    // down below.
    FName = FName.substr(FName.find_first_not_of('_'));

    // Inspect the result type.
    QualType RetTy = FT->getResultType();

    // FIXME: This should all be refactored into a chain of "summary lookup"
    //  filters.
    assert(ScratchArgs.isEmpty());

    if (FName == "pthread_create") {
      // Part of: <rdar://problem/7299394>.  This will be addressed
      // better with IPA.
      S = getPersistentStopSummary();
    } else if (FName == "NSMakeCollectable") {
      // Handle: id NSMakeCollectable(CFTypeRef)
      S = (RetTy->isObjCIdType())
          ? getUnarySummary(FT, cfmakecollectable)
          : getPersistentStopSummary();
    } else if (FName == "IOBSDNameMatching" ||
               FName == "IOServiceMatching" ||
               FName == "IOServiceNameMatching" ||
               FName == "IORegistryEntryIDMatching" ||
               FName == "IOOpenFirmwarePathMatching") {
      // Part of <rdar://problem/6961230>. (IOKit)
      // This should be addressed using a API table.
      S = getPersistentSummary(RetEffect::MakeOwned(RetEffect::CF, true),
                               DoNothing, DoNothing);
    } else if (FName == "IOServiceGetMatchingService" ||
               FName == "IOServiceGetMatchingServices") {
      // FIXES: <rdar://problem/6326900>
      // This should be addressed using a API table.  This strcmp is also
      // a little gross, but there is no need to super optimize here.
      ScratchArgs = AF.add(ScratchArgs, 1, DecRef);
      S = getPersistentSummary(RetEffect::MakeNoRet(), DoNothing, DoNothing);
    } else if (FName == "IOServiceAddNotification" ||
               FName == "IOServiceAddMatchingNotification") {
      // Part of <rdar://problem/6961230>. (IOKit)
      // This should be addressed using a API table.
      ScratchArgs = AF.add(ScratchArgs, 2, DecRef);
      S = getPersistentSummary(RetEffect::MakeNoRet(), DoNothing, DoNothing);
    } else if (FName == "CVPixelBufferCreateWithBytes") {
      // FIXES: <rdar://problem/7283567>
      // Eventually this can be improved by recognizing that the pixel
      // buffer passed to CVPixelBufferCreateWithBytes is released via
      // a callback and doing full IPA to make sure this is done correctly.
      // FIXME: This function has an out parameter that returns an
      // allocated object.
      ScratchArgs = AF.add(ScratchArgs, 7, StopTracking);
      S = getPersistentSummary(RetEffect::MakeNoRet(), DoNothing, DoNothing);
    } else if (FName == "CGBitmapContextCreateWithData") {
      // FIXES: <rdar://problem/7358899>
      // Eventually this can be improved by recognizing that 'releaseInfo'
      // passed to CGBitmapContextCreateWithData is released via
      // a callback and doing full IPA to make sure this is done correctly.
      ScratchArgs = AF.add(ScratchArgs, 8, StopTracking);
      S = getPersistentSummary(RetEffect::MakeOwned(RetEffect::CF, true),
                               DoNothing, DoNothing);
    } else if (FName == "CVPixelBufferCreateWithPlanarBytes") {
      // FIXES: <rdar://problem/7283567>
      // Eventually this can be improved by recognizing that the pixel
      // buffer passed to CVPixelBufferCreateWithPlanarBytes is released
      // via a callback and doing full IPA to make sure this is done
      // correctly.
      ScratchArgs = AF.add(ScratchArgs, 12, StopTracking);
      S = getPersistentSummary(RetEffect::MakeNoRet(), DoNothing, DoNothing);
    }

    // Did we get a summary?
    if (S)
      break;

    // Enable this code once the semantics of NSDeallocateObject are resolved
    // for GC.  <rdar://problem/6619988>
#if 0
    // Handle: NSDeallocateObject(id anObject);
    // This method does allow 'nil' (although we don't check it now).
    if (strcmp(FName, "NSDeallocateObject") == 0) {
      return RetTy == Ctx.VoidTy
        ? getPersistentSummary(RetEffect::MakeNoRet(), DoNothing, Dealloc)
        : getPersistentStopSummary();
    }
#endif

    if (RetTy->isPointerType()) {
      // For CoreFoundation ('CF') types.
      if (cocoa::isRefType(RetTy, "CF", FName)) {
        if (isRetain(FD, FName))
          S = getUnarySummary(FT, cfretain);
        else if (FName.find("MakeCollectable") != StringRef::npos)
          S = getUnarySummary(FT, cfmakecollectable);
        else
          S = getCFCreateGetRuleSummary(FD, FName);

        break;
      }

      // For CoreGraphics ('CG') types.
      if (cocoa::isRefType(RetTy, "CG", FName)) {
        if (isRetain(FD, FName))
          S = getUnarySummary(FT, cfretain);
        else
          S = getCFCreateGetRuleSummary(FD, FName);

        break;
      }

      // For the Disk Arbitration API (DiskArbitration/DADisk.h)
      if (cocoa::isRefType(RetTy, "DADisk") ||
          cocoa::isRefType(RetTy, "DADissenter") ||
          cocoa::isRefType(RetTy, "DASessionRef")) {
        S = getCFCreateGetRuleSummary(FD, FName);
        break;
      }

      break;
    }

    // Check for release functions, the only kind of functions that we care
    // about that don't return a pointer type.
    if (FName[0] == 'C' && (FName[1] == 'F' || FName[1] == 'G')) {
      // Test for 'CGCF'.
      FName = FName.substr(FName.startswith("CGCF") ? 4 : 2);

      if (isRelease(FD, FName))
        S = getUnarySummary(FT, cfrelease);
      else {
        assert (ScratchArgs.isEmpty());
        // Remaining CoreFoundation and CoreGraphics functions.
        // We use to assume that they all strictly followed the ownership idiom
        // and that ownership cannot be transferred.  While this is technically
        // correct, many methods allow a tracked object to escape.  For example:
        //
        //   CFMutableDictionaryRef x = CFDictionaryCreateMutable(...);
        //   CFDictionaryAddValue(y, key, x);
        //   CFRelease(x);
        //   ... it is okay to use 'x' since 'y' has a reference to it
        //
        // We handle this and similar cases with the follow heuristic.  If the
        // function name contains "InsertValue", "SetValue", "AddValue",
        // "AppendValue", or "SetAttribute", then we assume that arguments may
        // "escape."  This means that something else holds on to the object,
        // allowing it be used even after its local retain count drops to 0.
        ArgEffect E = (StrInStrNoCase(FName, "InsertValue") != StringRef::npos||
                       StrInStrNoCase(FName, "AddValue") != StringRef::npos ||
                       StrInStrNoCase(FName, "SetValue") != StringRef::npos ||
                       StrInStrNoCase(FName, "AppendValue") != StringRef::npos||
                       StrInStrNoCase(FName, "SetAttribute") != StringRef::npos)
                      ? MayEscape : DoNothing;

        S = getPersistentSummary(RetEffect::MakeNoRet(), DoNothing, E);
      }
    }
  }
  while (0);

  if (!S)
    S = getDefaultSummary();

  // Annotations override defaults.
  assert(S);
  updateSummaryFromAnnotations(*S, FD);

  FuncSummaries[FD] = S;
  return S;
}

RetainSummary*
RetainSummaryManager::getCFCreateGetRuleSummary(const FunctionDecl* FD,
                                                StringRef FName) {
  if (coreFoundation::followsCreateRule(FName))
    return getCFSummaryCreateRule(FD);

  return getCFSummaryGetRule(FD);
}

RetainSummary*
RetainSummaryManager::getUnarySummary(const FunctionType* FT,
                                      UnaryFuncKind func) {

  // Sanity check that this is *really* a unary function.  This can
  // happen if people do weird things.
  const FunctionProtoType* FTP = dyn_cast<FunctionProtoType>(FT);
  if (!FTP || FTP->getNumArgs() != 1)
    return getPersistentStopSummary();

  assert (ScratchArgs.isEmpty());

  switch (func) {
    case cfretain: {
      ScratchArgs = AF.add(ScratchArgs, 0, IncRef);
      return getPersistentSummary(RetEffect::MakeAlias(0),
                                  DoNothing, DoNothing);
    }

    case cfrelease: {
      ScratchArgs = AF.add(ScratchArgs, 0, DecRef);
      return getPersistentSummary(RetEffect::MakeNoRet(),
                                  DoNothing, DoNothing);
    }

    case cfmakecollectable: {
      ScratchArgs = AF.add(ScratchArgs, 0, MakeCollectable);
      return getPersistentSummary(RetEffect::MakeAlias(0),DoNothing, DoNothing);
    }

    default:
      assert (false && "Not a supported unary function.");
      return getDefaultSummary();
  }
}

RetainSummary* 
RetainSummaryManager::getCFSummaryCreateRule(const FunctionDecl* FD) {
  assert (ScratchArgs.isEmpty());

  if (FD->getIdentifier() == CFDictionaryCreateII) {
    ScratchArgs = AF.add(ScratchArgs, 1, DoNothingByRef);
    ScratchArgs = AF.add(ScratchArgs, 2, DoNothingByRef);
  }

  return getPersistentSummary(RetEffect::MakeOwned(RetEffect::CF, true));
}

RetainSummary* 
RetainSummaryManager::getCFSummaryGetRule(const FunctionDecl* FD) {
  assert (ScratchArgs.isEmpty());
  return getPersistentSummary(RetEffect::MakeNotOwned(RetEffect::CF),
                              DoNothing, DoNothing);
}

//===----------------------------------------------------------------------===//
// Summary creation for Selectors.
//===----------------------------------------------------------------------===//

RetainSummary*
RetainSummaryManager::getInitMethodSummary(QualType RetTy) {
  assert(ScratchArgs.isEmpty());
  // 'init' methods conceptually return a newly allocated object and claim
  // the receiver.
  if (cocoa::isCocoaObjectRef(RetTy) ||
      coreFoundation::isCFObjectRef(RetTy))
    return getPersistentSummary(ObjCInitRetE, DecRefMsg);

  return getDefaultSummary();
}

void
RetainSummaryManager::updateSummaryFromAnnotations(RetainSummary &Summ,
                                                   const FunctionDecl *FD) {
  if (!FD)
    return;

  // Effects on the parameters.
  unsigned parm_idx = 0;
  for (FunctionDecl::param_const_iterator pi = FD->param_begin(), 
         pe = FD->param_end(); pi != pe; ++pi, ++parm_idx) {
    const ParmVarDecl *pd = *pi;
    if (pd->getAttr<NSConsumedAttr>()) {
      if (!GCEnabled)
        Summ.addArg(AF, parm_idx, DecRef);      
    }
    else if(pd->getAttr<CFConsumedAttr>()) {
      Summ.addArg(AF, parm_idx, DecRef);      
    }   
  }
  
  QualType RetTy = FD->getResultType();

  // Determine if there is a special return effect for this method.
  if (cocoa::isCocoaObjectRef(RetTy)) {
    if (FD->getAttr<NSReturnsRetainedAttr>()) {
      Summ.setRetEffect(ObjCAllocRetE);
    }
    else if (FD->getAttr<CFReturnsRetainedAttr>()) {
      Summ.setRetEffect(RetEffect::MakeOwned(RetEffect::CF, true));
    }
    else if (FD->getAttr<NSReturnsNotRetainedAttr>()) {
      Summ.setRetEffect(RetEffect::MakeNotOwned(RetEffect::ObjC));
    }
    else if (FD->getAttr<CFReturnsNotRetainedAttr>()) {
      Summ.setRetEffect(RetEffect::MakeNotOwned(RetEffect::CF));
    }
  }
  else if (RetTy->getAs<PointerType>()) {
    if (FD->getAttr<CFReturnsRetainedAttr>()) {
      Summ.setRetEffect(RetEffect::MakeOwned(RetEffect::CF, true));
    }
    else if (FD->getAttr<CFReturnsNotRetainedAttr>()) {
      Summ.setRetEffect(RetEffect::MakeNotOwned(RetEffect::CF));
    }
  }
}

void
RetainSummaryManager::updateSummaryFromAnnotations(RetainSummary &Summ,
                                                  const ObjCMethodDecl *MD) {
  if (!MD)
    return;

  bool isTrackedLoc = false;

  // Effects on the receiver.
  if (MD->getAttr<NSConsumesSelfAttr>()) {
    if (!GCEnabled)
      Summ.setReceiverEffect(DecRefMsg);      
  }
  
  // Effects on the parameters.
  unsigned parm_idx = 0;
  for (ObjCMethodDecl::param_iterator pi=MD->param_begin(), pe=MD->param_end();
       pi != pe; ++pi, ++parm_idx) {
    const ParmVarDecl *pd = *pi;
    if (pd->getAttr<NSConsumedAttr>()) {
      if (!GCEnabled)
        Summ.addArg(AF, parm_idx, DecRef);      
    }
    else if(pd->getAttr<CFConsumedAttr>()) {
      Summ.addArg(AF, parm_idx, DecRef);      
    }   
  }
  
  // Determine if there is a special return effect for this method.
  if (cocoa::isCocoaObjectRef(MD->getResultType())) {
    if (MD->getAttr<NSReturnsRetainedAttr>()) {
      Summ.setRetEffect(ObjCAllocRetE);
      return;
    }
    if (MD->getAttr<NSReturnsNotRetainedAttr>()) {
      Summ.setRetEffect(RetEffect::MakeNotOwned(RetEffect::ObjC));
      return;
    }

    isTrackedLoc = true;
  }

  if (!isTrackedLoc)
    isTrackedLoc = MD->getResultType()->getAs<PointerType>() != NULL;

  if (isTrackedLoc) {
    if (MD->getAttr<CFReturnsRetainedAttr>())
      Summ.setRetEffect(RetEffect::MakeOwned(RetEffect::CF, true));
    else if (MD->getAttr<CFReturnsNotRetainedAttr>())
      Summ.setRetEffect(RetEffect::MakeNotOwned(RetEffect::CF));
  }
}

RetainSummary*
RetainSummaryManager::getCommonMethodSummary(const ObjCMethodDecl* MD,
                                             Selector S, QualType RetTy) {

  if (MD) {
    // Scan the method decl for 'void*' arguments.  These should be treated
    // as 'StopTracking' because they are often used with delegates.
    // Delegates are a frequent form of false positives with the retain
    // count checker.
    unsigned i = 0;
    for (ObjCMethodDecl::param_iterator I = MD->param_begin(),
         E = MD->param_end(); I != E; ++I, ++i)
      if (ParmVarDecl *PD = *I) {
        QualType Ty = Ctx.getCanonicalType(PD->getType());
        if (Ty.getLocalUnqualifiedType() == Ctx.VoidPtrTy)
          ScratchArgs = AF.add(ScratchArgs, i, StopTracking);
      }
  }

  // Any special effect for the receiver?
  ArgEffect ReceiverEff = DoNothing;

  // If one of the arguments in the selector has the keyword 'delegate' we
  // should stop tracking the reference count for the receiver.  This is
  // because the reference count is quite possibly handled by a delegate
  // method.
  if (S.isKeywordSelector()) {
    const std::string &str = S.getAsString();
    assert(!str.empty());
    if (StrInStrNoCase(str, "delegate:") != StringRef::npos)
      ReceiverEff = StopTracking;
  }

  // Look for methods that return an owned object.
  if (cocoa::isCocoaObjectRef(RetTy)) {
    // EXPERIMENTAL: assume the Cocoa conventions for all objects returned
    //  by instance methods.
    RetEffect E = cocoa::followsFundamentalRule(S, MD)
                  ? ObjCAllocRetE : RetEffect::MakeNotOwned(RetEffect::ObjC);

    return getPersistentSummary(E, ReceiverEff, MayEscape);
  }

  // Look for methods that return an owned core foundation object.
  if (coreFoundation::isCFObjectRef(RetTy)) {
    RetEffect E = cocoa::followsFundamentalRule(S, MD)
      ? RetEffect::MakeOwned(RetEffect::CF, true)
      : RetEffect::MakeNotOwned(RetEffect::CF);

    return getPersistentSummary(E, ReceiverEff, MayEscape);
  }

  if (ScratchArgs.isEmpty() && ReceiverEff == DoNothing)
    return getDefaultSummary();

  return getPersistentSummary(RetEffect::MakeNoRet(), ReceiverEff, MayEscape);
}

RetainSummary*
RetainSummaryManager::getInstanceMethodSummary(const ObjCMessage &msg,
                                               const GRState *state,
                                               const LocationContext *LC) {

  // We need the type-information of the tracked receiver object
  // Retrieve it from the state.
  const Expr *Receiver = msg.getInstanceReceiver();
  const ObjCInterfaceDecl* ID = 0;

  // FIXME: Is this really working as expected?  There are cases where
  //  we just use the 'ID' from the message expression.
  SVal receiverV;

  if (Receiver) {
    receiverV = state->getSValAsScalarOrLoc(Receiver);

    // FIXME: Eventually replace the use of state->get<RefBindings> with
    // a generic API for reasoning about the Objective-C types of symbolic
    // objects.
    if (SymbolRef Sym = receiverV.getAsLocSymbol())
      if (const RefVal *T = state->get<RefBindings>(Sym))
        if (const ObjCObjectPointerType* PT =
            T->getType()->getAs<ObjCObjectPointerType>())
          ID = PT->getInterfaceDecl();

    // FIXME: this is a hack.  This may or may not be the actual method
    //  that is called.
    if (!ID) {
      if (const ObjCObjectPointerType *PT =
          Receiver->getType()->getAs<ObjCObjectPointerType>())
        ID = PT->getInterfaceDecl();
    }
  } else {
    // FIXME: Hack for 'super'.
    ID = msg.getReceiverInterface();
  }

  // FIXME: The receiver could be a reference to a class, meaning that
  //  we should use the class method.
  RetainSummary *Summ = getInstanceMethodSummary(msg, ID);
  return Summ ? Summ : getDefaultSummary();
}

RetainSummary*
RetainSummaryManager::getInstanceMethodSummary(Selector S,
                                               IdentifierInfo *ClsName,
                                               const ObjCInterfaceDecl* ID,
                                               const ObjCMethodDecl *MD,
                                               QualType RetTy) {

  // Look up a summary in our summary cache.
  RetainSummary *Summ = ObjCMethodSummaries.find(ID, ClsName, S);

  if (!Summ) {
    assert(ScratchArgs.isEmpty());

    // "initXXX": pass-through for receiver.
    if (cocoa::deriveNamingConvention(S, MD) == cocoa::InitRule)
      Summ = getInitMethodSummary(RetTy);
    else
      Summ = getCommonMethodSummary(MD, S, RetTy);

    // Annotations override defaults.
    updateSummaryFromAnnotations(*Summ, MD);

    // Memoize the summary.
    ObjCMethodSummaries[ObjCSummaryKey(ID, ClsName, S)] = Summ;
  }

  return Summ;
}

RetainSummary*
RetainSummaryManager::getClassMethodSummary(Selector S, IdentifierInfo *ClsName,
                                            const ObjCInterfaceDecl *ID,
                                            const ObjCMethodDecl *MD,
                                            QualType RetTy) {

  assert(ClsName && "Class name must be specified.");
  RetainSummary *Summ = ObjCClassMethodSummaries.find(ID, ClsName, S);

  if (!Summ) {
    Summ = getCommonMethodSummary(MD, S, RetTy);
    // Annotations override defaults.
    updateSummaryFromAnnotations(*Summ, MD);
    // Memoize the summary.
    ObjCClassMethodSummaries[ObjCSummaryKey(ID, ClsName, S)] = Summ;
  }

  return Summ;
}

void RetainSummaryManager::InitializeClassMethodSummaries() {
  assert(ScratchArgs.isEmpty());
  RetainSummary* Summ = getPersistentSummary(ObjCAllocRetE);

  // Create the [NSAssertionHandler currentHander] summary.
  addClassMethSummary("NSAssertionHandler", "currentHandler",
                getPersistentSummary(RetEffect::MakeNotOwned(RetEffect::ObjC)));

  // Create the [NSAutoreleasePool addObject:] summary.
  ScratchArgs = AF.add(ScratchArgs, 0, Autorelease);
  addClassMethSummary("NSAutoreleasePool", "addObject",
                      getPersistentSummary(RetEffect::MakeNoRet(),
                                           DoNothing, Autorelease));

  // Create the summaries for [NSObject performSelector...].  We treat
  // these as 'stop tracking' for the arguments because they are often
  // used for delegates that can release the object.  When we have better
  // inter-procedural analysis we can potentially do something better.  This
  // workaround is to remove false positives.
  Summ = getPersistentSummary(RetEffect::MakeNoRet(), DoNothing, StopTracking);
  IdentifierInfo *NSObjectII = &Ctx.Idents.get("NSObject");
  addClsMethSummary(NSObjectII, Summ, "performSelector", "withObject",
                    "afterDelay", NULL);
  addClsMethSummary(NSObjectII, Summ, "performSelector", "withObject",
                    "afterDelay", "inModes", NULL);
  addClsMethSummary(NSObjectII, Summ, "performSelectorOnMainThread",
                    "withObject", "waitUntilDone", NULL);
  addClsMethSummary(NSObjectII, Summ, "performSelectorOnMainThread",
                    "withObject", "waitUntilDone", "modes", NULL);
  addClsMethSummary(NSObjectII, Summ, "performSelector", "onThread",
                    "withObject", "waitUntilDone", NULL);
  addClsMethSummary(NSObjectII, Summ, "performSelector", "onThread",
                    "withObject", "waitUntilDone", "modes", NULL);
  addClsMethSummary(NSObjectII, Summ, "performSelectorInBackground",
                    "withObject", NULL);
}

void RetainSummaryManager::InitializeMethodSummaries() {

  assert (ScratchArgs.isEmpty());

  // Create the "init" selector.  It just acts as a pass-through for the
  // receiver.
  RetainSummary *InitSumm = getPersistentSummary(ObjCInitRetE, DecRefMsg);
  addNSObjectMethSummary(GetNullarySelector("init", Ctx), InitSumm);

  // awakeAfterUsingCoder: behaves basically like an 'init' method.  It
  // claims the receiver and returns a retained object.
  addNSObjectMethSummary(GetUnarySelector("awakeAfterUsingCoder", Ctx),
                         InitSumm);

  // The next methods are allocators.
  RetainSummary *AllocSumm = getPersistentSummary(ObjCAllocRetE);
  RetainSummary *CFAllocSumm =
    getPersistentSummary(RetEffect::MakeOwned(RetEffect::CF, true));

  // Create the "retain" selector.
  RetEffect E = RetEffect::MakeReceiverAlias();
  RetainSummary *Summ = getPersistentSummary(E, IncRefMsg);
  addNSObjectMethSummary(GetNullarySelector("retain", Ctx), Summ);

  // Create the "release" selector.
  Summ = getPersistentSummary(E, DecRefMsg);
  addNSObjectMethSummary(GetNullarySelector("release", Ctx), Summ);

  // Create the "drain" selector.
  Summ = getPersistentSummary(E, isGCEnabled() ? DoNothing : DecRef);
  addNSObjectMethSummary(GetNullarySelector("drain", Ctx), Summ);

  // Create the -dealloc summary.
  Summ = getPersistentSummary(RetEffect::MakeNoRet(), Dealloc);
  addNSObjectMethSummary(GetNullarySelector("dealloc", Ctx), Summ);

  // Create the "autorelease" selector.
  Summ = getPersistentSummary(E, Autorelease);
  addNSObjectMethSummary(GetNullarySelector("autorelease", Ctx), Summ);

  // Specially handle NSAutoreleasePool.
  addInstMethSummary("NSAutoreleasePool", "init",
                     getPersistentSummary(RetEffect::MakeReceiverAlias(),
                                          NewAutoreleasePool));

  // For NSWindow, allocated objects are (initially) self-owned.
  // FIXME: For now we opt for false negatives with NSWindow, as these objects
  //  self-own themselves.  However, they only do this once they are displayed.
  //  Thus, we need to track an NSWindow's display status.
  //  This is tracked in <rdar://problem/6062711>.
  //  See also http://llvm.org/bugs/show_bug.cgi?id=3714.
  RetainSummary *NoTrackYet = getPersistentSummary(RetEffect::MakeNoRet(),
                                                   StopTracking,
                                                   StopTracking);

  addClassMethSummary("NSWindow", "alloc", NoTrackYet);

#if 0
  addInstMethSummary("NSWindow", NoTrackYet, "initWithContentRect",
                     "styleMask", "backing", "defer", NULL);

  addInstMethSummary("NSWindow", NoTrackYet, "initWithContentRect",
                     "styleMask", "backing", "defer", "screen", NULL);
#endif

  // For NSPanel (which subclasses NSWindow), allocated objects are not
  //  self-owned.
  // FIXME: For now we don't track NSPanels. object for the same reason
  //   as for NSWindow objects.
  addClassMethSummary("NSPanel", "alloc", NoTrackYet);

#if 0
  addInstMethSummary("NSPanel", NoTrackYet, "initWithContentRect",
                     "styleMask", "backing", "defer", NULL);

  addInstMethSummary("NSPanel", NoTrackYet, "initWithContentRect",
                     "styleMask", "backing", "defer", "screen", NULL);
#endif

  // Don't track allocated autorelease pools yet, as it is okay to prematurely
  // exit a method.
  addClassMethSummary("NSAutoreleasePool", "alloc", NoTrackYet);

  // Create NSAssertionHandler summaries.
  addPanicSummary("NSAssertionHandler", "handleFailureInFunction", "file",
                  "lineNumber", "description", NULL);

  addPanicSummary("NSAssertionHandler", "handleFailureInMethod", "object",
                  "file", "lineNumber", "description", NULL);

  // Create summaries QCRenderer/QCView -createSnapShotImageOfType:
  addInstMethSummary("QCRenderer", AllocSumm,
                     "createSnapshotImageOfType", NULL);
  addInstMethSummary("QCView", AllocSumm,
                     "createSnapshotImageOfType", NULL);

  // Create summaries for CIContext, 'createCGImage' and
  // 'createCGLayerWithSize'.  These objects are CF objects, and are not
  // automatically garbage collected.
  addInstMethSummary("CIContext", CFAllocSumm,
                     "createCGImage", "fromRect", NULL);
  addInstMethSummary("CIContext", CFAllocSumm,
                     "createCGImage", "fromRect", "format", "colorSpace", NULL);
  addInstMethSummary("CIContext", CFAllocSumm, "createCGLayerWithSize",
           "info", NULL);
}

//===----------------------------------------------------------------------===//
// AutoreleaseBindings - State used to track objects in autorelease pools.
//===----------------------------------------------------------------------===//

typedef llvm::ImmutableMap<SymbolRef, unsigned> ARCounts;
typedef llvm::ImmutableMap<SymbolRef, ARCounts> ARPoolContents;
typedef llvm::ImmutableList<SymbolRef> ARStack;

static int AutoRCIndex = 0;
static int AutoRBIndex = 0;

namespace { class AutoreleasePoolContents {}; }
namespace { class AutoreleaseStack {}; }

namespace clang {
namespace ento {
template<> struct GRStateTrait<AutoreleaseStack>
  : public GRStatePartialTrait<ARStack> {
  static inline void* GDMIndex() { return &AutoRBIndex; }
};

template<> struct GRStateTrait<AutoreleasePoolContents>
  : public GRStatePartialTrait<ARPoolContents> {
  static inline void* GDMIndex() { return &AutoRCIndex; }
};
} // end GR namespace
} // end clang namespace

static SymbolRef GetCurrentAutoreleasePool(const GRState* state) {
  ARStack stack = state->get<AutoreleaseStack>();
  return stack.isEmpty() ? SymbolRef() : stack.getHead();
}

static const GRState * SendAutorelease(const GRState *state,
                                       ARCounts::Factory &F, SymbolRef sym) {

  SymbolRef pool = GetCurrentAutoreleasePool(state);
  const ARCounts *cnts = state->get<AutoreleasePoolContents>(pool);
  ARCounts newCnts(0);

  if (cnts) {
    const unsigned *cnt = (*cnts).lookup(sym);
    newCnts = F.add(*cnts, sym, cnt ? *cnt  + 1 : 1);
  }
  else
    newCnts = F.add(F.getEmptyMap(), sym, 1);

  return state->set<AutoreleasePoolContents>(pool, newCnts);
}

//===----------------------------------------------------------------------===//
// Transfer functions.
//===----------------------------------------------------------------------===//

namespace {

class CFRefCount : public TransferFuncs {
public:
  class BindingsPrinter : public GRState::Printer {
  public:
    virtual void Print(raw_ostream& Out, const GRState* state,
                       const char* nl, const char* sep);
  };

  typedef llvm::DenseMap<const ExplodedNode*, const RetainSummary*>
    SummaryLogTy;

  RetainSummaryManager Summaries;
  SummaryLogTy SummaryLog;
  const LangOptions&   LOpts;
  ARCounts::Factory    ARCountFactory;

  BugType *useAfterRelease, *releaseNotOwned;
  BugType *deallocGC, *deallocNotOwned;
  BugType *leakWithinFunction, *leakAtReturn;
  BugType *overAutorelease;
  BugType *returnNotOwnedForOwned;
  BugReporter *BR;
  
  llvm::DenseMap<SymbolRef, const SimpleProgramPointTag*> DeadSymbolTags;

  const GRState * Update(const GRState * state, SymbolRef sym, RefVal V,
                         ArgEffect E, RefVal::Kind& hasErr);

  void ProcessNonLeakError(ExplodedNodeSet& Dst,
                           StmtNodeBuilder& Builder,
                           const Expr* NodeExpr, SourceRange ErrorRange,
                           ExplodedNode* Pred,
                           const GRState* St,
                           RefVal::Kind hasErr, SymbolRef Sym);

  const GRState * HandleSymbolDeath(const GRState * state, SymbolRef sid, RefVal V,
                               SmallVectorImpl<SymbolRef> &Leaked);

  ExplodedNode* ProcessLeaks(const GRState * state,
                                      SmallVectorImpl<SymbolRef> &Leaked,
                                      GenericNodeBuilderRefCount &Builder,
                                      ExprEngine &Eng,
                                      ExplodedNode *Pred = 0);

public:
  CFRefCount(ASTContext& Ctx, bool gcenabled, const LangOptions& lopts)
    : Summaries(Ctx, gcenabled, (bool)lopts.ObjCAutoRefCount),
      LOpts(lopts), useAfterRelease(0), releaseNotOwned(0),
      deallocGC(0), deallocNotOwned(0),
      leakWithinFunction(0), leakAtReturn(0), overAutorelease(0),
      returnNotOwnedForOwned(0), BR(0) {}

  virtual ~CFRefCount() {
    for (llvm::DenseMap<SymbolRef, const SimpleProgramPointTag *>::iterator
         it = DeadSymbolTags.begin(), ei = DeadSymbolTags.end(); it != ei; ++it)
      delete it->second;
  }

  void RegisterChecks(ExprEngine &Eng);

  virtual void RegisterPrinters(std::vector<GRState::Printer*>& Printers) {
    Printers.push_back(new BindingsPrinter());
  }

  bool isGCEnabled() const { return Summaries.isGCEnabled(); }
  bool isARCorGCEnabled() const { return Summaries.isARCorGCEnabled(); }
  
  const LangOptions& getLangOptions() const { return LOpts; }

  const RetainSummary *getSummaryOfNode(const ExplodedNode *N) const {
    SummaryLogTy::const_iterator I = SummaryLog.find(N);
    return I == SummaryLog.end() ? 0 : I->second;
  }

  // Calls.

  void evalSummary(ExplodedNodeSet& Dst,
                   ExprEngine& Eng,
                   StmtNodeBuilder& Builder,
                   const Expr* Ex,
                   const CallOrObjCMessage &callOrMsg,
                   InstanceReceiver Receiver,
                   const RetainSummary& Summ,
                   const MemRegion *Callee,
                   ExplodedNode* Pred, const GRState *state);

  virtual void evalCall(ExplodedNodeSet& Dst,
                        ExprEngine& Eng,
                        StmtNodeBuilder& Builder,
                        const CallExpr* CE, SVal L,
                        ExplodedNode* Pred);


  virtual void evalObjCMessage(ExplodedNodeSet& Dst,
                               ExprEngine& Engine,
                               StmtNodeBuilder& Builder,
                               ObjCMessage msg,
                               ExplodedNode* Pred,
                               const GRState *state);
  // Stores.
  virtual void evalBind(StmtNodeBuilderRef& B, SVal location, SVal val);

  // End-of-path.

  virtual void evalEndPath(ExprEngine& Engine,
                           EndOfFunctionNodeBuilder& Builder);

  virtual void evalDeadSymbols(ExplodedNodeSet& Dst,
                               ExprEngine& Engine,
                               StmtNodeBuilder& Builder,
                               ExplodedNode* Pred,
                               const GRState* state,
                               SymbolReaper& SymReaper);

  const ProgramPointTag *getDeadSymbolTag(SymbolRef sym);
  
  std::pair<ExplodedNode*, const GRState *>
  HandleAutoreleaseCounts(const GRState * state, GenericNodeBuilderRefCount Bd,
                          ExplodedNode* Pred, ExprEngine &Eng,
                          SymbolRef Sym, RefVal V, bool &stop);
  // Return statements.

  virtual void evalReturn(ExplodedNodeSet& Dst,
                          ExprEngine& Engine,
                          StmtNodeBuilder& Builder,
                          const ReturnStmt* S,
                          ExplodedNode* Pred);
  
  void evalReturnWithRetEffect(ExplodedNodeSet& Dst,
                               ExprEngine& Engine,
                               StmtNodeBuilder& Builder,
                               const ReturnStmt* S,
                               ExplodedNode* Pred,
                               RetEffect RE, RefVal X,
                               SymbolRef Sym, const GRState *state);


  // Assumptions.

  virtual const GRState *evalAssume(const GRState* state, SVal condition,
                                    bool assumption);
};

} // end anonymous namespace

static void PrintPool(raw_ostream &Out, SymbolRef Sym,
                      const GRState *state) {
  Out << ' ';
  if (Sym)
    Out << Sym->getSymbolID();
  else
    Out << "<pool>";
  Out << ":{";

  // Get the contents of the pool.
  if (const ARCounts *cnts = state->get<AutoreleasePoolContents>(Sym))
    for (ARCounts::iterator J=cnts->begin(), EJ=cnts->end(); J != EJ; ++J)
      Out << '(' << J.getKey() << ',' << J.getData() << ')';

  Out << '}';
}

void CFRefCount::BindingsPrinter::Print(raw_ostream& Out,
                                        const GRState* state,
                                        const char* nl, const char* sep) {

  RefBindings B = state->get<RefBindings>();

  if (!B.isEmpty())
    Out << sep << nl;

  for (RefBindings::iterator I=B.begin(), E=B.end(); I!=E; ++I) {
    Out << (*I).first << " : ";
    (*I).second.print(Out);
    Out << nl;
  }

  // Print the autorelease stack.
  Out << sep << nl << "AR pool stack:";
  ARStack stack = state->get<AutoreleaseStack>();

  PrintPool(Out, SymbolRef(), state);  // Print the caller's pool.
  for (ARStack::iterator I=stack.begin(), E=stack.end(); I!=E; ++I)
    PrintPool(Out, *I, state);

  Out << nl;
}

//===----------------------------------------------------------------------===//
// Error reporting.
//===----------------------------------------------------------------------===//

namespace {

  //===-------------===//
  // Bug Descriptions. //
  //===-------------===//

  class CFRefBug : public BugType {
  protected:
    CFRefCount& TF;

    CFRefBug(CFRefCount* tf, StringRef name)
    : BugType(name, "Memory (Core Foundation/Objective-C)"), TF(*tf) {}
  public:

    CFRefCount& getTF() { return TF; }

    // FIXME: Eventually remove.
    virtual const char* getDescription() const = 0;

    virtual bool isLeak() const { return false; }
  };

  class UseAfterRelease : public CFRefBug {
  public:
    UseAfterRelease(CFRefCount* tf)
    : CFRefBug(tf, "Use-after-release") {}

    const char* getDescription() const {
      return "Reference-counted object is used after it is released";
    }
  };

  class BadRelease : public CFRefBug {
  public:
    BadRelease(CFRefCount* tf) : CFRefBug(tf, "Bad release") {}

    const char* getDescription() const {
      return "Incorrect decrement of the reference count of an object that is "
             "not owned at this point by the caller";
    }
  };

  class DeallocGC : public CFRefBug {
  public:
    DeallocGC(CFRefCount *tf)
      : CFRefBug(tf, "-dealloc called while using garbage collection") {}

    const char *getDescription() const {
      return "-dealloc called while using garbage collection";
    }
  };

  class DeallocNotOwned : public CFRefBug {
  public:
    DeallocNotOwned(CFRefCount *tf)
      : CFRefBug(tf, "-dealloc sent to non-exclusively owned object") {}

    const char *getDescription() const {
      return "-dealloc sent to object that may be referenced elsewhere";
    }
  };

  class OverAutorelease : public CFRefBug {
  public:
    OverAutorelease(CFRefCount *tf) :
      CFRefBug(tf, "Object sent -autorelease too many times") {}

    const char *getDescription() const {
      return "Object sent -autorelease too many times";
    }
  };

  class ReturnedNotOwnedForOwned : public CFRefBug {
  public:
    ReturnedNotOwnedForOwned(CFRefCount *tf) :
      CFRefBug(tf, "Method should return an owned object") {}

    const char *getDescription() const {
      return "Object with a +0 retain count returned to caller where a +1 "
             "(owning) retain count is expected";
    }
  };

  class Leak : public CFRefBug {
    const bool isReturn;
  protected:
    Leak(CFRefCount* tf, StringRef name, bool isRet)
    : CFRefBug(tf, name), isReturn(isRet) {}
  public:

    const char* getDescription() const { return ""; }

    bool isLeak() const { return true; }
  };

  class LeakAtReturn : public Leak {
  public:
    LeakAtReturn(CFRefCount* tf, StringRef name)
    : Leak(tf, name, true) {}
  };

  class LeakWithinFunction : public Leak {
  public:
    LeakWithinFunction(CFRefCount* tf, StringRef name)
    : Leak(tf, name, false) {}
  };

  //===---------===//
  // Bug Reports.  //
  //===---------===//

  class CFRefReport : public RangedBugReport {
  protected:
    SymbolRef Sym;
    const CFRefCount &TF;
  public:
    CFRefReport(CFRefBug& D, const CFRefCount &tf,
                ExplodedNode *n, SymbolRef sym)
      : RangedBugReport(D, D.getDescription(), n), Sym(sym), TF(tf) {}

    CFRefReport(CFRefBug& D, const CFRefCount &tf,
                ExplodedNode *n, SymbolRef sym, StringRef endText)
      : RangedBugReport(D, D.getDescription(), endText, n), Sym(sym), TF(tf) {}

    virtual ~CFRefReport() {}

    CFRefBug& getBugType() const {
      return (CFRefBug&) RangedBugReport::getBugType();
    }

    virtual std::pair<ranges_iterator, ranges_iterator> getRanges() const {
      if (!getBugType().isLeak())
        return RangedBugReport::getRanges();
      else
        return std::make_pair(ranges_iterator(), ranges_iterator());
    }

    SymbolRef getSymbol() const { return Sym; }

    PathDiagnosticPiece* getEndPath(BugReporterContext& BRC,
                                    const ExplodedNode* N);

    std::pair<const char**,const char**> getExtraDescriptiveText();

    PathDiagnosticPiece* VisitNode(const ExplodedNode* N,
                                   const ExplodedNode* PrevN,
                                   BugReporterContext& BRC);
  };

  class CFRefLeakReport : public CFRefReport {
    SourceLocation AllocSite;
    const MemRegion* AllocBinding;
  public:
    CFRefLeakReport(CFRefBug& D, const CFRefCount &tf,
                    ExplodedNode *n, SymbolRef sym,
                    ExprEngine& Eng);

    PathDiagnosticPiece* getEndPath(BugReporterContext& BRC,
                                    const ExplodedNode* N);

    SourceLocation getLocation() const { return AllocSite; }
  };
} // end anonymous namespace



static const char* Msgs[] = {
  // GC only
  "Code is compiled to only use garbage collection",
  // No GC.
  "Code is compiled to use reference counts",
  // Hybrid, with GC.
  "Code is compiled to use either garbage collection (GC) or reference counts"
  " (non-GC).  The bug occurs with GC enabled",
  // Hybrid, without GC
  "Code is compiled to use either garbage collection (GC) or reference counts"
  " (non-GC).  The bug occurs in non-GC mode"
};

std::pair<const char**,const char**> CFRefReport::getExtraDescriptiveText() {
  CFRefCount& TF = static_cast<CFRefBug&>(getBugType()).getTF();

  switch (TF.getLangOptions().getGCMode()) {
    default:
      assert(false);

    case LangOptions::GCOnly:
      assert (TF.isGCEnabled());
      return std::make_pair(&Msgs[0], &Msgs[0]+1);

    case LangOptions::NonGC:
      assert (!TF.isGCEnabled());
      return std::make_pair(&Msgs[1], &Msgs[1]+1);

    case LangOptions::HybridGC:
      if (TF.isGCEnabled())
        return std::make_pair(&Msgs[2], &Msgs[2]+1);
      else
        return std::make_pair(&Msgs[3], &Msgs[3]+1);
  }
}

static inline bool contains(const SmallVectorImpl<ArgEffect>& V,
                            ArgEffect X) {
  for (SmallVectorImpl<ArgEffect>::const_iterator I=V.begin(), E=V.end();
       I!=E; ++I)
    if (*I == X) return true;

  return false;
}

PathDiagnosticPiece* CFRefReport::VisitNode(const ExplodedNode* N,
                                            const ExplodedNode* PrevN,
                                            BugReporterContext& BRC) {

  if (!isa<PostStmt>(N->getLocation()))
    return NULL;

  // Check if the type state has changed.
  const GRState *PrevSt = PrevN->getState();
  const GRState *CurrSt = N->getState();

  const RefVal* CurrT = CurrSt->get<RefBindings>(Sym);
  if (!CurrT) return NULL;

  const RefVal &CurrV = *CurrT;
  const RefVal *PrevT = PrevSt->get<RefBindings>(Sym);

  // Create a string buffer to constain all the useful things we want
  // to tell the user.
  std::string sbuf;
  llvm::raw_string_ostream os(sbuf);

  // This is the allocation site since the previous node had no bindings
  // for this symbol.
  if (!PrevT) {
    const Stmt* S = cast<PostStmt>(N->getLocation()).getStmt();

    if (const CallExpr *CE = dyn_cast<CallExpr>(S)) {
      // Get the name of the callee (if it is available).
      SVal X = CurrSt->getSValAsScalarOrLoc(CE->getCallee());
      if (const FunctionDecl* FD = X.getAsFunctionDecl())
        os << "Call to function '" << FD << '\'';
      else
        os << "function call";
    }
    else if (isa<ObjCMessageExpr>(S)) {
      os << "Method";
    } else {
      os << "Property";
    }

    if (CurrV.getObjKind() == RetEffect::CF) {
      os << " returns a Core Foundation object with a ";
    }
    else {
      assert (CurrV.getObjKind() == RetEffect::ObjC);
      os << " returns an Objective-C object with a ";
    }

    if (CurrV.isOwned()) {
      os << "+1 retain count";

      if (static_cast<CFRefBug&>(getBugType()).getTF().isGCEnabled()) {
        assert(CurrV.getObjKind() == RetEffect::CF);
        os << ".  "
        "Core Foundation objects are not automatically garbage collected.";
      }
    }
    else {
      assert (CurrV.isNotOwned());
      os << "+0 retain count";
    }

    PathDiagnosticLocation Pos(S, BRC.getSourceManager());
    return new PathDiagnosticEventPiece(Pos, os.str());
  }

  // Gather up the effects that were performed on the object at this
  // program point
  SmallVector<ArgEffect, 2> AEffects;

  if (const RetainSummary *Summ =
        TF.getSummaryOfNode(BRC.getNodeResolver().getOriginalNode(N))) {
    // We only have summaries attached to nodes after evaluating CallExpr and
    // ObjCMessageExprs.
    const Stmt* S = cast<PostStmt>(N->getLocation()).getStmt();

    if (const CallExpr *CE = dyn_cast<CallExpr>(S)) {
      // Iterate through the parameter expressions and see if the symbol
      // was ever passed as an argument.
      unsigned i = 0;

      for (CallExpr::const_arg_iterator AI=CE->arg_begin(), AE=CE->arg_end();
           AI!=AE; ++AI, ++i) {

        // Retrieve the value of the argument.  Is it the symbol
        // we are interested in?
        if (CurrSt->getSValAsScalarOrLoc(*AI).getAsLocSymbol() != Sym)
          continue;

        // We have an argument.  Get the effect!
        AEffects.push_back(Summ->getArg(i));
      }
    }
    else if (const ObjCMessageExpr *ME = dyn_cast<ObjCMessageExpr>(S)) {
      if (const Expr *receiver = ME->getInstanceReceiver())
        if (CurrSt->getSValAsScalarOrLoc(receiver).getAsLocSymbol() == Sym) {
          // The symbol we are tracking is the receiver.
          AEffects.push_back(Summ->getReceiverEffect());
        }
    }
  }

  do {
    // Get the previous type state.
    RefVal PrevV = *PrevT;

    // Specially handle -dealloc.
    if (!TF.isGCEnabled() && contains(AEffects, Dealloc)) {
      // Determine if the object's reference count was pushed to zero.
      assert(!(PrevV == CurrV) && "The typestate *must* have changed.");
      // We may not have transitioned to 'release' if we hit an error.
      // This case is handled elsewhere.
      if (CurrV.getKind() == RefVal::Released) {
        assert(CurrV.getCombinedCounts() == 0);
        os << "Object released by directly sending the '-dealloc' message";
        break;
      }
    }

    // Specially handle CFMakeCollectable and friends.
    if (contains(AEffects, MakeCollectable)) {
      // Get the name of the function.
      const Stmt* S = cast<PostStmt>(N->getLocation()).getStmt();
      SVal X = CurrSt->getSValAsScalarOrLoc(cast<CallExpr>(S)->getCallee());
      const FunctionDecl* FD = X.getAsFunctionDecl();
      const std::string& FName = FD->getNameAsString();

      if (TF.isGCEnabled()) {
        // Determine if the object's reference count was pushed to zero.
        assert(!(PrevV == CurrV) && "The typestate *must* have changed.");

        os << "In GC mode a call to '" << FName
        <<  "' decrements an object's retain count and registers the "
        "object with the garbage collector. ";

        if (CurrV.getKind() == RefVal::Released) {
          assert(CurrV.getCount() == 0);
          os << "Since it now has a 0 retain count the object can be "
          "automatically collected by the garbage collector.";
        }
        else
          os << "An object must have a 0 retain count to be garbage collected. "
          "After this call its retain count is +" << CurrV.getCount()
          << '.';
      }
      else
        os << "When GC is not enabled a call to '" << FName
        << "' has no effect on its argument.";

      // Nothing more to say.
      break;
    }

    // Determine if the typestate has changed.
    if (!(PrevV == CurrV))
      switch (CurrV.getKind()) {
        case RefVal::Owned:
        case RefVal::NotOwned:

          if (PrevV.getCount() == CurrV.getCount()) {
            // Did an autorelease message get sent?
            if (PrevV.getAutoreleaseCount() == CurrV.getAutoreleaseCount())
              return 0;

            assert(PrevV.getAutoreleaseCount() < CurrV.getAutoreleaseCount());
            os << "Object sent -autorelease message";
            break;
          }

          if (PrevV.getCount() > CurrV.getCount())
            os << "Reference count decremented.";
          else
            os << "Reference count incremented.";

          if (unsigned Count = CurrV.getCount())
            os << " The object now has a +" << Count << " retain count.";

          if (PrevV.getKind() == RefVal::Released) {
            assert(TF.isGCEnabled() && CurrV.getCount() > 0);
            os << " The object is not eligible for garbage collection until the "
            "retain count reaches 0 again.";
          }

          break;

        case RefVal::Released:
          os << "Object released.";
          break;

        case RefVal::ReturnedOwned:
          os << "Object returned to caller as an owning reference (single retain "
          "count transferred to caller)";
          break;

        case RefVal::ReturnedNotOwned:
          os << "Object returned to caller with a +0 retain count";
          break;

        default:
          return NULL;
      }

    // Emit any remaining diagnostics for the argument effects (if any).
    for (SmallVectorImpl<ArgEffect>::iterator I=AEffects.begin(),
         E=AEffects.end(); I != E; ++I) {

      // A bunch of things have alternate behavior under GC.
      if (TF.isGCEnabled())
        switch (*I) {
          default: break;
          case Autorelease:
            os << "In GC mode an 'autorelease' has no effect.";
            continue;
          case IncRefMsg:
            os << "In GC mode the 'retain' message has no effect.";
            continue;
          case DecRefMsg:
            os << "In GC mode the 'release' message has no effect.";
            continue;
        }
    }
  } while (0);

  if (os.str().empty())
    return 0; // We have nothing to say!

  const Stmt* S = cast<PostStmt>(N->getLocation()).getStmt();
  PathDiagnosticLocation Pos(S, BRC.getSourceManager());
  PathDiagnosticPiece* P = new PathDiagnosticEventPiece(Pos, os.str());

  // Add the range by scanning the children of the statement for any bindings
  // to Sym.
  for (Stmt::const_child_iterator I = S->child_begin(), E = S->child_end();
       I!=E; ++I)
    if (const Expr* Exp = dyn_cast_or_null<Expr>(*I))
      if (CurrSt->getSValAsScalarOrLoc(Exp).getAsLocSymbol() == Sym) {
        P->addRange(Exp->getSourceRange());
        break;
      }

  return P;
}

namespace {
  class FindUniqueBinding :
  public StoreManager::BindingsHandler {
    SymbolRef Sym;
    const MemRegion* Binding;
    bool First;

  public:
    FindUniqueBinding(SymbolRef sym) : Sym(sym), Binding(0), First(true) {}

    bool HandleBinding(StoreManager& SMgr, Store store, const MemRegion* R,
                       SVal val) {

      SymbolRef SymV = val.getAsSymbol();
      if (!SymV || SymV != Sym)
        return true;

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

      return true;
    }

    operator bool() { return First && Binding; }
    const MemRegion* getRegion() { return Binding; }
  };
}

static std::pair<const ExplodedNode*,const MemRegion*>
GetAllocationSite(GRStateManager& StateMgr, const ExplodedNode* N,
                  SymbolRef Sym) {

  // Find both first node that referred to the tracked symbol and the
  // memory location that value was store to.
  const ExplodedNode* Last = N;
  const MemRegion* FirstBinding = 0;

  while (N) {
    const GRState* St = N->getState();
    RefBindings B = St->get<RefBindings>();

    if (!B.lookup(Sym))
      break;

    FindUniqueBinding FB(Sym);
    StateMgr.iterBindings(St, FB);
    if (FB) FirstBinding = FB.getRegion();

    Last = N;
    N = N->pred_empty() ? NULL : *(N->pred_begin());
  }

  return std::make_pair(Last, FirstBinding);
}

PathDiagnosticPiece*
CFRefReport::getEndPath(BugReporterContext& BRC,
                        const ExplodedNode* EndN) {
  // Tell the BugReporterContext to report cases when the tracked symbol is
  // assigned to different variables, etc.
  BRC.addNotableSymbol(Sym);
  return RangedBugReport::getEndPath(BRC, EndN);
}

PathDiagnosticPiece*
CFRefLeakReport::getEndPath(BugReporterContext& BRC,
                            const ExplodedNode* EndN){

  // Tell the BugReporterContext to report cases when the tracked symbol is
  // assigned to different variables, etc.
  BRC.addNotableSymbol(Sym);

  // We are reporting a leak.  Walk up the graph to get to the first node where
  // the symbol appeared, and also get the first VarDecl that tracked object
  // is stored to.
  const ExplodedNode* AllocNode = 0;
  const MemRegion* FirstBinding = 0;

  llvm::tie(AllocNode, FirstBinding) =
    GetAllocationSite(BRC.getStateManager(), EndN, Sym);

  SourceManager& SMgr = BRC.getSourceManager();

  // Compute an actual location for the leak.  Sometimes a leak doesn't
  // occur at an actual statement (e.g., transition between blocks; end
  // of function) so we need to walk the graph and compute a real location.
  const ExplodedNode* LeakN = EndN;
  PathDiagnosticLocation L;

  while (LeakN) {
    ProgramPoint P = LeakN->getLocation();

    if (const PostStmt *PS = dyn_cast<PostStmt>(&P)) {
      L = PathDiagnosticLocation(PS->getStmt()->getLocStart(), SMgr);
      break;
    }
    else if (const BlockEdge *BE = dyn_cast<BlockEdge>(&P)) {
      if (const Stmt* Term = BE->getSrc()->getTerminator()) {
        L = PathDiagnosticLocation(Term->getLocStart(), SMgr);
        break;
      }
    }

    LeakN = LeakN->succ_empty() ? 0 : *(LeakN->succ_begin());
  }

  if (!L.isValid()) {
    const Decl &D = EndN->getCodeDecl();
    L = PathDiagnosticLocation(D.getBodyRBrace(), SMgr);
  }

  std::string sbuf;
  llvm::raw_string_ostream os(sbuf);

  os << "Object leaked: ";

  if (FirstBinding) {
    os << "object allocated and stored into '"
       << FirstBinding->getString() << '\'';
  }
  else
    os << "allocated object";

  // Get the retain count.
  const RefVal* RV = EndN->getState()->get<RefBindings>(Sym);

  if (RV->getKind() == RefVal::ErrorLeakReturned) {
    // FIXME: Per comments in rdar://6320065, "create" only applies to CF
    // objects.  Only "copy", "alloc", "retain" and "new" transfer ownership
    // to the caller for NS objects.
    const Decl *D = &EndN->getCodeDecl();
    if (const ObjCMethodDecl *MD = dyn_cast<ObjCMethodDecl>(D)) {
      os << " is returned from a method whose name ('"
         << MD->getSelector().getAsString()
         << "') does not start with 'copy', 'mutableCopy', 'alloc' or 'new'."
            "  This violates the naming convention rules"
            " given in the Memory Management Guide for Cocoa";
    }
    else {
      const FunctionDecl *FD = cast<FunctionDecl>(D);
      os << " is return from a function whose name ('"
         << FD->getNameAsString()
         << "') does not contain 'Copy' or 'Create'.  This violates the naming"
            " convention rules given the Memory Management Guide for Core"
            " Foundation";
    }    
  }
  else if (RV->getKind() == RefVal::ErrorGCLeakReturned) {
    ObjCMethodDecl& MD = cast<ObjCMethodDecl>(EndN->getCodeDecl());
    os << " and returned from method '" << MD.getSelector().getAsString()
       << "' is potentially leaked when using garbage collection.  Callers "
          "of this method do not expect a returned object with a +1 retain "
          "count since they expect the object to be managed by the garbage "
          "collector";
  }
  else
    os << " is not referenced later in this execution path and has a retain "
          "count of +" << RV->getCount();

  return new PathDiagnosticEventPiece(L, os.str());
}

CFRefLeakReport::CFRefLeakReport(CFRefBug& D, const CFRefCount &tf,
                                 ExplodedNode *n,
                                 SymbolRef sym, ExprEngine& Eng)
: CFRefReport(D, tf, n, sym) {

  // Most bug reports are cached at the location where they occurred.
  // With leaks, we want to unique them by the location where they were
  // allocated, and only report a single path.  To do this, we need to find
  // the allocation site of a piece of tracked memory, which we do via a
  // call to GetAllocationSite.  This will walk the ExplodedGraph backwards.
  // Note that this is *not* the trimmed graph; we are guaranteed, however,
  // that all ancestor nodes that represent the allocation site have the
  // same SourceLocation.
  const ExplodedNode* AllocNode = 0;

  llvm::tie(AllocNode, AllocBinding) =  // Set AllocBinding.
    GetAllocationSite(Eng.getStateManager(), getErrorNode(), getSymbol());

  // Get the SourceLocation for the allocation site.
  ProgramPoint P = AllocNode->getLocation();
  AllocSite = cast<PostStmt>(P).getStmt()->getLocStart();

  // Fill in the description of the bug.
  Description.clear();
  llvm::raw_string_ostream os(Description);
  SourceManager& SMgr = Eng.getContext().getSourceManager();
  unsigned AllocLine = SMgr.getExpansionLineNumber(AllocSite);
  os << "Potential leak ";
  if (tf.isGCEnabled()) {
    os << "(when using garbage collection) ";
  }
  os << "of an object allocated on line " << AllocLine;

  // FIXME: AllocBinding doesn't get populated for RegionStore yet.
  if (AllocBinding)
    os << " and stored into '" << AllocBinding->getString() << '\'';
}

//===----------------------------------------------------------------------===//
// Main checker logic.
//===----------------------------------------------------------------------===//

/// GetReturnType - Used to get the return type of a message expression or
///  function call with the intention of affixing that type to a tracked symbol.
///  While the the return type can be queried directly from RetEx, when
///  invoking class methods we augment to the return type to be that of
///  a pointer to the class (as opposed it just being id).
static QualType GetReturnType(const Expr* RetE, ASTContext& Ctx) {
  QualType RetTy = RetE->getType();
  // If RetE is not a message expression just return its type.
  // If RetE is a message expression, return its types if it is something
  /// more specific than id.
  if (const ObjCMessageExpr *ME = dyn_cast<ObjCMessageExpr>(RetE))
    if (const ObjCObjectPointerType *PT = RetTy->getAs<ObjCObjectPointerType>())
      if (PT->isObjCQualifiedIdType() || PT->isObjCIdType() ||
          PT->isObjCClassType()) {
        // At this point we know the return type of the message expression is
        // id, id<...>, or Class. If we have an ObjCInterfaceDecl, we know this
        // is a call to a class method whose type we can resolve.  In such
        // cases, promote the return type to XXX* (where XXX is the class).
        const ObjCInterfaceDecl *D = ME->getReceiverInterface();
        return !D ? RetTy :
                    Ctx.getObjCObjectPointerType(Ctx.getObjCInterfaceType(D));
      }

  return RetTy;
}


// HACK: Symbols that have ref-count state that are referenced directly
//  (not as structure or array elements, or via bindings) by an argument
//  should not have their ref-count state stripped after we have
//  done an invalidation pass.
//
// FIXME: This is a global to currently share between CFRefCount and
// RetainReleaseChecker.  Eventually all functionality in CFRefCount should
// be migrated to RetainReleaseChecker, and we can make this a non-global.
llvm::DenseSet<SymbolRef> WhitelistedSymbols;
namespace {
struct ResetWhiteList {
  ResetWhiteList() {}
  ~ResetWhiteList() { WhitelistedSymbols.clear(); } 
};
}

void CFRefCount::evalSummary(ExplodedNodeSet& Dst,
                             ExprEngine& Eng,
                             StmtNodeBuilder& Builder,
                             const Expr* Ex,
                             const CallOrObjCMessage &callOrMsg,
                             InstanceReceiver Receiver,
                             const RetainSummary& Summ,
                             const MemRegion *Callee,
                             ExplodedNode* Pred, const GRState *state) {

  // Evaluate the effect of the arguments.
  RefVal::Kind hasErr = (RefVal::Kind) 0;
  SourceRange ErrorRange;
  SymbolRef ErrorSym = 0;

  SmallVector<const MemRegion*, 10> RegionsToInvalidate;
  
  // Use RAII to make sure the whitelist is properly cleared.
  ResetWhiteList resetWhiteList;

  // Invalidate all instance variables of the receiver of a message.
  // FIXME: We should be able to do better with inter-procedural analysis.
  if (Receiver) {
    SVal V = Receiver.getSValAsScalarOrLoc(state);
    if (SymbolRef Sym = V.getAsLocSymbol()) {
      if (state->get<RefBindings>(Sym))
        WhitelistedSymbols.insert(Sym);
    }
    if (const MemRegion *region = V.getAsRegion())
      RegionsToInvalidate.push_back(region);
  }
  
  // Invalidate all instance variables for the callee of a C++ method call.
  // FIXME: We should be able to do better with inter-procedural analysis.
  // FIXME: we can probably do better for const versus non-const methods.
  if (callOrMsg.isCXXCall()) {
    if (const MemRegion *callee = callOrMsg.getCXXCallee().getAsRegion())
      RegionsToInvalidate.push_back(callee);
  }
  
  for (unsigned idx = 0, e = callOrMsg.getNumArgs(); idx != e; ++idx) {
    SVal V = callOrMsg.getArgSValAsScalarOrLoc(idx);
    SymbolRef Sym = V.getAsLocSymbol();

    if (Sym)
      if (RefBindings::data_type* T = state->get<RefBindings>(Sym)) {
        WhitelistedSymbols.insert(Sym);
        state = Update(state, Sym, *T, Summ.getArg(idx), hasErr);
        if (hasErr) {
          ErrorRange = callOrMsg.getArgSourceRange(idx);
          ErrorSym = Sym;
          break;
        }
      }

  tryAgain:
    if (isa<Loc>(V)) {
      if (loc::MemRegionVal* MR = dyn_cast<loc::MemRegionVal>(&V)) {
        if (Summ.getArg(idx) == DoNothingByRef)
          continue;

        // Invalidate the value of the variable passed by reference.
        const MemRegion *R = MR->getRegion();

        // Are we dealing with an ElementRegion?  If the element type is
        // a basic integer type (e.g., char, int) and the underying region
        // is a variable region then strip off the ElementRegion.
        // FIXME: We really need to think about this for the general case
        //   as sometimes we are reasoning about arrays and other times
        //   about (char*), etc., is just a form of passing raw bytes.
        //   e.g., void *p = alloca(); foo((char*)p);
        if (const ElementRegion *ER = dyn_cast<ElementRegion>(R)) {
          // Checking for 'integral type' is probably too promiscuous, but
          // we'll leave it in for now until we have a systematic way of
          // handling all of these cases.  Eventually we need to come up
          // with an interface to StoreManager so that this logic can be
          // approriately delegated to the respective StoreManagers while
          // still allowing us to do checker-specific logic (e.g.,
          // invalidating reference counts), probably via callbacks.
          if (ER->getElementType()->isIntegralOrEnumerationType()) {
            const MemRegion *superReg = ER->getSuperRegion();
            if (isa<VarRegion>(superReg) || isa<FieldRegion>(superReg) ||
                isa<ObjCIvarRegion>(superReg))
              R = cast<TypedRegion>(superReg);
          }
          // FIXME: What about layers of ElementRegions?
        }

        // Mark this region for invalidation.  We batch invalidate regions
        // below for efficiency.
        RegionsToInvalidate.push_back(R);
        continue;
      }
      else {
        // Nuke all other arguments passed by reference.
        // FIXME: is this necessary or correct? This handles the non-Region
        //  cases.  Is it ever valid to store to these?
        state = state->unbindLoc(cast<Loc>(V));
      }
    }
    else if (isa<nonloc::LocAsInteger>(V)) {
      // If we are passing a location wrapped as an integer, unwrap it and
      // invalidate the values referred by the location.
      V = cast<nonloc::LocAsInteger>(V).getLoc();
      goto tryAgain;
    }
  }

  // Block calls result in all captured values passed-via-reference to be
  // invalidated.
  if (const BlockDataRegion *BR = dyn_cast_or_null<BlockDataRegion>(Callee)) {
    RegionsToInvalidate.push_back(BR);
  }

  // Invalidate regions we designed for invalidation use the batch invalidation
  // API.

  // FIXME: We can have collisions on the conjured symbol if the
  //  expression *I also creates conjured symbols.  We probably want
  //  to identify conjured symbols by an expression pair: the enclosing
  //  expression (the context) and the expression itself.  This should
  //  disambiguate conjured symbols.
  unsigned Count = Builder.getCurrentBlockCount();
  StoreManager::InvalidatedSymbols IS;

  // NOTE: Even if RegionsToInvalidate is empty, we must still invalidate
  //  global variables.
  // NOTE: RetainReleaseChecker handles the actual invalidation of symbols.
  state =
    state->invalidateRegions(RegionsToInvalidate.data(),
                             RegionsToInvalidate.data() +
                             RegionsToInvalidate.size(),
                             Ex, Count, &IS,
                             /* invalidateGlobals = */
                             Eng.doesInvalidateGlobals(callOrMsg));

  // Evaluate the effect on the message receiver.
  if (!ErrorRange.isValid() && Receiver) {
    SymbolRef Sym = Receiver.getSValAsScalarOrLoc(state).getAsLocSymbol();
    if (Sym) {
      if (const RefVal* T = state->get<RefBindings>(Sym)) {
        state = Update(state, Sym, *T, Summ.getReceiverEffect(), hasErr);
        if (hasErr) {
          ErrorRange = Receiver.getSourceRange();
          ErrorSym = Sym;
        }
      }
    }
  }

  // Process any errors.
  if (hasErr) {
    ProcessNonLeakError(Dst, Builder, Ex, ErrorRange, Pred, state,
                        hasErr, ErrorSym);
    return;
  }

  // Consult the summary for the return value.
  RetEffect RE = Summ.getRetEffect();

  if (RE.getKind() == RetEffect::OwnedWhenTrackedReceiver) {
    bool found = false;
    if (Receiver) {
      SVal V = Receiver.getSValAsScalarOrLoc(state);
      if (SymbolRef Sym = V.getAsLocSymbol())
        if (state->get<RefBindings>(Sym)) {
          found = true;
          RE = Summaries.getObjAllocRetEffect();
        }
    } // FIXME: Otherwise, this is a send-to-super instance message.
    if (!found)
      RE = RetEffect::MakeNoRet();
  }

  switch (RE.getKind()) {
    default:
      assert (false && "Unhandled RetEffect."); break;

    case RetEffect::NoRet: {
      // Make up a symbol for the return value (not reference counted).
      // FIXME: Most of this logic is not specific to the retain/release
      // checker.

      // FIXME: We eventually should handle structs and other compound types
      // that are returned by value.

      // Use the result type from callOrMsg as it automatically adjusts
      // for methods/functions that return references.
      QualType resultTy = callOrMsg.getResultType(Eng.getContext());
      if (Loc::isLocType(resultTy) || 
            (resultTy->isIntegerType() && resultTy->isScalarType())) {
        unsigned Count = Builder.getCurrentBlockCount();
        SValBuilder &svalBuilder = Eng.getSValBuilder();
        SVal X = svalBuilder.getConjuredSymbolVal(NULL, Ex, resultTy, Count);
        state = state->BindExpr(Ex, X, false);
      }

      break;
    }

    case RetEffect::Alias: {
      unsigned idx = RE.getIndex();
      assert (idx < callOrMsg.getNumArgs());
      SVal V = callOrMsg.getArgSValAsScalarOrLoc(idx);
      state = state->BindExpr(Ex, V, false);
      break;
    }

    case RetEffect::ReceiverAlias: {
      assert(Receiver);
      SVal V = Receiver.getSValAsScalarOrLoc(state);
      state = state->BindExpr(Ex, V, false);
      break;
    }

    case RetEffect::OwnedAllocatedSymbol:
    case RetEffect::OwnedSymbol: {
      unsigned Count = Builder.getCurrentBlockCount();
      SValBuilder &svalBuilder = Eng.getSValBuilder();
      SymbolRef Sym = svalBuilder.getConjuredSymbol(Ex, Count);

      // Use the result type from callOrMsg as it automatically adjusts
      // for methods/functions that return references.      
      QualType resultTy = callOrMsg.getResultType(Eng.getContext());
      state = state->set<RefBindings>(Sym, RefVal::makeOwned(RE.getObjKind(),
                                                            resultTy));
      state = state->BindExpr(Ex, svalBuilder.makeLoc(Sym), false);

      // FIXME: Add a flag to the checker where allocations are assumed to
      // *not fail.
#if 0
      if (RE.getKind() == RetEffect::OwnedAllocatedSymbol) {
        bool isFeasible;
        state = state.assume(loc::SymbolVal(Sym), true, isFeasible);
        assert(isFeasible && "Cannot assume fresh symbol is non-null.");
      }
#endif

      break;
    }

    case RetEffect::GCNotOwnedSymbol:
    case RetEffect::ARCNotOwnedSymbol:
    case RetEffect::NotOwnedSymbol: {
      unsigned Count = Builder.getCurrentBlockCount();
      SValBuilder &svalBuilder = Eng.getSValBuilder();
      SymbolRef Sym = svalBuilder.getConjuredSymbol(Ex, Count);
      QualType RetT = GetReturnType(Ex, svalBuilder.getContext());
      state = state->set<RefBindings>(Sym, RefVal::makeNotOwned(RE.getObjKind(),
                                                               RetT));
      state = state->BindExpr(Ex, svalBuilder.makeLoc(Sym), false);
      break;
    }
  }

  // Generate a sink node if we are at the end of a path.
  ExplodedNode *NewNode =
    Summ.isEndPath() ? Builder.MakeSinkNode(Dst, Ex, Pred, state)
                     : Builder.MakeNode(Dst, Ex, Pred, state);

  // Annotate the edge with summary we used.
  if (NewNode) SummaryLog[NewNode] = &Summ;
}


void CFRefCount::evalCall(ExplodedNodeSet& Dst,
                          ExprEngine& Eng,
                          StmtNodeBuilder& Builder,
                          const CallExpr* CE, SVal L,
                          ExplodedNode* Pred) {

  RetainSummary *Summ = 0;

  // FIXME: Better support for blocks.  For now we stop tracking anything
  // that is passed to blocks.
  // FIXME: Need to handle variables that are "captured" by the block.
  if (dyn_cast_or_null<BlockDataRegion>(L.getAsRegion())) {
    Summ = Summaries.getPersistentStopSummary();
  }
  else if (const FunctionDecl* FD = L.getAsFunctionDecl()) {
    Summ = Summaries.getSummary(FD);
  }
  else if (const CXXMemberCallExpr *me = dyn_cast<CXXMemberCallExpr>(CE)) {
    if (const CXXMethodDecl *MD = me->getMethodDecl())
      Summ = Summaries.getSummary(MD);
    else
      Summ = Summaries.getDefaultSummary();    
  }
  else
    Summ = Summaries.getDefaultSummary();

  assert(Summ);
  evalSummary(Dst, Eng, Builder, CE,
              CallOrObjCMessage(CE, Pred->getState()),
              InstanceReceiver(), *Summ,L.getAsRegion(),
              Pred, Pred->getState());
}

void CFRefCount::evalObjCMessage(ExplodedNodeSet& Dst,
                                 ExprEngine& Eng,
                                 StmtNodeBuilder& Builder,
                                 ObjCMessage msg,
                                 ExplodedNode* Pred,
                                 const GRState *state) {
  RetainSummary *Summ =
    msg.isInstanceMessage()
      ? Summaries.getInstanceMethodSummary(msg, state,Pred->getLocationContext())
      : Summaries.getClassMethodSummary(msg);

  assert(Summ && "RetainSummary is null");
  evalSummary(Dst, Eng, Builder, msg.getOriginExpr(),
              CallOrObjCMessage(msg, Pred->getState()),
              InstanceReceiver(msg, Pred->getLocationContext()), *Summ, NULL,
              Pred, state);
}

namespace {
class StopTrackingCallback : public SymbolVisitor {
  const GRState *state;
public:
  StopTrackingCallback(const GRState *st) : state(st) {}
  const GRState *getState() const { return state; }

  bool VisitSymbol(SymbolRef sym) {
    state = state->remove<RefBindings>(sym);
    return true;
  }
};
} // end anonymous namespace


void CFRefCount::evalBind(StmtNodeBuilderRef& B, SVal location, SVal val) {
  // Are we storing to something that causes the value to "escape"?
  bool escapes = false;

  // A value escapes in three possible cases (this may change):
  //
  // (1) we are binding to something that is not a memory region.
  // (2) we are binding to a memregion that does not have stack storage
  // (3) we are binding to a memregion with stack storage that the store
  //     does not understand.
  const GRState *state = B.getState();

  if (!isa<loc::MemRegionVal>(location))
    escapes = true;
  else {
    const MemRegion* R = cast<loc::MemRegionVal>(location).getRegion();
    escapes = !R->hasStackStorage();

    if (!escapes) {
      // To test (3), generate a new state with the binding removed.  If it is
      // the same state, then it escapes (since the store cannot represent
      // the binding).
      escapes = (state == (state->bindLoc(cast<Loc>(location), UnknownVal())));
    }
  }

  // If our store can represent the binding and we aren't storing to something
  // that doesn't have local storage then just return and have the simulation
  // state continue as is.
  if (!escapes)
      return;

  // Otherwise, find all symbols referenced by 'val' that we are tracking
  // and stop tracking them.
  B.MakeNode(state->scanReachableSymbols<StopTrackingCallback>(val).getState());
}

 // Return statements.

void CFRefCount::evalReturn(ExplodedNodeSet& Dst,
                            ExprEngine& Eng,
                            StmtNodeBuilder& Builder,
                            const ReturnStmt* S,
                            ExplodedNode* Pred) {

  const Expr* RetE = S->getRetValue();
  if (!RetE)
    return;

  const GRState *state = Pred->getState();
  SymbolRef Sym = state->getSValAsScalarOrLoc(RetE).getAsLocSymbol();

  if (!Sym)
    return;

  // Get the reference count binding (if any).
  const RefVal* T = state->get<RefBindings>(Sym);

  if (!T)
    return;

  // Change the reference count.
  RefVal X = *T;

  switch (X.getKind()) {
    case RefVal::Owned: {
      unsigned cnt = X.getCount();
      assert (cnt > 0);
      X.setCount(cnt - 1);
      X = X ^ RefVal::ReturnedOwned;
      break;
    }

    case RefVal::NotOwned: {
      unsigned cnt = X.getCount();
      if (cnt) {
        X.setCount(cnt - 1);
        X = X ^ RefVal::ReturnedOwned;
      }
      else {
        X = X ^ RefVal::ReturnedNotOwned;
      }
      break;
    }

    default:
      return;
  }

  // Update the binding.
  state = state->set<RefBindings>(Sym, X);
  Pred = Builder.MakeNode(Dst, S, Pred, state);

  // Did we cache out?
  if (!Pred)
    return;

  // Update the autorelease counts.
  static SimpleProgramPointTag autoreleasetag("CFRefCount : Autorelease");
  GenericNodeBuilderRefCount Bd(Builder, S, &autoreleasetag);
  bool stop = false;
  llvm::tie(Pred, state) = HandleAutoreleaseCounts(state , Bd, Pred, Eng, Sym,
                                                   X, stop);

  // Did we cache out?
  if (!Pred || stop)
    return;

  // Get the updated binding.
  T = state->get<RefBindings>(Sym);
  assert(T);
  X = *T;

  // Consult the summary of the enclosing method.
  Decl const *CD = &Pred->getCodeDecl();

  if (const ObjCMethodDecl* MD = dyn_cast<ObjCMethodDecl>(CD)) {
    const RetainSummary &Summ = *Summaries.getMethodSummary(MD);
    return evalReturnWithRetEffect(Dst, Eng, Builder, S, 
                                   Pred, Summ.getRetEffect(), X,
                                   Sym, state);
  }

  if (const FunctionDecl *FD = dyn_cast<FunctionDecl>(CD)) {
    if (!isa<CXXMethodDecl>(FD))
      if (const RetainSummary *Summ = Summaries.getSummary(FD))
        return evalReturnWithRetEffect(Dst, Eng, Builder, S, 
                                       Pred, Summ->getRetEffect(), X,
                                       Sym, state);
  }
}

void CFRefCount::evalReturnWithRetEffect(ExplodedNodeSet &Dst, 
                                         ExprEngine &Eng,
                                         StmtNodeBuilder &Builder,
                                         const ReturnStmt *S,
                                         ExplodedNode *Pred,
                                         RetEffect RE, RefVal X,
                                         SymbolRef Sym, const GRState *state) {
  // Any leaks or other errors?
  if (X.isReturnedOwned() && X.getCount() == 0) {
    if (RE.getKind() != RetEffect::NoRet) {
      bool hasError = false;
      if (isGCEnabled() && RE.getObjKind() == RetEffect::ObjC) {
        // Things are more complicated with garbage collection.  If the
        // returned object is suppose to be an Objective-C object, we have
        // a leak (as the caller expects a GC'ed object) because no
        // method should return ownership unless it returns a CF object.
        hasError = true;
        X = X ^ RefVal::ErrorGCLeakReturned;
      }
      else if (!RE.isOwned()) {
        // Either we are using GC and the returned object is a CF type
        // or we aren't using GC.  In either case, we expect that the
        // enclosing method is expected to return ownership.
        hasError = true;
        X = X ^ RefVal::ErrorLeakReturned;
      }

      if (hasError) {
        // Generate an error node.
        static SimpleProgramPointTag
               ReturnOwnLeakTag("CFRefCount : ReturnsOwnLeak");
        state = state->set<RefBindings>(Sym, X);
        ExplodedNode *N =
          Builder.generateNode(PostStmt(S, Pred->getLocationContext(),
                                        &ReturnOwnLeakTag), state, Pred);
        if (N) {
          CFRefReport *report =
            new CFRefLeakReport(*static_cast<CFRefBug*>(leakAtReturn), *this,
                                N, Sym, Eng);
          BR->EmitReport(report);
        }
      }
    }
    return;
  }

  if (X.isReturnedNotOwned()) {
    if (RE.isOwned()) {
      // Trying to return a not owned object to a caller expecting an
      // owned object.
      static SimpleProgramPointTag
             ReturnNotOwnedForOwnedTag("CFRefCount : ReturnNotOwnedForOwned");
      state = state->set<RefBindings>(Sym, X ^ RefVal::ErrorReturnedNotOwned);
      if (ExplodedNode *N =
          Builder.generateNode(PostStmt(S, Pred->getLocationContext(),
                                        &ReturnNotOwnedForOwnedTag),
                               state, Pred)) {
          CFRefReport *report =
              new CFRefReport(*static_cast<CFRefBug*>(returnNotOwnedForOwned),
                              *this, N, Sym);
          BR->EmitReport(report);
      }
    }
  }
}

// Assumptions.

const GRState* CFRefCount::evalAssume(const GRState *state,
                                      SVal Cond, bool Assumption) {

  // FIXME: We may add to the interface of evalAssume the list of symbols
  //  whose assumptions have changed.  For now we just iterate through the
  //  bindings and check if any of the tracked symbols are NULL.  This isn't
  //  too bad since the number of symbols we will track in practice are
  //  probably small and evalAssume is only called at branches and a few
  //  other places.
  RefBindings B = state->get<RefBindings>();

  if (B.isEmpty())
    return state;

  bool changed = false;
  RefBindings::Factory& RefBFactory = state->get_context<RefBindings>();

  for (RefBindings::iterator I=B.begin(), E=B.end(); I!=E; ++I) {
    // Check if the symbol is null (or equal to any constant).
    // If this is the case, stop tracking the symbol.
    if (state->getSymVal(I.getKey())) {
      changed = true;
      B = RefBFactory.remove(B, I.getKey());
    }
  }

  if (changed)
    state = state->set<RefBindings>(B);

  return state;
}

const GRState * CFRefCount::Update(const GRState * state, SymbolRef sym,
                              RefVal V, ArgEffect E,
                              RefVal::Kind& hasErr) {

  // In GC mode [... release] and [... retain] do nothing.
  switch (E) {
    default: break;
    case IncRefMsg: E = isARCorGCEnabled() ? DoNothing : IncRef; break;
    case DecRefMsg: E = isARCorGCEnabled() ? DoNothing : DecRef; break;
    case MakeCollectable: E = isGCEnabled() ? DecRef : DoNothing; break;
    case NewAutoreleasePool: E = isGCEnabled() ? DoNothing :
                                                 NewAutoreleasePool; break;
  }

  // Handle all use-after-releases.
  if (!isGCEnabled() && V.getKind() == RefVal::Released) {
    V = V ^ RefVal::ErrorUseAfterRelease;
    hasErr = V.getKind();
    return state->set<RefBindings>(sym, V);
  }

  switch (E) {
    case DecRefMsg:
    case IncRefMsg:
    case MakeCollectable:
      assert(false &&
             "DecRefMsg/IncRefMsg/MakeCollectable already transformed");
      return state;
      
    case Dealloc:
      // Any use of -dealloc in GC is *bad*.
      if (isGCEnabled()) {
        V = V ^ RefVal::ErrorDeallocGC;
        hasErr = V.getKind();
        break;
      }

      switch (V.getKind()) {
        default:
          assert(false && "Invalid case.");
        case RefVal::Owned:
          // The object immediately transitions to the released state.
          V = V ^ RefVal::Released;
          V.clearCounts();
          return state->set<RefBindings>(sym, V);
        case RefVal::NotOwned:
          V = V ^ RefVal::ErrorDeallocNotOwned;
          hasErr = V.getKind();
          break;
      }
      break;

    case NewAutoreleasePool:
      assert(!isGCEnabled());
      return state->add<AutoreleaseStack>(sym);

    case MayEscape:
      if (V.getKind() == RefVal::Owned) {
        V = V ^ RefVal::NotOwned;
        break;
      }

      // Fall-through.

    case DoNothingByRef:
    case DoNothing:
      return state;

    case Autorelease:
      if (isGCEnabled())
        return state;

      // Update the autorelease counts.
      state = SendAutorelease(state, ARCountFactory, sym);
      V = V.autorelease();
      break;

    case StopTracking:
      return state->remove<RefBindings>(sym);

    case IncRef:
      switch (V.getKind()) {
        default:
          assert(false);

        case RefVal::Owned:
        case RefVal::NotOwned:
          V = V + 1;
          break;
        case RefVal::Released:
          // Non-GC cases are handled above.
          assert(isGCEnabled());
          V = (V ^ RefVal::Owned) + 1;
          break;
      }
      break;

    case SelfOwn:
      V = V ^ RefVal::NotOwned;
      // Fall-through.
    case DecRef:
    case DecRefBridgedTransfered:
      switch (V.getKind()) {
        default:
          // case 'RefVal::Released' handled above.
          assert (false);

        case RefVal::Owned:
          assert(V.getCount() > 0);
          if (V.getCount() == 1)
            V = V ^ (E == DecRefBridgedTransfered ? 
                      RefVal::NotOwned : RefVal::Released);
          V = V - 1;
          break;

        case RefVal::NotOwned:
          if (V.getCount() > 0)
            V = V - 1;
          else {
            V = V ^ RefVal::ErrorReleaseNotOwned;
            hasErr = V.getKind();
          }
          break;

        case RefVal::Released:
          // Non-GC cases are handled above.
          assert(isGCEnabled());
          V = V ^ RefVal::ErrorUseAfterRelease;
          hasErr = V.getKind();
          break;
      }
      break;
  }
  return state->set<RefBindings>(sym, V);
}

//===----------------------------------------------------------------------===//
// Handle dead symbols and end-of-path.
//===----------------------------------------------------------------------===//

std::pair<ExplodedNode*, const GRState *>
CFRefCount::HandleAutoreleaseCounts(const GRState * state, 
                                    GenericNodeBuilderRefCount Bd,
                                    ExplodedNode* Pred,
                                    ExprEngine &Eng,
                                    SymbolRef Sym, RefVal V, bool &stop) {

  unsigned ACnt = V.getAutoreleaseCount();
  stop = false;

  // No autorelease counts?  Nothing to be done.
  if (!ACnt)
    return std::make_pair(Pred, state);

  assert(!isGCEnabled() && "Autorelease counts in GC mode?");
  unsigned Cnt = V.getCount();

  // FIXME: Handle sending 'autorelease' to already released object.

  if (V.getKind() == RefVal::ReturnedOwned)
    ++Cnt;

  if (ACnt <= Cnt) {
    if (ACnt == Cnt) {
      V.clearCounts();
      if (V.getKind() == RefVal::ReturnedOwned)
        V = V ^ RefVal::ReturnedNotOwned;
      else
        V = V ^ RefVal::NotOwned;
    }
    else {
      V.setCount(Cnt - ACnt);
      V.setAutoreleaseCount(0);
    }
    state = state->set<RefBindings>(Sym, V);
    ExplodedNode *N = Bd.MakeNode(state, Pred);
    stop = (N == 0);
    return std::make_pair(N, state);
  }

  // Woah!  More autorelease counts then retain counts left.
  // Emit hard error.
  stop = true;
  V = V ^ RefVal::ErrorOverAutorelease;
  state = state->set<RefBindings>(Sym, V);

  if (ExplodedNode *N = Bd.MakeNode(state, Pred)) {
    N->markAsSink();

    std::string sbuf;
    llvm::raw_string_ostream os(sbuf);
    os << "Object over-autoreleased: object was sent -autorelease ";
    if (V.getAutoreleaseCount() > 1)
      os << V.getAutoreleaseCount() << " times ";
    os << "but the object has a +" << V.getCount() << " retain count";

    CFRefReport *report =
      new CFRefReport(*static_cast<CFRefBug*>(overAutorelease),
                      *this, N, Sym, os.str());
    BR->EmitReport(report);
  }

  return std::make_pair((ExplodedNode*)0, state);
}

const GRState *
CFRefCount::HandleSymbolDeath(const GRState * state, SymbolRef sid, RefVal V,
                              SmallVectorImpl<SymbolRef> &Leaked) {

  bool hasLeak = V.isOwned() ||
  ((V.isNotOwned() || V.isReturnedOwned()) && V.getCount() > 0);

  if (!hasLeak)
    return state->remove<RefBindings>(sid);

  Leaked.push_back(sid);
  return state->set<RefBindings>(sid, V ^ RefVal::ErrorLeak);
}

ExplodedNode*
CFRefCount::ProcessLeaks(const GRState * state,
                         SmallVectorImpl<SymbolRef> &Leaked,
                         GenericNodeBuilderRefCount &Builder,
                         ExprEngine& Eng,
                         ExplodedNode *Pred) {

  if (Leaked.empty())
    return Pred;

  // Generate an intermediate node representing the leak point.
  ExplodedNode *N = Builder.MakeNode(state, Pred);

  if (N) {
    for (SmallVectorImpl<SymbolRef>::iterator
         I = Leaked.begin(), E = Leaked.end(); I != E; ++I) {

      CFRefBug *BT = static_cast<CFRefBug*>(Pred ? leakWithinFunction
                                                 : leakAtReturn);
      assert(BT && "BugType not initialized.");
      CFRefLeakReport* report = new CFRefLeakReport(*BT, *this, N, *I, Eng);
      BR->EmitReport(report);
    }
  }

  return N;
}

void CFRefCount::evalEndPath(ExprEngine& Eng,
                             EndOfFunctionNodeBuilder& Builder) {

  const GRState *state = Builder.getState();
  GenericNodeBuilderRefCount Bd(Builder);
  RefBindings B = state->get<RefBindings>();
  ExplodedNode *Pred = 0;

  for (RefBindings::iterator I = B.begin(), E = B.end(); I != E; ++I) {
    bool stop = false;
    llvm::tie(Pred, state) = HandleAutoreleaseCounts(state, Bd, Pred, Eng,
                                                     (*I).first,
                                                     (*I).second, stop);

    if (stop)
      return;
  }

  B = state->get<RefBindings>();
  SmallVector<SymbolRef, 10> Leaked;

  for (RefBindings::iterator I = B.begin(), E = B.end(); I != E; ++I)
    state = HandleSymbolDeath(state, (*I).first, (*I).second, Leaked);

  ProcessLeaks(state, Leaked, Bd, Eng, Pred);
}

const ProgramPointTag *CFRefCount::getDeadSymbolTag(SymbolRef sym) {
  const SimpleProgramPointTag *&tag = DeadSymbolTags[sym];
  if (!tag) {
    llvm::SmallString<128> buf;
    llvm::raw_svector_ostream out(buf);
    out << "CFRefCount : Dead Symbol : " << sym->getSymbolID();
    tag = new SimpleProgramPointTag(out.str());
  }
  return tag;  
}

void CFRefCount::evalDeadSymbols(ExplodedNodeSet& Dst,
                                 ExprEngine& Eng,
                                 StmtNodeBuilder& Builder,
                                 ExplodedNode* Pred,
                                 const GRState* state,
                                 SymbolReaper& SymReaper) {
  const Stmt *S = Builder.getStmt();
  RefBindings B = state->get<RefBindings>();

  // Update counts from autorelease pools
  for (SymbolReaper::dead_iterator I = SymReaper.dead_begin(),
       E = SymReaper.dead_end(); I != E; ++I) {
    SymbolRef Sym = *I;
    if (const RefVal* T = B.lookup(Sym)){
      // Use the symbol as the tag.
      // FIXME: This might not be as unique as we would like.
      GenericNodeBuilderRefCount Bd(Builder, S, getDeadSymbolTag(Sym));
      bool stop = false;
      llvm::tie(Pred, state) = HandleAutoreleaseCounts(state, Bd, Pred, Eng,
                                                       Sym, *T, stop);
      if (stop)
        return;
    }
  }

  B = state->get<RefBindings>();
  SmallVector<SymbolRef, 10> Leaked;

  for (SymbolReaper::dead_iterator I = SymReaper.dead_begin(),
       E = SymReaper.dead_end(); I != E; ++I) {
      if (const RefVal* T = B.lookup(*I))
        state = HandleSymbolDeath(state, *I, *T, Leaked);
  }

  static SimpleProgramPointTag LeakPPTag("CFRefCount : Leak");
  {
    GenericNodeBuilderRefCount Bd(Builder, S, &LeakPPTag);
    Pred = ProcessLeaks(state, Leaked, Bd, Eng, Pred);
  }

  // Did we cache out?
  if (!Pred)
    return;

  // Now generate a new node that nukes the old bindings.
  RefBindings::Factory& F = state->get_context<RefBindings>();

  for (SymbolReaper::dead_iterator I = SymReaper.dead_begin(),
       E = SymReaper.dead_end(); I!=E; ++I) B = F.remove(B, *I);

  state = state->set<RefBindings>(B);
  Builder.MakeNode(Dst, S, Pred, state);
}

void CFRefCount::ProcessNonLeakError(ExplodedNodeSet& Dst,
                                     StmtNodeBuilder& Builder,
                                     const Expr* NodeExpr, 
                                     SourceRange ErrorRange,
                                     ExplodedNode* Pred,
                                     const GRState* St,
                                     RefVal::Kind hasErr, SymbolRef Sym) {
  Builder.BuildSinks = true;
  ExplodedNode *N  = Builder.MakeNode(Dst, NodeExpr, Pred, St);

  if (!N)
    return;

  CFRefBug *BT = 0;

  switch (hasErr) {
    default:
      assert(false && "Unhandled error.");
      return;
    case RefVal::ErrorUseAfterRelease:
      BT = static_cast<CFRefBug*>(useAfterRelease);
      break;
    case RefVal::ErrorReleaseNotOwned:
      BT = static_cast<CFRefBug*>(releaseNotOwned);
      break;
    case RefVal::ErrorDeallocGC:
      BT = static_cast<CFRefBug*>(deallocGC);
      break;
    case RefVal::ErrorDeallocNotOwned:
      BT = static_cast<CFRefBug*>(deallocNotOwned);
      break;
  }

  CFRefReport *report = new CFRefReport(*BT, *this, N, Sym);
  report->addRange(ErrorRange);
  BR->EmitReport(report);
}

//===----------------------------------------------------------------------===//
// Pieces of the retain/release checker implemented using a CheckerVisitor.
// More pieces of the retain/release checker will be migrated to this interface
// (ideally, all of it some day).
//===----------------------------------------------------------------------===//

namespace {
class RetainReleaseChecker
  : public Checker< check::PostStmt<BlockExpr>,
                    check::PostStmt<CastExpr>,
                    check::RegionChanges > {
public:
    bool wantsRegionUpdate;
    
    RetainReleaseChecker() : wantsRegionUpdate(true) {}
    
    
    void checkPostStmt(const BlockExpr *BE, CheckerContext &C) const;
                      
    void checkPostStmt(const CastExpr *CE, CheckerContext &C) const;

    const GRState *checkRegionChanges(const GRState *state,
                            const StoreManager::InvalidatedSymbols *invalidated,
                                      const MemRegion * const *begin,
                                      const MemRegion * const *end) const;
                                          
    bool wantsRegionChangeUpdate(const GRState *state) const {
      return wantsRegionUpdate;
    }
};
} // end anonymous namespace

const GRState *
RetainReleaseChecker::checkRegionChanges(const GRState *state,
                            const StoreManager::InvalidatedSymbols *invalidated,
                                         const MemRegion * const *begin,
                                         const MemRegion * const *end) const {
  if (!invalidated)
    return state;

  for (StoreManager::InvalidatedSymbols::const_iterator I=invalidated->begin(),
       E = invalidated->end(); I!=E; ++I) {
    SymbolRef sym = *I;
    if (WhitelistedSymbols.count(sym))
      continue;
    // Remove any existing reference-count binding.
    state = state->remove<RefBindings>(sym);
  }
  return state;
}

void RetainReleaseChecker::checkPostStmt(const BlockExpr *BE,
                                         CheckerContext &C) const {

  // Scan the BlockDecRefExprs for any object the retain/release checker
  // may be tracking.
  if (!BE->getBlockDecl()->hasCaptures())
    return;

  const GRState *state = C.getState();
  const BlockDataRegion *R =
    cast<BlockDataRegion>(state->getSVal(BE).getAsRegion());

  BlockDataRegion::referenced_vars_iterator I = R->referenced_vars_begin(),
                                            E = R->referenced_vars_end();

  if (I == E)
    return;

  // FIXME: For now we invalidate the tracking of all symbols passed to blocks
  // via captured variables, even though captured variables result in a copy
  // and in implicit increment/decrement of a retain count.
  SmallVector<const MemRegion*, 10> Regions;
  const LocationContext *LC = C.getPredecessor()->getLocationContext();
  MemRegionManager &MemMgr = C.getSValBuilder().getRegionManager();

  for ( ; I != E; ++I) {
    const VarRegion *VR = *I;
    if (VR->getSuperRegion() == R) {
      VR = MemMgr.getVarRegion(VR->getDecl(), LC);
    }
    Regions.push_back(VR);
  }

  state =
    state->scanReachableSymbols<StopTrackingCallback>(Regions.data(),
                                    Regions.data() + Regions.size()).getState();
  C.addTransition(state);
}

void RetainReleaseChecker::checkPostStmt(const CastExpr *CE,
                                         CheckerContext &C) const {
  const ObjCBridgedCastExpr *BE = dyn_cast<ObjCBridgedCastExpr>(CE);
  if (!BE)
    return;
  
  ArgEffect AE = IncRef;
  
  switch (BE->getBridgeKind()) {
    case clang::OBC_Bridge:
      // Do nothing.
      return;
    case clang::OBC_BridgeRetained:
      AE = IncRef;
      break;      
    case clang::OBC_BridgeTransfer:
      AE = DecRefBridgedTransfered;
      break;
  }
  
  const GRState *state = C.getState();
  SymbolRef Sym = state->getSVal(CE).getAsLocSymbol();
  if (!Sym)
    return;
  const RefVal* T = state->get<RefBindings>(Sym);
  if (!T)
    return;

  // This is gross.  Once the checker and CFRefCount are unified,
  // this will go away.
  CFRefCount &cf = static_cast<CFRefCount&>(C.getEngine().getTF());
  RefVal::Kind hasErr = (RefVal::Kind) 0;
  state = cf.Update(state, Sym, *T, AE, hasErr);
  
  if (hasErr) {
    
    return;
  }

  C.generateNode(state);
}

//===----------------------------------------------------------------------===//
// Transfer function creation for external clients.
//===----------------------------------------------------------------------===//

void CFRefCount::RegisterChecks(ExprEngine& Eng) {
  BugReporter &BR = Eng.getBugReporter();

  useAfterRelease = new UseAfterRelease(this);
  BR.Register(useAfterRelease);

  releaseNotOwned = new BadRelease(this);
  BR.Register(releaseNotOwned);

  deallocGC = new DeallocGC(this);
  BR.Register(deallocGC);

  deallocNotOwned = new DeallocNotOwned(this);
  BR.Register(deallocNotOwned);

  overAutorelease = new OverAutorelease(this);
  BR.Register(overAutorelease);

  returnNotOwnedForOwned = new ReturnedNotOwnedForOwned(this);
  BR.Register(returnNotOwnedForOwned);

  // First register "return" leaks.
  const char* name = 0;

  if (isGCEnabled())
    name = "Leak of returned object when using garbage collection";
  else if (getLangOptions().getGCMode() == LangOptions::HybridGC)
    name = "Leak of returned object when not using garbage collection (GC) in "
    "dual GC/non-GC code";
  else {
    assert(getLangOptions().getGCMode() == LangOptions::NonGC);
    name = "Leak of returned object";
  }

  // Leaks should not be reported if they are post-dominated by a sink.
  leakAtReturn = new LeakAtReturn(this, name);
  leakAtReturn->setSuppressOnSink(true);
  BR.Register(leakAtReturn);

  // Second, register leaks within a function/method.
  if (isGCEnabled())
    name = "Leak of object when using garbage collection";
  else if (getLangOptions().getGCMode() == LangOptions::HybridGC)
    name = "Leak of object when not using garbage collection (GC) in "
    "dual GC/non-GC code";
  else {
    assert(getLangOptions().getGCMode() == LangOptions::NonGC);
    name = "Leak";
  }

  // Leaks should not be reported if they are post-dominated by sinks.
  leakWithinFunction = new LeakWithinFunction(this, name);
  leakWithinFunction->setSuppressOnSink(true);
  BR.Register(leakWithinFunction);

  // Save the reference to the BugReporter.
  this->BR = &BR;

  // Register the RetainReleaseChecker with the ExprEngine object.
  // Functionality in CFRefCount will be migrated to RetainReleaseChecker
  // over time.
  // FIXME: HACK! Remove TransferFuncs and turn all of CFRefCount into fully
  // using the checker mechanism.
  Eng.getCheckerManager().registerChecker<RetainReleaseChecker>();
}

TransferFuncs* ento::MakeCFRefCountTF(ASTContext& Ctx, bool GCEnabled,
                                         const LangOptions& lopts) {
  return new CFRefCount(Ctx, GCEnabled, lopts);
}