CFRefCount.cpp

  
  // Handle "toll-free bridging" of calls to "Release" and "Retain".
  
  // FIXME: track the underlying object type associated so that we can
  //  flag illegal uses of toll-free bridging (or at least handle it
  //  at casts).
  
  Selector S = ME->getSelector();
  
  if (!S.isUnarySelector())
    return true;

  Expr* Receiver = ME->getReceiver();
  
  if (!Receiver)
    return true;

  // Check if we are calling "autorelease".

  enum { IsRelease, IsRetain, IsAutorelease, IsNone } mode = IsNone;
  
  if (S == AutoreleaseSelector)
    mode = IsAutorelease;
  else if (S == RetainSelector)
    mode = IsRetain;
  else if (S == ReleaseSelector)
    mode = IsRelease;
  
  if (mode == IsNone)
    return true;
  
  // We have "retain", "release", or "autorelease".  
  ValueStateManager& StateMgr = Eng.getStateManager();
  ValueState* St = Builder.GetState(Pred);
  RVal V = StateMgr.GetRVal(St, Receiver);
  
  // Was the argument something we are not tracking?  
  if (!isa<lval::SymbolVal>(V))
    return true;

  // Get the bindings.
  SymbolID Sym = cast<lval::SymbolVal>(V).getSymbol();
  RefBindings B = GetRefBindings(*St);
  
  // Find the tracked value.
  RefBindings::TreeTy* T = B.SlimFind(Sym);

  if (!T)
    return true;

  RefVal::Kind hasErr = (RefVal::Kind) 0;
  
  // Update the bindings.
  switch (mode) {
    case IsNone:
      assert(false);
      
    case IsRelease:
      B = Update(B, Sym, T->getValue().second, DecRef, hasErr);
      break;
      
    case IsRetain:
      B = Update(B, Sym, T->getValue().second, IncRef, hasErr);
      break;
      
    case IsAutorelease:
      // For now we just stop tracking a value if we see
      // it sent "autorelease."  In the future we can potentially
      // track the associated pool.
      B = Remove(B, Sym);
      break;
  }

  // Create a new state with the updated bindings.  
  ValueState StVals = *St;
  SetRefBindings(StVals, B);
  St = Eng.SetRVal(StateMgr.getPersistentState(StVals), ME, V);
  
  // Create an error node if it exists.  
  if (hasErr)
    ProcessNonLeakError(Dst, Builder, ME, Receiver, Pred, St, hasErr, Sym);
  else
    Builder.MakeNode(Dst, ME, Pred, St);

  return false;
}

// Stores.

void CFRefCount::EvalStore(ExplodedNodeSet<ValueState>& Dst,
                           GRExprEngine& Eng,
                           GRStmtNodeBuilder<ValueState>& Builder,
                           Expr* E, ExplodedNode<ValueState>* Pred,
                           ValueState* St, RVal TargetLV, RVal Val) {
  
  // Check if we have a binding for "Val" and if we are storing it to something
  // we don't understand or otherwise the value "escapes" the function.
  
  if (!isa<lval::SymbolVal>(Val))
    return;
  
  // Are we storing to something that causes the value to "escape"?
  
  bool escapes = false;
  
  if (!isa<lval::DeclVal>(TargetLV))
    escapes = true;
  else
    escapes = cast<lval::DeclVal>(TargetLV).getDecl()->hasGlobalStorage();
  
  if (!escapes)
    return;
  
  SymbolID Sym = cast<lval::SymbolVal>(Val).getSymbol();
  RefBindings B = GetRefBindings(*St);
  RefBindings::TreeTy* T = B.SlimFind(Sym);
  
  if (!T)
    return;
  
  // Nuke the binding.  
  St = NukeBinding(Eng.getStateManager(), St, Sym);
  
  // Hand of the remaining logic to the parent implementation.
  GRSimpleVals::EvalStore(Dst, Eng, Builder, E, Pred, St, TargetLV, Val);
}


ValueState* CFRefCount::NukeBinding(ValueStateManager& VMgr, ValueState* St,
                                    SymbolID sid) {
  ValueState StImpl = *St;
  RefBindings B = GetRefBindings(StImpl);
  StImpl.CheckerState = RefBFactory.Remove(B, sid).getRoot();
  return VMgr.getPersistentState(StImpl);
}

// End-of-path.

ValueState* CFRefCount::HandleSymbolDeath(ValueStateManager& VMgr,
                                          ValueState* St, SymbolID sid,
                                          RefVal V, bool& hasLeak) {
    
  hasLeak = V.isOwned() || 
            ((V.isNotOwned() || V.isReturnedOwned()) && V.getCount() > 0);

  if (!hasLeak)
    return NukeBinding(VMgr, St, sid);
  
  RefBindings B = GetRefBindings(*St);
  ValueState StImpl = *St;  

  StImpl.CheckerState =
    RefBFactory.Add(B, sid, RefVal::makeLeak(GetCount(V))).getRoot();
  
  return VMgr.getPersistentState(StImpl);
}

void CFRefCount::EvalEndPath(GRExprEngine& Eng,
                             GREndPathNodeBuilder<ValueState>& Builder) {
  
  ValueState* St = Builder.getState();
  RefBindings B = GetRefBindings(*St);
  
  llvm::SmallVector<SymbolID, 10> Leaked;
  
  for (RefBindings::iterator I = B.begin(), E = B.end(); I != E; ++I) {
    bool hasLeak = false;
    
    St = HandleSymbolDeath(Eng.getStateManager(), St,
                           (*I).first, (*I).second, hasLeak);
    
    if (hasLeak) Leaked.push_back((*I).first);
  }

  if (Leaked.empty())
    return;
  
  ExplodedNode<ValueState>* N = Builder.MakeNode(St);  
  
  if (!N)
    return;
    
  std::vector<SymbolID>*& LeaksAtNode = Leaks[N];
  assert (!LeaksAtNode);
  LeaksAtNode = new std::vector<SymbolID>();
  
  for (llvm::SmallVector<SymbolID, 10>::iterator I=Leaked.begin(),
       E = Leaked.end(); I != E; ++I)
    (*LeaksAtNode).push_back(*I);
}

// Dead symbols.

void CFRefCount::EvalDeadSymbols(ExplodedNodeSet<ValueState>& Dst,
                                 GRExprEngine& Eng,
                                 GRStmtNodeBuilder<ValueState>& Builder,
                                 ExplodedNode<ValueState>* Pred,
                                 Stmt* S,
                                 ValueState* St,
                                 const ValueStateManager::DeadSymbolsTy& Dead) {
    
  // FIXME: a lot of copy-and-paste from EvalEndPath.  Refactor.
  
  RefBindings B = GetRefBindings(*St);
  llvm::SmallVector<SymbolID, 10> Leaked;
  
  for (ValueStateManager::DeadSymbolsTy::const_iterator
       I=Dead.begin(), E=Dead.end(); I!=E; ++I) {
    
    RefBindings::TreeTy* T = B.SlimFind(*I);

    if (!T)
      continue;
    
    bool hasLeak = false;
    
    St = HandleSymbolDeath(Eng.getStateManager(), St,
                           *I, T->getValue().second, hasLeak);
    
    if (hasLeak) Leaked.push_back(*I);    
  }
  
  if (Leaked.empty())
    return;    
  
  ExplodedNode<ValueState>* N = Builder.MakeNode(Dst, S, Pred, St);  
  
  if (!N)
    return;
  
  std::vector<SymbolID>*& LeaksAtNode = Leaks[N];
  assert (!LeaksAtNode);
  LeaksAtNode = new std::vector<SymbolID>();
  
  for (llvm::SmallVector<SymbolID, 10>::iterator I=Leaked.begin(),
       E = Leaked.end(); I != E; ++I)
    (*LeaksAtNode).push_back(*I);    
}

 // Return statements.

void CFRefCount::EvalReturn(ExplodedNodeSet<ValueState>& Dst,
                            GRExprEngine& Eng,
                            GRStmtNodeBuilder<ValueState>& Builder,
                            ReturnStmt* S,
                            ExplodedNode<ValueState>* Pred) {
  
  Expr* RetE = S->getRetValue();
  if (!RetE) return;
  
  ValueStateManager& StateMgr = Eng.getStateManager();
  ValueState* St = Builder.GetState(Pred);
  RVal V = StateMgr.GetRVal(St, RetE);
  
  if (!isa<lval::SymbolVal>(V))
    return;
  
  // Get the reference count binding (if any).
  SymbolID Sym = cast<lval::SymbolVal>(V).getSymbol();
  RefBindings B = GetRefBindings(*St);
  RefBindings::TreeTy* T = B.SlimFind(Sym);
  
  if (!T)
    return;
  
  // Change the reference count.
  
  RefVal X = T->getValue().second;  
  
  switch (X.getKind()) {
      
    case RefVal::Owned: { 
      unsigned cnt = X.getCount();
      X = RefVal::makeReturnedOwned(cnt);
      break;
    }
      
    case RefVal::NotOwned: {
      unsigned cnt = X.getCount();
      X = cnt ? RefVal::makeReturnedOwned(cnt - 1)
              : RefVal::makeReturnedNotOwned();
      break;
    }
      
    default: 
      return;
  }
  
  // Update the binding.

  ValueState StImpl = *St;
  StImpl.CheckerState = RefBFactory.Add(B, Sym, X).getRoot();        
  Builder.MakeNode(Dst, S, Pred, StateMgr.getPersistentState(StImpl));
}

// Assumptions.

ValueState* CFRefCount::EvalAssume(GRExprEngine& Eng, ValueState* St,
                                   RVal Cond, bool Assumption,
                                   bool& isFeasible) {

  // 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 = GetRefBindings(*St);
  
  if (B.isEmpty())
    return St;
  
  bool changed = false;

  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 (St->getSymVal(I.getKey())) {
      changed = true;
      B = RefBFactory.Remove(B, I.getKey());
    }
  }
  
  if (!changed)
    return St;
  
  ValueState StImpl = *St;
  StImpl.CheckerState = B.getRoot();
  return Eng.getStateManager().getPersistentState(StImpl);
}

CFRefCount::RefBindings CFRefCount::Update(RefBindings B, SymbolID sym,
                                           RefVal V, ArgEffect E,
                                           RefVal::Kind& hasErr) {
  
  // FIXME: This dispatch can potentially be sped up by unifiying it into
  //  a single switch statement.  Opt for simplicity for now.
  
  switch (E) {
    default:
      assert (false && "Unhandled CFRef transition.");
      
    case DoNothing:
      if (!GCEnabled && V.getKind() == RefVal::Released) {
        V = RefVal::makeUseAfterRelease();        
        hasErr = V.getKind();
        break;
      }
      
      return B;
      
    case IncRef:      
      switch (V.getKind()) {
        default:
          assert(false);

        case RefVal::Owned:
          V = RefVal::makeOwned(V.getCount()+1);
          break;
                    
        case RefVal::NotOwned:
          V = RefVal::makeNotOwned(V.getCount()+1);
          break;
          
        case RefVal::Released:
          if (GCEnabled)
            V = RefVal::makeOwned();
          else {          
            V = RefVal::makeUseAfterRelease();
            hasErr = V.getKind();
          }
          
          break;
      }
      
      break;
      
    case DecRef:
      switch (V.getKind()) {
        default:
          assert (false);
          
        case RefVal::Owned: {
          unsigned Count = V.getCount();
          V = Count > 0 ? RefVal::makeOwned(Count - 1) : RefVal::makeReleased();
          break;
        }
          
        case RefVal::NotOwned: {
          unsigned Count = V.getCount();
          
          if (Count > 0)
            V = RefVal::makeNotOwned(Count - 1);
          else {
            V = RefVal::makeReleaseNotOwned();
            hasErr = V.getKind();
          }
          
          break;
        }

        case RefVal::Released:
          V = RefVal::makeUseAfterRelease();
          hasErr = V.getKind();
          break;          
      }
      
      break;
  }

  return RefBFactory.Add(B, sym, V);
}


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

namespace {
  
  //===-------------===//
  // Bug Descriptions. //
  //===-------------===//  
  
  class VISIBILITY_HIDDEN CFRefBug : public BugTypeCacheLocation {
  protected:
    CFRefCount& TF;
    
  public:
    CFRefBug(CFRefCount& tf) : TF(tf) {}
    
    CFRefCount& getTF() { return TF; }
    
    virtual bool isLeak() const { return false; }
  };
  
  class VISIBILITY_HIDDEN UseAfterRelease : public CFRefBug {
  public:
    UseAfterRelease(CFRefCount& tf) : CFRefBug(tf) {}
    
    virtual const char* getName() const {
      return "Core Foundation: Use-After-Release";
    }
    virtual const char* getDescription() const {
      return "Reference-counted object is used"
             " after it is released.";
    }
    
    virtual void EmitWarnings(BugReporter& BR);
  };
  
  class VISIBILITY_HIDDEN BadRelease : public CFRefBug {
  public:
    BadRelease(CFRefCount& tf) : CFRefBug(tf) {}
    
    virtual const char* getName() const {
      return "Core Foundation: Release of non-owned object";
    }
    virtual const char* getDescription() const {
      return "Incorrect decrement of the reference count of a "
      "CoreFoundation object: "
      "The object is not owned at this point by the caller.";
    }
    
    virtual void EmitWarnings(BugReporter& BR);
  };
  
  class VISIBILITY_HIDDEN Leak : public CFRefBug {
  public:
    Leak(CFRefCount& tf) : CFRefBug(tf) {}
    
    virtual const char* getName() const {
      return "Core Foundation: Memory Leak";
    }
    
    virtual const char* getDescription() const {
      return "Object leaked.";
    }
    
    virtual void EmitWarnings(BugReporter& BR);
    virtual void GetErrorNodes(std::vector<ExplodedNode<ValueState>*>& Nodes);
    virtual bool isLeak() const { return true; }
  };
  
  //===---------===//
  // Bug Reports.  //
  //===---------===//
  
  class VISIBILITY_HIDDEN CFRefReport : public RangedBugReport {
    SymbolID Sym;
  public:
    CFRefReport(CFRefBug& D, ExplodedNode<ValueState> *n, SymbolID sym)
      : RangedBugReport(D, n), Sym(sym) {}
        
    virtual ~CFRefReport() {}
    
    CFRefBug& getBugType() {
      return (CFRefBug&) RangedBugReport::getBugType();
    }
    const CFRefBug& getBugType() const {
      return (const CFRefBug&) RangedBugReport::getBugType();
    }
    
    virtual void getRanges(BugReporter& BR, const SourceRange*& beg,           
                           const SourceRange*& end) {
      
      if (!getBugType().isLeak())
        RangedBugReport::getRanges(BR, beg, end);
      else {
        beg = 0;
        end = 0;
      }
    }
    
    virtual PathDiagnosticPiece* getEndPath(BugReporter& BR,
                                            ExplodedNode<ValueState>* N);
    
    virtual std::pair<const char**,const char**> getExtraDescriptiveText();
    
    virtual PathDiagnosticPiece* VisitNode(ExplodedNode<ValueState>* N,
                                           ExplodedNode<ValueState>* PrevN,
                                           ExplodedGraph<ValueState>& G,
                                           BugReporter& BR);
  };
  
  
} // end anonymous namespace

void CFRefCount::RegisterChecks(GRExprEngine& Eng) {
  if (EmitStandardWarnings) GRSimpleVals::RegisterChecks(Eng);
  Eng.Register(new UseAfterRelease(*this));
  Eng.Register(new BadRelease(*this));
  Eng.Register(new Leak(*this));
}


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

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);
  }
}

PathDiagnosticPiece* CFRefReport::VisitNode(ExplodedNode<ValueState>* N,
                                            ExplodedNode<ValueState>* PrevN,
                                            ExplodedGraph<ValueState>& G,
                                            BugReporter& BR) {

  // Check if the type state has changed.
  
  ValueState* PrevSt = PrevN->getState();
  ValueState* CurrSt = N->getState();
  
  CFRefCount::RefBindings PrevB = CFRefCount::GetRefBindings(*PrevSt);
  CFRefCount::RefBindings CurrB = CFRefCount::GetRefBindings(*CurrSt);
  
  CFRefCount::RefBindings::TreeTy* PrevT = PrevB.SlimFind(Sym);
  CFRefCount::RefBindings::TreeTy* CurrT = CurrB.SlimFind(Sym);
  
  if (!CurrT)
    return NULL;  
  
  const char* Msg = NULL;  
  RefVal CurrV = CurrB.SlimFind(Sym)->getValue().second;

  if (!PrevT) {
    
    Stmt* S = cast<PostStmt>(N->getLocation()).getStmt();

    if (CurrV.isOwned()) {

      if (isa<CallExpr>(S))
        Msg = "Function call returns an object with a +1 retain count"
              " (owning reference).";
      else {
        assert (isa<ObjCMessageExpr>(S));
        Msg = "Method returns an object with a +1 retain count"
              " (owning reference).";
      }
    }
    else {
      assert (CurrV.isNotOwned());
      
      if (isa<CallExpr>(S))
        Msg = "Function call returns an object with a +0 retain count"
              " (non-owning reference).";
      else {
        assert (isa<ObjCMessageExpr>(S));
        Msg = "Method returns an object with a +0 retain count"
              " (non-owning reference).";
      }      
    }
    
    FullSourceLoc Pos(S->getLocStart(), BR.getContext().getSourceManager());
    PathDiagnosticPiece* P = new PathDiagnosticPiece(Pos, Msg);
    
    if (Expr* Exp = dyn_cast<Expr>(S))
      P->addRange(Exp->getSourceRange());
    
    return P;    
  }
  
  // Determine if the typestate has changed.
  
  RefVal PrevV = PrevB.SlimFind(Sym)->getValue().second;
  
  if (PrevV == CurrV)
    return NULL;
  
  // The typestate has changed.
  
  std::ostringstream os;
  
  switch (CurrV.getKind()) {
    case RefVal::Owned:
    case RefVal::NotOwned:
      assert (PrevV.getKind() == CurrV.getKind());
      
      if (PrevV.getCount() > CurrV.getCount())
        os << "Reference count decremented.";
      else
        os << "Reference count incremented.";
      
      if (unsigned Count = GetCount(CurrV)) {

        os << " Object has +" << Count;
        
        if (Count > 1)
          os << " retain counts.";
        else
          os << " retain count.";
      }
      
      Msg = os.str().c_str();
      
      break;
      
    case RefVal::Released:
      Msg = "Object released.";
      break;
      
    case RefVal::ReturnedOwned:
      Msg = "Object returned to caller as owning reference (single retain count"
            " transferred to caller).";
      break;
      
    case RefVal::ReturnedNotOwned:
      Msg = "Object returned to caller with a +0 (non-owning) retain count.";
      break;

    default:
      return NULL;
  }
  
  Stmt* S = cast<PostStmt>(N->getLocation()).getStmt();    
  FullSourceLoc Pos(S->getLocStart(), BR.getContext().getSourceManager());
  PathDiagnosticPiece* P = new PathDiagnosticPiece(Pos, Msg);
  
  // Add the range by scanning the children of the statement for any bindings
  // to Sym.
  
  ValueStateManager& VSM = BR.getEngine().getStateManager();
  
  for (Stmt::child_iterator I = S->child_begin(), E = S->child_end(); I!=E; ++I)
    if (Expr* Exp = dyn_cast_or_null<Expr>(*I)) {
      RVal X = VSM.GetRVal(CurrSt, Exp);
      
      if (lval::SymbolVal* SV = dyn_cast<lval::SymbolVal>(&X))
        if (SV->getSymbol() == Sym) {
          P->addRange(Exp->getSourceRange()); break;
        }
    }
  
  return P;
}

PathDiagnosticPiece* CFRefReport::getEndPath(BugReporter& BR,
                                             ExplodedNode<ValueState>* EndN) {
  
  if (!getBugType().isLeak())
    return RangedBugReport::getEndPath(BR, EndN);

  typedef CFRefCount::RefBindings RefBindings;

  // Get the retain count.
  unsigned long RetCount = 0;
  
  {
    ValueState* St = EndN->getState();
    RefBindings B = RefBindings((RefBindings::TreeTy*) St->CheckerState);
    RefBindings::TreeTy* T = B.SlimFind(Sym);
    assert (T);
    RetCount = GetCount(T->getValue().second);
  }

  // We are a leak.  Walk up the graph to get to the first node where the
  // symbol appeared.
  
  ExplodedNode<ValueState>* N = EndN;
  ExplodedNode<ValueState>* Last = N;
  
  // Find the first node that referred to the tracked symbol.  We also
  // try and find the first VarDecl the value was stored to.
  
  VarDecl* FirstDecl = 0;

  while (N) {
    ValueState* St = N->getState();
    RefBindings B = RefBindings((RefBindings::TreeTy*) St->CheckerState);
    RefBindings::TreeTy* T = B.SlimFind(Sym);
    
    if (!T)
      break;

    VarDecl* VD = 0;
    
    // Determine if there is an LVal binding to the symbol.
    for (ValueState::vb_iterator I=St->vb_begin(), E=St->vb_end(); I!=E; ++I) {
      if (!isa<lval::SymbolVal>(I->second)  // Is the value a symbol?
          || cast<lval::SymbolVal>(I->second).getSymbol() != Sym)
        continue;
      
      if (VD) {  // Multiple decls map to this symbol.
        VD = 0;
        break;
      }
      
      VD = I->first;
    }
    
    if (VD) FirstDecl = VD;
        
    Last = N;
    N = N->pred_empty() ? NULL : *(N->pred_begin());    
  }
  
  // Get the allocate site.
  
  assert (Last);
  Stmt* FirstStmt = cast<PostStmt>(Last->getLocation()).getStmt();

  SourceManager& SMgr = BR.getContext().getSourceManager();
  unsigned AllocLine = SMgr.getLogicalLineNumber(FirstStmt->getLocStart());

  // Get the leak site.  We may have multiple ExplodedNodes (one with the
  // leak) that occur on the same line number; if the node with the leak
  // has any immediate predecessor nodes with the same line number, find
  // any transitive-successors that have a different statement and use that
  // line number instead.  This avoids emiting a diagnostic like:
  //
  //    // 'y' is leaked.
  //  int x = foo(y);
  //
  //  instead we want:
  //
  //  int x = foo(y);
  //   // 'y' is leaked.
  
  Stmt* S = getStmt(BR);  // This is the statement where the leak occured.
  assert (S);
  unsigned EndLine = SMgr.getLogicalLineNumber(S->getLocStart());

  // Look in the *trimmed* graph at the immediate predecessor of EndN.  Does
  // it occur on the same line?
  
  assert (!EndN->pred_empty()); // Not possible to have 0 predecessors.
  N = *(EndN->pred_begin());
  
  do {
    ProgramPoint P = N->getLocation();

    if (!isa<PostStmt>(P))
      break;
    
    // Predecessor at same line?
    
    Stmt* SPred = cast<PostStmt>(P).getStmt();
    
    if (SMgr.getLogicalLineNumber(SPred->getLocStart()) != EndLine)
      break;
    
    // The predecessor (where the object was not yet leaked) is a statement
    // on the same line.  Get the first successor statement that appears
    // on a different line.  For this operation, we can traverse the
    // non-trimmed graph.
    
    N = getEndNode(); // This is the node where the leak occured in the
                      // original graph.
        
    while (!N->succ_empty()) {
      
      N = *(N->succ_begin());
      ProgramPoint P = N->getLocation();
      
      if (!isa<PostStmt>(P))
        continue;
      
      Stmt* SSucc = cast<PostStmt>(P).getStmt();
      
      if (SMgr.getLogicalLineNumber(SSucc->getLocStart()) != EndLine) {
        S = SSucc;
        break;
      }
    }    
  }
  while (false);
  
  // Construct the location.
    
  FullSourceLoc L(S->getLocStart(), SMgr);
  
  // Generate the diagnostic.
  std::ostringstream os;
  
  os << "Object allocated on line " << AllocLine;
  
  if (FirstDecl)
    os << " and stored into '" << FirstDecl->getName() << '\'';
    
  os << " is no longer referenced after this point and has a retain count of +"
     << RetCount << " (object leaked).";
  
  return new PathDiagnosticPiece(L, os.str());
}

void UseAfterRelease::EmitWarnings(BugReporter& BR) {

  for (CFRefCount::use_after_iterator I = TF.use_after_begin(),
        E = TF.use_after_end(); I != E; ++I) {
    
    CFRefReport report(*this, I->first, I->second.second);
    report.addRange(I->second.first->getSourceRange());    
    BR.EmitWarning(report);    
  }
}

void BadRelease::EmitWarnings(BugReporter& BR) {
  
  for (CFRefCount::bad_release_iterator I = TF.bad_release_begin(),
       E = TF.bad_release_end(); I != E; ++I) {
    
    CFRefReport report(*this, I->first, I->second.second);
    report.addRange(I->second.first->getSourceRange());    
    BR.EmitWarning(report);    
  }  
}

void Leak::EmitWarnings(BugReporter& BR) {
  
  for (CFRefCount::leaks_iterator I = TF.leaks_begin(),
       E = TF.leaks_end(); I != E; ++I) {
    
    std::vector<SymbolID>& SymV = *(I->second);
    unsigned n = SymV.size();
    
    for (unsigned i = 0; i < n; ++i) {
      CFRefReport report(*this, I->first, SymV[i]);
      BR.EmitWarning(report);
    }
  }  
}

void Leak::GetErrorNodes(std::vector<ExplodedNode<ValueState>*>& Nodes) {
  for (CFRefCount::leaks_iterator I=TF.leaks_begin(), E=TF.leaks_end();
       I!=E; ++I)
    Nodes.push_back(I->first);
}

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

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