lib/Analysis/GRExprEngineInternalChecks.cpp - fp2-dev/platform/external/clang - Gitiles

 //=-- GRExprEngineInternalChecks.cpp - Builtin GRExprEngine Checks---*- 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 BugType classes used by GRExprEngine to report
 //  bugs derived from builtin checks in the path-sensitive engine.
 //
 //===----------------------------------------------------------------------===//

 #include "clang/Analysis/PathSensitive/BugReporter.h"
 #include "clang/Analysis/PathSensitive/GRExprEngine.h"
 #include "clang/Basic/SourceManager.h"
 #include "llvm/Support/Compiler.h"
 #include "llvm/Support/raw_ostream.h"

 using namespace clang;

 //===----------------------------------------------------------------------===//
 // Utility functions.
 //===----------------------------------------------------------------------===//

 template <typename ITERATOR> inline
 ExplodedNode<GRState>* GetNode(ITERATOR I) {
   return *I;
 }

 template <> inline
 ExplodedNode<GRState>* GetNode(GRExprEngine::undef_arg_iterator I) {
   return I->first;
 }

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

 namespace {
 class VISIBILITY_HIDDEN BuiltinBug : public BugType {
   GRExprEngine &Eng;
 protected:
   const std::string desc;
 public:
   BuiltinBug(GRExprEngine *eng, const char* n, const char* d)
     : BugType(n, "Logic Errors"), Eng(*eng), desc(d) {}

   BuiltinBug(GRExprEngine *eng, const char* n)
     : BugType(n, "Logic Errors"), Eng(*eng), desc(n) {}

   virtual void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) = 0;

   void FlushReports(BugReporter& BR) { FlushReportsImpl(BR, Eng); }

   template <typename ITER>
   void Emit(BugReporter& BR, ITER I, ITER E) {
     for (; I != E; ++I) BR.EmitReport(new BugReport(*this, desc.c_str(),
                                                      GetNode(I)));
   }
 };

 class VISIBILITY_HIDDEN NullDeref : public BuiltinBug {
 public:
   NullDeref(GRExprEngine* eng)
     : BuiltinBug(eng,"Null dereference", "Dereference of null pointer") {}

   void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
     Emit(BR, Eng.null_derefs_begin(), Eng.null_derefs_end());
   }
 };

 class VISIBILITY_HIDDEN NilReceiverStructRet : public BugType {
   GRExprEngine &Eng;
 public:
   NilReceiverStructRet(GRExprEngine* eng) :
     BugType("'nil' receiver with struct return type", "Logic Errors"),
     Eng(*eng) {}

   void FlushReports(BugReporter& BR) {
     for (GRExprEngine::nil_receiver_struct_ret_iterator
           I=Eng.nil_receiver_struct_ret_begin(),
           E=Eng.nil_receiver_struct_ret_end(); I!=E; ++I) {

       std::string sbuf;
       llvm::raw_string_ostream os(sbuf);
       PostStmt P = cast<PostStmt>((*I)->getLocation());
       ObjCMessageExpr *ME = cast<ObjCMessageExpr>(P.getStmt());
       os << "The receiver in the message expression is 'nil' and results in the"
             " returned value (of type '"
          << ME->getType().getAsString()
          << "') to be garbage or otherwise undefined.";

       RangedBugReport *R = new RangedBugReport(*this, os.str().c_str(), *I);
       R->addRange(ME->getReceiver()->getSourceRange());
       BR.EmitReport(R);
     }
   }
 };

 class VISIBILITY_HIDDEN NilReceiverLargerThanVoidPtrRet : public BugType {
   GRExprEngine &Eng;
 public:
   NilReceiverLargerThanVoidPtrRet(GRExprEngine* eng) :
   BugType("'nil' receiver with return type larger than sizeof(void *)",
           "Logic Errors"),
   Eng(*eng) {}

   void FlushReports(BugReporter& BR) {
     for (GRExprEngine::nil_receiver_larger_than_voidptr_ret_iterator
          I=Eng.nil_receiver_larger_than_voidptr_ret_begin(),
          E=Eng.nil_receiver_larger_than_voidptr_ret_end(); I!=E; ++I) {

       std::string sbuf;
       llvm::raw_string_ostream os(sbuf);
       PostStmt P = cast<PostStmt>((*I)->getLocation());
       ObjCMessageExpr *ME = cast<ObjCMessageExpr>(P.getStmt());
       os << "The receiver in the message expression is 'nil' and results in the"
       " returned value (of type '"
       << ME->getType().getAsString()
       << "' and of size "
       << Eng.getContext().getTypeSize(ME->getType()) / 8
       << " bytes) to be garbage or otherwise undefined.";

       RangedBugReport *R = new RangedBugReport(*this, os.str().c_str(), *I);
       R->addRange(ME->getReceiver()->getSourceRange());
       BR.EmitReport(R);
     }
   }
 };

 class VISIBILITY_HIDDEN UndefinedDeref : public BuiltinBug {
 public:
   UndefinedDeref(GRExprEngine* eng)
     : BuiltinBug(eng,"Dereference of undefined pointer value") {}

   void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
     Emit(BR, Eng.undef_derefs_begin(), Eng.undef_derefs_end());
   }
 };

 class VISIBILITY_HIDDEN DivZero : public BuiltinBug {
 public:
   DivZero(GRExprEngine* eng)
     : BuiltinBug(eng,"Division-by-zero",
                  "Division by zero or undefined value.") {}

   void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
     Emit(BR, Eng.explicit_bad_divides_begin(), Eng.explicit_bad_divides_end());
   }
 };

 class VISIBILITY_HIDDEN UndefResult : public BuiltinBug {
 public:
   UndefResult(GRExprEngine* eng) : BuiltinBug(eng,"Undefined result",
                              "Result of operation is undefined.") {}

   void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
     Emit(BR, Eng.undef_results_begin(), Eng.undef_results_end());
   }
 };

 class VISIBILITY_HIDDEN BadCall : public BuiltinBug {
 public:
   BadCall(GRExprEngine *eng)
   : BuiltinBug(eng, "Invalid function call",
         "Called function pointer is a null or undefined pointer value") {}

   void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
     Emit(BR, Eng.bad_calls_begin(), Eng.bad_calls_end());
   }
 };

 class VISIBILITY_HIDDEN BadArg : public BuiltinBug {
 public:
   BadArg(GRExprEngine* eng) : BuiltinBug(eng,"Uninitialized argument",
     "Pass-by-value argument in function call is undefined.") {}

   BadArg(GRExprEngine* eng, const char* d)
     : BuiltinBug(eng,"Uninitialized argument", d) {}

   void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
     for (GRExprEngine::UndefArgsTy::iterator I = Eng.undef_arg_begin(),
          E = Eng.undef_arg_end(); I!=E; ++I) {
       // Generate a report for this bug.
       RangedBugReport *report = new RangedBugReport(*this, desc.c_str(),
                                                     I->first);
       report->addRange(I->second->getSourceRange());
       BR.EmitReport(report);
     }
   }
 };

 class VISIBILITY_HIDDEN BadMsgExprArg : public BadArg {
 public:
   BadMsgExprArg(GRExprEngine* eng)
     : BadArg(eng,"Pass-by-value argument in message expression is undefined"){}

   void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
     for (GRExprEngine::UndefArgsTy::iterator I=Eng.msg_expr_undef_arg_begin(),
          E = Eng.msg_expr_undef_arg_end(); I!=E; ++I) {
       // Generate a report for this bug.
       RangedBugReport *report = new RangedBugReport(*this, desc.c_str(),
                                                     I->first);
       report->addRange(I->second->getSourceRange());
       BR.EmitReport(report);
     }
   }
 };

 class VISIBILITY_HIDDEN BadReceiver : public BuiltinBug {
 public:
   BadReceiver(GRExprEngine* eng)
   : BuiltinBug(eng,"Uninitialized receiver",
                "Receiver in message expression is an uninitialized value") {}

   void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
     for (GRExprEngine::ErrorNodes::iterator I=Eng.undef_receivers_begin(),
          End = Eng.undef_receivers_end(); I!=End; ++I) {

       // Generate a report for this bug.
       RangedBugReport *report = new RangedBugReport(*this, desc.c_str(), *I);
       ExplodedNode<GRState>* N = *I;
       Stmt *S = cast<PostStmt>(N->getLocation()).getStmt();
       Expr* E = cast<ObjCMessageExpr>(S)->getReceiver();
       assert (E && "Receiver cannot be NULL");
       report->addRange(E->getSourceRange());
       BR.EmitReport(report);
     }
   }
 };

 class VISIBILITY_HIDDEN RetStack : public BuiltinBug {
 public:
   RetStack(GRExprEngine* eng)
     : BuiltinBug(eng, "Return of address to stack-allocated memory") {}

   void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
     for (GRExprEngine::ret_stackaddr_iterator I=Eng.ret_stackaddr_begin(),
          End = Eng.ret_stackaddr_end(); I!=End; ++I) {

       ExplodedNode<GRState>* N = *I;
       Stmt *S = cast<PostStmt>(N->getLocation()).getStmt();
       Expr* E = cast<ReturnStmt>(S)->getRetValue();
       assert (E && "Return expression cannot be NULL");

       // Get the value associated with E.
       loc::MemRegionVal V =
         cast<loc::MemRegionVal>(Eng.getStateManager().GetSVal(N->getState(),
                                                                E));

       // Generate a report for this bug.
       std::string buf;
       llvm::raw_string_ostream os(buf);
       SourceRange R;

       // Check if the region is a compound literal.
       if (const CompoundLiteralRegion* CR =
             dyn_cast<CompoundLiteralRegion>(V.getRegion())) {

         const CompoundLiteralExpr* CL = CR->getLiteralExpr();
         os << "Address of stack memory associated with a compound literal "
               "declared on line "
             << BR.getSourceManager()
                     .getInstantiationLineNumber(CL->getLocStart())
             << " returned.";

         R = CL->getSourceRange();
       }
       else if (const AllocaRegion* AR = dyn_cast<AllocaRegion>(V.getRegion())) {
         const Expr* ARE = AR->getExpr();
         SourceLocation L = ARE->getLocStart();
         R = ARE->getSourceRange();

         os << "Address of stack memory allocated by call to alloca() on line "
            << BR.getSourceManager().getInstantiationLineNumber(L)
            << " returned.";
       }
       else {
         os << "Address of stack memory associated with local variable '"
            << V.getRegion()->getString() << "' returned.";
       }

       RangedBugReport *report = new RangedBugReport(*this, os.str().c_str(), N);
       report->addRange(E->getSourceRange());
       if (R.isValid()) report->addRange(R);
       BR.EmitReport(report);
     }
   }
 };

 class VISIBILITY_HIDDEN RetUndef : public BuiltinBug {
 public:
   RetUndef(GRExprEngine* eng) : BuiltinBug(eng, "Uninitialized return value",
               "Uninitialized or undefined return value returned to caller.") {}

   void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
     Emit(BR, Eng.ret_undef_begin(), Eng.ret_undef_end());
   }
 };

 class VISIBILITY_HIDDEN UndefBranch : public BuiltinBug {
   struct VISIBILITY_HIDDEN FindUndefExpr {
     GRStateManager& VM;
     const GRState* St;

     FindUndefExpr(GRStateManager& V, const GRState* S) : VM(V), St(S) {}

     Expr* FindExpr(Expr* Ex) {
       if (!MatchesCriteria(Ex))
         return 0;

       for (Stmt::child_iterator I=Ex->child_begin(), E=Ex->child_end();I!=E;++I)
         if (Expr* ExI = dyn_cast_or_null<Expr>(*I)) {
           Expr* E2 = FindExpr(ExI);
           if (E2) return E2;
         }

       return Ex;
     }

     bool MatchesCriteria(Expr* Ex) { return VM.GetSVal(St, Ex).isUndef(); }
   };

 public:
   UndefBranch(GRExprEngine *eng)
     : BuiltinBug(eng,"Use of uninitialized value",
                  "Branch condition evaluates to an uninitialized value.") {}

   void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
     for (GRExprEngine::undef_branch_iterator I=Eng.undef_branches_begin(),
          E=Eng.undef_branches_end(); I!=E; ++I) {

       // What's going on here: we want to highlight the subexpression of the
       // condition that is the most likely source of the "uninitialized
       // branch condition."  We do a recursive walk of the condition's
       // subexpressions and roughly look for the most nested subexpression
       // that binds to Undefined.  We then highlight that expression's range.
       BlockEdge B = cast<BlockEdge>((*I)->getLocation());
       Expr* Ex = cast<Expr>(B.getSrc()->getTerminatorCondition());
       assert (Ex && "Block must have a terminator.");

       // Get the predecessor node and check if is a PostStmt with the Stmt
       // being the terminator condition.  We want to inspect the state
       // of that node instead because it will contain main information about
       // the subexpressions.
       assert (!(*I)->pred_empty());

       // Note: any predecessor will do.  They should have identical state,
       // since all the BlockEdge did was act as an error sink since the value
       // had to already be undefined.
       ExplodedNode<GRState> *N = *(*I)->pred_begin();
       ProgramPoint P = N->getLocation();
       const GRState* St = (*I)->getState();

       if (PostStmt* PS = dyn_cast<PostStmt>(&P))
         if (PS->getStmt() == Ex)
           St = N->getState();

       FindUndefExpr FindIt(Eng.getStateManager(), St);
       Ex = FindIt.FindExpr(Ex);

       RangedBugReport *R = new RangedBugReport(*this, desc.c_str(), *I);
       R->addRange(Ex->getSourceRange());
       BR.EmitReport(R);
     }
   }
 };

 class VISIBILITY_HIDDEN OutOfBoundMemoryAccess : public BuiltinBug {
 public:
   OutOfBoundMemoryAccess(GRExprEngine* eng)
     : BuiltinBug(eng,"Out-of-bounds memory access",
                      "Load or store into an out-of-bound memory position.") {}

   void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
     Emit(BR, Eng.explicit_oob_memacc_begin(), Eng.explicit_oob_memacc_end());
   }
 };

 class VISIBILITY_HIDDEN BadSizeVLA : public BuiltinBug {
 public:
   BadSizeVLA(GRExprEngine* eng) :
     BuiltinBug(eng, "Bad variable-length array (VLA) size") {}

   void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
     for (GRExprEngine::ErrorNodes::iterator
           I = Eng.ExplicitBadSizedVLA.begin(),
           E = Eng.ExplicitBadSizedVLA.end(); I!=E; ++I) {

       // Determine whether this was a 'zero-sized' VLA or a VLA with an
       // undefined size.
       GRExprEngine::NodeTy* N = *I;
       PostStmt PS = cast<PostStmt>(N->getLocation());
       DeclStmt *DS = cast<DeclStmt>(PS.getStmt());
       VarDecl* VD = cast<VarDecl>(*DS->decl_begin());
       QualType T = Eng.getContext().getCanonicalType(VD->getType());
       VariableArrayType* VT = cast<VariableArrayType>(T);
       Expr* SizeExpr = VT->getSizeExpr();

       std::string buf;
       llvm::raw_string_ostream os(buf);
       os << "The expression used to specify the number of elements in the "
             "variable-length array (VLA) '"
          << VD->getNameAsString() << "' evaluates to ";

       bool isUndefined = Eng.getStateManager().GetSVal(N->getState(),
                                                        SizeExpr).isUndef();

       if (isUndefined)
         os << "an undefined or garbage value.";
       else
         os << "0. VLAs with no elements have undefined behavior.";

       std::string shortBuf;
       llvm::raw_string_ostream os_short(shortBuf);
       os_short << "Variable-length array '" << VD->getNameAsString() << "' "
                << (isUndefined ? " garbage value for array size"
                    : " has zero elements (undefined behavior)");

       RangedBugReport *report = new RangedBugReport(*this,
                                                     os_short.str().c_str(),
                                                     os.str().c_str(), N);
       report->addRange(SizeExpr->getSourceRange());
       BR.EmitReport(report);
     }
   }
 };

 //===----------------------------------------------------------------------===//
 // __attribute__(nonnull) checking

 class VISIBILITY_HIDDEN CheckAttrNonNull : public GRSimpleAPICheck {
   BugType *BT;
   BugReporter &BR;

 public:
   CheckAttrNonNull(BugReporter &br) : BT(0), BR(br) {}

   virtual bool Audit(ExplodedNode<GRState>* N, GRStateManager& VMgr) {
     CallExpr* CE = cast<CallExpr>(cast<PostStmt>(N->getLocation()).getStmt());
     const GRState* state = N->getState();

     SVal X = VMgr.GetSVal(state, CE->getCallee());

     const FunctionDecl* FD = X.getAsFunctionDecl();
     if (!FD)
       return false;

     const NonNullAttr* Att = FD->getAttr<NonNullAttr>();

     if (!Att)
       return false;

     // Iterate through the arguments of CE and check them for null.
     unsigned idx = 0;
     bool hasError = false;

     for (CallExpr::arg_iterator I=CE->arg_begin(), E=CE->arg_end(); I!=E;
          ++I, ++idx) {

       if (!VMgr.isEqual(state, *I, 0) || !Att->isNonNull(idx))
         continue;

       // Lazily allocate the BugType object if it hasn't already been created.
       // Ownership is transferred to the BugReporter object once the BugReport
       // is passed to 'EmitWarning'.
       if (!BT) BT =
         new BugType("Argument with 'nonnull' attribute passed null", "API");

       RangedBugReport *R = new RangedBugReport(*BT,
                                    "Null pointer passed as an argument to a "
                                    "'nonnull' parameter", N);

       R->addRange((*I)->getSourceRange());
       BR.EmitReport(R);
       hasError = true;
     }

     return hasError;
   }
 };
 } // end anonymous namespace

 //===----------------------------------------------------------------------===//
 // Check registration.
 //===----------------------------------------------------------------------===//

 void GRExprEngine::RegisterInternalChecks() {
   // Register internal "built-in" BugTypes with the BugReporter. These BugTypes
   // are different than what probably many checks will do since they don't
   // create BugReports on-the-fly but instead wait until GRExprEngine finishes
   // analyzing a function.  Generation of BugReport objects is done via a call
   // to 'FlushReports' from BugReporter.
   BR.Register(new NullDeref(this));
   BR.Register(new UndefinedDeref(this));
   BR.Register(new UndefBranch(this));
   BR.Register(new DivZero(this));
   BR.Register(new UndefResult(this));
   BR.Register(new BadCall(this));
   BR.Register(new RetStack(this));
   BR.Register(new RetUndef(this));
   BR.Register(new BadArg(this));
   BR.Register(new BadMsgExprArg(this));
   BR.Register(new BadReceiver(this));
   BR.Register(new OutOfBoundMemoryAccess(this));
   BR.Register(new BadSizeVLA(this));
   BR.Register(new NilReceiverStructRet(this));
   BR.Register(new NilReceiverLargerThanVoidPtrRet(this));

   // The following checks do not need to have their associated BugTypes
   // explicitly registered with the BugReporter.  If they issue any BugReports,
   // their associated BugType will get registered with the BugReporter
   // automatically.  Note that the check itself is owned by the GRExprEngine
   // object.
   AddCheck(new CheckAttrNonNull(BR), Stmt::CallExprClass);
 }
	//=-- GRExprEngineInternalChecks.cpp - Builtin GRExprEngine Checks---- 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 BugType classes used by GRExprEngine to report
	// bugs derived from builtin checks in the path-sensitive engine.
	//
	//===----------------------------------------------------------------------===//

	#include "clang/Analysis/PathSensitive/BugReporter.h"
	#include "clang/Analysis/PathSensitive/GRExprEngine.h"
	#include "clang/Basic/SourceManager.h"
	#include "llvm/Support/Compiler.h"
	#include "llvm/Support/raw_ostream.h"

	using namespace clang;

	//===----------------------------------------------------------------------===//
	// Utility functions.
	//===----------------------------------------------------------------------===//

	template <typename ITERATOR> inline
	ExplodedNode<GRState>* GetNode(ITERATOR I) {
	return *I;
	}

	template <> inline
	ExplodedNode<GRState>* GetNode(GRExprEngine::undef_arg_iterator I) {
	return I->first;
	}

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

	namespace {
	class VISIBILITY_HIDDEN BuiltinBug : public BugType {
	GRExprEngine &Eng;
	protected:
	const std::string desc;
	public:
	BuiltinBug(GRExprEngine eng, const char n, const char* d)
	: BugType(n, "Logic Errors"), Eng(*eng), desc(d) {}

	BuiltinBug(GRExprEngine eng, const char n)
	: BugType(n, "Logic Errors"), Eng(*eng), desc(n) {}

	virtual void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) = 0;

	void FlushReports(BugReporter& BR) { FlushReportsImpl(BR, Eng); }

	template <typename ITER>
	void Emit(BugReporter& BR, ITER I, ITER E) {
	for (; I != E; ++I) BR.EmitReport(new BugReport(*this, desc.c_str(),
	GetNode(I)));
	}
	};

	class VISIBILITY_HIDDEN NullDeref : public BuiltinBug {
	public:
	NullDeref(GRExprEngine* eng)
	: BuiltinBug(eng,"Null dereference", "Dereference of null pointer") {}

	void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
	Emit(BR, Eng.null_derefs_begin(), Eng.null_derefs_end());
	}
	};

	class VISIBILITY_HIDDEN NilReceiverStructRet : public BugType {
	GRExprEngine &Eng;
	public:
	NilReceiverStructRet(GRExprEngine* eng) :
	BugType("'nil' receiver with struct return type", "Logic Errors"),
	Eng(*eng) {}

	void FlushReports(BugReporter& BR) {
	for (GRExprEngine::nil_receiver_struct_ret_iterator
	I=Eng.nil_receiver_struct_ret_begin(),
	E=Eng.nil_receiver_struct_ret_end(); I!=E; ++I) {

	std::string sbuf;
	llvm::raw_string_ostream os(sbuf);
	PostStmt P = cast<PostStmt>((*I)->getLocation());
	ObjCMessageExpr *ME = cast<ObjCMessageExpr>(P.getStmt());
	os << "The receiver in the message expression is 'nil' and results in the"
	" returned value (of type '"
	<< ME->getType().getAsString()
	<< "') to be garbage or otherwise undefined.";

	RangedBugReport R = new RangedBugReport(this, os.str().c_str(), *I);
	R->addRange(ME->getReceiver()->getSourceRange());
	BR.EmitReport(R);
	}
	}
	};

	class VISIBILITY_HIDDEN NilReceiverLargerThanVoidPtrRet : public BugType {
	GRExprEngine &Eng;
	public:
	NilReceiverLargerThanVoidPtrRet(GRExprEngine* eng) :
	BugType("'nil' receiver with return type larger than sizeof(void *)",
	"Logic Errors"),
	Eng(*eng) {}

	void FlushReports(BugReporter& BR) {
	for (GRExprEngine::nil_receiver_larger_than_voidptr_ret_iterator
	I=Eng.nil_receiver_larger_than_voidptr_ret_begin(),
	E=Eng.nil_receiver_larger_than_voidptr_ret_end(); I!=E; ++I) {

	std::string sbuf;
	llvm::raw_string_ostream os(sbuf);
	PostStmt P = cast<PostStmt>((*I)->getLocation());
	ObjCMessageExpr *ME = cast<ObjCMessageExpr>(P.getStmt());
	os << "The receiver in the message expression is 'nil' and results in the"
	" returned value (of type '"
	<< ME->getType().getAsString()
	<< "' and of size "
	<< Eng.getContext().getTypeSize(ME->getType()) / 8
	<< " bytes) to be garbage or otherwise undefined.";

	RangedBugReport R = new RangedBugReport(this, os.str().c_str(), *I);
	R->addRange(ME->getReceiver()->getSourceRange());
	BR.EmitReport(R);
	}
	}
	};

	class VISIBILITY_HIDDEN UndefinedDeref : public BuiltinBug {
	public:
	UndefinedDeref(GRExprEngine* eng)
	: BuiltinBug(eng,"Dereference of undefined pointer value") {}

	void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
	Emit(BR, Eng.undef_derefs_begin(), Eng.undef_derefs_end());
	}
	};

	class VISIBILITY_HIDDEN DivZero : public BuiltinBug {
	public:
	DivZero(GRExprEngine* eng)
	: BuiltinBug(eng,"Division-by-zero",
	"Division by zero or undefined value.") {}

	void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
	Emit(BR, Eng.explicit_bad_divides_begin(), Eng.explicit_bad_divides_end());
	}
	};

	class VISIBILITY_HIDDEN UndefResult : public BuiltinBug {
	public:
	UndefResult(GRExprEngine* eng) : BuiltinBug(eng,"Undefined result",
	"Result of operation is undefined.") {}

	void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
	Emit(BR, Eng.undef_results_begin(), Eng.undef_results_end());
	}
	};

	class VISIBILITY_HIDDEN BadCall : public BuiltinBug {
	public:
	BadCall(GRExprEngine *eng)
	: BuiltinBug(eng, "Invalid function call",
	"Called function pointer is a null or undefined pointer value") {}

	void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
	Emit(BR, Eng.bad_calls_begin(), Eng.bad_calls_end());
	}
	};

	class VISIBILITY_HIDDEN BadArg : public BuiltinBug {
	public:
	BadArg(GRExprEngine* eng) : BuiltinBug(eng,"Uninitialized argument",
	"Pass-by-value argument in function call is undefined.") {}

	BadArg(GRExprEngine* eng, const char* d)
	: BuiltinBug(eng,"Uninitialized argument", d) {}

	void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
	for (GRExprEngine::UndefArgsTy::iterator I = Eng.undef_arg_begin(),
	E = Eng.undef_arg_end(); I!=E; ++I) {
	// Generate a report for this bug.
	RangedBugReport report = new RangedBugReport(this, desc.c_str(),
	I->first);
	report->addRange(I->second->getSourceRange());
	BR.EmitReport(report);
	}
	}
	};

	class VISIBILITY_HIDDEN BadMsgExprArg : public BadArg {
	public:
	BadMsgExprArg(GRExprEngine* eng)
	: BadArg(eng,"Pass-by-value argument in message expression is undefined"){}

	void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
	for (GRExprEngine::UndefArgsTy::iterator I=Eng.msg_expr_undef_arg_begin(),
	E = Eng.msg_expr_undef_arg_end(); I!=E; ++I) {
	// Generate a report for this bug.
	RangedBugReport report = new RangedBugReport(this, desc.c_str(),
	I->first);
	report->addRange(I->second->getSourceRange());
	BR.EmitReport(report);
	}
	}
	};

	class VISIBILITY_HIDDEN BadReceiver : public BuiltinBug {
	public:
	BadReceiver(GRExprEngine* eng)
	: BuiltinBug(eng,"Uninitialized receiver",
	"Receiver in message expression is an uninitialized value") {}

	void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
	for (GRExprEngine::ErrorNodes::iterator I=Eng.undef_receivers_begin(),
	End = Eng.undef_receivers_end(); I!=End; ++I) {

	// Generate a report for this bug.
	RangedBugReport report = new RangedBugReport(this, desc.c_str(), *I);
	ExplodedNode<GRState>* N = *I;
	Stmt *S = cast<PostStmt>(N->getLocation()).getStmt();
	Expr* E = cast<ObjCMessageExpr>(S)->getReceiver();
	assert (E && "Receiver cannot be NULL");
	report->addRange(E->getSourceRange());
	BR.EmitReport(report);
	}
	}
	};

	class VISIBILITY_HIDDEN RetStack : public BuiltinBug {
	public:
	RetStack(GRExprEngine* eng)
	: BuiltinBug(eng, "Return of address to stack-allocated memory") {}

	void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
	for (GRExprEngine::ret_stackaddr_iterator I=Eng.ret_stackaddr_begin(),
	End = Eng.ret_stackaddr_end(); I!=End; ++I) {

	ExplodedNode<GRState>* N = *I;
	Stmt *S = cast<PostStmt>(N->getLocation()).getStmt();
	Expr* E = cast<ReturnStmt>(S)->getRetValue();
	assert (E && "Return expression cannot be NULL");

	// Get the value associated with E.
	loc::MemRegionVal V =
	cast<loc::MemRegionVal>(Eng.getStateManager().GetSVal(N->getState(),
	E));

	// Generate a report for this bug.
	std::string buf;
	llvm::raw_string_ostream os(buf);
	SourceRange R;

	// Check if the region is a compound literal.
	if (const CompoundLiteralRegion* CR =
	dyn_cast<CompoundLiteralRegion>(V.getRegion())) {

	const CompoundLiteralExpr* CL = CR->getLiteralExpr();
	os << "Address of stack memory associated with a compound literal "
	"declared on line "
	<< BR.getSourceManager()
	.getInstantiationLineNumber(CL->getLocStart())
	<< " returned.";

	R = CL->getSourceRange();
	}
	else if (const AllocaRegion* AR = dyn_cast<AllocaRegion>(V.getRegion())) {
	const Expr* ARE = AR->getExpr();
	SourceLocation L = ARE->getLocStart();
	R = ARE->getSourceRange();

	os << "Address of stack memory allocated by call to alloca() on line "
	<< BR.getSourceManager().getInstantiationLineNumber(L)
	<< " returned.";
	}
	else {
	os << "Address of stack memory associated with local variable '"
	<< V.getRegion()->getString() << "' returned.";
	}

	RangedBugReport report = new RangedBugReport(this, os.str().c_str(), N);
	report->addRange(E->getSourceRange());
	if (R.isValid()) report->addRange(R);
	BR.EmitReport(report);
	}
	}
	};

	class VISIBILITY_HIDDEN RetUndef : public BuiltinBug {
	public:
	RetUndef(GRExprEngine* eng) : BuiltinBug(eng, "Uninitialized return value",
	"Uninitialized or undefined return value returned to caller.") {}

	void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
	Emit(BR, Eng.ret_undef_begin(), Eng.ret_undef_end());
	}
	};

	class VISIBILITY_HIDDEN UndefBranch : public BuiltinBug {
	struct VISIBILITY_HIDDEN FindUndefExpr {
	GRStateManager& VM;
	const GRState* St;

	FindUndefExpr(GRStateManager& V, const GRState* S) : VM(V), St(S) {}

	Expr* FindExpr(Expr* Ex) {
	if (!MatchesCriteria(Ex))
	return 0;

	for (Stmt::child_iterator I=Ex->child_begin(), E=Ex->child_end();I!=E;++I)
	if (Expr* ExI = dyn_cast_or_null<Expr>(*I)) {
	Expr* E2 = FindExpr(ExI);
	if (E2) return E2;
	}

	return Ex;
	}

	bool MatchesCriteria(Expr* Ex) { return VM.GetSVal(St, Ex).isUndef(); }
	};

	public:
	UndefBranch(GRExprEngine *eng)
	: BuiltinBug(eng,"Use of uninitialized value",
	"Branch condition evaluates to an uninitialized value.") {}

	void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
	for (GRExprEngine::undef_branch_iterator I=Eng.undef_branches_begin(),
	E=Eng.undef_branches_end(); I!=E; ++I) {

	// What's going on here: we want to highlight the subexpression of the
	// condition that is the most likely source of the "uninitialized
	// branch condition." We do a recursive walk of the condition's
	// subexpressions and roughly look for the most nested subexpression
	// that binds to Undefined. We then highlight that expression's range.
	BlockEdge B = cast<BlockEdge>((*I)->getLocation());
	Expr* Ex = cast<Expr>(B.getSrc()->getTerminatorCondition());
	assert (Ex && "Block must have a terminator.");

	// Get the predecessor node and check if is a PostStmt with the Stmt
	// being the terminator condition. We want to inspect the state
	// of that node instead because it will contain main information about
	// the subexpressions.
	assert (!(*I)->pred_empty());

	// Note: any predecessor will do. They should have identical state,
	// since all the BlockEdge did was act as an error sink since the value
	// had to already be undefined.
	ExplodedNode<GRState> N = (*I)->pred_begin();
	ProgramPoint P = N->getLocation();
	const GRState* St = (*I)->getState();

	if (PostStmt* PS = dyn_cast<PostStmt>(&P))
	if (PS->getStmt() == Ex)
	St = N->getState();

	FindUndefExpr FindIt(Eng.getStateManager(), St);
	Ex = FindIt.FindExpr(Ex);

	RangedBugReport R = new RangedBugReport(this, desc.c_str(), *I);
	R->addRange(Ex->getSourceRange());
	BR.EmitReport(R);
	}
	}
	};

	class VISIBILITY_HIDDEN OutOfBoundMemoryAccess : public BuiltinBug {
	public:
	OutOfBoundMemoryAccess(GRExprEngine* eng)
	: BuiltinBug(eng,"Out-of-bounds memory access",
	"Load or store into an out-of-bound memory position.") {}

	void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
	Emit(BR, Eng.explicit_oob_memacc_begin(), Eng.explicit_oob_memacc_end());
	}
	};

	class VISIBILITY_HIDDEN BadSizeVLA : public BuiltinBug {
	public:
	BadSizeVLA(GRExprEngine* eng) :
	BuiltinBug(eng, "Bad variable-length array (VLA) size") {}

	void FlushReportsImpl(BugReporter& BR, GRExprEngine& Eng) {
	for (GRExprEngine::ErrorNodes::iterator
	I = Eng.ExplicitBadSizedVLA.begin(),
	E = Eng.ExplicitBadSizedVLA.end(); I!=E; ++I) {

	// Determine whether this was a 'zero-sized' VLA or a VLA with an
	// undefined size.
	GRExprEngine::NodeTy* N = *I;
	PostStmt PS = cast<PostStmt>(N->getLocation());
	DeclStmt *DS = cast<DeclStmt>(PS.getStmt());
	VarDecl* VD = cast<VarDecl>(*DS->decl_begin());
	QualType T = Eng.getContext().getCanonicalType(VD->getType());
	VariableArrayType* VT = cast<VariableArrayType>(T);
	Expr* SizeExpr = VT->getSizeExpr();

	std::string buf;
	llvm::raw_string_ostream os(buf);
	os << "The expression used to specify the number of elements in the "
	"variable-length array (VLA) '"
	<< VD->getNameAsString() << "' evaluates to ";

	bool isUndefined = Eng.getStateManager().GetSVal(N->getState(),
	SizeExpr).isUndef();

	if (isUndefined)
	os << "an undefined or garbage value.";
	else
	os << "0. VLAs with no elements have undefined behavior.";

	std::string shortBuf;
	llvm::raw_string_ostream os_short(shortBuf);
	os_short << "Variable-length array '" << VD->getNameAsString() << "' "
	<< (isUndefined ? " garbage value for array size"
	: " has zero elements (undefined behavior)");

	RangedBugReport report = new RangedBugReport(this,
	os_short.str().c_str(),
	os.str().c_str(), N);
	report->addRange(SizeExpr->getSourceRange());
	BR.EmitReport(report);
	}
	}
	};

	//===----------------------------------------------------------------------===//
	// __attribute__(nonnull) checking

	class VISIBILITY_HIDDEN CheckAttrNonNull : public GRSimpleAPICheck {
	BugType *BT;
	BugReporter &BR;

	public:
	CheckAttrNonNull(BugReporter &br) : BT(0), BR(br) {}

	virtual bool Audit(ExplodedNode<GRState>* N, GRStateManager& VMgr) {
	CallExpr* CE = cast<CallExpr>(cast<PostStmt>(N->getLocation()).getStmt());
	const GRState* state = N->getState();

	SVal X = VMgr.GetSVal(state, CE->getCallee());

	const FunctionDecl* FD = X.getAsFunctionDecl();
	if (!FD)
	return false;

	const NonNullAttr* Att = FD->getAttr<NonNullAttr>();

	if (!Att)
	return false;

	// Iterate through the arguments of CE and check them for null.
	unsigned idx = 0;
	bool hasError = false;

	for (CallExpr::arg_iterator I=CE->arg_begin(), E=CE->arg_end(); I!=E;
	++I, ++idx) {

	if (!VMgr.isEqual(state, *I, 0) \|\| !Att->isNonNull(idx))
	continue;

	// Lazily allocate the BugType object if it hasn't already been created.
	// Ownership is transferred to the BugReporter object once the BugReport
	// is passed to 'EmitWarning'.
	if (!BT) BT =
	new BugType("Argument with 'nonnull' attribute passed null", "API");

	RangedBugReport R = new RangedBugReport(BT,
	"Null pointer passed as an argument to a "
	"'nonnull' parameter", N);

	R->addRange((*I)->getSourceRange());
	BR.EmitReport(R);
	hasError = true;
	}

	return hasError;
	}
	};
	} // end anonymous namespace

	//===----------------------------------------------------------------------===//
	// Check registration.
	//===----------------------------------------------------------------------===//

	void GRExprEngine::RegisterInternalChecks() {
	// Register internal "built-in" BugTypes with the BugReporter. These BugTypes
	// are different than what probably many checks will do since they don't
	// create BugReports on-the-fly but instead wait until GRExprEngine finishes
	// analyzing a function. Generation of BugReport objects is done via a call
	// to 'FlushReports' from BugReporter.
	BR.Register(new NullDeref(this));
	BR.Register(new UndefinedDeref(this));
	BR.Register(new UndefBranch(this));
	BR.Register(new DivZero(this));
	BR.Register(new UndefResult(this));
	BR.Register(new BadCall(this));
	BR.Register(new RetStack(this));
	BR.Register(new RetUndef(this));
	BR.Register(new BadArg(this));
	BR.Register(new BadMsgExprArg(this));
	BR.Register(new BadReceiver(this));
	BR.Register(new OutOfBoundMemoryAccess(this));
	BR.Register(new BadSizeVLA(this));
	BR.Register(new NilReceiverStructRet(this));
	BR.Register(new NilReceiverLargerThanVoidPtrRet(this));

	// The following checks do not need to have their associated BugTypes
	// explicitly registered with the BugReporter. If they issue any BugReports,
	// their associated BugType will get registered with the BugReporter
	// automatically. Note that the check itself is owned by the GRExprEngine
	// object.
	AddCheck(new CheckAttrNonNull(BR), Stmt::CallExprClass);
	}