clang/test/Sema/warn-lifetime-analysis-nocfg.cpp - llvm-project - Git at Google

 // RUN: %clang_cc1 -fsyntax-only -Wdangling -Wdangling-field -Wreturn-stack-address -verify %s
 struct [[gsl::Owner(int)]] MyIntOwner {
   MyIntOwner();
   int &operator*();
 };

 struct [[gsl::Pointer(int)]] MyIntPointer {
   MyIntPointer(int *p = nullptr);
   // Conversion operator and constructor conversion will result in two
   // different ASTs. The former is tested with another owner and
   // pointer type.
   MyIntPointer(const MyIntOwner &);
   int &operator*();
   MyIntOwner toOwner();
 };

 struct MySpecialIntPointer : MyIntPointer {
 };

 // We did see examples in the wild when a derived class changes
 // the ownership model. So we have a test for it.
 struct [[gsl::Owner(int)]] MyOwnerIntPointer : MyIntPointer {
 };

 struct [[gsl::Pointer(long)]] MyLongPointerFromConversion {
   MyLongPointerFromConversion(long *p = nullptr);
   long &operator*();
 };

 struct [[gsl::Owner(long)]] MyLongOwnerWithConversion {
   MyLongOwnerWithConversion();
   operator MyLongPointerFromConversion();
   long &operator*();
   MyIntPointer releaseAsMyPointer();
   long *releaseAsRawPointer();
 };

 void danglingHeapObject() {
   new MyLongPointerFromConversion(MyLongOwnerWithConversion{}); // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
   new MyIntPointer(MyIntOwner{}); // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
 }

 void intentionalFalseNegative() {
   int i;
   MyIntPointer p{&i};
   // In this case we do not have enough information in a statement local
   // analysis to detect the problem.
   new MyIntPointer(p);
   new MyIntPointer(MyIntPointer{p});
 }

 MyIntPointer ownershipTransferToMyPointer() {
   MyLongOwnerWithConversion t;
   return t.releaseAsMyPointer(); // ok
 }

 long *ownershipTransferToRawPointer() {
   MyLongOwnerWithConversion t;
   return t.releaseAsRawPointer(); // ok
 }

 struct Y {
   int a[4];
 };

 void dangligGslPtrFromTemporary() {
   MyIntPointer p = Y{}.a; // TODO
   (void)p;
 }

 struct DanglingGslPtrField {
   MyIntPointer p; // expected-note {{pointer member declared here}}
   MyLongPointerFromConversion p2; // expected-note {{pointer member declared here}}
   DanglingGslPtrField(int i) : p(&i) {} // TODO
   DanglingGslPtrField() : p2(MyLongOwnerWithConversion{}) {} // expected-warning {{initializing pointer member 'p2' to point to a temporary object whose lifetime is shorter than the lifetime of the constructed object}}
   DanglingGslPtrField(double) : p(MyIntOwner{}) {} // expected-warning {{initializing pointer member 'p' to point to a temporary object whose lifetime is shorter than the lifetime of the constructed object}}
 };

 MyIntPointer danglingGslPtrFromLocal() {
   int j;
   return &j; // TODO
 }

 MyIntPointer returningLocalPointer() {
   MyIntPointer localPointer;
   return localPointer; // ok
 }

 MyIntPointer daglingGslPtrFromLocalOwner() {
   MyIntOwner localOwner;
   return localOwner; // expected-warning {{address of stack memory associated with local variable 'localOwner' returned}}
 }

 MyLongPointerFromConversion daglingGslPtrFromLocalOwnerConv() {
   MyLongOwnerWithConversion localOwner;
   return localOwner; // expected-warning {{address of stack memory associated with local variable 'localOwner' returned}}
 }

 MyIntPointer danglingGslPtrFromTemporary() {
   return MyIntOwner{}; // expected-warning {{returning address of local temporary object}}
 }

 MyIntOwner makeTempOwner();

 MyIntPointer danglingGslPtrFromTemporary2() {
   return makeTempOwner(); // expected-warning {{returning address of local temporary object}}
 }

 MyLongPointerFromConversion danglingGslPtrFromTemporaryConv() {
   return MyLongOwnerWithConversion{}; // expected-warning {{returning address of local temporary object}}
 }

 int *noFalsePositive(MyIntOwner &o) {
   MyIntPointer p = o;
   return &*p; // ok
 }

 MyIntPointer global;
 MyLongPointerFromConversion global2;

 void initLocalGslPtrWithTempOwner() {
   MyIntPointer p = MyIntOwner{}; // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
   p = MyIntOwner{}; // TODO ?
   global = MyIntOwner{}; // TODO ?
   MyLongPointerFromConversion p2 = MyLongOwnerWithConversion{}; // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
   p2 = MyLongOwnerWithConversion{}; // TODO ?
   global2 = MyLongOwnerWithConversion{}; // TODO ?
 }

 namespace __gnu_cxx {
 template <typename T>
 struct basic_iterator {
   basic_iterator operator++();
   T& operator*() const;
   T* operator->() const;
 };

 template<typename T>
 bool operator!=(basic_iterator<T>, basic_iterator<T>);
 }

 namespace std {
 template<typename T> struct remove_reference       { typedef T type; };
 template<typename T> struct remove_reference<T &>  { typedef T type; };
 template<typename T> struct remove_reference<T &&> { typedef T type; };

 template<typename T>
 typename remove_reference<T>::type &&move(T &&t) noexcept;

 template <typename C>
 auto data(const C &c) -> decltype(c.data());

 template <typename C>
 auto begin(C &c) -> decltype(c.begin());

 template<typename T, int N>
 T *begin(T (&array)[N]);

 template <typename T>
 struct vector {
   typedef __gnu_cxx::basic_iterator<T> iterator;
   iterator begin();
   iterator end();
   const T *data() const;
   T &at(int n);
 };

 template<typename T>
 struct basic_string_view {
   basic_string_view(const T *);
   const T *begin() const;
 };

 template<class _Mystr> struct iter {
     iter& operator-=(int);

     iter operator-(int _Off) const {
         iter _Tmp = *this;
         return _Tmp -= _Off;
     }
 };

 template<typename T>
 struct basic_string {
   basic_string();
   basic_string(const T *);
   const T *c_str() const;
   operator basic_string_view<T> () const;
   using const_iterator = iter<T>;
 };


 template<typename T>
 struct unique_ptr {
   T &operator*();
   T *get() const;
 };

 template<typename T>
 struct optional {
   optional();
   optional(const T&);
   T &operator*() &;
   T &&operator*() &&;
   T &value() &;
   T &&value() &&;
 };

 template<typename T>
 struct stack {
   T &top();
 };

 struct any {};

 template<typename T>
 T any_cast(const any& operand);

 template<typename T>
 struct reference_wrapper {
   template<typename U>
   reference_wrapper(U &&);
 };

 template<typename T>
 reference_wrapper<T> ref(T& t) noexcept;
 }

 struct Unannotated {
   typedef std::vector<int>::iterator iterator;
   iterator begin();
   operator iterator() const;
 };

 void modelIterators() {
   std::vector<int>::iterator it = std::vector<int>().begin(); // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
   (void)it;
 }

 std::vector<int>::iterator modelIteratorReturn() {
   return std::vector<int>().begin(); // expected-warning {{returning address of local temporary object}}
 }

 const int *modelFreeFunctions() {
   return std::data(std::vector<int>()); // expected-warning {{returning address of local temporary object}}
 }

 int &modelAnyCast() {
   return std::any_cast<int&>(std::any{}); // expected-warning {{returning reference to local temporary object}}
 }

 int modelAnyCast2() {
   return std::any_cast<int>(std::any{}); // ok
 }

 int modelAnyCast3() {
   return std::any_cast<int&>(std::any{}); // ok
 }

 const char *danglingRawPtrFromLocal() {
   std::basic_string<char> s;
   return s.c_str(); // expected-warning {{address of stack memory associated with local variable 's' returned}}
 }

 int &danglingRawPtrFromLocal2() {
   std::optional<int> o;
   return o.value(); // expected-warning {{reference to stack memory associated with local variable 'o' returned}}
 }

 int &danglingRawPtrFromLocal3() {
   std::optional<int> o;
   return *o; // expected-warning {{reference to stack memory associated with local variable 'o' returned}}
 }

 const char *danglingRawPtrFromTemp() {
   return std::basic_string<char>().c_str(); // expected-warning {{returning address of local temporary object}}
 }

 std::unique_ptr<int> getUniquePtr();

 int *danglingUniquePtrFromTemp() {
   return getUniquePtr().get(); // expected-warning {{returning address of local temporary object}}
 }

 int *danglingUniquePtrFromTemp2() {
   return std::unique_ptr<int>().get(); // expected-warning {{returning address of local temporary object}}
 }

 void danglingReferenceFromTempOwner() {
   int &&r = *std::optional<int>();          // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
   int &&r2 = *std::optional<int>(5);        // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
   int &&r3 = std::optional<int>(5).value(); // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
   int &r4 = std::vector<int>().at(3);       // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
 }

 std::vector<int> getTempVec();
 std::optional<std::vector<int>> getTempOptVec();

 void testLoops() {
   for (auto i : getTempVec()) // ok
     ;
   for (auto i : *getTempOptVec()) // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
     ;
 }

 int &usedToBeFalsePositive(std::vector<int> &v) {
   std::vector<int>::iterator it = v.begin();
   int& value = *it;
   return value; // ok
 }

 int &doNotFollowReferencesForLocalOwner() {
   std::unique_ptr<int> localOwner;
   int &p = *localOwner.get();
   // In real world code localOwner is usually moved here.
   return p; // ok
 }

 const char *trackThroughMultiplePointer() {
   return std::basic_string_view<char>(std::basic_string<char>()).begin(); // expected-warning {{returning address of local temporary object}}
 }

 struct X {
   X(std::unique_ptr<int> up) :
     pointee(*up), pointee2(up.get()), pointer(std::move(up)) {}
   int &pointee;
   int *pointee2;
   std::unique_ptr<int> pointer;
 };

 std::vector<int>::iterator getIt();
 std::vector<int> getVec();

 const int &handleGslPtrInitsThroughReference() {
   const auto &it = getIt(); // Ok, it is lifetime extended.
   return *it;
 }

 void handleGslPtrInitsThroughReference2() {
   const std::vector<int> &v = getVec();
   const int *val = v.data(); // Ok, it is lifetime extended.
 }

 void handleTernaryOperator(bool cond) {
     std::basic_string<char> def;
     std::basic_string_view<char> v = cond ? def : ""; // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
 }

 std::reference_wrapper<int> danglingPtrFromNonOwnerLocal() {
   int i = 5;
   return i; // TODO
 }

 std::reference_wrapper<int> danglingPtrFromNonOwnerLocal2() {
   int i = 5;
   return std::ref(i); // TODO
 }

 std::reference_wrapper<int> danglingPtrFromNonOwnerLocal3() {
   int i = 5;
   return std::reference_wrapper<int>(i); // TODO
 }

 std::reference_wrapper<Unannotated> danglingPtrFromNonOwnerLocal4() {
   Unannotated i;
   return std::reference_wrapper<Unannotated>(i); // TODO
 }

 std::reference_wrapper<Unannotated> danglingPtrFromNonOwnerLocal5() {
   Unannotated i;
   return std::ref(i); // TODO
 }

 int *returnPtrToLocalArray() {
   int a[5];
   return std::begin(a); // TODO
 }

 struct ptr_wrapper {
   std::vector<int>::iterator member;
 };

 ptr_wrapper getPtrWrapper();

 std::vector<int>::iterator returnPtrFromWrapper() {
   ptr_wrapper local = getPtrWrapper();
   return local.member;
 }

 std::vector<int>::iterator returnPtrFromWrapperThroughRef() {
   ptr_wrapper local = getPtrWrapper();
   ptr_wrapper &local2 = local;
   return local2.member;
 }

 std::vector<int>::iterator returnPtrFromWrapperThroughRef2() {
   ptr_wrapper local = getPtrWrapper();
   std::vector<int>::iterator &local2 = local.member;
   return local2;
 }

 void checkPtrMemberFromAggregate() {
   std::vector<int>::iterator local = getPtrWrapper().member; // OK.
 }

 std::vector<int>::iterator doNotInterferWithUnannotated() {
   Unannotated value;
   // Conservative choice for now. Probably not ok, but we do not warn.
   return std::begin(value);
 }

 std::vector<int>::iterator doNotInterferWithUnannotated2() {
   Unannotated value;
   return value;
 }

 std::vector<int>::iterator supportDerefAddrofChain(int a, std::vector<int>::iterator value) {
   switch (a)  {
     default:
       return value;
     case 1:
       return *&value;
     case 2:
       return *&*&value;
     case 3:
       return *&*&*&value;
   }
 }

 int &supportDerefAddrofChain2(int a, std::vector<int>::iterator value) {
   switch (a)  {
     default:
       return *value;
     case 1:
       return **&value;
     case 2:
       return **&*&value;
     case 3:
       return **&*&*&value;
   }
 }

 int *supportDerefAddrofChain3(int a, std::vector<int>::iterator value) {
   switch (a)  {
     default:
       return &*value;
     case 1:
       return &*&*value;
     case 2:
       return &*&**&value;
     case 3:
       return &*&**&*&value;
   }
 }

 MyIntPointer handleDerivedToBaseCast1(MySpecialIntPointer ptr) {
   return ptr;
 }

 MyIntPointer handleDerivedToBaseCast2(MyOwnerIntPointer ptr) {
   return ptr; // expected-warning {{address of stack memory associated with parameter 'ptr' returned}}
 }

 std::vector<int>::iterator noFalsePositiveWithVectorOfPointers() {
   std::vector<std::vector<int>::iterator> iters;
   return iters.at(0);
 }

 void testForBug49342()
 {
   auto it = std::iter<char>{} - 2; // Used to be false positive.
 }
	// RUN: %clang_cc1 -fsyntax-only -Wdangling -Wdangling-field -Wreturn-stack-address -verify %s
	struct [[gsl::Owner(int)]] MyIntOwner {
	MyIntOwner();
	int &operator*();
	};

	struct [[gsl::Pointer(int)]] MyIntPointer {
	MyIntPointer(int *p = nullptr);
	// Conversion operator and constructor conversion will result in two
	// different ASTs. The former is tested with another owner and
	// pointer type.
	MyIntPointer(const MyIntOwner &);
	int &operator*();
	MyIntOwner toOwner();
	};

	struct MySpecialIntPointer : MyIntPointer {
	};

	// We did see examples in the wild when a derived class changes
	// the ownership model. So we have a test for it.
	struct [[gsl::Owner(int)]] MyOwnerIntPointer : MyIntPointer {
	};

	struct [[gsl::Pointer(long)]] MyLongPointerFromConversion {
	MyLongPointerFromConversion(long *p = nullptr);
	long &operator*();
	};

	struct [[gsl::Owner(long)]] MyLongOwnerWithConversion {
	MyLongOwnerWithConversion();
	operator MyLongPointerFromConversion();
	long &operator*();
	MyIntPointer releaseAsMyPointer();
	long *releaseAsRawPointer();
	};

	void danglingHeapObject() {
	new MyLongPointerFromConversion(MyLongOwnerWithConversion{}); // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
	new MyIntPointer(MyIntOwner{}); // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
	}

	void intentionalFalseNegative() {
	int i;
	MyIntPointer p{&i};
	// In this case we do not have enough information in a statement local
	// analysis to detect the problem.
	new MyIntPointer(p);
	new MyIntPointer(MyIntPointer{p});
	}

	MyIntPointer ownershipTransferToMyPointer() {
	MyLongOwnerWithConversion t;
	return t.releaseAsMyPointer(); // ok
	}

	long *ownershipTransferToRawPointer() {
	MyLongOwnerWithConversion t;
	return t.releaseAsRawPointer(); // ok
	}

	struct Y {
	int a[4];
	};

	void dangligGslPtrFromTemporary() {
	MyIntPointer p = Y{}.a; // TODO
	(void)p;
	}

	struct DanglingGslPtrField {
	MyIntPointer p; // expected-note {{pointer member declared here}}
	MyLongPointerFromConversion p2; // expected-note {{pointer member declared here}}
	DanglingGslPtrField(int i) : p(&i) {} // TODO
	DanglingGslPtrField() : p2(MyLongOwnerWithConversion{}) {} // expected-warning {{initializing pointer member 'p2' to point to a temporary object whose lifetime is shorter than the lifetime of the constructed object}}
	DanglingGslPtrField(double) : p(MyIntOwner{}) {} // expected-warning {{initializing pointer member 'p' to point to a temporary object whose lifetime is shorter than the lifetime of the constructed object}}
	};

	MyIntPointer danglingGslPtrFromLocal() {
	int j;
	return &j; // TODO
	}

	MyIntPointer returningLocalPointer() {
	MyIntPointer localPointer;
	return localPointer; // ok
	}

	MyIntPointer daglingGslPtrFromLocalOwner() {
	MyIntOwner localOwner;
	return localOwner; // expected-warning {{address of stack memory associated with local variable 'localOwner' returned}}
	}

	MyLongPointerFromConversion daglingGslPtrFromLocalOwnerConv() {
	MyLongOwnerWithConversion localOwner;
	return localOwner; // expected-warning {{address of stack memory associated with local variable 'localOwner' returned}}
	}

	MyIntPointer danglingGslPtrFromTemporary() {
	return MyIntOwner{}; // expected-warning {{returning address of local temporary object}}
	}

	MyIntOwner makeTempOwner();

	MyIntPointer danglingGslPtrFromTemporary2() {
	return makeTempOwner(); // expected-warning {{returning address of local temporary object}}
	}

	MyLongPointerFromConversion danglingGslPtrFromTemporaryConv() {
	return MyLongOwnerWithConversion{}; // expected-warning {{returning address of local temporary object}}
	}

	int *noFalsePositive(MyIntOwner &o) {
	MyIntPointer p = o;
	return &*p; // ok
	}

	MyIntPointer global;
	MyLongPointerFromConversion global2;

	void initLocalGslPtrWithTempOwner() {
	MyIntPointer p = MyIntOwner{}; // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
	p = MyIntOwner{}; // TODO ?
	global = MyIntOwner{}; // TODO ?
	MyLongPointerFromConversion p2 = MyLongOwnerWithConversion{}; // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
	p2 = MyLongOwnerWithConversion{}; // TODO ?
	global2 = MyLongOwnerWithConversion{}; // TODO ?
	}

	namespace __gnu_cxx {
	template <typename T>
	struct basic_iterator {
	basic_iterator operator++();
	T& operator*() const;
	T* operator->() const;
	};

	template<typename T>
	bool operator!=(basic_iterator<T>, basic_iterator<T>);
	}

	namespace std {
	template<typename T> struct remove_reference { typedef T type; };
	template<typename T> struct remove_reference<T &> { typedef T type; };
	template<typename T> struct remove_reference<T &&> { typedef T type; };

	template<typename T>
	typename remove_reference<T>::type &&move(T &&t) noexcept;

	template <typename C>
	auto data(const C &c) -> decltype(c.data());

	template <typename C>
	auto begin(C &c) -> decltype(c.begin());

	template<typename T, int N>
	T *begin(T (&array)[N]);

	template <typename T>
	struct vector {
	typedef __gnu_cxx::basic_iterator<T> iterator;
	iterator begin();
	iterator end();
	const T *data() const;
	T &at(int n);
	};

	template<typename T>
	struct basic_string_view {
	basic_string_view(const T *);
	const T *begin() const;
	};

	template<class _Mystr> struct iter {
	iter& operator-=(int);

	iter operator-(int _Off) const {
	iter _Tmp = *this;
	return _Tmp -= _Off;
	}
	};

	template<typename T>
	struct basic_string {
	basic_string();
	basic_string(const T *);
	const T *c_str() const;
	operator basic_string_view<T> () const;
	using const_iterator = iter<T>;
	};


	template<typename T>
	struct unique_ptr {
	T &operator*();
	T *get() const;
	};

	template<typename T>
	struct optional {
	optional();
	optional(const T&);
	T &operator*() &;
	T &&operator*() &&;
	T &value() &;
	T &&value() &&;
	};

	template<typename T>
	struct stack {
	T &top();
	};

	struct any {};

	template<typename T>
	T any_cast(const any& operand);

	template<typename T>
	struct reference_wrapper {
	template<typename U>
	reference_wrapper(U &&);
	};

	template<typename T>
	reference_wrapper<T> ref(T& t) noexcept;
	}

	struct Unannotated {
	typedef std::vector<int>::iterator iterator;
	iterator begin();
	operator iterator() const;
	};

	void modelIterators() {
	std::vector<int>::iterator it = std::vector<int>().begin(); // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
	(void)it;
	}

	std::vector<int>::iterator modelIteratorReturn() {
	return std::vector<int>().begin(); // expected-warning {{returning address of local temporary object}}
	}

	const int *modelFreeFunctions() {
	return std::data(std::vector<int>()); // expected-warning {{returning address of local temporary object}}
	}

	int &modelAnyCast() {
	return std::any_cast<int&>(std::any{}); // expected-warning {{returning reference to local temporary object}}
	}

	int modelAnyCast2() {
	return std::any_cast<int>(std::any{}); // ok
	}

	int modelAnyCast3() {
	return std::any_cast<int&>(std::any{}); // ok
	}

	const char *danglingRawPtrFromLocal() {
	std::basic_string<char> s;
	return s.c_str(); // expected-warning {{address of stack memory associated with local variable 's' returned}}
	}

	int &danglingRawPtrFromLocal2() {
	std::optional<int> o;
	return o.value(); // expected-warning {{reference to stack memory associated with local variable 'o' returned}}
	}

	int &danglingRawPtrFromLocal3() {
	std::optional<int> o;
	return *o; // expected-warning {{reference to stack memory associated with local variable 'o' returned}}
	}

	const char *danglingRawPtrFromTemp() {
	return std::basic_string<char>().c_str(); // expected-warning {{returning address of local temporary object}}
	}

	std::unique_ptr<int> getUniquePtr();

	int *danglingUniquePtrFromTemp() {
	return getUniquePtr().get(); // expected-warning {{returning address of local temporary object}}
	}

	int *danglingUniquePtrFromTemp2() {
	return std::unique_ptr<int>().get(); // expected-warning {{returning address of local temporary object}}
	}

	void danglingReferenceFromTempOwner() {
	int &&r = *std::optional<int>(); // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
	int &&r2 = *std::optional<int>(5); // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
	int &&r3 = std::optional<int>(5).value(); // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
	int &r4 = std::vector<int>().at(3); // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
	}

	std::vector<int> getTempVec();
	std::optional<std::vector<int>> getTempOptVec();

	void testLoops() {
	for (auto i : getTempVec()) // ok
	;
	for (auto i : *getTempOptVec()) // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
	;
	}

	int &usedToBeFalsePositive(std::vector<int> &v) {
	std::vector<int>::iterator it = v.begin();
	int& value = *it;
	return value; // ok
	}

	int &doNotFollowReferencesForLocalOwner() {
	std::unique_ptr<int> localOwner;
	int &p = *localOwner.get();
	// In real world code localOwner is usually moved here.
	return p; // ok
	}

	const char *trackThroughMultiplePointer() {
	return std::basic_string_view<char>(std::basic_string<char>()).begin(); // expected-warning {{returning address of local temporary object}}
	}

	struct X {
	X(std::unique_ptr<int> up) :
	pointee(*up), pointee2(up.get()), pointer(std::move(up)) {}
	int &pointee;
	int *pointee2;
	std::unique_ptr<int> pointer;
	};

	std::vector<int>::iterator getIt();
	std::vector<int> getVec();

	const int &handleGslPtrInitsThroughReference() {
	const auto &it = getIt(); // Ok, it is lifetime extended.
	return *it;
	}

	void handleGslPtrInitsThroughReference2() {
	const std::vector<int> &v = getVec();
	const int *val = v.data(); // Ok, it is lifetime extended.
	}

	void handleTernaryOperator(bool cond) {
	std::basic_string<char> def;
	std::basic_string_view<char> v = cond ? def : ""; // expected-warning {{object backing the pointer will be destroyed at the end of the full-expression}}
	}

	std::reference_wrapper<int> danglingPtrFromNonOwnerLocal() {
	int i = 5;
	return i; // TODO
	}

	std::reference_wrapper<int> danglingPtrFromNonOwnerLocal2() {
	int i = 5;
	return std::ref(i); // TODO
	}

	std::reference_wrapper<int> danglingPtrFromNonOwnerLocal3() {
	int i = 5;
	return std::reference_wrapper<int>(i); // TODO
	}

	std::reference_wrapper<Unannotated> danglingPtrFromNonOwnerLocal4() {
	Unannotated i;
	return std::reference_wrapper<Unannotated>(i); // TODO
	}

	std::reference_wrapper<Unannotated> danglingPtrFromNonOwnerLocal5() {
	Unannotated i;
	return std::ref(i); // TODO
	}

	int *returnPtrToLocalArray() {
	int a[5];
	return std::begin(a); // TODO
	}

	struct ptr_wrapper {
	std::vector<int>::iterator member;
	};

	ptr_wrapper getPtrWrapper();

	std::vector<int>::iterator returnPtrFromWrapper() {
	ptr_wrapper local = getPtrWrapper();
	return local.member;
	}

	std::vector<int>::iterator returnPtrFromWrapperThroughRef() {
	ptr_wrapper local = getPtrWrapper();
	ptr_wrapper &local2 = local;
	return local2.member;
	}

	std::vector<int>::iterator returnPtrFromWrapperThroughRef2() {
	ptr_wrapper local = getPtrWrapper();
	std::vector<int>::iterator &local2 = local.member;
	return local2;
	}

	void checkPtrMemberFromAggregate() {
	std::vector<int>::iterator local = getPtrWrapper().member; // OK.
	}

	std::vector<int>::iterator doNotInterferWithUnannotated() {
	Unannotated value;
	// Conservative choice for now. Probably not ok, but we do not warn.
	return std::begin(value);
	}

	std::vector<int>::iterator doNotInterferWithUnannotated2() {
	Unannotated value;
	return value;
	}

	std::vector<int>::iterator supportDerefAddrofChain(int a, std::vector<int>::iterator value) {
	switch (a) {
	default:
	return value;
	case 1:
	return *&value;
	case 2:
	return &&value;
	case 3:
	return &&*&value;
	}
	}

	int &supportDerefAddrofChain2(int a, std::vector<int>::iterator value) {
	switch (a) {
	default:
	return *value;
	case 1:
	return **&value;
	case 2:
	return *&&value;
	case 3:
	return *&&*&value;
	}
	}

	int *supportDerefAddrofChain3(int a, std::vector<int>::iterator value) {
	switch (a) {
	default:
	return &*value;
	case 1:
	return &&value;
	case 2:
	return &&*&value;
	case 3:
	return &&&&value;
	}
	}

	MyIntPointer handleDerivedToBaseCast1(MySpecialIntPointer ptr) {
	return ptr;
	}

	MyIntPointer handleDerivedToBaseCast2(MyOwnerIntPointer ptr) {
	return ptr; // expected-warning {{address of stack memory associated with parameter 'ptr' returned}}
	}

	std::vector<int>::iterator noFalsePositiveWithVectorOfPointers() {
	std::vector<std::vector<int>::iterator> iters;
	return iters.at(0);
	}

	void testForBug49342()
	{
	auto it = std::iter<char>{} - 2; // Used to be false positive.
	}