test/Analysis/Inputs/system-header-simulator-cxx.h - third_party/swift-clang - Git at Google

 // Like the compiler, the static analyzer treats some functions differently if
 // they come from a system header -- for example, it is assumed that system
 // functions do not arbitrarily free() their parameters, and that some bugs
 // found in system headers cannot be fixed by the user and should be
 // suppressed.
 #pragma clang system_header

 typedef unsigned char uint8_t;

 typedef __typeof__(sizeof(int)) size_t;
 void *memmove(void *s1, const void *s2, size_t n);

 namespace std {
   template <class T1, class T2>
   struct pair {
     T1 first;
     T2 second;

     pair() : first(), second() {}
     pair(const T1 &a, const T2 &b) : first(a), second(b) {}

     template<class U1, class U2>
     pair(const pair<U1, U2> &other) : first(other.first), second(other.second) {}
   };

   typedef __typeof__(sizeof(int)) size_t;

   template<typename T>
   class vector {
     T *_start;
     T *_finish;
     T *_end_of_storage;
   public:
     vector() : _start(0), _finish(0), _end_of_storage(0) {}
     ~vector();

     size_t size() const {
       return size_t(_finish - _start);
     }

     void push_back();
     T pop_back();

     T &operator[](size_t n) {
       return _start[n];
     }

     const T &operator[](size_t n) const {
       return _start[n];
     }

     T *begin() { return _start; }
     const T *begin() const { return _start; }

     T *end() { return _finish; }
     const T *end() const { return _finish; }
   };

   class exception {
   public:
     exception() throw();
     virtual ~exception() throw();
     virtual const char *what() const throw() {
       return 0;
     }
   };

   class bad_alloc : public exception {
     public:
     bad_alloc() throw();
     bad_alloc(const bad_alloc&) throw();
     bad_alloc& operator=(const bad_alloc&) throw();
     virtual const char* what() const throw() {
       return 0;
     }
   };

   struct nothrow_t {};

   extern const nothrow_t nothrow;

   // libc++'s implementation
   template <class _E>
   class initializer_list
   {
     const _E* __begin_;
     size_t    __size_;

     initializer_list(const _E* __b, size_t __s)
       : __begin_(__b),
         __size_(__s)
     {}

   public:
     typedef _E        value_type;
     typedef const _E& reference;
     typedef const _E& const_reference;
     typedef size_t    size_type;

     typedef const _E* iterator;
     typedef const _E* const_iterator;

     initializer_list() : __begin_(0), __size_(0) {}

     size_t    size()  const {return __size_;}
     const _E* begin() const {return __begin_;}
     const _E* end()   const {return __begin_ + __size_;}
   };

   template <bool, class _Tp = void> struct enable_if {};
   template <class _Tp> struct enable_if<true, _Tp> {typedef _Tp type;};

   template <class _Tp, _Tp __v>
   struct integral_constant
   {
       static const _Tp      value = __v;
       typedef _Tp               value_type;
       typedef integral_constant type;

      operator value_type() const {return value;}

      value_type operator ()() const {return value;}
   };

   template <class _Tp, _Tp __v>
   const _Tp integral_constant<_Tp, __v>::value;

     template <class _Tp, class _Arg>
     struct is_trivially_assignable
       : integral_constant<bool, __is_trivially_assignable(_Tp, _Arg)>
     {
     };

   typedef integral_constant<bool,true>  true_type;
   typedef integral_constant<bool,false> false_type;

   template <class _Tp> struct is_const            : public false_type {};
   template <class _Tp> struct is_const<_Tp const> : public true_type {};

   template <class _Tp> struct  is_reference        : public false_type {};
   template <class _Tp> struct  is_reference<_Tp&>  : public true_type {};

   template <class _Tp, class _Up> struct  is_same           : public false_type {};
   template <class _Tp>            struct  is_same<_Tp, _Tp> : public true_type {};

   template <class _Tp, bool = is_const<_Tp>::value || is_reference<_Tp>::value    >
   struct __add_const             {typedef _Tp type;};

   template <class _Tp>
   struct __add_const<_Tp, false> {typedef const _Tp type;};

   template <class _Tp> struct add_const {typedef typename __add_const<_Tp>::type type;};

   template <class _Tp> struct  remove_const            {typedef _Tp type;};
   template <class _Tp> struct  remove_const<const _Tp> {typedef _Tp type;};

   template <class _Tp> struct  add_lvalue_reference    {typedef _Tp& type;};

   template <class _Tp> struct is_trivially_copy_assignable
       : public is_trivially_assignable<typename add_lvalue_reference<_Tp>::type,
             typename add_lvalue_reference<typename add_const<_Tp>::type>::type> {};

     template<class InputIter, class OutputIter>
     OutputIter __copy(InputIter II, InputIter IE, OutputIter OI) {
       while (II != IE)
         *OI++ = *II++;

       return OI;
     }

   template <class _Tp, class _Up>
   inline
   typename enable_if
   <
       is_same<typename remove_const<_Tp>::type, _Up>::value &&
       is_trivially_copy_assignable<_Up>::value,
       _Up*
   >::type __copy(_Tp* __first, _Tp* __last, _Up* __result) {
       size_t __n = __last - __first;

       if (__n > 0)
         memmove(__result, __first, __n * sizeof(_Up));

       return __result + __n;
     }

   template<class InputIter, class OutputIter>
   OutputIter copy(InputIter II, InputIter IE, OutputIter OI) {
     return __copy(II, IE, OI);
   }

   template <class _BidirectionalIterator, class _OutputIterator>
   inline
   _OutputIterator
   __copy_backward(_BidirectionalIterator __first, _BidirectionalIterator __last,
                   _OutputIterator __result)
   {
       while (__first != __last)
           *--__result = *--__last;
       return __result;
   }

   template <class _Tp, class _Up>
   inline
   typename enable_if
   <
       is_same<typename remove_const<_Tp>::type, _Up>::value &&
       is_trivially_copy_assignable<_Up>::value,
       _Up*
   >::type __copy_backward(_Tp* __first, _Tp* __last, _Up* __result) {
       size_t __n = __last - __first;

     if (__n > 0)
     {
         __result -= __n;
         memmove(__result, __first, __n * sizeof(_Up));
     }
     return __result;
   }

   template<class InputIter, class OutputIter>
   OutputIter copy_backward(InputIter II, InputIter IE, OutputIter OI) {
     return __copy_backward(II, IE, OI);
   }

   struct input_iterator_tag { };
   struct output_iterator_tag { };
   struct forward_iterator_tag : public input_iterator_tag { };
   struct bidirectional_iterator_tag : public forward_iterator_tag { };
   struct random_access_iterator_tag : public bidirectional_iterator_tag { };

 }

 void* operator new(std::size_t, const std::nothrow_t&) throw();
 void* operator new[](std::size_t, const std::nothrow_t&) throw();
 void operator delete(void*, const std::nothrow_t&) throw();
 void operator delete[](void*, const std::nothrow_t&) throw();

 void* operator new (std::size_t size, void* ptr) throw() { return ptr; };
 void* operator new[] (std::size_t size, void* ptr) throw() { return ptr; };
 void operator delete (void* ptr, void*) throw() {};
 void operator delete[] (void* ptr, void*) throw() {};

 namespace __cxxabiv1 {
 extern "C" {
 extern char *__cxa_demangle(const char *mangled_name,
                             char *output_buffer,
                             size_t *length,
                             int *status);
 }}
 namespace abi = __cxxabiv1;
	// Like the compiler, the static analyzer treats some functions differently if
	// they come from a system header -- for example, it is assumed that system
	// functions do not arbitrarily free() their parameters, and that some bugs
	// found in system headers cannot be fixed by the user and should be
	// suppressed.
	#pragma clang system_header

	typedef unsigned char uint8_t;

	typedef __typeof__(sizeof(int)) size_t;
	void memmove(void s1, const void *s2, size_t n);

	namespace std {
	template <class T1, class T2>
	struct pair {
	T1 first;
	T2 second;

	pair() : first(), second() {}
	pair(const T1 &a, const T2 &b) : first(a), second(b) {}

	template<class U1, class U2>
	pair(const pair<U1, U2> &other) : first(other.first), second(other.second) {}
	};

	typedef __typeof__(sizeof(int)) size_t;

	template<typename T>
	class vector {
	T *_start;
	T *_finish;
	T *_end_of_storage;
	public:
	vector() : _start(0), _finish(0), _end_of_storage(0) {}
	~vector();

	size_t size() const {
	return size_t(_finish - _start);
	}

	void push_back();
	T pop_back();

	T &operator[](size_t n) {
	return _start[n];
	}

	const T &operator[](size_t n) const {
	return _start[n];
	}

	T *begin() { return _start; }
	const T *begin() const { return _start; }

	T *end() { return _finish; }
	const T *end() const { return _finish; }
	};

	class exception {
	public:
	exception() throw();
	virtual ~exception() throw();
	virtual const char *what() const throw() {
	return 0;
	}
	};

	class bad_alloc : public exception {
	public:
	bad_alloc() throw();
	bad_alloc(const bad_alloc&) throw();
	bad_alloc& operator=(const bad_alloc&) throw();
	virtual const char* what() const throw() {
	return 0;
	}
	};

	struct nothrow_t {};

	extern const nothrow_t nothrow;

	// libc++'s implementation
	template <class _E>
	class initializer_list
	{
	const _E* __begin_;
	size_t __size_;

	initializer_list(const _E* __b, size_t __s)
	: __begin_(__b),
	__size_(__s)
	{}

	public:
	typedef _E value_type;
	typedef const _E& reference;
	typedef const _E& const_reference;
	typedef size_t size_type;

	typedef const _E* iterator;
	typedef const _E* const_iterator;

	initializer_list() : __begin_(0), __size_(0) {}

	size_t size() const {return __size_;}
	const _E* begin() const {return __begin_;}
	const _E* end() const {return __begin_ + __size_;}
	};

	template <bool, class _Tp = void> struct enable_if {};
	template <class _Tp> struct enable_if<true, _Tp> {typedef _Tp type;};

	template <class _Tp, _Tp __v>
	struct integral_constant
	{
	static const _Tp value = __v;
	typedef _Tp value_type;
	typedef integral_constant type;

	operator value_type() const {return value;}

	value_type operator ()() const {return value;}
	};

	template <class _Tp, _Tp __v>
	const _Tp integral_constant<_Tp, __v>::value;

	template <class _Tp, class _Arg>
	struct is_trivially_assignable
	: integral_constant<bool, __is_trivially_assignable(_Tp, _Arg)>
	{
	};

	typedef integral_constant<bool,true> true_type;
	typedef integral_constant<bool,false> false_type;

	template <class _Tp> struct is_const : public false_type {};
	template <class _Tp> struct is_const<_Tp const> : public true_type {};

	template <class _Tp> struct is_reference : public false_type {};
	template <class _Tp> struct is_reference<_Tp&> : public true_type {};

	template <class _Tp, class _Up> struct is_same : public false_type {};
	template <class _Tp> struct is_same<_Tp, _Tp> : public true_type {};

	template <class _Tp, bool = is_const<_Tp>::value \|\| is_reference<_Tp>::value >
	struct __add_const {typedef _Tp type;};

	template <class _Tp>
	struct __add_const<_Tp, false> {typedef const _Tp type;};

	template <class _Tp> struct add_const {typedef typename __add_const<_Tp>::type type;};

	template <class _Tp> struct remove_const {typedef _Tp type;};
	template <class _Tp> struct remove_const<const _Tp> {typedef _Tp type;};

	template <class _Tp> struct add_lvalue_reference {typedef _Tp& type;};

	template <class _Tp> struct is_trivially_copy_assignable
	: public is_trivially_assignable<typename add_lvalue_reference<_Tp>::type,
	typename add_lvalue_reference<typename add_const<_Tp>::type>::type> {};

	template<class InputIter, class OutputIter>
	OutputIter __copy(InputIter II, InputIter IE, OutputIter OI) {
	while (II != IE)
	OI++ = II++;

	return OI;
	}

	template <class _Tp, class _Up>
	inline
	typename enable_if
	<
	is_same<typename remove_const<_Tp>::type, _Up>::value &&
	is_trivially_copy_assignable<_Up>::value,
	_Up*
	>::type __copy(_Tp* __first, _Tp* __last, _Up* __result) {
	size_t __n = __last - __first;

	if (__n > 0)
	memmove(__result, __first, __n * sizeof(_Up));

	return __result + __n;
	}

	template<class InputIter, class OutputIter>
	OutputIter copy(InputIter II, InputIter IE, OutputIter OI) {
	return __copy(II, IE, OI);
	}

	template <class _BidirectionalIterator, class _OutputIterator>
	inline
	_OutputIterator
	__copy_backward(_BidirectionalIterator __first, _BidirectionalIterator __last,
	_OutputIterator __result)
	{
	while (__first != __last)
	--__result = --__last;
	return __result;
	}

	template <class _Tp, class _Up>
	inline
	typename enable_if
	<
	is_same<typename remove_const<_Tp>::type, _Up>::value &&
	is_trivially_copy_assignable<_Up>::value,
	_Up*
	>::type __copy_backward(_Tp* __first, _Tp* __last, _Up* __result) {
	size_t __n = __last - __first;

	if (__n > 0)
	{
	__result -= __n;
	memmove(__result, __first, __n * sizeof(_Up));
	}
	return __result;
	}

	template<class InputIter, class OutputIter>
	OutputIter copy_backward(InputIter II, InputIter IE, OutputIter OI) {
	return __copy_backward(II, IE, OI);
	}

	struct input_iterator_tag { };
	struct output_iterator_tag { };
	struct forward_iterator_tag : public input_iterator_tag { };
	struct bidirectional_iterator_tag : public forward_iterator_tag { };
	struct random_access_iterator_tag : public bidirectional_iterator_tag { };

	}

	void* operator new(std::size_t, const std::nothrow_t&) throw();
	void* operator new[](std::size_t, const std::nothrow_t&) throw();
	void operator delete(void*, const std::nothrow_t&) throw();
	void operator delete[](void*, const std::nothrow_t&) throw();

	void* operator new (std::size_t size, void* ptr) throw() { return ptr; };
	void* operator new[] (std::size_t size, void* ptr) throw() { return ptr; };
	void operator delete (void* ptr, void*) throw() {};
	void operator delete[] (void* ptr, void*) throw() {};

	namespace __cxxabiv1 {
	extern "C" {
	extern char __cxa_demangle(const char mangled_name,
	char *output_buffer,
	size_t *length,
	int *status);
	}}
	namespace abi = __cxxabiv1;