gcc/testsuite/g++.dg/torture/pr65694.C - gcc - Git at Google

 /* { dg-do compile } */
 /* { dg-options "-Wno-sign-compare -Wno-return-type -Wno-overflow" } */
 /* { dg-additional-options "-mthumb" { target arm_thumb2_ok } } */

 struct A {
   enum { __value };
 };
 template <class _T1> struct B { _T1 first; };
 template <typename _Iterator, bool> struct C {
   typedef typename _Iterator::iterator_type iterator_type;
   static iterator_type _S_base(_Iterator p1) { return p1.base(); }
 };
 template <typename _RandomAccessIterator>
 typename _RandomAccessIterator::difference_type
 __distance(_RandomAccessIterator p1, _RandomAccessIterator p2, int) {
   return p2 - p1;
 }

 template <typename _InputIterator>
 typename _InputIterator::difference_type distance(_InputIterator p1,
                                                   _InputIterator p2) {
   return __distance(p1, p2, 0);
 }

 template <typename _Iterator, typename> class D {
   _Iterator _M_current;

 public:
   typedef _Iterator iterator_type;
   typedef int difference_type;
   _Iterator base() { return _M_current; }
 };

 template <typename _Iterator, typename _Container>
 typename D<_Iterator, _Container>::difference_type
 operator-(D<_Iterator, _Container> p1, D<_Iterator, _Container> p2) {
   return p1.base() - p2.base();
 }

 struct F {
   static unsigned short *__copy_m(unsigned short *p1, unsigned short *p2,
                                   unsigned short *p3) {
     int a = p2 - p1;
     if (a)
       __builtin_memmove(p3, p1, a);
     return p3 + a;
   }
 };
 class G {
 public:
   void allocate(int p1) {
     if (p1 > max_size())
       operator new(sizeof(short));
   }
   unsigned max_size() { return -1 / sizeof(short); }
 };

 template <typename> class L : public G {};

 struct H {
   static unsigned short *allocate(int p1) {
     L<short> d;
     d.allocate(p1);
   }
 };
 struct I {
   template <typename _InputIterator, typename _ForwardIterator>
   static _ForwardIterator __uninit_copy(_InputIterator p1, _InputIterator p2,
                                         _ForwardIterator p3) {
     return copy(p1, p2, p3);
   }
 };
 struct J {
   typedef unsigned short *pointer;
   struct K {
     unsigned short *_M_start;
     unsigned short *_M_finish;
   };
   J();
   J(int p1, int) { _M_create_storage(p1); }
   K _M_impl;
   pointer _M_allocate(unsigned p1) { p1 ? H::allocate(p1) : pointer(); }
   void _M_create_storage(int p1) { _M_allocate(p1); }
 };

 C<D<unsigned short *, int>, 1>::iterator_type
 __miter_base(D<unsigned short *, int> p1) {
   return C<D<unsigned short *, int>, 1>::_S_base(p1);
 }

 template <bool, typename _II, typename _OI>
 _OI __copy_move_a(_II p1, _II p2, _OI p3) {
   return F::__copy_m(p1, p2, p3);
 }

 template <bool _IsMove, typename _II, typename _OI>
 _OI __copy_move_a2(_II p1, _II p2, _OI p3) {
   return __copy_move_a<_IsMove>(p1, p2, p3);
 }

 template <typename _II, typename _OI> _OI copy(_II p1, _II p2, _OI p3) {
   C<D<unsigned short *, int>, 1>::iterator_type b, c = __miter_base(p1);
   b = __miter_base(p2);
   return __copy_move_a2<A::__value>(c, b, p3);
 }

 template <typename _InputIterator, typename _ForwardIterator>
 _ForwardIterator uninitialized_copy(_InputIterator p1, _InputIterator p2,
                                     _ForwardIterator p3) {
   return I::__uninit_copy(p1, p2, p3);
 }

 template <typename _InputIterator, typename _ForwardIterator, typename _Tp>
 _ForwardIterator __uninitialized_copy_a(_InputIterator p1, _InputIterator p2,
                                         _ForwardIterator p3, L<_Tp>) {
   return uninitialized_copy(p1, p2, p3);
 }

 class M : J {
   J _Base;

 public:
   M();
   M(int p1, int p2 = int()) : _Base(p1, p2) {}
   M(D<unsigned short *, int> p1, D<unsigned short *, int> p2) {
     _M_initialize_dispatch(p1, p2, int());
   }
   D<pointer, int> begin();
   D<pointer, int> end();
   int size() { return _M_impl._M_finish - _M_impl._M_start; }
   void _M_initialize_dispatch(D<unsigned short *, int> p1,
                               D<unsigned short *, int> p2, int) {
     L<short> e;
     int f = distance(p1, p2);
     _M_impl._M_start = _M_allocate(f);
     _M_impl._M_finish = __uninitialized_copy_a(p1, p2, _M_impl._M_start, e);
   }
 };

 B<M> g, h;
 void twoMeans() {
   M i(g.first.begin(), h.first.end());
   M(i.size());
 }
	/* { dg-do compile } */
	/* { dg-options "-Wno-sign-compare -Wno-return-type -Wno-overflow" } */
	/* { dg-additional-options "-mthumb" { target arm_thumb2_ok } } */

	struct A {
	enum { __value };
	};
	template <class _T1> struct B { _T1 first; };
	template <typename _Iterator, bool> struct C {
	typedef typename _Iterator::iterator_type iterator_type;
	static iterator_type _S_base(_Iterator p1) { return p1.base(); }
	};
	template <typename _RandomAccessIterator>
	typename _RandomAccessIterator::difference_type
	__distance(_RandomAccessIterator p1, _RandomAccessIterator p2, int) {
	return p2 - p1;
	}

	template <typename _InputIterator>
	typename _InputIterator::difference_type distance(_InputIterator p1,
	_InputIterator p2) {
	return __distance(p1, p2, 0);
	}

	template <typename _Iterator, typename> class D {
	_Iterator _M_current;

	public:
	typedef _Iterator iterator_type;
	typedef int difference_type;
	_Iterator base() { return _M_current; }
	};

	template <typename _Iterator, typename _Container>
	typename D<_Iterator, _Container>::difference_type
	operator-(D<_Iterator, _Container> p1, D<_Iterator, _Container> p2) {
	return p1.base() - p2.base();
	}

	struct F {
	static unsigned short __copy_m(unsigned short p1, unsigned short *p2,
	unsigned short *p3) {
	int a = p2 - p1;
	if (a)
	__builtin_memmove(p3, p1, a);
	return p3 + a;
	}
	};
	class G {
	public:
	void allocate(int p1) {
	if (p1 > max_size())
	operator new(sizeof(short));
	}
	unsigned max_size() { return -1 / sizeof(short); }
	};

	template <typename> class L : public G {};

	struct H {
	static unsigned short *allocate(int p1) {
	L<short> d;
	d.allocate(p1);
	}
	};
	struct I {
	template <typename _InputIterator, typename _ForwardIterator>
	static _ForwardIterator __uninit_copy(_InputIterator p1, _InputIterator p2,
	_ForwardIterator p3) {
	return copy(p1, p2, p3);
	}
	};
	struct J {
	typedef unsigned short *pointer;
	struct K {
	unsigned short *_M_start;
	unsigned short *_M_finish;
	};
	J();
	J(int p1, int) { _M_create_storage(p1); }
	K _M_impl;
	pointer _M_allocate(unsigned p1) { p1 ? H::allocate(p1) : pointer(); }
	void _M_create_storage(int p1) { _M_allocate(p1); }
	};

	C<D<unsigned short *, int>, 1>::iterator_type
	__miter_base(D<unsigned short *, int> p1) {
	return C<D<unsigned short *, int>, 1>::_S_base(p1);
	}

	template <bool, typename _II, typename _OI>
	_OI __copy_move_a(_II p1, _II p2, _OI p3) {
	return F::__copy_m(p1, p2, p3);
	}

	template <bool _IsMove, typename _II, typename _OI>
	_OI __copy_move_a2(_II p1, _II p2, _OI p3) {
	return __copy_move_a<_IsMove>(p1, p2, p3);
	}

	template <typename _II, typename _OI> _OI copy(_II p1, _II p2, _OI p3) {
	C<D<unsigned short *, int>, 1>::iterator_type b, c = __miter_base(p1);
	b = __miter_base(p2);
	return __copy_move_a2<A::__value>(c, b, p3);
	}

	template <typename _InputIterator, typename _ForwardIterator>
	_ForwardIterator uninitialized_copy(_InputIterator p1, _InputIterator p2,
	_ForwardIterator p3) {
	return I::__uninit_copy(p1, p2, p3);
	}

	template <typename _InputIterator, typename _ForwardIterator, typename _Tp>
	_ForwardIterator __uninitialized_copy_a(_InputIterator p1, _InputIterator p2,
	_ForwardIterator p3, L<_Tp>) {
	return uninitialized_copy(p1, p2, p3);
	}

	class M : J {
	J _Base;

	public:
	M();
	M(int p1, int p2 = int()) : _Base(p1, p2) {}
	M(D<unsigned short , int> p1, D<unsigned short , int> p2) {
	_M_initialize_dispatch(p1, p2, int());
	}
	D<pointer, int> begin();
	D<pointer, int> end();
	int size() { return _M_impl._M_finish - _M_impl._M_start; }
	void _M_initialize_dispatch(D<unsigned short *, int> p1,
	D<unsigned short *, int> p2, int) {
	L<short> e;
	int f = distance(p1, p2);
	_M_impl._M_start = _M_allocate(f);
	_M_impl._M_finish = __uninitialized_copy_a(p1, p2, _M_impl._M_start, e);
	}
	};

	B<M> g, h;
	void twoMeans() {
	M i(g.first.begin(), h.first.end());
	M(i.size());
	}