libcxx/test/std/containers/associative/multimap/multimap.ops/upper_bound.pass.cpp - nest-cam/4320010/libcxx-ba865ff - Git at Google

 //===----------------------------------------------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is dual licensed under the MIT and the University of Illinois Open
 // Source Licenses. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 // <map>

 // class multimap

 //       iterator upper_bound(const key_type& k);
 // const_iterator upper_bound(const key_type& k) const;

 #include <map>
 #include <cassert>

 #include "min_allocator.h"
 #include "private_constructor.hpp"
 #include "is_transparent.h"

 int main()
 {
     typedef std::pair<const int, double> V;
     {
     typedef std::multimap<int, double> M;
     {
         typedef M::iterator R;
         V ar[] =
         {
             V(5, 1),
             V(5, 2),
             V(5, 3),
             V(7, 1),
             V(7, 2),
             V(7, 3),
             V(9, 1),
             V(9, 2),
             V(9, 3)
         };
         M m(ar, ar+sizeof(ar)/sizeof(ar[0]));
         R r = m.upper_bound(4);
         assert(r == m.begin());
         r = m.upper_bound(5);
         assert(r == next(m.begin(), 3));
         r = m.upper_bound(6);
         assert(r == next(m.begin(), 3));
         r = m.upper_bound(7);
         assert(r == next(m.begin(), 6));
         r = m.upper_bound(8);
         assert(r == next(m.begin(), 6));
         r = m.upper_bound(9);
         assert(r == next(m.begin(), 9));
         r = m.upper_bound(10);
         assert(r == m.end());
     }
     {
         typedef M::const_iterator R;
         V ar[] =
         {
             V(5, 1),
             V(5, 2),
             V(5, 3),
             V(7, 1),
             V(7, 2),
             V(7, 3),
             V(9, 1),
             V(9, 2),
             V(9, 3)
         };
         const M m(ar, ar+sizeof(ar)/sizeof(ar[0]));
         R r = m.upper_bound(4);
         assert(r == m.begin());
         r = m.upper_bound(5);
         assert(r == next(m.begin(), 3));
         r = m.upper_bound(6);
         assert(r == next(m.begin(), 3));
         r = m.upper_bound(7);
         assert(r == next(m.begin(), 6));
         r = m.upper_bound(8);
         assert(r == next(m.begin(), 6));
         r = m.upper_bound(9);
         assert(r == next(m.begin(), 9));
         r = m.upper_bound(10);
         assert(r == m.end());
     }
     }
 #if __cplusplus >= 201103L
     {
     typedef std::multimap<int, double, std::less<int>, min_allocator<std::pair<const int, double>>> M;
     {
         typedef M::iterator R;
         V ar[] =
         {
             V(5, 1),
             V(5, 2),
             V(5, 3),
             V(7, 1),
             V(7, 2),
             V(7, 3),
             V(9, 1),
             V(9, 2),
             V(9, 3)
         };
         M m(ar, ar+sizeof(ar)/sizeof(ar[0]));
         R r = m.upper_bound(4);
         assert(r == m.begin());
         r = m.upper_bound(5);
         assert(r == next(m.begin(), 3));
         r = m.upper_bound(6);
         assert(r == next(m.begin(), 3));
         r = m.upper_bound(7);
         assert(r == next(m.begin(), 6));
         r = m.upper_bound(8);
         assert(r == next(m.begin(), 6));
         r = m.upper_bound(9);
         assert(r == next(m.begin(), 9));
         r = m.upper_bound(10);
         assert(r == m.end());
     }
     {
         typedef M::const_iterator R;
         V ar[] =
         {
             V(5, 1),
             V(5, 2),
             V(5, 3),
             V(7, 1),
             V(7, 2),
             V(7, 3),
             V(9, 1),
             V(9, 2),
             V(9, 3)
         };
         const M m(ar, ar+sizeof(ar)/sizeof(ar[0]));
         R r = m.upper_bound(4);
         assert(r == m.begin());
         r = m.upper_bound(5);
         assert(r == next(m.begin(), 3));
         r = m.upper_bound(6);
         assert(r == next(m.begin(), 3));
         r = m.upper_bound(7);
         assert(r == next(m.begin(), 6));
         r = m.upper_bound(8);
         assert(r == next(m.begin(), 6));
         r = m.upper_bound(9);
         assert(r == next(m.begin(), 9));
         r = m.upper_bound(10);
         assert(r == m.end());
     }
     }
 #endif
 #if _LIBCPP_STD_VER > 11
     {
     typedef std::pair<const int, double> V;
     typedef std::multimap<int, double, std::less<>> M;
     typedef M::iterator R;
     V ar[] =
     {
         V(5, 1),
         V(5, 2),
         V(5, 3),
         V(7, 1),
         V(7, 2),
         V(7, 3),
         V(9, 1),
         V(9, 2),
         V(9, 3)
     };
     M m(ar, ar+sizeof(ar)/sizeof(ar[0]));
     R r = m.upper_bound(4);
     assert(r == m.begin());
     r = m.upper_bound(5);
     assert(r == next(m.begin(), 3));
     r = m.upper_bound(6);
     assert(r == next(m.begin(), 3));
     r = m.upper_bound(7);
     assert(r == next(m.begin(), 6));
     r = m.upper_bound(8);
     assert(r == next(m.begin(), 6));
     r = m.upper_bound(9);
     assert(r == next(m.begin(), 9));
     r = m.upper_bound(10);
     assert(r == m.end());

     r = m.upper_bound(C2Int(4));
     assert(r == m.begin());
     r = m.upper_bound(C2Int(5));
     assert(r == next(m.begin(), 3));
     r = m.upper_bound(C2Int(6));
     assert(r == next(m.begin(), 3));
     r = m.upper_bound(C2Int(7));
     assert(r == next(m.begin(), 6));
     r = m.upper_bound(C2Int(8));
     assert(r == next(m.begin(), 6));
     r = m.upper_bound(C2Int(9));
     assert(r == next(m.begin(), 9));
     r = m.upper_bound(C2Int(10));
     }

     {
     typedef PrivateConstructor PC;
     typedef std::multimap<PC, double, std::less<>> M;
     typedef M::iterator R;

     M m;
     m.insert ( std::make_pair<PC, double> ( PC::make(5), 1 ));
     m.insert ( std::make_pair<PC, double> ( PC::make(5), 2 ));
     m.insert ( std::make_pair<PC, double> ( PC::make(5), 3 ));
     m.insert ( std::make_pair<PC, double> ( PC::make(7), 1 ));
     m.insert ( std::make_pair<PC, double> ( PC::make(7), 2 ));
     m.insert ( std::make_pair<PC, double> ( PC::make(7), 3 ));
     m.insert ( std::make_pair<PC, double> ( PC::make(9), 1 ));
     m.insert ( std::make_pair<PC, double> ( PC::make(9), 2 ));
     m.insert ( std::make_pair<PC, double> ( PC::make(9), 3 ));

     R r = m.upper_bound(4);
     assert(r == m.begin());
     r = m.upper_bound(5);
     assert(r == next(m.begin(), 3));
     r = m.upper_bound(6);
     assert(r == next(m.begin(), 3));
     r = m.upper_bound(7);
     assert(r == next(m.begin(), 6));
     r = m.upper_bound(8);
     assert(r == next(m.begin(), 6));
     r = m.upper_bound(9);
     assert(r == next(m.begin(), 9));
     r = m.upper_bound(10);
     assert(r == m.end());
     }

 #endif
 }
	//===----------------------------------------------------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is dual licensed under the MIT and the University of Illinois Open
	// Source Licenses. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	// <map>

	// class multimap

	// iterator upper_bound(const key_type& k);
	// const_iterator upper_bound(const key_type& k) const;

	#include <map>
	#include <cassert>

	#include "min_allocator.h"
	#include "private_constructor.hpp"
	#include "is_transparent.h"

	int main()
	{
	typedef std::pair<const int, double> V;
	{
	typedef std::multimap<int, double> M;
	{
	typedef M::iterator R;
	V ar[] =
	{
	V(5, 1),
	V(5, 2),
	V(5, 3),
	V(7, 1),
	V(7, 2),
	V(7, 3),
	V(9, 1),
	V(9, 2),
	V(9, 3)
	};
	M m(ar, ar+sizeof(ar)/sizeof(ar[0]));
	R r = m.upper_bound(4);
	assert(r == m.begin());
	r = m.upper_bound(5);
	assert(r == next(m.begin(), 3));
	r = m.upper_bound(6);
	assert(r == next(m.begin(), 3));
	r = m.upper_bound(7);
	assert(r == next(m.begin(), 6));
	r = m.upper_bound(8);
	assert(r == next(m.begin(), 6));
	r = m.upper_bound(9);
	assert(r == next(m.begin(), 9));
	r = m.upper_bound(10);
	assert(r == m.end());
	}
	{
	typedef M::const_iterator R;
	V ar[] =
	{
	V(5, 1),
	V(5, 2),
	V(5, 3),
	V(7, 1),
	V(7, 2),
	V(7, 3),
	V(9, 1),
	V(9, 2),
	V(9, 3)
	};
	const M m(ar, ar+sizeof(ar)/sizeof(ar[0]));
	R r = m.upper_bound(4);
	assert(r == m.begin());
	r = m.upper_bound(5);
	assert(r == next(m.begin(), 3));
	r = m.upper_bound(6);
	assert(r == next(m.begin(), 3));
	r = m.upper_bound(7);
	assert(r == next(m.begin(), 6));
	r = m.upper_bound(8);
	assert(r == next(m.begin(), 6));
	r = m.upper_bound(9);
	assert(r == next(m.begin(), 9));
	r = m.upper_bound(10);
	assert(r == m.end());
	}
	}
	#if __cplusplus >= 201103L
	{
	typedef std::multimap<int, double, std::less<int>, min_allocator<std::pair<const int, double>>> M;
	{
	typedef M::iterator R;
	V ar[] =
	{
	V(5, 1),
	V(5, 2),
	V(5, 3),
	V(7, 1),
	V(7, 2),
	V(7, 3),
	V(9, 1),
	V(9, 2),
	V(9, 3)
	};
	M m(ar, ar+sizeof(ar)/sizeof(ar[0]));
	R r = m.upper_bound(4);
	assert(r == m.begin());
	r = m.upper_bound(5);
	assert(r == next(m.begin(), 3));
	r = m.upper_bound(6);
	assert(r == next(m.begin(), 3));
	r = m.upper_bound(7);
	assert(r == next(m.begin(), 6));
	r = m.upper_bound(8);
	assert(r == next(m.begin(), 6));
	r = m.upper_bound(9);
	assert(r == next(m.begin(), 9));
	r = m.upper_bound(10);
	assert(r == m.end());
	}
	{
	typedef M::const_iterator R;
	V ar[] =
	{
	V(5, 1),
	V(5, 2),
	V(5, 3),
	V(7, 1),
	V(7, 2),
	V(7, 3),
	V(9, 1),
	V(9, 2),
	V(9, 3)
	};
	const M m(ar, ar+sizeof(ar)/sizeof(ar[0]));
	R r = m.upper_bound(4);
	assert(r == m.begin());
	r = m.upper_bound(5);
	assert(r == next(m.begin(), 3));
	r = m.upper_bound(6);
	assert(r == next(m.begin(), 3));
	r = m.upper_bound(7);
	assert(r == next(m.begin(), 6));
	r = m.upper_bound(8);
	assert(r == next(m.begin(), 6));
	r = m.upper_bound(9);
	assert(r == next(m.begin(), 9));
	r = m.upper_bound(10);
	assert(r == m.end());
	}
	}
	#endif
	#if _LIBCPP_STD_VER > 11
	{
	typedef std::pair<const int, double> V;
	typedef std::multimap<int, double, std::less<>> M;
	typedef M::iterator R;
	V ar[] =
	{
	V(5, 1),
	V(5, 2),
	V(5, 3),
	V(7, 1),
	V(7, 2),
	V(7, 3),
	V(9, 1),
	V(9, 2),
	V(9, 3)
	};
	M m(ar, ar+sizeof(ar)/sizeof(ar[0]));
	R r = m.upper_bound(4);
	assert(r == m.begin());
	r = m.upper_bound(5);
	assert(r == next(m.begin(), 3));
	r = m.upper_bound(6);
	assert(r == next(m.begin(), 3));
	r = m.upper_bound(7);
	assert(r == next(m.begin(), 6));
	r = m.upper_bound(8);
	assert(r == next(m.begin(), 6));
	r = m.upper_bound(9);
	assert(r == next(m.begin(), 9));
	r = m.upper_bound(10);
	assert(r == m.end());

	r = m.upper_bound(C2Int(4));
	assert(r == m.begin());
	r = m.upper_bound(C2Int(5));
	assert(r == next(m.begin(), 3));
	r = m.upper_bound(C2Int(6));
	assert(r == next(m.begin(), 3));
	r = m.upper_bound(C2Int(7));
	assert(r == next(m.begin(), 6));
	r = m.upper_bound(C2Int(8));
	assert(r == next(m.begin(), 6));
	r = m.upper_bound(C2Int(9));
	assert(r == next(m.begin(), 9));
	r = m.upper_bound(C2Int(10));
	}

	{
	typedef PrivateConstructor PC;
	typedef std::multimap<PC, double, std::less<>> M;
	typedef M::iterator R;

	M m;
	m.insert ( std::make_pair<PC, double> ( PC::make(5), 1 ));
	m.insert ( std::make_pair<PC, double> ( PC::make(5), 2 ));
	m.insert ( std::make_pair<PC, double> ( PC::make(5), 3 ));
	m.insert ( std::make_pair<PC, double> ( PC::make(7), 1 ));
	m.insert ( std::make_pair<PC, double> ( PC::make(7), 2 ));
	m.insert ( std::make_pair<PC, double> ( PC::make(7), 3 ));
	m.insert ( std::make_pair<PC, double> ( PC::make(9), 1 ));
	m.insert ( std::make_pair<PC, double> ( PC::make(9), 2 ));
	m.insert ( std::make_pair<PC, double> ( PC::make(9), 3 ));

	R r = m.upper_bound(4);
	assert(r == m.begin());
	r = m.upper_bound(5);
	assert(r == next(m.begin(), 3));
	r = m.upper_bound(6);
	assert(r == next(m.begin(), 3));
	r = m.upper_bound(7);
	assert(r == next(m.begin(), 6));
	r = m.upper_bound(8);
	assert(r == next(m.begin(), 6));
	r = m.upper_bound(9);
	assert(r == next(m.begin(), 9));
	r = m.upper_bound(10);
	assert(r == m.end());
	}

	#endif
	}