libcxx/test/std/algorithms/alg.nonmodifying/alg.search/search_n_pred.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.
 //
 //===----------------------------------------------------------------------===//

 // <algorithm>

 // template<class ForwardIterator, class Size, class T, class BinaryPredicate>
 //   ForwardIterator
 //   search_n(ForwardIterator first, ForwardIterator last, Size count,
 //            const T& value, BinaryPredicate pred);

 #include <algorithm>
 #include <cassert>

 #include "test_iterators.h"
 #include "user_defined_integral.hpp"

 struct count_equal
 {
     static unsigned count;
     template <class T>
     bool operator()(const T& x, const T& y)
         {++count; return x == y;}
 };

 unsigned count_equal::count = 0;


 template <class Iter>
 void
 test()
 {
     int ia[] = {0, 1, 2, 3, 4, 5};
     const unsigned sa = sizeof(ia)/sizeof(ia[0]);
     count_equal::count = 0;
     assert(std::search_n(Iter(ia), Iter(ia+sa), 0, 0, count_equal()) == Iter(ia));
     assert(count_equal::count <= sa);
     count_equal::count = 0;
     assert(std::search_n(Iter(ia), Iter(ia+sa), 1, 0, count_equal()) == Iter(ia+0));
     assert(count_equal::count <= sa);
     count_equal::count = 0;
     assert(std::search_n(Iter(ia), Iter(ia+sa), 2, 0, count_equal()) == Iter(ia+sa));
     assert(count_equal::count <= sa);
     count_equal::count = 0;
     assert(std::search_n(Iter(ia), Iter(ia+sa), sa, 0, count_equal()) == Iter(ia+sa));
     assert(count_equal::count <= sa);
     count_equal::count = 0;
     assert(std::search_n(Iter(ia), Iter(ia+sa), 0, 3, count_equal()) == Iter(ia));
     assert(count_equal::count <= sa);
     count_equal::count = 0;
     assert(std::search_n(Iter(ia), Iter(ia+sa), 1, 3, count_equal()) == Iter(ia+3));
     assert(count_equal::count <= sa);
     count_equal::count = 0;
     assert(std::search_n(Iter(ia), Iter(ia+sa), 2, 3, count_equal()) == Iter(ia+sa));
     assert(count_equal::count <= sa);
     count_equal::count = 0;
     assert(std::search_n(Iter(ia), Iter(ia+sa), sa, 3, count_equal()) == Iter(ia+sa));
     assert(count_equal::count <= sa);
     count_equal::count = 0;
     assert(std::search_n(Iter(ia), Iter(ia+sa), 0, 5, count_equal()) == Iter(ia));
     assert(count_equal::count <= sa);
     count_equal::count = 0;
     assert(std::search_n(Iter(ia), Iter(ia+sa), 1, 5, count_equal()) == Iter(ia+5));
     assert(count_equal::count <= sa);
     count_equal::count = 0;
     assert(std::search_n(Iter(ia), Iter(ia+sa), 2, 5, count_equal()) == Iter(ia+sa));
     assert(count_equal::count <= sa);
     count_equal::count = 0;
     assert(std::search_n(Iter(ia), Iter(ia+sa), sa, 5, count_equal()) == Iter(ia+sa));
     assert(count_equal::count <= sa);
     count_equal::count = 0;

     int ib[] = {0, 0, 1, 1, 2, 2};
     const unsigned sb = sizeof(ib)/sizeof(ib[0]);
     assert(std::search_n(Iter(ib), Iter(ib+sb), 0, 0, count_equal()) == Iter(ib));
     assert(count_equal::count <= sb);
     count_equal::count = 0;
     assert(std::search_n(Iter(ib), Iter(ib+sb), 1, 0, count_equal()) == Iter(ib+0));
     assert(count_equal::count <= sb);
     count_equal::count = 0;
     assert(std::search_n(Iter(ib), Iter(ib+sb), 2, 0, count_equal()) == Iter(ib+0));
     assert(count_equal::count <= sb);
     count_equal::count = 0;
     assert(std::search_n(Iter(ib), Iter(ib+sb), 3, 0, count_equal()) == Iter(ib+sb));
     assert(count_equal::count <= sb);
     count_equal::count = 0;
     assert(std::search_n(Iter(ib), Iter(ib+sb), sb, 0, count_equal()) == Iter(ib+sb));
     assert(count_equal::count <= sb);
     count_equal::count = 0;
     assert(std::search_n(Iter(ib), Iter(ib+sb), 0, 1, count_equal()) == Iter(ib));
     assert(count_equal::count <= sb);
     count_equal::count = 0;
     assert(std::search_n(Iter(ib), Iter(ib+sb), 1, 1, count_equal()) == Iter(ib+2));
     assert(count_equal::count <= sb);
     count_equal::count = 0;
     assert(std::search_n(Iter(ib), Iter(ib+sb), 2, 1, count_equal()) == Iter(ib+2));
     assert(count_equal::count <= sb);
     count_equal::count = 0;
     assert(std::search_n(Iter(ib), Iter(ib+sb), 3, 1, count_equal()) == Iter(ib+sb));
     assert(count_equal::count <= sb);
     count_equal::count = 0;
     assert(std::search_n(Iter(ib), Iter(ib+sb), sb, 1, count_equal()) == Iter(ib+sb));
     assert(count_equal::count <= sb);
     count_equal::count = 0;
     assert(std::search_n(Iter(ib), Iter(ib+sb), 0, 2, count_equal()) == Iter(ib));
     assert(count_equal::count <= sb);
     count_equal::count = 0;
     assert(std::search_n(Iter(ib), Iter(ib+sb), 1, 2, count_equal()) == Iter(ib+4));
     assert(count_equal::count <= sb);
     count_equal::count = 0;
     assert(std::search_n(Iter(ib), Iter(ib+sb), 2, 2, count_equal()) == Iter(ib+4));
     assert(count_equal::count <= sb);
     count_equal::count = 0;
     assert(std::search_n(Iter(ib), Iter(ib+sb), 3, 2, count_equal()) == Iter(ib+sb));
     assert(count_equal::count <= sb);
     count_equal::count = 0;
     assert(std::search_n(Iter(ib), Iter(ib+sb), sb, 2, count_equal()) == Iter(ib+sb));
     assert(count_equal::count <= sb);
     count_equal::count = 0;

     int ic[] = {0, 0, 0};
     const unsigned sc = sizeof(ic)/sizeof(ic[0]);
     assert(std::search_n(Iter(ic), Iter(ic+sc), 0, 0, count_equal()) == Iter(ic));
     assert(count_equal::count <= sc);
     count_equal::count = 0;
     assert(std::search_n(Iter(ic), Iter(ic+sc), 1, 0, count_equal()) == Iter(ic));
     assert(count_equal::count <= sc);
     count_equal::count = 0;
     assert(std::search_n(Iter(ic), Iter(ic+sc), 2, 0, count_equal()) == Iter(ic));
     assert(count_equal::count <= sc);
     count_equal::count = 0;
     assert(std::search_n(Iter(ic), Iter(ic+sc), 3, 0, count_equal()) == Iter(ic));
     assert(count_equal::count <= sc);
     count_equal::count = 0;
     assert(std::search_n(Iter(ic), Iter(ic+sc), 4, 0, count_equal()) == Iter(ic+sc));
     assert(count_equal::count <= sc);
     count_equal::count = 0;

     // Check that we properly convert the size argument to an integral.
     std::search_n(Iter(ic), Iter(ic+sc), UserDefinedIntegral<unsigned>(4), 0, count_equal());
     count_equal::count = 0;
 }

 int main()
 {
     test<forward_iterator<const int*> >();
     test<bidirectional_iterator<const int*> >();
     test<random_access_iterator<const int*> >();
 }
	//===----------------------------------------------------------------------===//
	//
	// 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.
	//
	//===----------------------------------------------------------------------===//

	// <algorithm>

	// template<class ForwardIterator, class Size, class T, class BinaryPredicate>
	// ForwardIterator
	// search_n(ForwardIterator first, ForwardIterator last, Size count,
	// const T& value, BinaryPredicate pred);

	#include <algorithm>
	#include <cassert>

	#include "test_iterators.h"
	#include "user_defined_integral.hpp"

	struct count_equal
	{
	static unsigned count;
	template <class T>
	bool operator()(const T& x, const T& y)
	{++count; return x == y;}
	};

	unsigned count_equal::count = 0;


	template <class Iter>
	void
	test()
	{
	int ia[] = {0, 1, 2, 3, 4, 5};
	const unsigned sa = sizeof(ia)/sizeof(ia[0]);
	count_equal::count = 0;
	assert(std::search_n(Iter(ia), Iter(ia+sa), 0, 0, count_equal()) == Iter(ia));
	assert(count_equal::count <= sa);
	count_equal::count = 0;
	assert(std::search_n(Iter(ia), Iter(ia+sa), 1, 0, count_equal()) == Iter(ia+0));
	assert(count_equal::count <= sa);
	count_equal::count = 0;
	assert(std::search_n(Iter(ia), Iter(ia+sa), 2, 0, count_equal()) == Iter(ia+sa));
	assert(count_equal::count <= sa);
	count_equal::count = 0;
	assert(std::search_n(Iter(ia), Iter(ia+sa), sa, 0, count_equal()) == Iter(ia+sa));
	assert(count_equal::count <= sa);
	count_equal::count = 0;
	assert(std::search_n(Iter(ia), Iter(ia+sa), 0, 3, count_equal()) == Iter(ia));
	assert(count_equal::count <= sa);
	count_equal::count = 0;
	assert(std::search_n(Iter(ia), Iter(ia+sa), 1, 3, count_equal()) == Iter(ia+3));
	assert(count_equal::count <= sa);
	count_equal::count = 0;
	assert(std::search_n(Iter(ia), Iter(ia+sa), 2, 3, count_equal()) == Iter(ia+sa));
	assert(count_equal::count <= sa);
	count_equal::count = 0;
	assert(std::search_n(Iter(ia), Iter(ia+sa), sa, 3, count_equal()) == Iter(ia+sa));
	assert(count_equal::count <= sa);
	count_equal::count = 0;
	assert(std::search_n(Iter(ia), Iter(ia+sa), 0, 5, count_equal()) == Iter(ia));
	assert(count_equal::count <= sa);
	count_equal::count = 0;
	assert(std::search_n(Iter(ia), Iter(ia+sa), 1, 5, count_equal()) == Iter(ia+5));
	assert(count_equal::count <= sa);
	count_equal::count = 0;
	assert(std::search_n(Iter(ia), Iter(ia+sa), 2, 5, count_equal()) == Iter(ia+sa));
	assert(count_equal::count <= sa);
	count_equal::count = 0;
	assert(std::search_n(Iter(ia), Iter(ia+sa), sa, 5, count_equal()) == Iter(ia+sa));
	assert(count_equal::count <= sa);
	count_equal::count = 0;

	int ib[] = {0, 0, 1, 1, 2, 2};
	const unsigned sb = sizeof(ib)/sizeof(ib[0]);
	assert(std::search_n(Iter(ib), Iter(ib+sb), 0, 0, count_equal()) == Iter(ib));
	assert(count_equal::count <= sb);
	count_equal::count = 0;
	assert(std::search_n(Iter(ib), Iter(ib+sb), 1, 0, count_equal()) == Iter(ib+0));
	assert(count_equal::count <= sb);
	count_equal::count = 0;
	assert(std::search_n(Iter(ib), Iter(ib+sb), 2, 0, count_equal()) == Iter(ib+0));
	assert(count_equal::count <= sb);
	count_equal::count = 0;
	assert(std::search_n(Iter(ib), Iter(ib+sb), 3, 0, count_equal()) == Iter(ib+sb));
	assert(count_equal::count <= sb);
	count_equal::count = 0;
	assert(std::search_n(Iter(ib), Iter(ib+sb), sb, 0, count_equal()) == Iter(ib+sb));
	assert(count_equal::count <= sb);
	count_equal::count = 0;
	assert(std::search_n(Iter(ib), Iter(ib+sb), 0, 1, count_equal()) == Iter(ib));
	assert(count_equal::count <= sb);
	count_equal::count = 0;
	assert(std::search_n(Iter(ib), Iter(ib+sb), 1, 1, count_equal()) == Iter(ib+2));
	assert(count_equal::count <= sb);
	count_equal::count = 0;
	assert(std::search_n(Iter(ib), Iter(ib+sb), 2, 1, count_equal()) == Iter(ib+2));
	assert(count_equal::count <= sb);
	count_equal::count = 0;
	assert(std::search_n(Iter(ib), Iter(ib+sb), 3, 1, count_equal()) == Iter(ib+sb));
	assert(count_equal::count <= sb);
	count_equal::count = 0;
	assert(std::search_n(Iter(ib), Iter(ib+sb), sb, 1, count_equal()) == Iter(ib+sb));
	assert(count_equal::count <= sb);
	count_equal::count = 0;
	assert(std::search_n(Iter(ib), Iter(ib+sb), 0, 2, count_equal()) == Iter(ib));
	assert(count_equal::count <= sb);
	count_equal::count = 0;
	assert(std::search_n(Iter(ib), Iter(ib+sb), 1, 2, count_equal()) == Iter(ib+4));
	assert(count_equal::count <= sb);
	count_equal::count = 0;
	assert(std::search_n(Iter(ib), Iter(ib+sb), 2, 2, count_equal()) == Iter(ib+4));
	assert(count_equal::count <= sb);
	count_equal::count = 0;
	assert(std::search_n(Iter(ib), Iter(ib+sb), 3, 2, count_equal()) == Iter(ib+sb));
	assert(count_equal::count <= sb);
	count_equal::count = 0;
	assert(std::search_n(Iter(ib), Iter(ib+sb), sb, 2, count_equal()) == Iter(ib+sb));
	assert(count_equal::count <= sb);
	count_equal::count = 0;

	int ic[] = {0, 0, 0};
	const unsigned sc = sizeof(ic)/sizeof(ic[0]);
	assert(std::search_n(Iter(ic), Iter(ic+sc), 0, 0, count_equal()) == Iter(ic));
	assert(count_equal::count <= sc);
	count_equal::count = 0;
	assert(std::search_n(Iter(ic), Iter(ic+sc), 1, 0, count_equal()) == Iter(ic));
	assert(count_equal::count <= sc);
	count_equal::count = 0;
	assert(std::search_n(Iter(ic), Iter(ic+sc), 2, 0, count_equal()) == Iter(ic));
	assert(count_equal::count <= sc);
	count_equal::count = 0;
	assert(std::search_n(Iter(ic), Iter(ic+sc), 3, 0, count_equal()) == Iter(ic));
	assert(count_equal::count <= sc);
	count_equal::count = 0;
	assert(std::search_n(Iter(ic), Iter(ic+sc), 4, 0, count_equal()) == Iter(ic+sc));
	assert(count_equal::count <= sc);
	count_equal::count = 0;

	// Check that we properly convert the size argument to an integral.
	std::search_n(Iter(ic), Iter(ic+sc), UserDefinedIntegral<unsigned>(4), 0, count_equal());
	count_equal::count = 0;
	}

	int main()
	{
	test<forward_iterator<const int*> >();
	test<bidirectional_iterator<const int*> >();
	test<random_access_iterator<const int*> >();
	}