libcxx/test/std/algorithms/alg.modifying.operations/alg.unique/unique_copy_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<InputIterator InIter, class OutIter,
 //          EquivalenceRelation<auto, InIter::value_type> Pred>
 //   requires OutputIterator<OutIter, RvalueOf<InIter::value_type>::type>
 //         && HasAssign<InIter::value_type, InIter::reference>
 //         && Constructible<InIter::value_type, InIter::reference>
 //         && CopyConstructible<Pred>
 //   OutIter
 //   unique_copy(InIter first, InIter last, OutIter result, Pred pred);

 #include <algorithm>
 #include <cassert>

 #include "test_iterators.h"

 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 InIter, class OutIter>
 void
 test()
 {
     const int ia[] = {0};
     const unsigned sa = sizeof(ia)/sizeof(ia[0]);
     int ja[sa] = {-1};
     count_equal::count = 0;
     OutIter r = std::unique_copy(InIter(ia), InIter(ia+sa), OutIter(ja), count_equal());
     assert(base(r) == ja + sa);
     assert(ja[0] == 0);
     assert(count_equal::count == sa-1);

     const int ib[] = {0, 1};
     const unsigned sb = sizeof(ib)/sizeof(ib[0]);
     int jb[sb] = {-1};
     count_equal::count = 0;
     r = std::unique_copy(InIter(ib), InIter(ib+sb), OutIter(jb), count_equal());
     assert(base(r) == jb + sb);
     assert(jb[0] == 0);
     assert(jb[1] == 1);
     assert(count_equal::count == sb-1);

     const int ic[] = {0, 0};
     const unsigned sc = sizeof(ic)/sizeof(ic[0]);
     int jc[sc] = {-1};
     count_equal::count = 0;
     r = std::unique_copy(InIter(ic), InIter(ic+sc), OutIter(jc), count_equal());
     assert(base(r) == jc + 1);
     assert(jc[0] == 0);
     assert(count_equal::count == sc-1);

     const int id[] = {0, 0, 1};
     const unsigned sd = sizeof(id)/sizeof(id[0]);
     int jd[sd] = {-1};
     count_equal::count = 0;
     r = std::unique_copy(InIter(id), InIter(id+sd), OutIter(jd), count_equal());
     assert(base(r) == jd + 2);
     assert(jd[0] == 0);
     assert(jd[1] == 1);
     assert(count_equal::count == sd-1);

     const int ie[] = {0, 0, 1, 0};
     const unsigned se = sizeof(ie)/sizeof(ie[0]);
     int je[se] = {-1};
     count_equal::count = 0;
     r = std::unique_copy(InIter(ie), InIter(ie+se), OutIter(je), count_equal());
     assert(base(r) == je + 3);
     assert(je[0] == 0);
     assert(je[1] == 1);
     assert(je[2] == 0);
     assert(count_equal::count == se-1);

     const int ig[] = {0, 0, 1, 1};
     const unsigned sg = sizeof(ig)/sizeof(ig[0]);
     int jg[sg] = {-1};
     count_equal::count = 0;
     r = std::unique_copy(InIter(ig), InIter(ig+sg), OutIter(jg), count_equal());
     assert(base(r) == jg + 2);
     assert(jg[0] == 0);
     assert(jg[1] == 1);
     assert(count_equal::count == sg-1);

     const int ih[] = {0, 1, 1};
     const unsigned sh = sizeof(ih)/sizeof(ih[0]);
     int jh[sh] = {-1};
     count_equal::count = 0;
     r = std::unique_copy(InIter(ih), InIter(ih+sh), OutIter(jh), count_equal());
     assert(base(r) == jh + 2);
     assert(jh[0] == 0);
     assert(jh[1] == 1);
     assert(count_equal::count == sh-1);

     const int ii[] = {0, 1, 1, 1, 2, 2, 2};
     const unsigned si = sizeof(ii)/sizeof(ii[0]);
     int ji[si] = {-1};
     count_equal::count = 0;
     r = std::unique_copy(InIter(ii), InIter(ii+si), OutIter(ji), count_equal());
     assert(base(r) == ji + 3);
     assert(ji[0] == 0);
     assert(ji[1] == 1);
     assert(ji[2] == 2);
     assert(count_equal::count == si-1);
 }

 int main()
 {
     test<input_iterator<const int*>, output_iterator<int*> >();
     test<input_iterator<const int*>, forward_iterator<int*> >();
     test<input_iterator<const int*>, bidirectional_iterator<int*> >();
     test<input_iterator<const int*>, random_access_iterator<int*> >();
     test<input_iterator<const int*>, int*>();

     test<forward_iterator<const int*>, output_iterator<int*> >();
     test<forward_iterator<const int*>, forward_iterator<int*> >();
     test<forward_iterator<const int*>, bidirectional_iterator<int*> >();
     test<forward_iterator<const int*>, random_access_iterator<int*> >();
     test<forward_iterator<const int*>, int*>();

     test<bidirectional_iterator<const int*>, output_iterator<int*> >();
     test<bidirectional_iterator<const int*>, forward_iterator<int*> >();
     test<bidirectional_iterator<const int*>, bidirectional_iterator<int*> >();
     test<bidirectional_iterator<const int*>, random_access_iterator<int*> >();
     test<bidirectional_iterator<const int*>, int*>();

     test<random_access_iterator<const int*>, output_iterator<int*> >();
     test<random_access_iterator<const int*>, forward_iterator<int*> >();
     test<random_access_iterator<const int*>, bidirectional_iterator<int*> >();
     test<random_access_iterator<const int*>, random_access_iterator<int*> >();
     test<random_access_iterator<const int*>, int*>();

     test<const int*, output_iterator<int*> >();
     test<const int*, forward_iterator<int*> >();
     test<const int*, bidirectional_iterator<int*> >();
     test<const int*, random_access_iterator<int*> >();
     test<const int*, 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<InputIterator InIter, class OutIter,
	// EquivalenceRelation<auto, InIter::value_type> Pred>
	// requires OutputIterator<OutIter, RvalueOf<InIter::value_type>::type>
	// && HasAssign<InIter::value_type, InIter::reference>
	// && Constructible<InIter::value_type, InIter::reference>
	// && CopyConstructible<Pred>
	// OutIter
	// unique_copy(InIter first, InIter last, OutIter result, Pred pred);

	#include <algorithm>
	#include <cassert>

	#include "test_iterators.h"

	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 InIter, class OutIter>
	void
	test()
	{
	const int ia[] = {0};
	const unsigned sa = sizeof(ia)/sizeof(ia[0]);
	int ja[sa] = {-1};
	count_equal::count = 0;
	OutIter r = std::unique_copy(InIter(ia), InIter(ia+sa), OutIter(ja), count_equal());
	assert(base(r) == ja + sa);
	assert(ja[0] == 0);
	assert(count_equal::count == sa-1);

	const int ib[] = {0, 1};
	const unsigned sb = sizeof(ib)/sizeof(ib[0]);
	int jb[sb] = {-1};
	count_equal::count = 0;
	r = std::unique_copy(InIter(ib), InIter(ib+sb), OutIter(jb), count_equal());
	assert(base(r) == jb + sb);
	assert(jb[0] == 0);
	assert(jb[1] == 1);
	assert(count_equal::count == sb-1);

	const int ic[] = {0, 0};
	const unsigned sc = sizeof(ic)/sizeof(ic[0]);
	int jc[sc] = {-1};
	count_equal::count = 0;
	r = std::unique_copy(InIter(ic), InIter(ic+sc), OutIter(jc), count_equal());
	assert(base(r) == jc + 1);
	assert(jc[0] == 0);
	assert(count_equal::count == sc-1);

	const int id[] = {0, 0, 1};
	const unsigned sd = sizeof(id)/sizeof(id[0]);
	int jd[sd] = {-1};
	count_equal::count = 0;
	r = std::unique_copy(InIter(id), InIter(id+sd), OutIter(jd), count_equal());
	assert(base(r) == jd + 2);
	assert(jd[0] == 0);
	assert(jd[1] == 1);
	assert(count_equal::count == sd-1);

	const int ie[] = {0, 0, 1, 0};
	const unsigned se = sizeof(ie)/sizeof(ie[0]);
	int je[se] = {-1};
	count_equal::count = 0;
	r = std::unique_copy(InIter(ie), InIter(ie+se), OutIter(je), count_equal());
	assert(base(r) == je + 3);
	assert(je[0] == 0);
	assert(je[1] == 1);
	assert(je[2] == 0);
	assert(count_equal::count == se-1);

	const int ig[] = {0, 0, 1, 1};
	const unsigned sg = sizeof(ig)/sizeof(ig[0]);
	int jg[sg] = {-1};
	count_equal::count = 0;
	r = std::unique_copy(InIter(ig), InIter(ig+sg), OutIter(jg), count_equal());
	assert(base(r) == jg + 2);
	assert(jg[0] == 0);
	assert(jg[1] == 1);
	assert(count_equal::count == sg-1);

	const int ih[] = {0, 1, 1};
	const unsigned sh = sizeof(ih)/sizeof(ih[0]);
	int jh[sh] = {-1};
	count_equal::count = 0;
	r = std::unique_copy(InIter(ih), InIter(ih+sh), OutIter(jh), count_equal());
	assert(base(r) == jh + 2);
	assert(jh[0] == 0);
	assert(jh[1] == 1);
	assert(count_equal::count == sh-1);

	const int ii[] = {0, 1, 1, 1, 2, 2, 2};
	const unsigned si = sizeof(ii)/sizeof(ii[0]);
	int ji[si] = {-1};
	count_equal::count = 0;
	r = std::unique_copy(InIter(ii), InIter(ii+si), OutIter(ji), count_equal());
	assert(base(r) == ji + 3);
	assert(ji[0] == 0);
	assert(ji[1] == 1);
	assert(ji[2] == 2);
	assert(count_equal::count == si-1);
	}

	int main()
	{
	test<input_iterator<const int>, output_iterator<int> >();
	test<input_iterator<const int>, forward_iterator<int> >();
	test<input_iterator<const int>, bidirectional_iterator<int> >();
	test<input_iterator<const int>, random_access_iterator<int> >();
	test<input_iterator<const int>, int>();

	test<forward_iterator<const int>, output_iterator<int> >();
	test<forward_iterator<const int>, forward_iterator<int> >();
	test<forward_iterator<const int>, bidirectional_iterator<int> >();
	test<forward_iterator<const int>, random_access_iterator<int> >();
	test<forward_iterator<const int>, int>();

	test<bidirectional_iterator<const int>, output_iterator<int> >();
	test<bidirectional_iterator<const int>, forward_iterator<int> >();
	test<bidirectional_iterator<const int>, bidirectional_iterator<int> >();
	test<bidirectional_iterator<const int>, random_access_iterator<int> >();
	test<bidirectional_iterator<const int>, int>();

	test<random_access_iterator<const int>, output_iterator<int> >();
	test<random_access_iterator<const int>, forward_iterator<int> >();
	test<random_access_iterator<const int>, bidirectional_iterator<int> >();
	test<random_access_iterator<const int>, random_access_iterator<int> >();
	test<random_access_iterator<const int>, int>();

	test<const int, output_iterator<int> >();
	test<const int, forward_iterator<int> >();
	test<const int, bidirectional_iterator<int> >();
	test<const int, random_access_iterator<int> >();
	test<const int, int>();
	}