libstdc++-v3/testsuite/25_algorithms/pstl/alg_sorting/minmax_element.cc - gcc - Git at Google

 // -*- C++ -*-
 // { dg-options "-ltbb" }
 // { dg-do run { target c++17 } }
 // { dg-timeout-factor 3 }
 // { dg-require-effective-target tbb_backend }

 //===-- minmax_element.pass.cpp -------------------------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include "pstl/pstl_test_config.h"

 #ifdef PSTL_STANDALONE_TESTS

 #include "pstl/execution"
 #include "pstl/algorithm"
 #else
 #include <execution>
 #include <algorithm>
 #endif // PSTL_STANDALONE_TESTS

 #include "pstl/test_utils.h"

 #include <set>
 #include <cassert>
 #include <cmath>

 using namespace TestUtils;

 struct check_minelement
 {
     template <typename Policy, typename Iterator>
     void
     operator()(Policy&& exec, Iterator begin, Iterator end)
     {
         typedef typename std::iterator_traits<Iterator>::value_type T;
         const Iterator expect = std::min_element(begin, end);
         const Iterator result = std::min_element(exec, begin, end);
         const Iterator result_pred = std::min_element(exec, begin, end, std::less<T>());
         EXPECT_TRUE(expect == result, "wrong return result from min_element");
         EXPECT_TRUE(expect == result_pred, "wrong return result from min_element");
     }
 };

 struct check_maxelement
 {
     template <typename Policy, typename Iterator>
     void
     operator()(Policy&& exec, Iterator begin, Iterator end)
     {
         typedef typename std::iterator_traits<Iterator>::value_type T;
         const Iterator expect = std::max_element(begin, end);
         const Iterator result = std::max_element(exec, begin, end);
         const Iterator result_pred = std::max_element(exec, begin, end, std::less<T>());
         EXPECT_TRUE(expect == result, "wrong return result from max_element");
         EXPECT_TRUE(expect == result_pred, "wrong return result from max_element");
     }
 };

 struct check_minmaxelement
 {
     template <typename Policy, typename Iterator>
     void
     operator()(Policy&& exec, Iterator begin, Iterator end)
     {
         typedef typename std::iterator_traits<Iterator>::value_type T;
         const std::pair<Iterator, Iterator> expect = std::minmax_element(begin, end);
         const std::pair<Iterator, Iterator> got = std::minmax_element(exec, begin, end);
         const std::pair<Iterator, Iterator> got_pred = std::minmax_element(exec, begin, end, std::less<T>());
         EXPECT_TRUE(expect.first == got.first, "wrong return result from minmax_element (min part)");
         EXPECT_TRUE(expect.second == got.second, "wrong return result from minmax_element (max part)");
         EXPECT_TRUE(expect == got_pred, "wrong return result from minmax_element");
     }
 };

 template <typename T>
 struct sequence_wrapper
 {
     TestUtils::Sequence<T> seq;
     const T min_value;
     const T max_value;
     static const std::size_t bits = 30; // We assume that T can handle signed 2^bits+1 value

     // TestUtils::HashBits returns value between 0 and (1<<bits)-1,
     // therefore we could threat 1<<bits as maximum and -(1<<bits) as a minimum
     sequence_wrapper(std::size_t n) : seq(n), min_value(-(1 << bits)), max_value(1 << bits) {}

     void
     pattern_fill()
     {
         seq.fill([](std::size_t i) -> T { return T(TestUtils::HashBits(i, bits)); });
     }

     // sets first one at position `at` and bunch of them farther
     void
     set_desired_value(std::size_t at, T value)
     {
         if (seq.size() == 0)
             return;
         seq[at] = value;

         //Producing serveral red herrings
         for (std::size_t i = at + 1; i < seq.size(); i += 1 + TestUtils::HashBits(i, 5))
             seq[i] = value;
     }
 };

 template <typename T>
 void
 test_by_type(std::size_t n)
 {
     sequence_wrapper<T> wseq(n);

     // to avoid overtesing we use std::set to leave only unique indexes
     std::set<std::size_t> targets{0};
     if (n > 1)
     {
         targets.insert(1);
         targets.insert(2.718282 * n / 3);
         targets.insert(n / 2);
         targets.insert(n / 7.389056);
         targets.insert(n - 1); // last
     }

     for (std::set<std::size_t>::iterator it = targets.begin(); it != targets.end(); ++it)
     {
         wseq.pattern_fill();
         wseq.set_desired_value(*it, wseq.min_value);
         TestUtils::invoke_on_all_policies(check_minelement(), wseq.seq.cbegin(), wseq.seq.cend());
         TestUtils::invoke_on_all_policies(check_minelement(), wseq.seq.begin(), wseq.seq.end());

         wseq.set_desired_value(*it, wseq.max_value);
         TestUtils::invoke_on_all_policies(check_maxelement(), wseq.seq.cbegin(), wseq.seq.cend());
         TestUtils::invoke_on_all_policies(check_maxelement(), wseq.seq.begin(), wseq.seq.end());

         if (targets.size() > 1)
         {
             for (std::set<std::size_t>::reverse_iterator rit = targets.rbegin(); rit != targets.rend(); ++rit)
             {
                 if (*rit == *it) // we requires at least 2 unique indexes in targets
                     break;
                 wseq.pattern_fill();
                 wseq.set_desired_value(*it, wseq.min_value);  // setting minimum element
                 wseq.set_desired_value(*rit, wseq.max_value); // setting maximum element
                 TestUtils::invoke_on_all_policies(check_minmaxelement(), wseq.seq.cbegin(), wseq.seq.cend());
                 TestUtils::invoke_on_all_policies(check_minmaxelement(), wseq.seq.begin(), wseq.seq.end());
             }
         }
         else
         { // we must check this corner case; it can not be tested in loop above
             TestUtils::invoke_on_all_policies(check_minmaxelement(), wseq.seq.cbegin(), wseq.seq.cend());
             TestUtils::invoke_on_all_policies(check_minmaxelement(), wseq.seq.begin(), wseq.seq.end());
         }
     }
 }

 // should provide minimal requirements only
 struct OnlyLessCompare
 {
     int32_t val;
     OnlyLessCompare() : val(0) {}
     OnlyLessCompare(int32_t val_) : val(val_) {}
     bool
     operator<(const OnlyLessCompare& other) const
     {
         return val < other.val;
     }
 };

 template <typename T>
 struct test_non_const
 {
     template <typename Policy, typename Iterator>
     void
     operator()(Policy&& exec, Iterator iter)
     {
         max_element(exec, iter, iter, non_const(std::less<T>()));
         min_element(exec, iter, iter, non_const(std::less<T>()));
         minmax_element(exec, iter, iter, non_const(std::less<T>()));
     }
 };

 int32_t
 main()
 {
     using TestUtils::float64_t;
     const std::size_t N = 100000;

     for (std::size_t n = 0; n < N; n = n < 16 ? n + 1 : size_t(3.14159 * n))
     {
         test_by_type<float64_t>(n);
         test_by_type<OnlyLessCompare>(n);
     }

     test_algo_basic_single<int32_t>(run_for_rnd_fw<test_non_const<int32_t>>());

     std::cout << TestUtils::done() << std::endl;
     return 0;
 }
	// -- C++ --
	// { dg-options "-ltbb" }
	// { dg-do run { target c++17 } }
	// { dg-timeout-factor 3 }
	// { dg-require-effective-target tbb_backend }

	//===-- minmax_element.pass.cpp -------------------------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include "pstl/pstl_test_config.h"

	#ifdef PSTL_STANDALONE_TESTS

	#include "pstl/execution"
	#include "pstl/algorithm"
	#else
	#include <execution>
	#include <algorithm>
	#endif // PSTL_STANDALONE_TESTS

	#include "pstl/test_utils.h"

	#include <set>
	#include <cassert>
	#include <cmath>

	using namespace TestUtils;

	struct check_minelement
	{
	template <typename Policy, typename Iterator>
	void
	operator()(Policy&& exec, Iterator begin, Iterator end)
	{
	typedef typename std::iterator_traits<Iterator>::value_type T;
	const Iterator expect = std::min_element(begin, end);
	const Iterator result = std::min_element(exec, begin, end);
	const Iterator result_pred = std::min_element(exec, begin, end, std::less<T>());
	EXPECT_TRUE(expect == result, "wrong return result from min_element");
	EXPECT_TRUE(expect == result_pred, "wrong return result from min_element");
	}
	};

	struct check_maxelement
	{
	template <typename Policy, typename Iterator>
	void
	operator()(Policy&& exec, Iterator begin, Iterator end)
	{
	typedef typename std::iterator_traits<Iterator>::value_type T;
	const Iterator expect = std::max_element(begin, end);
	const Iterator result = std::max_element(exec, begin, end);
	const Iterator result_pred = std::max_element(exec, begin, end, std::less<T>());
	EXPECT_TRUE(expect == result, "wrong return result from max_element");
	EXPECT_TRUE(expect == result_pred, "wrong return result from max_element");
	}
	};

	struct check_minmaxelement
	{
	template <typename Policy, typename Iterator>
	void
	operator()(Policy&& exec, Iterator begin, Iterator end)
	{
	typedef typename std::iterator_traits<Iterator>::value_type T;
	const std::pair<Iterator, Iterator> expect = std::minmax_element(begin, end);
	const std::pair<Iterator, Iterator> got = std::minmax_element(exec, begin, end);
	const std::pair<Iterator, Iterator> got_pred = std::minmax_element(exec, begin, end, std::less<T>());
	EXPECT_TRUE(expect.first == got.first, "wrong return result from minmax_element (min part)");
	EXPECT_TRUE(expect.second == got.second, "wrong return result from minmax_element (max part)");
	EXPECT_TRUE(expect == got_pred, "wrong return result from minmax_element");
	}
	};

	template <typename T>
	struct sequence_wrapper
	{
	TestUtils::Sequence<T> seq;
	const T min_value;
	const T max_value;
	static const std::size_t bits = 30; // We assume that T can handle signed 2^bits+1 value

	// TestUtils::HashBits returns value between 0 and (1<<bits)-1,
	// therefore we could threat 1<<bits as maximum and -(1<<bits) as a minimum
	sequence_wrapper(std::size_t n) : seq(n), min_value(-(1 << bits)), max_value(1 << bits) {}

	void
	pattern_fill()
	{
	seq.fill([](std::size_t i) -> T { return T(TestUtils::HashBits(i, bits)); });
	}

	// sets first one at position `at` and bunch of them farther
	void
	set_desired_value(std::size_t at, T value)
	{
	if (seq.size() == 0)
	return;
	seq[at] = value;

	//Producing serveral red herrings
	for (std::size_t i = at + 1; i < seq.size(); i += 1 + TestUtils::HashBits(i, 5))
	seq[i] = value;
	}
	};

	template <typename T>
	void
	test_by_type(std::size_t n)
	{
	sequence_wrapper<T> wseq(n);

	// to avoid overtesing we use std::set to leave only unique indexes
	std::set<std::size_t> targets{0};
	if (n > 1)
	{
	targets.insert(1);
	targets.insert(2.718282 * n / 3);
	targets.insert(n / 2);
	targets.insert(n / 7.389056);
	targets.insert(n - 1); // last
	}

	for (std::set<std::size_t>::iterator it = targets.begin(); it != targets.end(); ++it)
	{
	wseq.pattern_fill();
	wseq.set_desired_value(*it, wseq.min_value);
	TestUtils::invoke_on_all_policies(check_minelement(), wseq.seq.cbegin(), wseq.seq.cend());
	TestUtils::invoke_on_all_policies(check_minelement(), wseq.seq.begin(), wseq.seq.end());

	wseq.set_desired_value(*it, wseq.max_value);
	TestUtils::invoke_on_all_policies(check_maxelement(), wseq.seq.cbegin(), wseq.seq.cend());
	TestUtils::invoke_on_all_policies(check_maxelement(), wseq.seq.begin(), wseq.seq.end());

	if (targets.size() > 1)
	{
	for (std::set<std::size_t>::reverse_iterator rit = targets.rbegin(); rit != targets.rend(); ++rit)
	{
	if (rit == it) // we requires at least 2 unique indexes in targets
	break;
	wseq.pattern_fill();
	wseq.set_desired_value(*it, wseq.min_value); // setting minimum element
	wseq.set_desired_value(*rit, wseq.max_value); // setting maximum element
	TestUtils::invoke_on_all_policies(check_minmaxelement(), wseq.seq.cbegin(), wseq.seq.cend());
	TestUtils::invoke_on_all_policies(check_minmaxelement(), wseq.seq.begin(), wseq.seq.end());
	}
	}
	else
	{ // we must check this corner case; it can not be tested in loop above
	TestUtils::invoke_on_all_policies(check_minmaxelement(), wseq.seq.cbegin(), wseq.seq.cend());
	TestUtils::invoke_on_all_policies(check_minmaxelement(), wseq.seq.begin(), wseq.seq.end());
	}
	}
	}

	// should provide minimal requirements only
	struct OnlyLessCompare
	{
	int32_t val;
	OnlyLessCompare() : val(0) {}
	OnlyLessCompare(int32_t val_) : val(val_) {}
	bool
	operator<(const OnlyLessCompare& other) const
	{
	return val < other.val;
	}
	};

	template <typename T>
	struct test_non_const
	{
	template <typename Policy, typename Iterator>
	void
	operator()(Policy&& exec, Iterator iter)
	{
	max_element(exec, iter, iter, non_const(std::less<T>()));
	min_element(exec, iter, iter, non_const(std::less<T>()));
	minmax_element(exec, iter, iter, non_const(std::less<T>()));
	}
	};

	int32_t
	main()
	{
	using TestUtils::float64_t;
	const std::size_t N = 100000;

	for (std::size_t n = 0; n < N; n = n < 16 ? n + 1 : size_t(3.14159 * n))
	{
	test_by_type<float64_t>(n);
	test_by_type<OnlyLessCompare>(n);
	}

	test_algo_basic_single<int32_t>(run_for_rnd_fw<test_non_const<int32_t>>());

	std::cout << TestUtils::done() << std::endl;
	return 0;
	}