forked from OSchip/llvm-project
174 lines
6.5 KiB
C++
174 lines
6.5 KiB
C++
// -*- C++ -*-
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//===-- test_lexicographical_compare.cpp ----------------------------------===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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#include "pstl_test_config.h"
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#include <string>
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#include <iostream>
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#include "pstl/execution"
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#include "pstl/algorithm"
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#include "utils.h"
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using namespace TestUtils;
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struct test_one_policy
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{
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template <typename ExecutionPolicy, typename Iterator1, typename Iterator2, typename Predicate>
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void
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operator()(ExecutionPolicy&& exec, Iterator1 begin1, Iterator1 end1, Iterator2 begin2, Iterator2 end2,
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Predicate pred)
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{
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const bool expected = std::lexicographical_compare(begin1, end1, begin2, end2, pred);
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const bool actual = std::lexicographical_compare(exec, begin1, end1, begin2, end2, pred);
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EXPECT_TRUE(actual == expected, "wrong return result from lexicographical compare with predicate");
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}
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template <typename ExecutionPolicy, typename Iterator1, typename Iterator2>
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void
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operator()(ExecutionPolicy&& exec, Iterator1 begin1, Iterator1 end1, Iterator2 begin2, Iterator2 end2)
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{
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const bool expected = std::lexicographical_compare(begin1, end1, begin2, end2);
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const bool actual = std::lexicographical_compare(exec, begin1, end1, begin2, end2);
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EXPECT_TRUE(actual == expected, "wrong return result from lexicographical compare without predicate");
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}
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};
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template <typename T1, typename T2, typename Predicate>
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void
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test(Predicate pred)
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{
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const std::size_t max_n = 1000000;
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Sequence<T1> in1(max_n, [](std::size_t k) { return T1(k); });
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Sequence<T2> in2(2 * max_n, [](std::size_t k) { return T2(k); });
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std::size_t n2;
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// Test case: Call algorithm's version without predicate.
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invoke_on_all_policies(test_one_policy(), in1.cbegin(), in1.cbegin() + max_n, in2.cbegin() + 3 * max_n / 10,
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in2.cbegin() + 5 * max_n / 10);
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// Test case: If one range is a prefix of another, the shorter range is lexicographically less than the other.
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std::size_t max_n2 = max_n / 10;
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invoke_on_all_policies(test_one_policy(), in1.begin(), in1.begin() + max_n, in2.cbegin(), in2.cbegin() + max_n2,
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pred);
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invoke_on_all_policies(test_one_policy(), in1.begin(), in1.begin() + max_n, in2.begin() + max_n2,
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in2.begin() + 3 * max_n2, pred);
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// Test case: If one range is a prefix of another, the shorter range is lexicographically less than the other.
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max_n2 = 2 * max_n;
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invoke_on_all_policies(test_one_policy(), in1.cbegin(), in1.cbegin() + max_n, in2.begin(), in2.begin() + max_n2,
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pred);
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for (std::size_t n1 = 0; n1 <= max_n; n1 = n1 <= 16 ? n1 + 1 : std::size_t(3.1415 * n1))
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{
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// Test case: If two ranges have equivalent elements and are of the same length, then the ranges are lexicographically equal.
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n2 = n1;
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invoke_on_all_policies(test_one_policy(), in1.begin(), in1.begin() + n1, in2.begin(), in2.begin() + n2, pred);
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n2 = n1;
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// Test case: two ranges have different elements and are of the same length (second sequence less than first)
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std::size_t ind = n1 / 2;
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in2[ind] = T2(-1);
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invoke_on_all_policies(test_one_policy(), in1.begin(), in1.begin() + n1, in2.begin(), in2.begin() + n2, pred);
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in2[ind] = T2(ind);
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// Test case: two ranges have different elements and are of the same length (first sequence less than second)
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ind = n1 / 5;
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in1[ind] = T1(-1);
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invoke_on_all_policies(test_one_policy(), in1.begin(), in1.begin() + n1, in2.cbegin(), in2.cbegin() + n2, pred);
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in1[ind] = T1(ind);
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}
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}
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template <typename Predicate>
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void
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test_string(Predicate pred)
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{
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const std::size_t max_n = 1000000;
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std::string in1 = "";
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std::string in2 = "";
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for (std::size_t n1 = 0; n1 <= max_n; ++n1)
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{
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in1 += n1;
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}
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for (std::size_t n1 = 0; n1 <= 2 * max_n; ++n1)
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{
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in2 += n1;
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}
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std::size_t n2;
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for (std::size_t n1 = 0; n1 < in1.size(); n1 = n1 <= 16 ? n1 + 1 : std::size_t(3.1415 * n1))
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{
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// Test case: If two ranges have equivalent elements and are of the same length, then the ranges are lexicographically equal.
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n2 = n1;
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invoke_on_all_policies(test_one_policy(), in1.begin(), in1.begin() + n1, in2.begin(), in2.begin() + n2, pred);
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n2 = n1;
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// Test case: two ranges have different elements and are of the same length (second sequence less than first)
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in2[n1 / 2] = 'a';
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invoke_on_all_policies(test_one_policy(), in1.begin(), in1.begin() + n1, in2.begin(), in2.begin() + n2, pred);
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// Test case: two ranges have different elements and are of the same length (first sequence less than second)
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in1[n1 / 5] = 'a';
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invoke_on_all_policies(test_one_policy(), in1.begin(), in1.begin() + n1, in2.cbegin(), in2.cbegin() + n2, pred);
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}
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invoke_on_all_policies(test_one_policy(), in1.cbegin(), in1.cbegin() + max_n, in2.cbegin() + 3 * max_n / 10,
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in2.cbegin() + 5 * max_n / 10);
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}
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template <typename T>
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struct LocalWrapper
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{
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explicit LocalWrapper(std::size_t k) : my_val(k) {}
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bool
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operator<(const LocalWrapper<T>& w) const
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{
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return my_val < w.my_val;
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}
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private:
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T my_val;
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};
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template <typename T>
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struct test_non_const
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{
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template <typename Policy, typename FirstIterator, typename SecondInterator>
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void
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operator()(Policy&& exec, FirstIterator first_iter, SecondInterator second_iter)
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{
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invoke_if(exec, [&]() {
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lexicographical_compare(exec, first_iter, first_iter, second_iter, second_iter, non_const(std::less<T>()));
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});
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}
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};
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int32_t
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main()
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{
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test<uint16_t, float64_t>(std::less<float64_t>());
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test<float32_t, int32_t>(std::greater<float32_t>());
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#if !__PSTL_ICC_18_TEST_EARLY_EXIT_AVX_RELEASE_BROKEN
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test<float64_t, int32_t>([](const float64_t x, const int32_t y) { return x * x < y * y; });
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#endif
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test<LocalWrapper<int32_t>, LocalWrapper<int32_t>>(
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[](const LocalWrapper<int32_t>& x, const LocalWrapper<int32_t>& y) { return x < y; });
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test_string([](const char x, const char y) { return x < y; });
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test_algo_basic_double<int32_t>(run_for_rnd_fw<test_non_const<int32_t>>());
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std::cout << done() << std::endl;
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return 0;
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}
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