to reflect the new license. These used slightly different spellings that defeated my regular expressions. We understand that people may be surprised that we're moving the header entirely to discuss the new license. We checked this carefully with the Foundation's lawyer and we believe this is the correct approach. Essentially, all code in the project is now made available by the LLVM project under our new license, so you will see that the license headers include that license only. Some of our contributors have contributed code under our old license, and accordingly, we have retained a copy of our old license notice in the top-level files in each project and repository. llvm-svn: 351648
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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