llvm-project/pstl/test/test_nth_element.cpp
JF Bastien e637637ae4 Initial PSTL commit
The initial commit of the Parallel STL upstream (under LLVM umbrella) based on
Parallel STL 20181204 open source release, which is available by
https://github.com/intel/parallelstl

Author: Mikhail Dvorskiy <mikhail.dvorskiy@intel.com>

Differential Revision: https://reviews.llvm.org/D55889

llvm-svn: 349653
2018-12-19 17:45:32 +00:00

177 lines
6.5 KiB
C++

// -*- C++ -*-
//===-- test_nth_element.cpp ----------------------------------------------===//
//
// 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.
//
//===----------------------------------------------------------------------===//
#include "pstl_test_config.h"
#include <algorithm>
#include <iostream>
#include "pstl/execution"
#include "pstl/algorithm"
#include "utils.h"
using namespace TestUtils;
// User defined type with minimal requirements
template <typename T>
struct DataType
{
explicit DataType(int32_t k) : my_val(k) {}
DataType(DataType&& input)
{
my_val = std::move(input.my_val);
input.my_val = T(0);
}
DataType&
operator=(DataType&& input)
{
my_val = std::move(input.my_val);
input.my_val = T(0);
return *this;
}
T
get_val() const
{
return my_val;
}
friend std::ostream&
operator<<(std::ostream& stream, const DataType<T>& input)
{
return stream << input.my_val;
}
private:
T my_val;
};
template <typename T>
bool
is_equal(const DataType<T>& x, const DataType<T>& y)
{
return x.get_val() == y.get_val();
}
template <typename T>
bool
is_equal(const T& x, const T& y)
{
return x == y;
}
struct test_one_policy
{
#if __PSTL_ICC_17_VC141_TEST_SIMD_LAMBDA_DEBUG_32_BROKEN || \
__PSTL_ICC_16_VC14_TEST_SIMD_LAMBDA_DEBUG_32_BROKEN // dummy specialization by policy type, in case of broken configuration
template <typename Iterator1, typename Size, typename Generator1, typename Generator2, typename Compare>
typename std::enable_if<is_same_iterator_category<Iterator1, std::random_access_iterator_tag>::value, void>::type
operator()(pstl::execution::unsequenced_policy, Iterator1 first1, Iterator1 last1, Iterator1 first2,
Iterator1 last2, Size n, Size m, Generator1 generator1, Generator2 generator2, Compare comp)
{
}
template <typename Iterator1, typename Size, typename Generator1, typename Generator2, typename Compare>
typename std::enable_if<is_same_iterator_category<Iterator1, std::random_access_iterator_tag>::value, void>::type
operator()(pstl::execution::parallel_unsequenced_policy, Iterator1 first1, Iterator1 last1, Iterator1 first2,
Iterator1 last2, Size n, Size m, Generator1 generator1, Generator2 generator2, Compare comp)
{
}
#endif
// nth_element works only with random access iterators
template <typename Policy, typename Iterator1, typename Size, typename Generator1, typename Generator2,
typename Compare>
typename std::enable_if<is_same_iterator_category<Iterator1, std::random_access_iterator_tag>::value, void>::type
operator()(Policy&& exec, Iterator1 first1, Iterator1 last1, Iterator1 first2, Iterator1 last2, Size n, Size m,
Generator1 generator1, Generator2 generator2, Compare comp)
{
using T = typename std::iterator_traits<Iterator1>::value_type;
const Iterator1 mid1 = std::next(first1, m);
const Iterator1 mid2 = std::next(first2, m);
fill_data(first1, mid1, generator1);
fill_data(mid1, last1, generator2);
fill_data(first2, mid2, generator1);
fill_data(mid2, last2, generator2);
std::nth_element(first1, mid1, last1, comp);
std::nth_element(exec, first2, mid2, last2, comp);
if (m > 0 && m < n)
{
EXPECT_TRUE(is_equal(*mid1, *mid2), "wrong result from nth_element with predicate");
}
EXPECT_TRUE(std::find_first_of(first2, mid2, mid2, last2, [comp](T& x, T& y) { return comp(y, x); }) == mid2,
"wrong effect from nth_element with predicate");
}
template <typename Policy, typename Iterator1, typename Size, typename Generator1, typename Generator2,
typename Compare>
typename std::enable_if<!is_same_iterator_category<Iterator1, std::random_access_iterator_tag>::value, void>::type
operator()(Policy&& exec, Iterator1 first1, Iterator1 last1, Iterator1 first2, Iterator1 last2, Size n, Size m,
Generator1 generator1, Generator2 generator2, Compare comp)
{
}
};
template <typename T, typename Generator1, typename Generator2, typename Compare>
void
test_by_type(Generator1 generator1, Generator2 generator2, Compare comp)
{
using namespace std;
size_t max_size = 10000;
Sequence<T> in1(max_size, [](size_t v) { return T(v); });
Sequence<T> exp(max_size, [](size_t v) { return T(v); });
size_t m;
for (size_t n = 0; n <= max_size; n = n <= 16 ? n + 1 : size_t(3.1415 * n))
{
m = 0;
invoke_on_all_policies(test_one_policy(), exp.begin(), exp.begin() + n, in1.begin(), in1.begin() + n, n, m,
generator1, generator2, comp);
m = n / 7;
invoke_on_all_policies(test_one_policy(), exp.begin(), exp.begin() + n, in1.begin(), in1.begin() + n, n, m,
generator1, generator2, comp);
m = 3 * n / 5;
invoke_on_all_policies(test_one_policy(), exp.begin(), exp.begin() + n, in1.begin(), in1.begin() + n, n, m,
generator1, generator2, comp);
}
invoke_on_all_policies(test_one_policy(), exp.begin(), exp.begin() + max_size, in1.begin(), in1.begin() + max_size,
max_size, max_size, generator1, generator2, comp);
}
template <typename T>
struct test_non_const
{
template <typename Policy, typename Iterator>
void
operator()(Policy&& exec, Iterator iter)
{
invoke_if(exec, [&]() { nth_element(exec, iter, iter, iter, non_const(std::less<T>())); });
}
};
int32_t
main()
{
test_by_type<int32_t>([](int32_t i) { return 10 * i; }, [](int32_t i) { return i + 1; }, std::less<int32_t>());
test_by_type<int32_t>([](int32_t) { return 0; }, [](int32_t) { return 0; }, std::less<int32_t>());
test_by_type<float64_t>([](int32_t i) { return -2 * i; }, [](int32_t i) { return -(2 * i + 1); },
[](const float64_t x, const float64_t y) { return x > y; });
test_by_type<DataType<float32_t>>(
[](int32_t i) { return DataType<float32_t>(2 * i + 1); }, [](int32_t i) { return DataType<float32_t>(2 * i); },
[](const DataType<float32_t>& x, const DataType<float32_t>& y) { return x.get_val() < y.get_val(); });
test_algo_basic_single<int32_t>(run_for_rnd<test_non_const<int32_t>>());
std::cout << done() << std::endl;
return 0;
}