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// -----------------------------------------------------------------------------------------------------
// Copyright (c) 2006-2020, Knut Reinert & Freie Universität Berlin
// Copyright (c) 2016-2020, Knut Reinert & MPI für molekulare Genetik
// This file may be used, modified and/or redistributed under the terms of the 3-clause BSD-License
// shipped with this file and also available at: https://github.com/seqan/seqan3/blob/master/LICENSE.md
// -----------------------------------------------------------------------------------------------------
#include <deque>
#include <forward_list>
#include <list>
#include <random>
#include <string>
#include <vector>
#include <benchmark/benchmark.h>
#include <seqan3/range/views/drop.hpp>
#include <seqan3/range/views/single_pass_input.hpp>
// ============================================================================
// sequential_read
// ============================================================================
template <typename container_t, typename adaptor_t, bool single_pass = false>
void sequential_read(benchmark::State & state)
{
container_t c;
c.resize(1'000'000);
uint8_t i = 0;
for (auto & e : c)
e = ++i; // dummy values
uint8_t dummy = 0;
// if single_pass, add seqan3::views::single_pass_input, otherwise just &
using single_t = std::conditional_t<single_pass, decltype(c | seqan3::views::single_pass_input), container_t &>;
if constexpr (std::same_as<adaptor_t, void>)
{
for (auto _ : state)
{
single_t s{c};
for (auto e : s)
dummy += e;
}
}
else
{
auto adaptor = adaptor_t{}(1'000);
for (auto _ : state)
{
single_t s{c};
auto v = s | adaptor | adaptor | adaptor | adaptor | adaptor;
for (auto e : v)
dummy += e;
}
}
[[maybe_unused]] volatile uint8_t dummy2 = dummy;
}
BENCHMARK_TEMPLATE(sequential_read, std::string, void);
BENCHMARK_TEMPLATE(sequential_read, std::string, decltype(std::views::drop));
BENCHMARK_TEMPLATE(sequential_read, std::string, decltype(seqan3::views::drop));
BENCHMARK_TEMPLATE(sequential_read, std::vector<uint8_t>, void);
BENCHMARK_TEMPLATE(sequential_read, std::vector<uint8_t>, decltype(std::views::drop));
BENCHMARK_TEMPLATE(sequential_read, std::vector<uint8_t>, decltype(seqan3::views::drop));
BENCHMARK_TEMPLATE(sequential_read, std::deque<uint8_t>, void);
BENCHMARK_TEMPLATE(sequential_read, std::deque<uint8_t>, decltype(std::views::drop));
BENCHMARK_TEMPLATE(sequential_read, std::deque<uint8_t>, decltype(seqan3::views::drop));
BENCHMARK_TEMPLATE(sequential_read, std::list<uint8_t>, void);
BENCHMARK_TEMPLATE(sequential_read, std::list<uint8_t>, decltype(std::views::drop));
BENCHMARK_TEMPLATE(sequential_read, std::list<uint8_t>, decltype(seqan3::views::drop));
BENCHMARK_TEMPLATE(sequential_read, std::forward_list<uint8_t>, void);
BENCHMARK_TEMPLATE(sequential_read, std::forward_list<uint8_t>, decltype(std::views::drop));
BENCHMARK_TEMPLATE(sequential_read, std::forward_list<uint8_t>, decltype(seqan3::views::drop));
BENCHMARK_TEMPLATE(sequential_read, std::vector<uint8_t>, void, true);
BENCHMARK_TEMPLATE(sequential_read, std::vector<uint8_t>, decltype(std::views::drop), true);
BENCHMARK_TEMPLATE(sequential_read, std::vector<uint8_t>, decltype(seqan3::views::drop), true);
BENCHMARK_TEMPLATE(sequential_read, std::forward_list<uint8_t>, void, true);
BENCHMARK_TEMPLATE(sequential_read, std::forward_list<uint8_t>, decltype(std::views::drop), true);
BENCHMARK_TEMPLATE(sequential_read, std::forward_list<uint8_t>, decltype(seqan3::views::drop), true);
// ============================================================================
// random access
// ============================================================================
template <typename container_t, typename adaptor_t>
void random_access(benchmark::State & state)
{
container_t c;
c.resize(1'005'000); // 5'000 more that will be dropped
uint8_t i = 0;
for (auto & e : c)
e = ++i; // dummy values
std::vector<size_t> access_positions;
access_positions.resize(1'000'000);
std::mt19937 gen(42);
std::uniform_int_distribution<size_t> dis(0, 1'000'000 - 1);
for (size_t i = 0; i < 1'000'000; ++i)
access_positions[i] = dis(gen);
size_t dummy = 0;
if constexpr (std::same_as<adaptor_t, void>)
{
for (auto _ : state)
{
for (auto i : access_positions)
dummy += c[i];
}
}
else
{
auto adaptor = adaptor_t{}(1'000);
for (auto _ : state)
{
auto v = c | adaptor | adaptor | adaptor | adaptor | adaptor;
for (auto i : access_positions)
dummy += v[i];
}
}
[[maybe_unused]] volatile size_t dummy2 = dummy;
}
BENCHMARK_TEMPLATE(random_access, std::string, void);
BENCHMARK_TEMPLATE(random_access, std::string, decltype(std::views::drop));
BENCHMARK_TEMPLATE(random_access, std::string, decltype(seqan3::views::drop));
BENCHMARK_TEMPLATE(random_access, std::vector<uint8_t>, void);
BENCHMARK_TEMPLATE(random_access, std::vector<uint8_t>, decltype(std::views::drop));
BENCHMARK_TEMPLATE(random_access, std::vector<uint8_t>, decltype(seqan3::views::drop));
BENCHMARK_TEMPLATE(random_access, std::deque<uint8_t>, void);
BENCHMARK_TEMPLATE(random_access, std::deque<uint8_t>, decltype(std::views::drop));
BENCHMARK_TEMPLATE(random_access, std::deque<uint8_t>, decltype(seqan3::views::drop));
// ============================================================================
// run
// ============================================================================
BENCHMARK_MAIN();
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