I'm reading C++ Concurrency in Action by Anthony Williams. In the chapter about designing concurrent code there is parallel version of std::for_each algorihtm. Here is slightly modified code from the book:
join_thread.hpp
#pragma once
#include <vector>
#include <thread>
class join_threads
{
public:
explicit join_threads(std::vector<std::thread>& threads)
: threads_(threads) {}
~join_threads()
{
for (size_t i = 0; i < threads_.size(); ++i)
{
if(threads_[i].joinable())
{
threads_[i].join();
}
}
}
private:
std::vector<std::thread>& threads_;
};
parallel_for_each.hpp
#pragma once
#include <future>
#include <algorithm>
#include "join_threads.hpp"
template<typename Iterator, typename Func>
void parallel_for_each(Iterator first, Iterator last, Func func)
{
const auto length = std::distance(first, last);
if (0 == length) return;
const auto min_per_thread = 25u;
const unsigned max_threads = (length + min_per_thread - 1) / min_per_thread;
const auto hardware_threads = std::thread::hardware_concurrency();
const auto num_threads= std::min(hardware_threads != 0 ?
hardware_threads : 2u, max_threads);
const auto block_size = length / num_threads;
std::vector<std::future<void>> futures(num_threads - 1);
std::vector<std::thread> threads(num_threads-1);
join_threads joiner(threads);
auto block_start = first;
for (unsigned i = 0; i < num_threads - 1; ++i)
{
auto block_end = block_start;
std::advance(block_end, block_size);
std::packaged_task<void (void)> task([block_start, block_end, func]()
{
std::for_each(block_start, block_end, func);
});
futures[i] = task.get_future();
threads[i] = std::thread(std::move(task));
block_start = block_end;
}
std::for_each(block_start, last, func);
for (size_t i = 0; i < num_threads - 1; ++i)
{
futures[i].get();
}
}
I benchmarked it with sequential version of std::for_each using the following program:
main.cpp
#include <iostream>
#include <random>
#include <chrono>
#include "parallel_for_each.hpp"
using namespace std;
constexpr size_t ARRAY_SIZE = 500'000'000;
typedef std::vector<uint64_t> Array;
template <class FE, class F>
void test_for_each(const Array& a, FE fe, F f, atomic<uint64_t>& result)
{
auto time_begin = chrono::high_resolution_clock::now();
result = 0;
fe(a.begin(), a.end(), f);
auto time_end = chrono::high_resolution_clock::now();
cout << "Result = " << result << endl;
cout << "Time: " << chrono::duration_cast<chrono::milliseconds>(
time_end - time_begin).count() << endl;
}
int main()
{
random_device device;
default_random_engine engine(device());
uniform_int_distribution<uint8_t> distribution(0, 255);
Array a;
a.reserve(ARRAY_SIZE);
cout << "Generating array ... " << endl;
for (size_t i = 0; i < ARRAY_SIZE; ++i)
a.push_back(distribution(engine));
atomic<uint64_t> result;
auto acc = [&result](uint64_t value) { result += value; };
cout << "parallel_for_each ..." << endl;
test_for_each(a, parallel_for_each<Array::const_iterator, decltype(acc)>, acc, result);
cout << "for_each ..." << endl;
test_for_each(a, for_each<Array::const_iterator, decltype(acc)>, acc, result);
return 0;
}
The parallel version of the algorithm on my machine is more than two times slower than sequential one:
parallel_for_each ...
Result = 63750301073
Time: 5448
for_each ...
Result = 63750301073
Time: 2496
I'm using GCC 6.2 compiler on Ubuntu Linux running on Intel(R) Core(TM) i3-6100 CPU @ 3.70GHz.
How such a behavior can be explained? Is this because of sharing of atomic<uint64_t>
variable between threads and cache ping-pong?
I profiled both separately with perf. For the parallel version the stats are the following:
1137982167 cache-references
247652893 cache-misses # 21,762 % of all cache refs
60868183996 cycles
27409239189 instructions # 0,45 insns per cycle
3287117194 branches
80895 faults
4 migrations
And for the sequential one:
402791485 cache-references
246561299 cache-misses # 61,213 % of all cache refs
40284812779 cycles
26515783790 instructions # 0,66 insns per cycle
3188784664 branches
48179 faults
3 migrations
It is obvious that the parallel version generates far more cache references, cycles and faults but why?