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349 lines
9.3 KiB
C++
349 lines
9.3 KiB
C++
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// This file is part of OpenCV project.
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// It is subject to the license terms in the LICENSE file found in the top-level directory
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// of this distribution and at http://opencv.org/license.html.
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//
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// Copyright (C) 2021 Intel Corporation
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#include "../test_precomp.hpp"
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#include "../common/gapi_streaming_tests_common.hpp"
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#include <chrono>
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#include <future>
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#define private public
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#include "streaming/onevpl/accelerators/utils/shared_lock.hpp"
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#undef private
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#include "streaming/onevpl/accelerators/utils/elastic_barrier.hpp"
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namespace opencv_test
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{
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namespace
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{
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using cv::gapi::wip::onevpl::SharedLock;
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struct TestBarrier : public cv::gapi::wip::onevpl::elastic_barrier<TestBarrier> {
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void on_first_in_impl(size_t visitor_id) {
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static std::atomic<int> thread_counter{};
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thread_counter++;
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EXPECT_EQ(thread_counter.load(), 1);
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visitors_in.insert(visitor_id);
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last_visitor_id = visitor_id;
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thread_counter--;
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EXPECT_EQ(thread_counter.load(), 0);
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}
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void on_last_out_impl(size_t visitor_id) {
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static std::atomic<int> thread_counter{};
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thread_counter++;
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EXPECT_EQ(thread_counter.load(), 1);
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visitors_out.insert(visitor_id);
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last_visitor_id = visitor_id;
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thread_counter--;
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EXPECT_EQ(thread_counter.load(), 0);
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}
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size_t last_visitor_id = 0;
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std::set<size_t> visitors_in;
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std::set<size_t> visitors_out;
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};
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TEST(OneVPL_SharedLock, Create) {
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SharedLock lock;
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EXPECT_EQ(lock.shared_counter.load(), size_t{0});
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}
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TEST(OneVPL_SharedLock, Read_SingleThread)
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{
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SharedLock lock;
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const size_t single_thread_read_count = 100;
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for(size_t i = 0; i < single_thread_read_count; i++) {
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lock.shared_lock();
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EXPECT_FALSE(lock.owns());
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}
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EXPECT_EQ(lock.shared_counter.load(), single_thread_read_count);
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for(size_t i = 0; i < single_thread_read_count; i++) {
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lock.unlock_shared();
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EXPECT_FALSE(lock.owns());
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}
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EXPECT_EQ(lock.shared_counter.load(), size_t{0});
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}
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TEST(OneVPL_SharedLock, TryLock_SingleThread)
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{
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SharedLock lock;
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EXPECT_TRUE(lock.try_lock());
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EXPECT_TRUE(lock.owns());
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lock.unlock();
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EXPECT_FALSE(lock.owns());
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EXPECT_EQ(lock.shared_counter.load(), size_t{0});
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}
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TEST(OneVPL_SharedLock, Write_SingleThread)
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{
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SharedLock lock;
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lock.lock();
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EXPECT_TRUE(lock.owns());
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lock.unlock();
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EXPECT_FALSE(lock.owns());
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EXPECT_EQ(lock.shared_counter.load(), size_t{0});
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}
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TEST(OneVPL_SharedLock, TryLockTryLock_SingleThread)
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{
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SharedLock lock;
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lock.try_lock();
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EXPECT_FALSE(lock.try_lock());
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lock.unlock();
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EXPECT_FALSE(lock.owns());
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}
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TEST(OneVPL_SharedLock, ReadTryLock_SingleThread)
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{
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SharedLock lock;
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lock.shared_lock();
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EXPECT_FALSE(lock.owns());
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EXPECT_FALSE(lock.try_lock());
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lock.unlock_shared();
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EXPECT_TRUE(lock.try_lock());
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EXPECT_TRUE(lock.owns());
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lock.unlock();
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}
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TEST(OneVPL_SharedLock, WriteTryLock_SingleThread)
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{
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SharedLock lock;
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lock.lock();
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EXPECT_TRUE(lock.owns());
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EXPECT_FALSE(lock.try_lock());
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lock.unlock();
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EXPECT_TRUE(lock.try_lock());
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EXPECT_TRUE(lock.owns());
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lock.unlock();
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}
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TEST(OneVPL_SharedLock, Write_MultiThread)
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{
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SharedLock lock;
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std::promise<void> barrier;
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std::shared_future<void> sync = barrier.get_future();
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static const size_t inc_count = 10000000;
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size_t shared_value = 0;
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auto work = [&lock, &shared_value](size_t count) {
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for (size_t i = 0; i < count; i ++) {
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lock.lock();
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shared_value ++;
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lock.unlock();
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}
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};
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std::thread worker_thread([&barrier, sync, work] () {
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std::thread sub_worker([&barrier, work] () {
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barrier.set_value();
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work(inc_count);
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});
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sync.wait();
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work(inc_count);
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sub_worker.join();
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});
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sync.wait();
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work(inc_count);
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worker_thread.join();
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EXPECT_EQ(shared_value, inc_count * 3);
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}
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TEST(OneVPL_SharedLock, ReadWrite_MultiThread)
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{
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SharedLock lock;
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std::promise<void> barrier;
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std::future<void> sync = barrier.get_future();
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static const size_t inc_count = 10000000;
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size_t shared_value = 0;
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auto write_work = [&lock, &shared_value](size_t count) {
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for (size_t i = 0; i < count; i ++) {
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lock.lock();
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shared_value ++;
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lock.unlock();
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}
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};
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auto read_work = [&lock, &shared_value](size_t count) {
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auto old_shared_value = shared_value;
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for (size_t i = 0; i < count; i ++) {
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lock.shared_lock();
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EXPECT_TRUE(shared_value >= old_shared_value);
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old_shared_value = shared_value;
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lock.unlock_shared();
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}
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};
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std::thread writer_thread([&barrier, write_work] () {
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barrier.set_value();
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write_work(inc_count);
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});
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sync.wait();
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read_work(inc_count);
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writer_thread.join();
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EXPECT_EQ(shared_value, inc_count);
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}
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TEST(OneVPL_ElasticBarrier, single_thread_visit)
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{
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TestBarrier barrier;
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const size_t max_visit_count = 10000;
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size_t visit_id = 0;
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for (visit_id = 0; visit_id < max_visit_count; visit_id++) {
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barrier.visit_in(visit_id);
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EXPECT_EQ(barrier.visitors_in.size(), size_t{1});
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}
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EXPECT_EQ(barrier.last_visitor_id, size_t{0});
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EXPECT_EQ(barrier.visitors_out.size(), size_t{0});
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for (visit_id = 0; visit_id < max_visit_count; visit_id++) {
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barrier.visit_out(visit_id);
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EXPECT_EQ(barrier.visitors_in.size(), size_t{1});
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}
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EXPECT_EQ(barrier.last_visitor_id, visit_id - 1);
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EXPECT_EQ(barrier.visitors_out.size(), size_t{1});
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}
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TEST(OneVPL_ElasticBarrier, multi_thread_visit)
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{
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TestBarrier tested_barrier;
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static const size_t max_visit_count = 10000000;
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std::atomic<size_t> visit_in_wait_counter{};
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std::promise<void> start_sync_barrier;
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std::shared_future<void> start_sync = start_sync_barrier.get_future();
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std::promise<void> phase_sync_barrier;
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std::shared_future<void> phase_sync = phase_sync_barrier.get_future();
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auto visit_worker_job = [&tested_barrier,
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&visit_in_wait_counter,
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start_sync,
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phase_sync] (size_t worker_id) {
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start_sync.wait();
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// first phase
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const size_t begin_range = worker_id * max_visit_count;
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const size_t end_range = (worker_id + 1) * max_visit_count;
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for (size_t visit_id = begin_range; visit_id < end_range; visit_id++) {
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tested_barrier.visit_in(visit_id);
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}
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// notify all worker first phase ready
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visit_in_wait_counter.fetch_add(1);
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// wait main second phase
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phase_sync.wait();
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// second phase
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for (size_t visit_id = begin_range; visit_id < end_range; visit_id++) {
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tested_barrier.visit_out(visit_id);
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}
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};
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auto visit_main_job = [&tested_barrier,
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&visit_in_wait_counter,
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&phase_sync_barrier] (size_t total_workers_count,
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size_t worker_id) {
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const size_t begin_range = worker_id * max_visit_count;
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const size_t end_range = (worker_id + 1) * max_visit_count;
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for (size_t visit_id = begin_range; visit_id < end_range; visit_id++) {
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tested_barrier.visit_in(visit_id);
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}
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// wait all workers first phase done
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visit_in_wait_counter.fetch_add(1);
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while (visit_in_wait_counter.load() != total_workers_count) {
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std::this_thread::yield();
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};
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// TEST invariant: last_visitor_id MUST be one from any FIRST worker visitor_id
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bool one_of_available_ids_matched = false;
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for (size_t id = 0; id < total_workers_count; id ++) {
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size_t expected_last_visitor_for_id = id * max_visit_count;
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one_of_available_ids_matched |=
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(tested_barrier.last_visitor_id == expected_last_visitor_for_id) ;
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}
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EXPECT_TRUE(one_of_available_ids_matched);
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// unblock all workers to work out second phase
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phase_sync_barrier.set_value();
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// continue second phase
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for (size_t visit_id = begin_range; visit_id < end_range; visit_id++) {
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tested_barrier.visit_out(visit_id);
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}
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};
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size_t max_worker_count = std::thread::hardware_concurrency();
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if (max_worker_count < 2) {
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max_worker_count = 2; // logical 2 threads required at least
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}
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std::vector<std::thread> workers;
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workers.reserve(max_worker_count);
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for (size_t worker_id = 1; worker_id < max_worker_count; worker_id++) {
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workers.emplace_back(visit_worker_job, worker_id);
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}
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// let's go for first phase
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start_sync_barrier.set_value();
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// utilize main thread as well
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visit_main_job(max_worker_count, 0);
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// join all threads second phase
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for (auto& w : workers) {
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w.join();
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}
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// TEST invariant: last_visitor_id MUST be one from any LATTER worker visitor_id
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bool one_of_available_ids_matched = false;
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for (size_t id = 0; id < max_worker_count; id ++) {
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one_of_available_ids_matched |=
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(tested_barrier.last_visitor_id == ((id + 1) * max_visit_count - 1)) ;
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}
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EXPECT_TRUE(one_of_available_ids_matched);
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}
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}
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} // opencv_test
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