// Copyright (c) 2020 Andrey Semashev // // Distributed under the Boost Software License, Version 1.0. // See accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) // This test is based on ordering.cpp by Helge Bahmann and Tim Blechmann. // The test Was modified to use atomic_ref template instead of atomic. // Attempt to determine whether the memory ordering/ fence operations // work as expected: // Let two threads race accessing multiple shared variables and // verify that "observable" order of operations matches with the // ordering constraints specified. // // We assume that "memory ordering violation" events are exponentially // distributed, with unknown "average time between violations" // (which is just the reciprocal of exp distribution parameter lambda). // Use a "relaxed ordering" implementation that intentionally exhibits // a (hopefully observable) such violation to compute the maximum-likelihood // estimate for this time. From this, compute an estimate that covers the // unknown value with 0.995 confidence (using chi square quantile). // // Use this estimate to pick a timeout for the race tests of the // atomic implementations such that under the assumed distribution // we get 0.995 probability to detect a race (if there is one). // // Overall this yields 0.995 * 0.995 > 0.99 confidence that the // fences work as expected if this test program does not // report an error. #include #include #include #include #include #include #include #include #include #include #include #include #include #include // Two threads perform the following operations: // // thread # 1 thread # 2 // store(a, 1) store(b, 1) // x = read(b) y = read(a) // // Under relaxed memory ordering, the case (x, y) == (0, 0) is // possible. Under sequential consistency, this case is impossible. // // This "problem" is reproducible on all platforms, even x86. template class total_store_order_test { public: total_store_order_test(void); void run(boost::posix_time::time_duration & timeout); bool detected_conflict(void) const { return detected_conflict_; } private: void thread1fn(void); void thread2fn(void); void check_conflict(void); private: int a_value_; boost::atomic_ref a_; /* insert a bit of padding to push the two variables into different cache lines and increase the likelihood of detecting a conflict */ char pad1_[512]; int b_value_; boost::atomic_ref b_; char pad2_[512]; boost::barrier barrier_; int vrfyb1_, vrfya2_; boost::atomic terminate_threads_; boost::atomic termination_consensus_; bool detected_conflict_; boost::mutex m_; boost::condition_variable c_; }; template total_store_order_test::total_store_order_test(void) : a_value_(0), a_(a_value_), b_value_(0), b_(b_value_), barrier_(2), vrfyb1_(0), vrfya2_(0), terminate_threads_(false), termination_consensus_(0), detected_conflict_(false) { } template void total_store_order_test::run(boost::posix_time::time_duration & timeout) { boost::system_time start = boost::get_system_time(); boost::system_time end = start + timeout; boost::thread t1(boost::bind(&total_store_order_test::thread1fn, this)); boost::thread t2(boost::bind(&total_store_order_test::thread2fn, this)); { boost::unique_lock< boost::mutex > guard(m_); while (boost::get_system_time() < end && !detected_conflict_) c_.timed_wait(guard, end); } terminate_threads_.store(true, boost::memory_order_relaxed); t2.join(); t1.join(); boost::posix_time::time_duration duration = boost::get_system_time() - start; if (duration < timeout) timeout = duration; } volatile int backoff_dummy; template void total_store_order_test::thread1fn(void) { while (true) { a_.store(1, store_order); int b = b_.load(load_order); barrier_.wait(); vrfyb1_ = b; barrier_.wait(); check_conflict(); /* both threads synchronize via barriers, so either both threads must exit here, or they must both do another round, otherwise one of them will wait forever */ if (terminate_threads_.load(boost::memory_order_relaxed)) { while (true) { int tmp = termination_consensus_.fetch_or(1, boost::memory_order_relaxed); if (tmp == 3) return; if (tmp & 4) break; } } termination_consensus_.fetch_xor(4, boost::memory_order_relaxed); unsigned int delay = rand() % 10000; a_.store(0, boost::memory_order_relaxed); barrier_.wait(); while (delay--) backoff_dummy = delay; } } template void total_store_order_test::thread2fn(void) { while (true) { b_.store(1, store_order); int a = a_.load(load_order); barrier_.wait(); vrfya2_ = a; barrier_.wait(); check_conflict(); /* both threads synchronize via barriers, so either both threads must exit here, or they must both do another round, otherwise one of them will wait forever */ if (terminate_threads_.load(boost::memory_order_relaxed)) { while (true) { int tmp = termination_consensus_.fetch_or(2, boost::memory_order_relaxed); if (tmp == 3) return; if (tmp & 4) break; } } termination_consensus_.fetch_xor(4, boost::memory_order_relaxed); unsigned int delay = rand() % 10000; b_.store(0, boost::memory_order_relaxed); barrier_.wait(); while (delay--) backoff_dummy = delay; } } template void total_store_order_test::check_conflict(void) { if (vrfyb1_ == 0 && vrfya2_ == 0) { boost::lock_guard< boost::mutex > guard(m_); detected_conflict_ = true; terminate_threads_.store(true, boost::memory_order_relaxed); c_.notify_all(); } } void test_seq_cst(void) { double sum = 0.0; /* take 10 samples */ for (std::size_t n = 0; n < 10; n++) { boost::posix_time::time_duration timeout(0, 0, 10); total_store_order_test test; test.run(timeout); if (!test.detected_conflict()) { std::cout << "Failed to detect order=seq_cst violation while ith order=relaxed -- intrinsic ordering too strong for this test\n"; return; } std::cout << "seq_cst violation with order=relaxed after " << timeout.total_microseconds() << " us\n"; sum = sum + timeout.total_microseconds(); } /* determine maximum likelihood estimate for average time between race observations */ double avg_race_time_mle = (sum / 10); /* pick 0.995 confidence (7.44 = chi square 0.995 confidence) */ double avg_race_time_995 = avg_race_time_mle * 2 * 10 / 7.44; /* 5.298 = 0.995 quantile of exponential distribution */ boost::posix_time::time_duration timeout = boost::posix_time::microseconds((long)(5.298 * avg_race_time_995)); std::cout << "run seq_cst for " << timeout.total_microseconds() << " us\n"; total_store_order_test test; test.run(timeout); BOOST_TEST(!test.detected_conflict()); // sequential consistency error } int main(int, char *[]) { test_seq_cst(); return boost::report_errors(); }