faux-folly/folly/test/BatonTest.cpp - nest-cam/4320010/faux-folly - Git at Google

 /*
  * Copyright 2015 Facebook, Inc.
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *   http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include <folly/Baton.h>
 #include <folly/test/DeterministicSchedule.h>
 #include <thread>
 #include <semaphore.h>
 #include <gflags/gflags.h>
 #include <gtest/gtest.h>
 #include <folly/Benchmark.h>

 using namespace folly;
 using namespace folly::test;
 using folly::detail::EmulatedFutexAtomic;

 typedef DeterministicSchedule DSched;

 TEST(Baton, basic) {
   Baton<> b;
   b.post();
   b.wait();
 }

 template <template<typename> class Atom>
 void run_pingpong_test(int numRounds) {
   Baton<Atom> batons[17];
   Baton<Atom>& a = batons[0];
   Baton<Atom>& b = batons[16]; // to get it on a different cache line
   auto thr = DSched::thread([&]{
     for (int i = 0; i < numRounds; ++i) {
       a.wait();
       a.reset();
       b.post();
     }
   });
   for (int i = 0; i < numRounds; ++i) {
     a.post();
     b.wait();
     b.reset();
   }
   DSched::join(thr);
 }

 TEST(Baton, pingpong) {
   DSched sched(DSched::uniform(0));

   run_pingpong_test<DeterministicAtomic>(1000);
 }

 BENCHMARK(baton_pingpong, iters) {
   run_pingpong_test<std::atomic>(iters);
 }

 BENCHMARK(baton_pingpong_emulated_futex, iters) {
   run_pingpong_test<EmulatedFutexAtomic>(iters);
 }

 BENCHMARK(posix_sem_pingpong, iters) {
   sem_t sems[3];
   sem_t* a = sems + 0;
   sem_t* b = sems + 2; // to get it on a different cache line

   sem_init(a, 0, 0);
   sem_init(b, 0, 0);
   auto thr = std::thread([=]{
     for (size_t i = 0; i < iters; ++i) {
       sem_wait(a);
       sem_post(b);
     }
   });
   for (size_t i = 0; i < iters; ++i) {
     sem_post(a);
     sem_wait(b);
   }
   thr.join();
 }

 template <template<typename> class Atom, typename Clock>
 void run_basic_timed_wait_tests() {
   Baton<Atom> b;
   b.post();
   // tests if early delivery works fine
   EXPECT_TRUE(b.timed_wait(Clock::now()));
 }

 template <template<typename> class Atom, typename Clock>
 void run_timed_wait_tmo_tests() {
   Baton<Atom> b;

   auto thr = DSched::thread([&]{
     bool rv = b.timed_wait(Clock::now() + std::chrono::milliseconds(1));
     // main thread is guaranteed to not post until timeout occurs
     EXPECT_FALSE(rv);
   });
   DSched::join(thr);
 }

 template <template<typename> class Atom, typename Clock>
 void run_timed_wait_regular_test() {
   Baton<Atom> b;

   auto thr = DSched::thread([&] {
     // To wait forever we'd like to use time_point<Clock>::max, but
     // std::condition_variable does math to convert the timeout to
     // system_clock without handling overflow.
     auto farFuture = Clock::now() + std::chrono::hours(1000);
     bool rv = b.timed_wait(farFuture);
     if (!std::is_same<Atom<int>, DeterministicAtomic<int>>::value) {
       // DeterministicAtomic ignores actual times, so doesn't guarantee
       // a lack of timeout
       EXPECT_TRUE(rv);
     }
   });

   if (!std::is_same<Atom<int>, DeterministicAtomic<int>>::value) {
     // If we are using std::atomic (or EmulatedFutexAtomic) then
     // a sleep here guarantees to a large extent that 'thr' will
     // execute wait before we post it, thus testing late delivery. For
     // DeterministicAtomic, we just rely on DeterministicSchedule to do
     // the scheduling.  The test won't fail if we lose the race, we just
     // don't get coverage.
     std::this_thread::sleep_for(std::chrono::milliseconds(2));
   }

   b.post();
   DSched::join(thr);
 }

 TEST(Baton, timed_wait_basic_system_clock) {
   run_basic_timed_wait_tests<std::atomic, std::chrono::system_clock>();
   run_basic_timed_wait_tests<EmulatedFutexAtomic, std::chrono::system_clock>();
   run_basic_timed_wait_tests<DeterministicAtomic, std::chrono::system_clock>();
 }

 TEST(Baton, timed_wait_timeout_system_clock) {
   run_timed_wait_tmo_tests<std::atomic, std::chrono::system_clock>();
   run_timed_wait_tmo_tests<EmulatedFutexAtomic, std::chrono::system_clock>();
   run_timed_wait_tmo_tests<DeterministicAtomic, std::chrono::system_clock>();
 }

 TEST(Baton, timed_wait_system_clock) {
   run_timed_wait_regular_test<std::atomic, std::chrono::system_clock>();
   run_timed_wait_regular_test<EmulatedFutexAtomic, std::chrono::system_clock>();
   run_timed_wait_regular_test<DeterministicAtomic, std::chrono::system_clock>();
 }

 TEST(Baton, timed_wait_basic_steady_clock) {
   run_basic_timed_wait_tests<std::atomic, std::chrono::steady_clock>();
   run_basic_timed_wait_tests<EmulatedFutexAtomic, std::chrono::steady_clock>();
   run_basic_timed_wait_tests<DeterministicAtomic, std::chrono::steady_clock>();
 }

 TEST(Baton, timed_wait_timeout_steady_clock) {
   run_timed_wait_tmo_tests<std::atomic, std::chrono::steady_clock>();
   run_timed_wait_tmo_tests<EmulatedFutexAtomic, std::chrono::steady_clock>();
   run_timed_wait_tmo_tests<DeterministicAtomic, std::chrono::steady_clock>();
 }

 TEST(Baton, timed_wait_steady_clock) {
   run_timed_wait_regular_test<std::atomic, std::chrono::steady_clock>();
   run_timed_wait_regular_test<EmulatedFutexAtomic, std::chrono::steady_clock>();
   run_timed_wait_regular_test<DeterministicAtomic, std::chrono::steady_clock>();
 }

 template <template<typename> class Atom>
 void run_try_wait_tests() {
   Baton<Atom> b;
   EXPECT_FALSE(b.try_wait());
   b.post();
   EXPECT_TRUE(b.try_wait());
 }

 TEST(Baton, try_wait) {
   run_try_wait_tests<std::atomic>();
   run_try_wait_tests<EmulatedFutexAtomic>();
   run_try_wait_tests<DeterministicAtomic>();
 }

 // I am omitting a benchmark result snapshot because these microbenchmarks
 // mainly illustrate that PreBlockAttempts is very effective for rapid
 // handoffs.  The performance of Baton and sem_t is essentially identical
 // to the required futex calls for the blocking case

 int main(int argc, char** argv) {
   testing::InitGoogleTest(&argc, argv);
   gflags::ParseCommandLineFlags(&argc, &argv, true);

   auto rv = RUN_ALL_TESTS();
   if (!rv && FLAGS_benchmark) {
     folly::runBenchmarks();
   }
   return rv;
 }
	/*
	* Copyright 2015 Facebook, Inc.
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include <folly/Baton.h>
	#include <folly/test/DeterministicSchedule.h>
	#include <thread>
	#include <semaphore.h>
	#include <gflags/gflags.h>
	#include <gtest/gtest.h>
	#include <folly/Benchmark.h>

	using namespace folly;
	using namespace folly::test;
	using folly::detail::EmulatedFutexAtomic;

	typedef DeterministicSchedule DSched;

	TEST(Baton, basic) {
	Baton<> b;
	b.post();
	b.wait();
	}

	template <template<typename> class Atom>
	void run_pingpong_test(int numRounds) {
	Baton<Atom> batons[17];
	Baton<Atom>& a = batons[0];
	Baton<Atom>& b = batons[16]; // to get it on a different cache line
	auto thr = DSched::thread([&]{
	for (int i = 0; i < numRounds; ++i) {
	a.wait();
	a.reset();
	b.post();
	}
	});
	for (int i = 0; i < numRounds; ++i) {
	a.post();
	b.wait();
	b.reset();
	}
	DSched::join(thr);
	}

	TEST(Baton, pingpong) {
	DSched sched(DSched::uniform(0));

	run_pingpong_test<DeterministicAtomic>(1000);
	}

	BENCHMARK(baton_pingpong, iters) {
	run_pingpong_test<std::atomic>(iters);
	}

	BENCHMARK(baton_pingpong_emulated_futex, iters) {
	run_pingpong_test<EmulatedFutexAtomic>(iters);
	}

	BENCHMARK(posix_sem_pingpong, iters) {
	sem_t sems[3];
	sem_t* a = sems + 0;
	sem_t* b = sems + 2; // to get it on a different cache line

	sem_init(a, 0, 0);
	sem_init(b, 0, 0);
	auto thr = std::thread([=]{
	for (size_t i = 0; i < iters; ++i) {
	sem_wait(a);
	sem_post(b);
	}
	});
	for (size_t i = 0; i < iters; ++i) {
	sem_post(a);
	sem_wait(b);
	}
	thr.join();
	}

	template <template<typename> class Atom, typename Clock>
	void run_basic_timed_wait_tests() {
	Baton<Atom> b;
	b.post();
	// tests if early delivery works fine
	EXPECT_TRUE(b.timed_wait(Clock::now()));
	}

	template <template<typename> class Atom, typename Clock>
	void run_timed_wait_tmo_tests() {
	Baton<Atom> b;

	auto thr = DSched::thread([&]{
	bool rv = b.timed_wait(Clock::now() + std::chrono::milliseconds(1));
	// main thread is guaranteed to not post until timeout occurs
	EXPECT_FALSE(rv);
	});
	DSched::join(thr);
	}

	template <template<typename> class Atom, typename Clock>
	void run_timed_wait_regular_test() {
	Baton<Atom> b;

	auto thr = DSched::thread([&] {
	// To wait forever we'd like to use time_point<Clock>::max, but
	// std::condition_variable does math to convert the timeout to
	// system_clock without handling overflow.
	auto farFuture = Clock::now() + std::chrono::hours(1000);
	bool rv = b.timed_wait(farFuture);
	if (!std::is_same<Atom<int>, DeterministicAtomic<int>>::value) {
	// DeterministicAtomic ignores actual times, so doesn't guarantee
	// a lack of timeout
	EXPECT_TRUE(rv);
	}
	});

	if (!std::is_same<Atom<int>, DeterministicAtomic<int>>::value) {
	// If we are using std::atomic (or EmulatedFutexAtomic) then
	// a sleep here guarantees to a large extent that 'thr' will
	// execute wait before we post it, thus testing late delivery. For
	// DeterministicAtomic, we just rely on DeterministicSchedule to do
	// the scheduling. The test won't fail if we lose the race, we just
	// don't get coverage.
	std::this_thread::sleep_for(std::chrono::milliseconds(2));
	}

	b.post();
	DSched::join(thr);
	}

	TEST(Baton, timed_wait_basic_system_clock) {
	run_basic_timed_wait_tests<std::atomic, std::chrono::system_clock>();
	run_basic_timed_wait_tests<EmulatedFutexAtomic, std::chrono::system_clock>();
	run_basic_timed_wait_tests<DeterministicAtomic, std::chrono::system_clock>();
	}

	TEST(Baton, timed_wait_timeout_system_clock) {
	run_timed_wait_tmo_tests<std::atomic, std::chrono::system_clock>();
	run_timed_wait_tmo_tests<EmulatedFutexAtomic, std::chrono::system_clock>();
	run_timed_wait_tmo_tests<DeterministicAtomic, std::chrono::system_clock>();
	}

	TEST(Baton, timed_wait_system_clock) {
	run_timed_wait_regular_test<std::atomic, std::chrono::system_clock>();
	run_timed_wait_regular_test<EmulatedFutexAtomic, std::chrono::system_clock>();
	run_timed_wait_regular_test<DeterministicAtomic, std::chrono::system_clock>();
	}

	TEST(Baton, timed_wait_basic_steady_clock) {
	run_basic_timed_wait_tests<std::atomic, std::chrono::steady_clock>();
	run_basic_timed_wait_tests<EmulatedFutexAtomic, std::chrono::steady_clock>();
	run_basic_timed_wait_tests<DeterministicAtomic, std::chrono::steady_clock>();
	}

	TEST(Baton, timed_wait_timeout_steady_clock) {
	run_timed_wait_tmo_tests<std::atomic, std::chrono::steady_clock>();
	run_timed_wait_tmo_tests<EmulatedFutexAtomic, std::chrono::steady_clock>();
	run_timed_wait_tmo_tests<DeterministicAtomic, std::chrono::steady_clock>();
	}

	TEST(Baton, timed_wait_steady_clock) {
	run_timed_wait_regular_test<std::atomic, std::chrono::steady_clock>();
	run_timed_wait_regular_test<EmulatedFutexAtomic, std::chrono::steady_clock>();
	run_timed_wait_regular_test<DeterministicAtomic, std::chrono::steady_clock>();
	}

	template <template<typename> class Atom>
	void run_try_wait_tests() {
	Baton<Atom> b;
	EXPECT_FALSE(b.try_wait());
	b.post();
	EXPECT_TRUE(b.try_wait());
	}

	TEST(Baton, try_wait) {
	run_try_wait_tests<std::atomic>();
	run_try_wait_tests<EmulatedFutexAtomic>();
	run_try_wait_tests<DeterministicAtomic>();
	}

	// I am omitting a benchmark result snapshot because these microbenchmarks
	// mainly illustrate that PreBlockAttempts is very effective for rapid
	// handoffs. The performance of Baton and sem_t is essentially identical
	// to the required futex calls for the blocking case

	int main(int argc, char** argv) {
	testing::InitGoogleTest(&argc, argv);
	gflags::ParseCommandLineFlags(&argc, &argv, true);

	auto rv = RUN_ALL_TESTS();
	if (!rv && FLAGS_benchmark) {
	folly::runBenchmarks();
	}
	return rv;
	}