faux-folly/folly/test/FutexTest.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/detail/Futex.h>
 #include <folly/test/DeterministicSchedule.h>

 #include <chrono>
 #include <functional>
 #include <ratio>
 #include <thread>

 #include <gflags/gflags.h>
 #include <glog/logging.h>
 #include <gtest/gtest.h>
 #include <time.h>

 using namespace folly::detail;
 using namespace folly::test;
 using namespace std;
 using namespace std::chrono;

 typedef DeterministicSchedule DSched;

 template <template<typename> class Atom>
 void run_basic_thread(
     Futex<Atom>& f) {
   EXPECT_TRUE(f.futexWait(0));
 }

 template <template<typename> class Atom>
 void run_basic_tests() {
   Futex<Atom> f(0);

   EXPECT_FALSE(f.futexWait(1));
   EXPECT_EQ(f.futexWake(), 0);

   auto thr = DSched::thread(std::bind(run_basic_thread<Atom>, std::ref(f)));

   while (f.futexWake() != 1) {
     std::this_thread::yield();
   }

   DSched::join(thr);
 }

 template <template<typename> class Atom, typename Clock, typename Duration>
 void liveClockWaitUntilTests() {
   Futex<Atom> f(0);

   /* FYI: 100 iterations in the AARCH64 qemu emulator takes about 6.5 minutes */
   for (int stress = 0; stress < 100 ; ++stress) {
     auto fp = &f; // workaround for t5336595
     auto thrA = DSched::thread([fp,stress]{
       while (true) {
         const auto deadline = time_point_cast<Duration>(
             Clock::now() + microseconds(1 << (stress % 20)));
         const auto res = fp->futexWaitUntil(0, deadline);
         EXPECT_TRUE(res == FutexResult::TIMEDOUT || res == FutexResult::AWOKEN);
         if (res == FutexResult::AWOKEN) {
           break;
         }
       }
     });

     while (f.futexWake() != 1) {
       std::this_thread::yield();
     }

     DSched::join(thrA);
   }

   {
     const auto start = Clock::now();
     const auto deadline = time_point_cast<Duration>(start + milliseconds(100));
     EXPECT_EQ(f.futexWaitUntil(0, deadline), FutexResult::TIMEDOUT);
     LOG(INFO) << "Futex wait timed out after waiting for "
               << duration_cast<milliseconds>(Clock::now() - start).count()
               << "ms using clock with " << Duration::period::den
               << " precision, should be ~100ms";
   }

   {
     const auto start = Clock::now();
     const auto deadline = time_point_cast<Duration>(
         start - 2 * start.time_since_epoch());
     EXPECT_EQ(f.futexWaitUntil(0, deadline), FutexResult::TIMEDOUT);
     LOG(INFO) << "Futex wait with invalid deadline timed out after waiting for "
               << duration_cast<milliseconds>(Clock::now() - start).count()
               << "ms using clock with " << Duration::period::den
               << " precision, should be ~0ms";
   }
 }

 template <typename Clock>
 void deterministicAtomicWaitUntilTests() {
   Futex<DeterministicAtomic> f(0);

   // Futex wait must eventually fail with either FutexResult::TIMEDOUT or
   // FutexResult::INTERRUPTED
   const auto res = f.futexWaitUntil(0, Clock::now() + milliseconds(100));
   EXPECT_TRUE(res == FutexResult::TIMEDOUT || res == FutexResult::INTERRUPTED);
 }

 template<template<typename> class Atom>
 void run_wait_until_tests() {
   liveClockWaitUntilTests<Atom, system_clock, system_clock::duration>();
   liveClockWaitUntilTests<Atom, steady_clock, steady_clock::duration>();

   typedef duration<int64_t, std::ratio<1, 10000000>> decimicroseconds;
   liveClockWaitUntilTests<Atom, system_clock, decimicroseconds>();
 }

 template <>
 void run_wait_until_tests<DeterministicAtomic>() {
   deterministicAtomicWaitUntilTests<system_clock>();
   deterministicAtomicWaitUntilTests<steady_clock>();
 }

 uint64_t diff(uint64_t a, uint64_t b) {
   return a > b ? a - b : b - a;
 }

 void run_system_clock_test() {
   /* Test to verify that system_clock uses clock_gettime(CLOCK_REALTIME, ...)
    * for the time_points */
   struct timespec ts;
   const int maxIters = 1000;
   int iter = 0;
   const uint64_t delta = 10000000 /* 10 ms */;

   /** The following loop is only to make the test more robust in the presence of
    * clock adjustments that can occur. We just run the loop maxIter times and
    * expect with very high probability that there will be atleast one iteration
    * of the test during which clock adjustments > delta have not occurred. */
   while (iter < maxIters) {
     uint64_t a = duration_cast<nanoseconds>(system_clock::now()
                                             .time_since_epoch()).count();

     clock_gettime(CLOCK_REALTIME, &ts);
     uint64_t b = ts.tv_sec * 1000000000ULL + ts.tv_nsec;

     uint64_t c = duration_cast<nanoseconds>(system_clock::now()
                                             .time_since_epoch()).count();

     if (diff(a, b) <= delta &&
         diff(b, c) <= delta &&
         diff(a, c) <= 2 * delta) {
       /* Success! system_clock uses CLOCK_REALTIME for time_points */
       break;
     }
     iter++;
   }
   EXPECT_TRUE(iter < maxIters);
 }

 void run_steady_clock_test() {
   /* Test to verify that steady_clock uses clock_gettime(CLOCK_MONOTONIC, ...)
    * for the time_points */
   EXPECT_TRUE(steady_clock::is_steady);

   const uint64_t A = duration_cast<nanoseconds>(steady_clock::now()
                                                 .time_since_epoch()).count();

   struct timespec ts;
   clock_gettime(CLOCK_MONOTONIC, &ts);
   const uint64_t B = ts.tv_sec * 1000000000ULL + ts.tv_nsec;

   const uint64_t C = duration_cast<nanoseconds>(steady_clock::now()
                                                 .time_since_epoch()).count();
   EXPECT_TRUE(A <= B && B <= C);
 }

 TEST(Futex, clock_source) {
   run_system_clock_test();

   /* On some systems steady_clock is just an alias for system_clock. So,
    * we must skip run_steady_clock_test if the two clocks are the same. */
   if (!std::is_same<system_clock,steady_clock>::value) {
     run_steady_clock_test();
   }
 }

 TEST(Futex, basic_live) {
   run_basic_tests<std::atomic>();
   run_wait_until_tests<std::atomic>();
 }

 TEST(Futex, basic_emulated) {
   run_basic_tests<EmulatedFutexAtomic>();
   run_wait_until_tests<EmulatedFutexAtomic>();
 }

 TEST(Futex, basic_deterministic) {
   DSched sched(DSched::uniform(0));
   run_basic_tests<DeterministicAtomic>();
   run_wait_until_tests<DeterministicAtomic>();
 }

 int main(int argc, char ** argv) {
   testing::InitGoogleTest(&argc, argv);
   gflags::ParseCommandLineFlags(&argc, &argv, true);
   return RUN_ALL_TESTS();
 }
	/*
	* 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/detail/Futex.h>
	#include <folly/test/DeterministicSchedule.h>

	#include <chrono>
	#include <functional>
	#include <ratio>
	#include <thread>

	#include <gflags/gflags.h>
	#include <glog/logging.h>
	#include <gtest/gtest.h>
	#include <time.h>

	using namespace folly::detail;
	using namespace folly::test;
	using namespace std;
	using namespace std::chrono;

	typedef DeterministicSchedule DSched;

	template <template<typename> class Atom>
	void run_basic_thread(
	Futex<Atom>& f) {
	EXPECT_TRUE(f.futexWait(0));
	}

	template <template<typename> class Atom>
	void run_basic_tests() {
	Futex<Atom> f(0);

	EXPECT_FALSE(f.futexWait(1));
	EXPECT_EQ(f.futexWake(), 0);

	auto thr = DSched::thread(std::bind(run_basic_thread<Atom>, std::ref(f)));

	while (f.futexWake() != 1) {
	std::this_thread::yield();
	}

	DSched::join(thr);
	}

	template <template<typename> class Atom, typename Clock, typename Duration>
	void liveClockWaitUntilTests() {
	Futex<Atom> f(0);

	/* FYI: 100 iterations in the AARCH64 qemu emulator takes about 6.5 minutes */
	for (int stress = 0; stress < 100 ; ++stress) {
	auto fp = &f; // workaround for t5336595
	auto thrA = DSched::thread([fp,stress]{
	while (true) {
	const auto deadline = time_point_cast<Duration>(
	Clock::now() + microseconds(1 << (stress % 20)));
	const auto res = fp->futexWaitUntil(0, deadline);
	EXPECT_TRUE(res == FutexResult::TIMEDOUT \|\| res == FutexResult::AWOKEN);
	if (res == FutexResult::AWOKEN) {
	break;
	}
	}
	});

	while (f.futexWake() != 1) {
	std::this_thread::yield();
	}

	DSched::join(thrA);
	}

	{
	const auto start = Clock::now();
	const auto deadline = time_point_cast<Duration>(start + milliseconds(100));
	EXPECT_EQ(f.futexWaitUntil(0, deadline), FutexResult::TIMEDOUT);
	LOG(INFO) << "Futex wait timed out after waiting for "
	<< duration_cast<milliseconds>(Clock::now() - start).count()
	<< "ms using clock with " << Duration::period::den
	<< " precision, should be ~100ms";
	}

	{
	const auto start = Clock::now();
	const auto deadline = time_point_cast<Duration>(
	start - 2 * start.time_since_epoch());
	EXPECT_EQ(f.futexWaitUntil(0, deadline), FutexResult::TIMEDOUT);
	LOG(INFO) << "Futex wait with invalid deadline timed out after waiting for "
	<< duration_cast<milliseconds>(Clock::now() - start).count()
	<< "ms using clock with " << Duration::period::den
	<< " precision, should be ~0ms";
	}
	}

	template <typename Clock>
	void deterministicAtomicWaitUntilTests() {
	Futex<DeterministicAtomic> f(0);

	// Futex wait must eventually fail with either FutexResult::TIMEDOUT or
	// FutexResult::INTERRUPTED
	const auto res = f.futexWaitUntil(0, Clock::now() + milliseconds(100));
	EXPECT_TRUE(res == FutexResult::TIMEDOUT \|\| res == FutexResult::INTERRUPTED);
	}

	template<template<typename> class Atom>
	void run_wait_until_tests() {
	liveClockWaitUntilTests<Atom, system_clock, system_clock::duration>();
	liveClockWaitUntilTests<Atom, steady_clock, steady_clock::duration>();

	typedef duration<int64_t, std::ratio<1, 10000000>> decimicroseconds;
	liveClockWaitUntilTests<Atom, system_clock, decimicroseconds>();
	}

	template <>
	void run_wait_until_tests<DeterministicAtomic>() {
	deterministicAtomicWaitUntilTests<system_clock>();
	deterministicAtomicWaitUntilTests<steady_clock>();
	}

	uint64_t diff(uint64_t a, uint64_t b) {
	return a > b ? a - b : b - a;
	}

	void run_system_clock_test() {
	/* Test to verify that system_clock uses clock_gettime(CLOCK_REALTIME, ...)
	* for the time_points */
	struct timespec ts;
	const int maxIters = 1000;
	int iter = 0;
	const uint64_t delta = 10000000 /* 10 ms */;

	/** The following loop is only to make the test more robust in the presence of
	* clock adjustments that can occur. We just run the loop maxIter times and
	* expect with very high probability that there will be atleast one iteration
	* of the test during which clock adjustments > delta have not occurred. */
	while (iter < maxIters) {
	uint64_t a = duration_cast<nanoseconds>(system_clock::now()
	.time_since_epoch()).count();

	clock_gettime(CLOCK_REALTIME, &ts);
	uint64_t b = ts.tv_sec * 1000000000ULL + ts.tv_nsec;

	uint64_t c = duration_cast<nanoseconds>(system_clock::now()
	.time_since_epoch()).count();

	if (diff(a, b) <= delta &&
	diff(b, c) <= delta &&
	diff(a, c) <= 2 * delta) {
	/* Success! system_clock uses CLOCK_REALTIME for time_points */
	break;
	}
	iter++;
	}
	EXPECT_TRUE(iter < maxIters);
	}

	void run_steady_clock_test() {
	/* Test to verify that steady_clock uses clock_gettime(CLOCK_MONOTONIC, ...)
	* for the time_points */
	EXPECT_TRUE(steady_clock::is_steady);

	const uint64_t A = duration_cast<nanoseconds>(steady_clock::now()
	.time_since_epoch()).count();

	struct timespec ts;
	clock_gettime(CLOCK_MONOTONIC, &ts);
	const uint64_t B = ts.tv_sec * 1000000000ULL + ts.tv_nsec;

	const uint64_t C = duration_cast<nanoseconds>(steady_clock::now()
	.time_since_epoch()).count();
	EXPECT_TRUE(A <= B && B <= C);
	}

	TEST(Futex, clock_source) {
	run_system_clock_test();

	/* On some systems steady_clock is just an alias for system_clock. So,
	* we must skip run_steady_clock_test if the two clocks are the same. */
	if (!std::is_same<system_clock,steady_clock>::value) {
	run_steady_clock_test();
	}
	}

	TEST(Futex, basic_live) {
	run_basic_tests<std::atomic>();
	run_wait_until_tests<std::atomic>();
	}

	TEST(Futex, basic_emulated) {
	run_basic_tests<EmulatedFutexAtomic>();
	run_wait_until_tests<EmulatedFutexAtomic>();
	}

	TEST(Futex, basic_deterministic) {
	DSched sched(DSched::uniform(0));
	run_basic_tests<DeterministicAtomic>();
	run_wait_until_tests<DeterministicAtomic>();
	}

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