libcxxabi/test/guard_threaded_test.pass.cpp - llvm-project - Git at Google

 //===----------------------------------------------------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 // UNSUPPORTED: c++03
 // UNSUPPORTED: libcxxabi-no-threads
 // UNSUPPORTED: no-exceptions

 #define TESTING_CXA_GUARD
 #include "../src/cxa_guard_impl.h"
 #include <unordered_map>
 #include <thread>
 #include <atomic>
 #include <array>
 #include <cassert>
 #include <memory>
 #include <vector>

 #include "make_test_thread.h"
 #include "test_macros.h"


 using namespace __cxxabiv1;

 // Misc test configuration. It's used to tune the flakyness of the test.
 // ThreadsPerTest - The number of threads used
 constexpr int ThreadsPerTest = 10;
 // The number of instances of a test to run concurrently.
 constexpr int ConcurrentRunsPerTest = 10;
 // The number of times to rerun each test.
 constexpr int TestSamples = 50;


 void BusyWait() {
   std::this_thread::yield();
 }

 void YieldAfterBarrier() {
   std::this_thread::sleep_for(std::chrono::nanoseconds(10));
   std::this_thread::yield();
 }

 struct Barrier {
   explicit Barrier(int n) : m_threads(n), m_remaining(n) { }
   Barrier(Barrier const&) = delete;
   Barrier& operator=(Barrier const&) = delete;

   void arrive_and_wait() const {
     --m_remaining;
     while (m_remaining.load()) {
       BusyWait();
     }
   }

   void arrive_and_drop()  const {
     --m_remaining;
   }

   void wait_for_threads(int n) const {
     while ((m_threads - m_remaining.load()) < n) {
       std::this_thread::yield();
     }
   }

 private:
   const int m_threads;
   mutable std::atomic<int> m_remaining;
 };


 enum class InitResult {
   COMPLETE,
   PERFORMED,
   WAITED,
   ABORTED
 };
 constexpr InitResult COMPLETE = InitResult::COMPLETE;
 constexpr InitResult PERFORMED = InitResult::PERFORMED;
 constexpr InitResult WAITED = InitResult::WAITED;
 constexpr InitResult ABORTED = InitResult::ABORTED;


 template <class Impl, class GuardType, class Init>
 InitResult check_guard(GuardType *g, Init init) {
   uint8_t *first_byte = reinterpret_cast<uint8_t*>(g);
   if (std::__libcpp_atomic_load(first_byte, std::_AO_Acquire) == 0) {
     Impl impl(g);
     if (impl.cxa_guard_acquire() == INIT_IS_PENDING) {
 #ifndef TEST_HAS_NO_EXCEPTIONS
       try {
 #endif
         init();
         impl.cxa_guard_release();
         return PERFORMED;
 #ifndef TEST_HAS_NO_EXCEPTIONS
       } catch (...) {
         impl.cxa_guard_abort();
         return ABORTED;
       }
 #endif
     }
     return WAITED;
   }
   return COMPLETE;
 }


 template <class GuardType, class Impl>
 struct FunctionLocalStatic {
   FunctionLocalStatic() {}
   FunctionLocalStatic(FunctionLocalStatic const&) = delete;

   template <class InitFunc>
   InitResult access(InitFunc&& init) {
     auto res = check_guard<Impl>(&guard_object, init);
     ++result_counts[static_cast<int>(res)];
     return res;
   }

   template <class InitFn>
   struct AccessCallback {
     void operator()() const { this_obj->access(init); }

     FunctionLocalStatic *this_obj;
     InitFn init;
   };

   template <class InitFn, class Callback = AccessCallback< InitFn >  >
   Callback access_callback(InitFn init) {
     return Callback{this, init};
   }

   int get_count(InitResult I) const {
     return result_counts[static_cast<int>(I)].load();
   }

   int num_completed() const {
     return get_count(COMPLETE) + get_count(PERFORMED) + get_count(WAITED);
   }

   int num_waiting() const {
     return waiting_threads.load();
   }

 private:
   GuardType guard_object = {};
   std::atomic<int> waiting_threads{0};
   std::array<std::atomic<int>, 4> result_counts{};
   static_assert(static_cast<int>(ABORTED) == 3, "only 4 result kinds expected");
 };

 struct ThreadGroup {
   ThreadGroup() = default;
   ThreadGroup(ThreadGroup const&) = delete;

   template <class ...Args>
   void Create(Args&& ...args) {
     threads.emplace_back(std::forward<Args>(args)...);
   }

   template <class Callback>
   void CreateThreadsWithBarrier(int N, Callback cb) {
     auto start = std::make_shared<Barrier>(N + 1);
     for (int I=0; I < N; ++I) {
       Create([start, cb]() {
         start->arrive_and_wait();
         cb();
       });
     }
     start->arrive_and_wait();
   }

   void JoinAll() {
     for (auto& t : threads) {
       t.join();
     }
   }

 private:
   std::vector<std::thread> threads;
 };


 template <class GuardType, class Impl>
 void test_free_for_all(int num_waiters) {
   FunctionLocalStatic<GuardType, Impl> test_obj;

   ThreadGroup threads;

   bool already_init = false;
   threads.CreateThreadsWithBarrier(num_waiters,
     test_obj.access_callback([&]() {
       assert(!already_init);
       already_init = true;
     })
   );

   // wait for the other threads to finish initialization.
   threads.JoinAll();

   assert(test_obj.get_count(PERFORMED) == 1);
   assert(test_obj.get_count(COMPLETE) + test_obj.get_count(WAITED) == num_waiters - 1);
 }

 template <class GuardType, class Impl>
 void test_waiting_for_init(int num_waiters) {
     FunctionLocalStatic<GuardType, Impl> test_obj;

     ThreadGroup threads;

     Barrier start_init(2);
     threads.Create(test_obj.access_callback(
       [&]() {
         start_init.arrive_and_wait();
         // Take our sweet time completing the initialization...
         //
         // There's a race condition between the other threads reaching the
         // start_init barrier, and them actually hitting the cxa guard.
         // But we're trying to test the waiting logic, we want as many
         // threads to enter the waiting loop as possible.
         YieldAfterBarrier();
       }
     ));
     start_init.wait_for_threads(1);

     threads.CreateThreadsWithBarrier(num_waiters,
         test_obj.access_callback([]() { assert(false); })
     );
     // unblock the initializing thread
     start_init.arrive_and_drop();

     // wait for the other threads to finish initialization.
     threads.JoinAll();

     assert(test_obj.get_count(PERFORMED) == 1);
     assert(test_obj.get_count(ABORTED) == 0);
     assert(test_obj.get_count(COMPLETE) + test_obj.get_count(WAITED) == num_waiters);
 }


 template <class GuardType, class Impl>
 void test_aborted_init(int num_waiters) {
   FunctionLocalStatic<GuardType, Impl> test_obj;

   Barrier start_init(2);
   ThreadGroup threads;
   threads.Create(test_obj.access_callback(
     [&]() {
       start_init.arrive_and_wait();
       YieldAfterBarrier();
       throw 42;
     })
   );
   start_init.wait_for_threads(1);

   bool already_init = false;
   threads.CreateThreadsWithBarrier(num_waiters,
       test_obj.access_callback([&]() {
         assert(!already_init);
         already_init = true;
       })
     );
   // unblock the initializing thread
   start_init.arrive_and_drop();

   // wait for the other threads to finish initialization.
   threads.JoinAll();

   assert(test_obj.get_count(ABORTED) == 1);
   assert(test_obj.get_count(PERFORMED) == 1);
   assert(test_obj.get_count(WAITED) + test_obj.get_count(COMPLETE) == num_waiters - 1);
 }


 template <class GuardType, class Impl>
 void test_completed_init(int num_waiters) {

   FunctionLocalStatic<GuardType, Impl> test_obj;

   test_obj.access([]() {}); // initialize the object
   assert(test_obj.num_waiting() == 0);
   assert(test_obj.num_completed() == 1);
   assert(test_obj.get_count(PERFORMED) == 1);

   ThreadGroup threads;
   threads.CreateThreadsWithBarrier(num_waiters,
       test_obj.access_callback([]() { assert(false); })
   );
   // wait for the other threads to finish initialization.
   threads.JoinAll();

   assert(test_obj.get_count(ABORTED) == 0);
   assert(test_obj.get_count(PERFORMED) == 1);
   assert(test_obj.get_count(WAITED) == 0);
   assert(test_obj.get_count(COMPLETE) == num_waiters);
 }

 template <class Impl>
 void test_impl() {
   using TestFn = void(*)(int);
   TestFn TestList[] = {
     test_free_for_all<uint32_t, Impl>,
     test_free_for_all<uint32_t, Impl>,
     test_waiting_for_init<uint32_t, Impl>,
     test_waiting_for_init<uint64_t, Impl>,
     test_aborted_init<uint32_t, Impl>,
     test_aborted_init<uint64_t, Impl>,
     test_completed_init<uint32_t, Impl>,
     test_completed_init<uint64_t, Impl>
   };

   for (auto test_func : TestList) {
       ThreadGroup test_threads;
       test_threads.CreateThreadsWithBarrier(ConcurrentRunsPerTest, [=]() {
         for (int I = 0; I < TestSamples; ++I) {
           test_func(ThreadsPerTest);
         }
       });
       test_threads.JoinAll();
     }
   }

 void test_all_impls() {
   using MutexImpl = SelectImplementation<Implementation::GlobalLock>::type;

   // Attempt to test the Futex based implementation if it's supported on the
   // target platform.
   using RealFutexImpl = SelectImplementation<Implementation::Futex>::type;
   using FutexImpl = typename std::conditional<
       PlatformSupportsFutex(),
       RealFutexImpl,
       MutexImpl
   >::type;

   test_impl<MutexImpl>();
   if (PlatformSupportsFutex())
     test_impl<FutexImpl>();
 }

 // A dummy
 template <bool Dummy = true>
 void test_futex_syscall() {
   if (!PlatformSupportsFutex())
     return;
   int lock1 = 0;
   int lock2 = 0;
   int lock3 = 0;
   std::thread waiter1 = support::make_test_thread([&]() {
     int expect = 0;
     PlatformFutexWait(&lock1, expect);
     assert(lock1 == 1);
   });
   std::thread waiter2 = support::make_test_thread([&]() {
     int expect = 0;
     PlatformFutexWait(&lock2, expect);
     assert(lock2 == 2);
   });
   std::thread waiter3 = support::make_test_thread([&]() {
     int expect = 42; // not the value
     PlatformFutexWait(&lock3, expect); // doesn't block
   });
   std::thread waker = support::make_test_thread([&]() {
     lock1 = 1;
     PlatformFutexWake(&lock1);
     lock2 = 2;
     PlatformFutexWake(&lock2);
   });
   waiter1.join();
   waiter2.join();
   waiter3.join();
   waker.join();
 }

 int main(int, char**) {
   // Test each multi-threaded implementation with real threads.
   test_all_impls();
   // Test the basic sanity of the futex syscall wrappers.
   test_futex_syscall();

   return 0;
 }
	//===----------------------------------------------------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	// UNSUPPORTED: c++03
	// UNSUPPORTED: libcxxabi-no-threads
	// UNSUPPORTED: no-exceptions

	#define TESTING_CXA_GUARD
	#include "../src/cxa_guard_impl.h"
	#include <unordered_map>
	#include <thread>
	#include <atomic>
	#include <array>
	#include <cassert>
	#include <memory>
	#include <vector>

	#include "make_test_thread.h"
	#include "test_macros.h"


	using namespace __cxxabiv1;

	// Misc test configuration. It's used to tune the flakyness of the test.
	// ThreadsPerTest - The number of threads used
	constexpr int ThreadsPerTest = 10;
	// The number of instances of a test to run concurrently.
	constexpr int ConcurrentRunsPerTest = 10;
	// The number of times to rerun each test.
	constexpr int TestSamples = 50;



	void BusyWait() {
	std::this_thread::yield();
	}

	void YieldAfterBarrier() {
	std::this_thread::sleep_for(std::chrono::nanoseconds(10));
	std::this_thread::yield();
	}

	struct Barrier {
	explicit Barrier(int n) : m_threads(n), m_remaining(n) { }
	Barrier(Barrier const&) = delete;
	Barrier& operator=(Barrier const&) = delete;

	void arrive_and_wait() const {
	--m_remaining;
	while (m_remaining.load()) {
	BusyWait();
	}
	}

	void arrive_and_drop() const {
	--m_remaining;
	}

	void wait_for_threads(int n) const {
	while ((m_threads - m_remaining.load()) < n) {
	std::this_thread::yield();
	}
	}

	private:
	const int m_threads;
	mutable std::atomic<int> m_remaining;
	};


	enum class InitResult {
	COMPLETE,
	PERFORMED,
	WAITED,
	ABORTED
	};
	constexpr InitResult COMPLETE = InitResult::COMPLETE;
	constexpr InitResult PERFORMED = InitResult::PERFORMED;
	constexpr InitResult WAITED = InitResult::WAITED;
	constexpr InitResult ABORTED = InitResult::ABORTED;


	template <class Impl, class GuardType, class Init>
	InitResult check_guard(GuardType *g, Init init) {
	uint8_t first_byte = reinterpret_cast<uint8_t>(g);
	if (std::__libcpp_atomic_load(first_byte, std::_AO_Acquire) == 0) {
	Impl impl(g);
	if (impl.cxa_guard_acquire() == INIT_IS_PENDING) {
	#ifndef TEST_HAS_NO_EXCEPTIONS
	try {
	#endif
	init();
	impl.cxa_guard_release();
	return PERFORMED;
	#ifndef TEST_HAS_NO_EXCEPTIONS
	} catch (...) {
	impl.cxa_guard_abort();
	return ABORTED;
	}
	#endif
	}
	return WAITED;
	}
	return COMPLETE;
	}


	template <class GuardType, class Impl>
	struct FunctionLocalStatic {
	FunctionLocalStatic() {}
	FunctionLocalStatic(FunctionLocalStatic const&) = delete;

	template <class InitFunc>
	InitResult access(InitFunc&& init) {
	auto res = check_guard<Impl>(&guard_object, init);
	++result_counts[static_cast<int>(res)];
	return res;
	}

	template <class InitFn>
	struct AccessCallback {
	void operator()() const { this_obj->access(init); }

	FunctionLocalStatic *this_obj;
	InitFn init;
	};

	template <class InitFn, class Callback = AccessCallback< InitFn > >
	Callback access_callback(InitFn init) {
	return Callback{this, init};
	}

	int get_count(InitResult I) const {
	return result_counts[static_cast<int>(I)].load();
	}

	int num_completed() const {
	return get_count(COMPLETE) + get_count(PERFORMED) + get_count(WAITED);
	}

	int num_waiting() const {
	return waiting_threads.load();
	}

	private:
	GuardType guard_object = {};
	std::atomic<int> waiting_threads{0};
	std::array<std::atomic<int>, 4> result_counts{};
	static_assert(static_cast<int>(ABORTED) == 3, "only 4 result kinds expected");
	};

	struct ThreadGroup {
	ThreadGroup() = default;
	ThreadGroup(ThreadGroup const&) = delete;

	template <class ...Args>
	void Create(Args&& ...args) {
	threads.emplace_back(std::forward<Args>(args)...);
	}

	template <class Callback>
	void CreateThreadsWithBarrier(int N, Callback cb) {
	auto start = std::make_shared<Barrier>(N + 1);
	for (int I=0; I < N; ++I) {
	Create([start, cb]() {
	start->arrive_and_wait();
	cb();
	});
	}
	start->arrive_and_wait();
	}

	void JoinAll() {
	for (auto& t : threads) {
	t.join();
	}
	}

	private:
	std::vector<std::thread> threads;
	};


	template <class GuardType, class Impl>
	void test_free_for_all(int num_waiters) {
	FunctionLocalStatic<GuardType, Impl> test_obj;

	ThreadGroup threads;

	bool already_init = false;
	threads.CreateThreadsWithBarrier(num_waiters,
	test_obj.access_callback([&]() {
	assert(!already_init);
	already_init = true;
	})
	);

	// wait for the other threads to finish initialization.
	threads.JoinAll();

	assert(test_obj.get_count(PERFORMED) == 1);
	assert(test_obj.get_count(COMPLETE) + test_obj.get_count(WAITED) == num_waiters - 1);
	}

	template <class GuardType, class Impl>
	void test_waiting_for_init(int num_waiters) {
	FunctionLocalStatic<GuardType, Impl> test_obj;

	ThreadGroup threads;

	Barrier start_init(2);
	threads.Create(test_obj.access_callback(
	[&]() {
	start_init.arrive_and_wait();
	// Take our sweet time completing the initialization...
	//
	// There's a race condition between the other threads reaching the
	// start_init barrier, and them actually hitting the cxa guard.
	// But we're trying to test the waiting logic, we want as many
	// threads to enter the waiting loop as possible.
	YieldAfterBarrier();
	}
	));
	start_init.wait_for_threads(1);

	threads.CreateThreadsWithBarrier(num_waiters,
	test_obj.access_callback([]() { assert(false); })
	);
	// unblock the initializing thread
	start_init.arrive_and_drop();

	// wait for the other threads to finish initialization.
	threads.JoinAll();

	assert(test_obj.get_count(PERFORMED) == 1);
	assert(test_obj.get_count(ABORTED) == 0);
	assert(test_obj.get_count(COMPLETE) + test_obj.get_count(WAITED) == num_waiters);
	}


	template <class GuardType, class Impl>
	void test_aborted_init(int num_waiters) {
	FunctionLocalStatic<GuardType, Impl> test_obj;

	Barrier start_init(2);
	ThreadGroup threads;
	threads.Create(test_obj.access_callback(
	[&]() {
	start_init.arrive_and_wait();
	YieldAfterBarrier();
	throw 42;
	})
	);
	start_init.wait_for_threads(1);

	bool already_init = false;
	threads.CreateThreadsWithBarrier(num_waiters,
	test_obj.access_callback([&]() {
	assert(!already_init);
	already_init = true;
	})
	);
	// unblock the initializing thread
	start_init.arrive_and_drop();

	// wait for the other threads to finish initialization.
	threads.JoinAll();

	assert(test_obj.get_count(ABORTED) == 1);
	assert(test_obj.get_count(PERFORMED) == 1);
	assert(test_obj.get_count(WAITED) + test_obj.get_count(COMPLETE) == num_waiters - 1);
	}


	template <class GuardType, class Impl>
	void test_completed_init(int num_waiters) {

	FunctionLocalStatic<GuardType, Impl> test_obj;

	test_obj.access([]() {}); // initialize the object
	assert(test_obj.num_waiting() == 0);
	assert(test_obj.num_completed() == 1);
	assert(test_obj.get_count(PERFORMED) == 1);

	ThreadGroup threads;
	threads.CreateThreadsWithBarrier(num_waiters,
	test_obj.access_callback([]() { assert(false); })
	);
	// wait for the other threads to finish initialization.
	threads.JoinAll();

	assert(test_obj.get_count(ABORTED) == 0);
	assert(test_obj.get_count(PERFORMED) == 1);
	assert(test_obj.get_count(WAITED) == 0);
	assert(test_obj.get_count(COMPLETE) == num_waiters);
	}

	template <class Impl>
	void test_impl() {
	using TestFn = void(*)(int);
	TestFn TestList[] = {
	test_free_for_all<uint32_t, Impl>,
	test_free_for_all<uint32_t, Impl>,
	test_waiting_for_init<uint32_t, Impl>,
	test_waiting_for_init<uint64_t, Impl>,
	test_aborted_init<uint32_t, Impl>,
	test_aborted_init<uint64_t, Impl>,
	test_completed_init<uint32_t, Impl>,
	test_completed_init<uint64_t, Impl>
	};

	for (auto test_func : TestList) {
	ThreadGroup test_threads;
	test_threads.CreateThreadsWithBarrier(ConcurrentRunsPerTest, [=]() {
	for (int I = 0; I < TestSamples; ++I) {
	test_func(ThreadsPerTest);
	}
	});
	test_threads.JoinAll();
	}
	}

	void test_all_impls() {
	using MutexImpl = SelectImplementation<Implementation::GlobalLock>::type;

	// Attempt to test the Futex based implementation if it's supported on the
	// target platform.
	using RealFutexImpl = SelectImplementation<Implementation::Futex>::type;
	using FutexImpl = typename std::conditional<
	PlatformSupportsFutex(),
	RealFutexImpl,
	MutexImpl
	>::type;

	test_impl<MutexImpl>();
	if (PlatformSupportsFutex())
	test_impl<FutexImpl>();
	}

	// A dummy
	template <bool Dummy = true>
	void test_futex_syscall() {
	if (!PlatformSupportsFutex())
	return;
	int lock1 = 0;
	int lock2 = 0;
	int lock3 = 0;
	std::thread waiter1 = support::make_test_thread([&]() {
	int expect = 0;
	PlatformFutexWait(&lock1, expect);
	assert(lock1 == 1);
	});
	std::thread waiter2 = support::make_test_thread([&]() {
	int expect = 0;
	PlatformFutexWait(&lock2, expect);
	assert(lock2 == 2);
	});
	std::thread waiter3 = support::make_test_thread([&]() {
	int expect = 42; // not the value
	PlatformFutexWait(&lock3, expect); // doesn't block
	});
	std::thread waker = support::make_test_thread([&]() {
	lock1 = 1;
	PlatformFutexWake(&lock1);
	lock2 = 2;
	PlatformFutexWake(&lock2);
	});
	waiter1.join();
	waiter2.join();
	waiter3.join();
	waker.join();
	}

	int main(int, char**) {
	// Test each multi-threaded implementation with real threads.
	test_all_impls();
	// Test the basic sanity of the futex syscall wrappers.
	test_futex_syscall();

	return 0;
	}