/* * Copyright (c) 2014-2015, Siemens AG. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include namespace embb { namespace base { namespace test { MutexTest::MutexTest() : mutex_(), counter_(0), number_threads_(partest::TestSuite::GetDefaultNumThreads()), number_iterations_(partest::TestSuite::GetDefaultNumIterations()) { CreateUnit("Mutex protected counter") .Pre(&MutexTest::PreMutexCount, this) .Add(&MutexTest::TestMutexCount, this, number_threads_, number_iterations_) .Post(&MutexTest::PostMutexCount, this); CreateUnit("Recursive mutex") .Add(&MutexTest::TestRecursiveMutex, this); CreateUnit("Lock guard protected counter") .Pre(&MutexTest::PreLockGuardCount, this) .Add(&MutexTest::TestLockGuardCount, this, number_threads_, number_iterations_) .Post(&MutexTest::PostLockGuardCount, this); CreateUnit("Unique Lock").Add(&MutexTest::TestUniqueLock, this); } void MutexTest::PreMutexCount() { counter_ = 0; } void MutexTest::TestMutexCount() { mutex_.Lock(); ++counter_; mutex_.Unlock(); } void MutexTest::PostMutexCount() { PT_EXPECT_EQ((size_t)counter_, number_iterations_ * number_threads_); } void MutexTest::TestRecursiveMutex() { embb::base::RecursiveMutex mutex; int number = 5; for (int i = 0; i < number; i++) { mutex.Lock(); bool obtained = mutex.TryLock(); PT_EXPECT_EQ(obtained, true); } for (int i = 0; i < number; i++) { mutex.Unlock(); mutex.Unlock(); } } void MutexTest::PreLockGuardCount() { counter_ = 0; } void MutexTest::TestLockGuardCount() { LockGuard guard(mutex_); ++counter_; } void MutexTest::PostLockGuardCount() { PT_EXPECT_EQ((size_t)counter_, number_iterations_ * number_threads_); } void MutexTest::TestUniqueLock() { { // Test standard usage and releasing #ifdef EMBB_USE_EXCEPTIONS bool exception_thrown = false; #endif UniqueLock lock(mutex_); PT_EXPECT_EQ(lock.OwnsLock(), true); #ifdef EMBB_USE_EXCEPTIONS // Locked lock should not by re-lockable EMBB_TRY { lock.Lock(); } EMBB_CATCH(ErrorException&) { exception_thrown = true; } PT_EXPECT_EQ(exception_thrown, true); // Locked lock should not by re-try-lockable EMBB_TRY { lock.TryLock(); } EMBB_CATCH(ErrorException&) { exception_thrown = true; } PT_EXPECT_EQ(exception_thrown, true); #endif // EMBB_USE_EXCEPTIONS lock.Unlock(); PT_EXPECT_EQ(lock.OwnsLock(), false); #ifdef EMBB_USE_EXCEPTIONS // Unlocked lock should not by re-unlockable exception_thrown = false; EMBB_TRY { lock.Unlock(); } EMBB_CATCH(ErrorException&) { exception_thrown = true; } PT_EXPECT_EQ(exception_thrown, true); #endif // EMBB_USE_EXCEPTIONS lock.Lock(); PT_EXPECT_EQ(lock.OwnsLock(), true); lock.Release()->Unlock(); PT_EXPECT_EQ(lock.OwnsLock(), false); #ifdef EMBB_USE_EXCEPTIONS // Released lock should not by lockable exception_thrown = false; EMBB_TRY { lock.Lock(); } EMBB_CATCH(ErrorException&) { exception_thrown = true; } PT_EXPECT_EQ(exception_thrown, true); // Released lock should not by try-lockable exception_thrown = false; EMBB_TRY { lock.TryLock(); } EMBB_CATCH(ErrorException&) { exception_thrown = true; } PT_EXPECT_EQ(exception_thrown, true); // Released lock should not by unlockable exception_thrown = false; EMBB_TRY { lock.Unlock(); } EMBB_CATCH(ErrorException&) { exception_thrown = true; } PT_EXPECT_EQ(exception_thrown, true); #endif // EMBB_USE_EXCEPTIONS } { // Test deferred lock construction UniqueLock<> lock(mutex_, embb::base::defer_lock); PT_EXPECT_EQ(lock.OwnsLock(), false); } { // Test try-lock construction UniqueLock<> lock(mutex_, embb::base::try_lock); PT_EXPECT_EQ(lock.OwnsLock(), true); } { // Test adopt lock construction mutex_.Lock(); UniqueLock<> lock(mutex_, embb::base::adopt_lock); PT_EXPECT_EQ(lock.OwnsLock(), true); } { // Test lock swapping UniqueLock<> lock1(mutex_); PT_EXPECT_EQ(lock1.OwnsLock(), true); { UniqueLock<> lock2; PT_EXPECT_EQ(lock2.OwnsLock(), false); lock1.Swap(lock2); PT_EXPECT_EQ(lock1.OwnsLock(), false); PT_EXPECT_EQ(lock2.OwnsLock(), true); } // At this point, "lock2" was destroyed and "mutex_" must be unlocked. UniqueLock<> lock3(mutex_, embb::base::try_lock); PT_EXPECT_EQ(lock3.OwnsLock(), true); } } SpinLockTest::SpinLockTest() : spinlock_(), counter_(0), number_threads_(partest::TestSuite::GetDefaultNumThreads()), number_iterations_(partest::TestSuite::GetDefaultNumIterations()), counter_iterations_(10000) { CreateUnit("Spinlock protected counter (using Lock)") .Add(&SpinLockTest::TestSpinlockCountLock, this, number_threads_, number_iterations_) .Post(&SpinLockTest::PostSpinlockCount, this); CreateUnit("Spinlock protected counter (using Trylock)") .Add(&SpinLockTest::TestSpinlockCountLockTryLock, this, number_threads_, number_iterations_) .Post(&SpinLockTest::PostSpinlockCount, this); CreateUnit("Test spinning (too many spins), single thread") .Add(&SpinLockTest::TestSpinLockTooManySpins, this, 1, 1); } void SpinLockTest::TestSpinlockCountLock() { for (unsigned int i = 0; i != counter_iterations_; ++i){ spinlock_.Lock(); counter_++; spinlock_.Unlock(); } } void SpinLockTest::TestSpinlockCountLockTryLock() { for (unsigned int i = 0; i != counter_iterations_; ++i){ while (!spinlock_.TryLock()) {} counter_++; spinlock_.Unlock(); } } void SpinLockTest::PostSpinlockCount() { PT_EXPECT_EQ(counter_, number_iterations_ * number_threads_* counter_iterations_); counter_ = 0; } void SpinLockTest::TestSpinLockTooManySpins() { Spinlock lock; lock.Lock(); bool success = lock.TryLock(100); PT_ASSERT(!success); lock.Unlock(); success = lock.TryLock(100); PT_ASSERT(success); } } // namespace test } // namespace base } // namespace embb