// Copyright 2016 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "base/task_scheduler/scheduler_lock.h" #include #include "base/compiler_specific.h" #include "base/macros.h" #include "base/rand_util.h" #include "base/synchronization/waitable_event.h" #include "base/task_scheduler/test_utils.h" #include "base/threading/platform_thread.h" #include "base/threading/simple_thread.h" #include "testing/gtest/include/gtest/gtest.h" namespace base { namespace internal { namespace { // Adapted from base::Lock's BasicLockTestThread to make sure // Acquire()/Release() don't crash. class BasicLockTestThread : public SimpleThread { public: explicit BasicLockTestThread(SchedulerLock* lock) : SimpleThread("BasicLockTestThread"), lock_(lock), acquired_(0) {} int acquired() const { return acquired_; } private: void Run() override { for (int i = 0; i < 10; i++) { lock_->Acquire(); acquired_++; lock_->Release(); } for (int i = 0; i < 10; i++) { lock_->Acquire(); acquired_++; PlatformThread::Sleep(TimeDelta::FromMilliseconds(base::RandInt(0, 19))); lock_->Release(); } } SchedulerLock* const lock_; int acquired_; DISALLOW_COPY_AND_ASSIGN(BasicLockTestThread); }; class BasicLockAcquireAndWaitThread : public SimpleThread { public: explicit BasicLockAcquireAndWaitThread(SchedulerLock* lock) : SimpleThread("BasicLockAcquireAndWaitThread"), lock_(lock), lock_acquire_event_(WaitableEvent::ResetPolicy::AUTOMATIC, WaitableEvent::InitialState::NOT_SIGNALED), main_thread_continue_event_(WaitableEvent::ResetPolicy::AUTOMATIC, WaitableEvent::InitialState::NOT_SIGNALED) { } void WaitForLockAcquisition() { lock_acquire_event_.Wait(); } void ContinueMain() { main_thread_continue_event_.Signal(); } private: void Run() override { lock_->Acquire(); lock_acquire_event_.Signal(); main_thread_continue_event_.Wait(); lock_->Release(); } SchedulerLock* const lock_; WaitableEvent lock_acquire_event_; WaitableEvent main_thread_continue_event_; DISALLOW_COPY_AND_ASSIGN(BasicLockAcquireAndWaitThread); }; TEST(TaskSchedulerLock, Basic) { SchedulerLock lock; BasicLockTestThread thread(&lock); thread.Start(); int acquired = 0; for (int i = 0; i < 5; i++) { lock.Acquire(); acquired++; lock.Release(); } for (int i = 0; i < 10; i++) { lock.Acquire(); acquired++; PlatformThread::Sleep(TimeDelta::FromMilliseconds(base::RandInt(0, 19))); lock.Release(); } for (int i = 0; i < 5; i++) { lock.Acquire(); acquired++; PlatformThread::Sleep(TimeDelta::FromMilliseconds(base::RandInt(0, 19))); lock.Release(); } thread.Join(); EXPECT_EQ(acquired, 20); EXPECT_EQ(thread.acquired(), 20); } TEST(TaskSchedulerLock, AcquirePredecessor) { SchedulerLock predecessor; SchedulerLock lock(&predecessor); predecessor.Acquire(); lock.Acquire(); lock.Release(); predecessor.Release(); } TEST(TaskSchedulerLock, AcquirePredecessorWrongOrder) { SchedulerLock predecessor; SchedulerLock lock(&predecessor); EXPECT_DCHECK_DEATH({ lock.Acquire(); predecessor.Acquire(); }, ""); } TEST(TaskSchedulerLock, AcquireNonPredecessor) { SchedulerLock lock1; SchedulerLock lock2; EXPECT_DCHECK_DEATH({ lock1.Acquire(); lock2.Acquire(); }, ""); } TEST(TaskSchedulerLock, AcquireMultipleLocksInOrder) { SchedulerLock lock1; SchedulerLock lock2(&lock1); SchedulerLock lock3(&lock2); lock1.Acquire(); lock2.Acquire(); lock3.Acquire(); lock3.Release(); lock2.Release(); lock1.Release(); } TEST(TaskSchedulerLock, AcquireMultipleLocksInTheMiddleOfAChain) { SchedulerLock lock1; SchedulerLock lock2(&lock1); SchedulerLock lock3(&lock2); lock2.Acquire(); lock3.Acquire(); lock3.Release(); lock2.Release(); } TEST(TaskSchedulerLock, AcquireMultipleLocksNoTransitivity) { SchedulerLock lock1; SchedulerLock lock2(&lock1); SchedulerLock lock3(&lock2); EXPECT_DCHECK_DEATH({ lock1.Acquire(); lock3.Acquire(); }, ""); } TEST(TaskSchedulerLock, AcquireLocksDifferentThreadsSafely) { SchedulerLock lock1; SchedulerLock lock2; BasicLockAcquireAndWaitThread thread(&lock1); thread.Start(); lock2.Acquire(); thread.WaitForLockAcquisition(); thread.ContinueMain(); thread.Join(); lock2.Release(); } TEST(TaskSchedulerLock, AcquireLocksWithPredecessorDifferentThreadsSafelyPredecessorFirst) { // A lock and its predecessor may be safely acquired on different threads. // This Thread Other Thread // predecessor.Acquire() // lock.Acquire() // predecessor.Release() // lock.Release() SchedulerLock predecessor; SchedulerLock lock(&predecessor); predecessor.Acquire(); BasicLockAcquireAndWaitThread thread(&lock); thread.Start(); thread.WaitForLockAcquisition(); predecessor.Release(); thread.ContinueMain(); thread.Join(); } TEST(TaskSchedulerLock, AcquireLocksWithPredecessorDifferentThreadsSafelyPredecessorLast) { // A lock and its predecessor may be safely acquired on different threads. // This Thread Other Thread // lock.Acquire() // predecessor.Acquire() // lock.Release() // predecessor.Release() SchedulerLock predecessor; SchedulerLock lock(&predecessor); lock.Acquire(); BasicLockAcquireAndWaitThread thread(&predecessor); thread.Start(); thread.WaitForLockAcquisition(); lock.Release(); thread.ContinueMain(); thread.Join(); } TEST(TaskSchedulerLock, AcquireLocksWithPredecessorDifferentThreadsSafelyNoInterference) { // Acquisition of an unrelated lock on another thread should not affect a // legal lock acquisition with a predecessor on this thread. // This Thread Other Thread // predecessor.Acquire() // unrelated.Acquire() // lock.Acquire() // unrelated.Release() // lock.Release() // predecessor.Release(); SchedulerLock predecessor; SchedulerLock lock(&predecessor); predecessor.Acquire(); SchedulerLock unrelated; BasicLockAcquireAndWaitThread thread(&unrelated); thread.Start(); thread.WaitForLockAcquisition(); lock.Acquire(); thread.ContinueMain(); thread.Join(); lock.Release(); predecessor.Release(); } TEST(TaskSchedulerLock, SelfReferentialLock) { struct SelfReferentialLock { SelfReferentialLock() : lock(&lock) {} SchedulerLock lock; }; EXPECT_DCHECK_DEATH({ SelfReferentialLock lock; }, ""); } TEST(TaskSchedulerLock, PredecessorCycle) { struct LockCycle { LockCycle() : lock1(&lock2), lock2(&lock1) {} SchedulerLock lock1; SchedulerLock lock2; }; EXPECT_DCHECK_DEATH({ LockCycle cycle; }, ""); } TEST(TaskSchedulerLock, PredecessorLongerCycle) { struct LockCycle { LockCycle() : lock1(&lock5), lock2(&lock1), lock3(&lock2), lock4(&lock3), lock5(&lock4) {} SchedulerLock lock1; SchedulerLock lock2; SchedulerLock lock3; SchedulerLock lock4; SchedulerLock lock5; }; EXPECT_DCHECK_DEATH({ LockCycle cycle; }, ""); } } // namespace } // namespace internal } // namespace base