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// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
#include "vm/thread_pool.h"
#include "vm/flags.h"
#include "vm/lockers.h"
namespace dart {
DEFINE_FLAG(int, worker_timeout_millis, 5000,
"Free workers when they have been idle for this amount of time.");
Monitor* ThreadPool::exit_monitor_ = NULL;
int* ThreadPool::exit_count_ = NULL;
ThreadPool::ThreadPool()
: shutting_down_(false),
all_workers_(NULL),
idle_workers_(NULL),
count_started_(0),
count_stopped_(0),
count_running_(0),
count_idle_(0) {
}
ThreadPool::~ThreadPool() {
Shutdown();
}
void ThreadPool::Run(Task* task) {
Worker* worker = NULL;
bool new_worker = false;
{
// We need ThreadPool::mutex_ to access worker lists and other
// ThreadPool state.
MutexLocker ml(&mutex_);
if (shutting_down_) {
return;
}
if (idle_workers_ == NULL) {
worker = new Worker(this);
ASSERT(worker != NULL);
new_worker = true;
count_started_++;
// Add worker to the all_workers_ list.
worker->all_next_ = all_workers_;
all_workers_ = worker;
worker->owned_ = true;
} else {
// Get the first worker from the idle worker list.
worker = idle_workers_;
idle_workers_ = worker->idle_next_;
worker->idle_next_ = NULL;
count_idle_--;
}
count_running_++;
}
// Release ThreadPool::mutex_ before calling Worker functions.
ASSERT(worker != NULL);
worker->SetTask(task);
if (new_worker) {
// Call StartThread after we've assigned the first task.
worker->StartThread();
}
}
void ThreadPool::Shutdown() {
Worker* saved = NULL;
{
MutexLocker ml(&mutex_);
shutting_down_ = true;
saved = all_workers_;
all_workers_ = NULL;
idle_workers_ = NULL;
Worker* current = saved;
while (current != NULL) {
Worker* next = current->all_next_;
current->idle_next_ = NULL;
current->owned_ = false;
current = next;
count_stopped_++;
}
count_idle_ = 0;
count_running_ = 0;
ASSERT(count_started_ == count_stopped_);
}
// Release ThreadPool::mutex_ before calling Worker functions.
Worker* current = saved;
while (current != NULL) {
// We may access all_next_ without holding ThreadPool::mutex_ here
// because the worker is no longer owned by the ThreadPool.
Worker* next = current->all_next_;
current->all_next_ = NULL;
current->Shutdown();
current = next;
}
}
bool ThreadPool::IsIdle(Worker* worker) {
ASSERT(worker != NULL && worker->owned_);
for (Worker* current = idle_workers_;
current != NULL;
current = current->idle_next_) {
if (current == worker) {
return true;
}
}
return false;
}
bool ThreadPool::RemoveWorkerFromIdleList(Worker* worker) {
ASSERT(worker != NULL && worker->owned_);
if (idle_workers_ == NULL) {
return false;
}
// Special case head of list.
if (idle_workers_ == worker) {
idle_workers_ = worker->idle_next_;
worker->idle_next_ = NULL;
return true;
}
for (Worker* current = idle_workers_;
current->idle_next_ != NULL;
current = current->idle_next_) {
if (current->idle_next_ == worker) {
current->idle_next_ = worker->idle_next_;
worker->idle_next_ = NULL;
return true;
}
}
return false;
}
bool ThreadPool::RemoveWorkerFromAllList(Worker* worker) {
ASSERT(worker != NULL && worker->owned_);
if (all_workers_ == NULL) {
return false;
}
// Special case head of list.
if (all_workers_ == worker) {
all_workers_ = worker->all_next_;
worker->all_next_ = NULL;
worker->owned_ = false;
worker->pool_ = NULL;
return true;
}
for (Worker* current = all_workers_;
current->all_next_ != NULL;
current = current->all_next_) {
if (current->all_next_ == worker) {
current->all_next_ = worker->all_next_;
worker->all_next_ = NULL;
worker->owned_ = false;
return true;
}
}
return false;
}
void ThreadPool::SetIdle(Worker* worker) {
MutexLocker ml(&mutex_);
if (shutting_down_) {
return;
}
ASSERT(worker->owned_ && !IsIdle(worker));
worker->idle_next_ = idle_workers_;
idle_workers_ = worker;
count_idle_++;
count_running_--;
}
bool ThreadPool::ReleaseIdleWorker(Worker* worker) {
MutexLocker ml(&mutex_);
if (shutting_down_) {
return false;
}
// Remove from idle list.
if (!RemoveWorkerFromIdleList(worker)) {
return false;
}
// Remove from all list.
bool found = RemoveWorkerFromAllList(worker);
ASSERT(found);
count_stopped_++;
count_idle_--;
return true;
}
ThreadPool::Task::Task() {
}
ThreadPool::Task::~Task() {
}
ThreadPool::Worker::Worker(ThreadPool* pool)
: pool_(pool),
task_(NULL),
owned_(false),
all_next_(NULL),
idle_next_(NULL) {
}
void ThreadPool::Worker::StartThread() {
#if defined(DEBUG)
// Must call SetTask before StartThread.
{ // NOLINT
MonitorLocker ml(&monitor_);
ASSERT(task_ != NULL);
}
#endif
int result = OSThread::Start(&Worker::Main, reinterpret_cast<uword>(this));
if (result != 0) {
FATAL1("Could not start worker thread: result = %d.", result);
}
}
void ThreadPool::Worker::SetTask(Task* task) {
MonitorLocker ml(&monitor_);
ASSERT(task_ == NULL);
task_ = task;
ml.Notify();
}
static int64_t ComputeTimeout(int64_t idle_start) {
if (FLAG_worker_timeout_millis <= 0) {
// No timeout.
return 0;
} else {
int64_t waited = OS::GetCurrentTimeMillis() - idle_start;
if (waited >= FLAG_worker_timeout_millis) {
// We must have gotten a spurious wakeup just before we timed
// out. Give the worker one last desperate chance to live. We
// are merciful.
return 1;
} else {
return FLAG_worker_timeout_millis - waited;
}
}
}
void ThreadPool::Worker::Loop() {
MonitorLocker ml(&monitor_);
int64_t idle_start;
while (true) {
ASSERT(task_ != NULL);
Task* task = task_;
task_ = NULL;
// Release monitor while handling the task.
monitor_.Exit();
task->Run();
delete task;
monitor_.Enter();
ASSERT(task_ == NULL);
if (IsDone()) {
return;
}
ASSERT(pool_ != NULL);
pool_->SetIdle(this);
idle_start = OS::GetCurrentTimeMillis();
while (true) {
Monitor::WaitResult result = ml.Wait(ComputeTimeout(idle_start));
if (task_ != NULL) {
// We've found a task. Process it, regardless of whether the
// worker is done_.
break;
}
if (IsDone()) {
return;
}
if (result == Monitor::kTimedOut &&
pool_->ReleaseIdleWorker(this)) {
return;
}
}
}
UNREACHABLE();
}
void ThreadPool::Worker::Shutdown() {
MonitorLocker ml(&monitor_);
pool_ = NULL; // Fail fast if someone tries to access pool_.
ml.Notify();
}
// static
void ThreadPool::Worker::Main(uword args) {
Worker* worker = reinterpret_cast<Worker*>(args);
worker->Loop();
// It should be okay to access these unlocked here in this assert.
ASSERT(!worker->owned_ &&
worker->all_next_ == NULL &&
worker->idle_next_ == NULL);
// The exit monitor is only used during testing.
if (ThreadPool::exit_monitor_) {
MonitorLocker ml(ThreadPool::exit_monitor_);
(*ThreadPool::exit_count_)++;
ml.Notify();
}
delete worker;
}
} // namespace dart