// Copyright (c) 2012 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/threading/sequenced_worker_pool.h"
#include <list>
#include <map>
#include <set>
#include <utility>
#include <vector>
#include "base/atomic_sequence_num.h"
#include "base/callback.h"
#include "base/compiler_specific.h"
#include "base/critical_closure.h"
#include "base/debug/trace_event.h"
#include "base/lazy_instance.h"
#include "base/logging.h"
#include "base/memory/linked_ptr.h"
#include "base/message_loop/message_loop_proxy.h"
#include "base/stl_util.h"
#include "base/strings/stringprintf.h"
#include "base/synchronization/condition_variable.h"
#include "base/synchronization/lock.h"
#include "base/threading/platform_thread.h"
#include "base/threading/simple_thread.h"
#include "base/threading/thread_local.h"
#include "base/threading/thread_restrictions.h"
#include "base/time/time.h"
#include "base/tracked_objects.h"
#if defined(OS_MACOSX)
#include "base/mac/scoped_nsautorelease_pool.h"
#endif
#if !defined(OS_NACL)
#include "base/metrics/histogram.h"
#endif
namespace base {
namespace {
struct SequencedTask : public TrackingInfo {
SequencedTask()
: sequence_token_id(0),
trace_id(0),
sequence_task_number(0),
shutdown_behavior(SequencedWorkerPool::BLOCK_SHUTDOWN) {}
explicit SequencedTask(const tracked_objects::Location& from_here)
: base::TrackingInfo(from_here, TimeTicks()),
sequence_token_id(0),
trace_id(0),
sequence_task_number(0),
shutdown_behavior(SequencedWorkerPool::BLOCK_SHUTDOWN) {}
~SequencedTask() {}
int sequence_token_id;
int trace_id;
int64 sequence_task_number;
SequencedWorkerPool::WorkerShutdown shutdown_behavior;
tracked_objects::Location posted_from;
Closure task;
// Non-delayed tasks and delayed tasks are managed together by time-to-run
// order. We calculate the time by adding the posted time and the given delay.
TimeTicks time_to_run;
};
struct SequencedTaskLessThan {
public:
bool operator()(const SequencedTask& lhs, const SequencedTask& rhs) const {
if (lhs.time_to_run < rhs.time_to_run)
return true;
if (lhs.time_to_run > rhs.time_to_run)
return false;
// If the time happen to match, then we use the sequence number to decide.
return lhs.sequence_task_number < rhs.sequence_task_number;
}
};
// SequencedWorkerPoolTaskRunner ---------------------------------------------
// A TaskRunner which posts tasks to a SequencedWorkerPool with a
// fixed ShutdownBehavior.
//
// Note that this class is RefCountedThreadSafe (inherited from TaskRunner).
class SequencedWorkerPoolTaskRunner : public TaskRunner {
public:
SequencedWorkerPoolTaskRunner(
const scoped_refptr<SequencedWorkerPool>& pool,
SequencedWorkerPool::WorkerShutdown shutdown_behavior);
// TaskRunner implementation
virtual bool PostDelayedTask(const tracked_objects::Location& from_here,
const Closure& task,
TimeDelta delay) OVERRIDE;
virtual bool RunsTasksOnCurrentThread() const OVERRIDE;
private:
virtual ~SequencedWorkerPoolTaskRunner();
const scoped_refptr<SequencedWorkerPool> pool_;
const SequencedWorkerPool::WorkerShutdown shutdown_behavior_;
DISALLOW_COPY_AND_ASSIGN(SequencedWorkerPoolTaskRunner);
};
SequencedWorkerPoolTaskRunner::SequencedWorkerPoolTaskRunner(
const scoped_refptr<SequencedWorkerPool>& pool,
SequencedWorkerPool::WorkerShutdown shutdown_behavior)
: pool_(pool),
shutdown_behavior_(shutdown_behavior) {
}
SequencedWorkerPoolTaskRunner::~SequencedWorkerPoolTaskRunner() {
}
bool SequencedWorkerPoolTaskRunner::PostDelayedTask(
const tracked_objects::Location& from_here,
const Closure& task,
TimeDelta delay) {
if (delay == TimeDelta()) {
return pool_->PostWorkerTaskWithShutdownBehavior(
from_here, task, shutdown_behavior_);
}
return pool_->PostDelayedWorkerTask(from_here, task, delay);
}
bool SequencedWorkerPoolTaskRunner::RunsTasksOnCurrentThread() const {
return pool_->RunsTasksOnCurrentThread();
}
// SequencedWorkerPoolSequencedTaskRunner ------------------------------------
// A SequencedTaskRunner which posts tasks to a SequencedWorkerPool with a
// fixed sequence token.
//
// Note that this class is RefCountedThreadSafe (inherited from TaskRunner).
class SequencedWorkerPoolSequencedTaskRunner : public SequencedTaskRunner {
public:
SequencedWorkerPoolSequencedTaskRunner(
const scoped_refptr<SequencedWorkerPool>& pool,
SequencedWorkerPool::SequenceToken token,
SequencedWorkerPool::WorkerShutdown shutdown_behavior);
// TaskRunner implementation
virtual bool PostDelayedTask(const tracked_objects::Location& from_here,
const Closure& task,
TimeDelta delay) OVERRIDE;
virtual bool RunsTasksOnCurrentThread() const OVERRIDE;
// SequencedTaskRunner implementation
virtual bool PostNonNestableDelayedTask(
const tracked_objects::Location& from_here,
const Closure& task,
TimeDelta delay) OVERRIDE;
private:
virtual ~SequencedWorkerPoolSequencedTaskRunner();
const scoped_refptr<SequencedWorkerPool> pool_;
const SequencedWorkerPool::SequenceToken token_;
const SequencedWorkerPool::WorkerShutdown shutdown_behavior_;
DISALLOW_COPY_AND_ASSIGN(SequencedWorkerPoolSequencedTaskRunner);
};
SequencedWorkerPoolSequencedTaskRunner::SequencedWorkerPoolSequencedTaskRunner(
const scoped_refptr<SequencedWorkerPool>& pool,
SequencedWorkerPool::SequenceToken token,
SequencedWorkerPool::WorkerShutdown shutdown_behavior)
: pool_(pool),
token_(token),
shutdown_behavior_(shutdown_behavior) {
}
SequencedWorkerPoolSequencedTaskRunner::
~SequencedWorkerPoolSequencedTaskRunner() {
}
bool SequencedWorkerPoolSequencedTaskRunner::PostDelayedTask(
const tracked_objects::Location& from_here,
const Closure& task,
TimeDelta delay) {
if (delay == TimeDelta()) {
return pool_->PostSequencedWorkerTaskWithShutdownBehavior(
token_, from_here, task, shutdown_behavior_);
}
return pool_->PostDelayedSequencedWorkerTask(token_, from_here, task, delay);
}
bool SequencedWorkerPoolSequencedTaskRunner::RunsTasksOnCurrentThread() const {
return pool_->IsRunningSequenceOnCurrentThread(token_);
}
bool SequencedWorkerPoolSequencedTaskRunner::PostNonNestableDelayedTask(
const tracked_objects::Location& from_here,
const Closure& task,
TimeDelta delay) {
// There's no way to run nested tasks, so simply forward to
// PostDelayedTask.
return PostDelayedTask(from_here, task, delay);
}
// Create a process-wide unique ID to represent this task in trace events. This
// will be mangled with a Process ID hash to reduce the likelyhood of colliding
// with MessageLoop pointers on other processes.
uint64 GetTaskTraceID(const SequencedTask& task,
void* pool) {
return (static_cast<uint64>(task.trace_id) << 32) |
static_cast<uint64>(reinterpret_cast<intptr_t>(pool));
}
base::LazyInstance<base::ThreadLocalPointer<
SequencedWorkerPool::SequenceToken> >::Leaky g_lazy_tls_ptr =
LAZY_INSTANCE_INITIALIZER;
} // namespace
// Worker ---------------------------------------------------------------------
class SequencedWorkerPool::Worker : public SimpleThread {
public:
// Hold a (cyclic) ref to |worker_pool|, since we want to keep it
// around as long as we are running.
Worker(const scoped_refptr<SequencedWorkerPool>& worker_pool,
int thread_number,
const std::string& thread_name_prefix);
virtual ~Worker();
// SimpleThread implementation. This actually runs the background thread.
virtual void Run() OVERRIDE;
void set_running_task_info(SequenceToken token,
WorkerShutdown shutdown_behavior) {
running_sequence_ = token;
running_shutdown_behavior_ = shutdown_behavior;
}
SequenceToken running_sequence() const {
return running_sequence_;
}
WorkerShutdown running_shutdown_behavior() const {
return running_shutdown_behavior_;
}
private:
scoped_refptr<SequencedWorkerPool> worker_pool_;
SequenceToken running_sequence_;
WorkerShutdown running_shutdown_behavior_;
DISALLOW_COPY_AND_ASSIGN(Worker);
};
// Inner ----------------------------------------------------------------------
class SequencedWorkerPool::Inner {
public:
// Take a raw pointer to |worker| to avoid cycles (since we're owned
// by it).
Inner(SequencedWorkerPool* worker_pool, size_t max_threads,
const std::string& thread_name_prefix,
TestingObserver* observer);
~Inner();
SequenceToken GetSequenceToken();
SequenceToken GetNamedSequenceToken(const std::string& name);
// This function accepts a name and an ID. If the name is null, the
// token ID is used. This allows us to implement the optional name lookup
// from a single function without having to enter the lock a separate time.
bool PostTask(const std::string* optional_token_name,
SequenceToken sequence_token,
WorkerShutdown shutdown_behavior,
const tracked_objects::Location& from_here,
const Closure& task,
TimeDelta delay);
bool RunsTasksOnCurrentThread() const;
bool IsRunningSequenceOnCurrentThread(SequenceToken sequence_token) const;
void CleanupForTesting();
void SignalHasWorkForTesting();
int GetWorkSignalCountForTesting() const;
void Shutdown(int max_blocking_tasks_after_shutdown);
bool IsShutdownInProgress();
// Runs the worker loop on the background thread.
void ThreadLoop(Worker* this_worker);
private:
enum GetWorkStatus {
GET_WORK_FOUND,
GET_WORK_NOT_FOUND,
GET_WORK_WAIT,
};
enum CleanupState {
CLEANUP_REQUESTED,
CLEANUP_STARTING,
CLEANUP_RUNNING,
CLEANUP_FINISHING,
CLEANUP_DONE,
};
// Called from within the lock, this converts the given token name into a
// token ID, creating a new one if necessary.
int LockedGetNamedTokenID(const std::string& name);
// Called from within the lock, this returns the next sequence task number.
int64 LockedGetNextSequenceTaskNumber();
// Called from within the lock, returns the shutdown behavior of the task
// running on the currently executing worker thread. If invoked from a thread
// that is not one of the workers, returns CONTINUE_ON_SHUTDOWN.
WorkerShutdown LockedCurrentThreadShutdownBehavior() const;
// Gets new task. There are 3 cases depending on the return value:
//
// 1) If the return value is |GET_WORK_FOUND|, |task| is filled in and should
// be run immediately.
// 2) If the return value is |GET_WORK_NOT_FOUND|, there are no tasks to run,
// and |task| is not filled in. In this case, the caller should wait until
// a task is posted.
// 3) If the return value is |GET_WORK_WAIT|, there are no tasks to run
// immediately, and |task| is not filled in. Likewise, |wait_time| is
// filled in the time to wait until the next task to run. In this case, the
// caller should wait the time.
//
// In any case, the calling code should clear the given
// delete_these_outside_lock vector the next time the lock is released.
// See the implementation for a more detailed description.
GetWorkStatus GetWork(SequencedTask* task,
TimeDelta* wait_time,
std::vector<Closure>* delete_these_outside_lock);
void HandleCleanup();
// Peforms init and cleanup around running the given task. WillRun...
// returns the value from PrepareToStartAdditionalThreadIfNecessary.
// The calling code should call FinishStartingAdditionalThread once the
// lock is released if the return values is nonzero.
int WillRunWorkerTask(const SequencedTask& task);
void DidRunWorkerTask(const SequencedTask& task);
// Returns true if there are no threads currently running the given
// sequence token.
bool IsSequenceTokenRunnable(int sequence_token_id) const;
// Checks if all threads are busy and the addition of one more could run an
// additional task waiting in the queue. This must be called from within
// the lock.
//
// If another thread is helpful, this will mark the thread as being in the
// process of starting and returns the index of the new thread which will be
// 0 or more. The caller should then call FinishStartingAdditionalThread to
// complete initialization once the lock is released.
//
// If another thread is not necessary, returne 0;
//
// See the implementedion for more.
int PrepareToStartAdditionalThreadIfHelpful();
// The second part of thread creation after
// PrepareToStartAdditionalThreadIfHelpful with the thread number it
// generated. This actually creates the thread and should be called outside
// the lock to avoid blocking important work starting a thread in the lock.
void FinishStartingAdditionalThread(int thread_number);
// Signal |has_work_| and increment |has_work_signal_count_|.
void SignalHasWork();
// Checks whether there is work left that's blocking shutdown. Must be
// called inside the lock.
bool CanShutdown() const;
SequencedWorkerPool* const worker_pool_;
// The last sequence number used. Managed by GetSequenceToken, since this
// only does threadsafe increment operations, you do not need to hold the
// lock. This is class-static to make SequenceTokens issued by
// GetSequenceToken unique across SequencedWorkerPool instances.
static base::StaticAtomicSequenceNumber g_last_sequence_number_;
// This lock protects |everything in this class|. Do not read or modify
// anything without holding this lock. Do not block while holding this
// lock.
mutable Lock lock_;
// Condition variable that is waited on by worker threads until new
// tasks are posted or shutdown starts.
ConditionVariable has_work_cv_;
// Condition variable that is waited on by non-worker threads (in
// Shutdown()) until CanShutdown() goes to true.
ConditionVariable can_shutdown_cv_;
// The maximum number of worker threads we'll create.
const size_t max_threads_;
const std::string thread_name_prefix_;
// Associates all known sequence token names with their IDs.
std::map<std::string, int> named_sequence_tokens_;
// Owning pointers to all threads we've created so far, indexed by
// ID. Since we lazily create threads, this may be less than
// max_threads_ and will be initially empty.
typedef std::map<PlatformThreadId, linked_ptr<Worker> > ThreadMap;
ThreadMap threads_;
// Set to true when we're in the process of creating another thread.
// See PrepareToStartAdditionalThreadIfHelpful for more.
bool thread_being_created_;
// Number of threads currently waiting for work.
size_t waiting_thread_count_;
// Number of threads currently running tasks that have the BLOCK_SHUTDOWN
// or SKIP_ON_SHUTDOWN flag set.
size_t blocking_shutdown_thread_count_;
// A set of all pending tasks in time-to-run order. These are tasks that are
// either waiting for a thread to run on, waiting for their time to run,
// or blocked on a previous task in their sequence. We have to iterate over
// the tasks by time-to-run order, so we use the set instead of the
// traditional priority_queue.
typedef std::set<SequencedTask, SequencedTaskLessThan> PendingTaskSet;
PendingTaskSet pending_tasks_;
// The next sequence number for a new sequenced task.
int64 next_sequence_task_number_;
// Number of tasks in the pending_tasks_ list that are marked as blocking
// shutdown.
size_t blocking_shutdown_pending_task_count_;
// Lists all sequence tokens currently executing.
std::set<int> current_sequences_;
// An ID for each posted task to distinguish the task from others in traces.
int trace_id_;
// Set when Shutdown is called and no further tasks should be
// allowed, though we may still be running existing tasks.
bool shutdown_called_;
// The number of new BLOCK_SHUTDOWN tasks that may be posted after Shudown()
// has been called.
int max_blocking_tasks_after_shutdown_;
// State used to cleanup for testing, all guarded by lock_.
CleanupState cleanup_state_;
size_t cleanup_idlers_;
ConditionVariable cleanup_cv_;
TestingObserver* const testing_observer_;
DISALLOW_COPY_AND_ASSIGN(Inner);
};
// Worker definitions ---------------------------------------------------------
SequencedWorkerPool::Worker::Worker(
const scoped_refptr<SequencedWorkerPool>& worker_pool,
int thread_number,
const std::string& prefix)
: SimpleThread(
prefix + StringPrintf("Worker%d", thread_number).c_str()),
worker_pool_(worker_pool),
running_shutdown_behavior_(CONTINUE_ON_SHUTDOWN) {
Start();
}
SequencedWorkerPool::Worker::~Worker() {
}
void SequencedWorkerPool::Worker::Run() {
// Store a pointer to the running sequence in thread local storage for
// static function access.
g_lazy_tls_ptr.Get().Set(&running_sequence_);
// Just jump back to the Inner object to run the thread, since it has all the
// tracking information and queues. It might be more natural to implement
// using DelegateSimpleThread and have Inner implement the Delegate to avoid
// having these worker objects at all, but that method lacks the ability to
// send thread-specific information easily to the thread loop.
worker_pool_->inner_->ThreadLoop(this);
// Release our cyclic reference once we're done.
worker_pool_ = NULL;
}
// Inner definitions ---------------------------------------------------------
SequencedWorkerPool::Inner::Inner(
SequencedWorkerPool* worker_pool,
size_t max_threads,
const std::string& thread_name_prefix,
TestingObserver* observer)
: worker_pool_(worker_pool),
lock_(),
has_work_cv_(&lock_),
can_shutdown_cv_(&lock_),
max_threads_(max_threads),
thread_name_prefix_(thread_name_prefix),
thread_being_created_(false),
waiting_thread_count_(0),
blocking_shutdown_thread_count_(0),
next_sequence_task_number_(0),
blocking_shutdown_pending_task_count_(0),
trace_id_(0),
shutdown_called_(false),
max_blocking_tasks_after_shutdown_(0),
cleanup_state_(CLEANUP_DONE),
cleanup_idlers_(0),
cleanup_cv_(&lock_),
testing_observer_(observer) {}
SequencedWorkerPool::Inner::~Inner() {
// You must call Shutdown() before destroying the pool.
DCHECK(shutdown_called_);
// Need to explicitly join with the threads before they're destroyed or else
// they will be running when our object is half torn down.
for (ThreadMap::iterator it = threads_.begin(); it != threads_.end(); ++it)
it->second->Join();
threads_.clear();
if (testing_observer_)
testing_observer_->OnDestruct();
}
SequencedWorkerPool::SequenceToken
SequencedWorkerPool::Inner::GetSequenceToken() {
// Need to add one because StaticAtomicSequenceNumber starts at zero, which
// is used as a sentinel value in SequenceTokens.
return SequenceToken(g_last_sequence_number_.GetNext() + 1);
}
SequencedWorkerPool::SequenceToken
SequencedWorkerPool::Inner::GetNamedSequenceToken(const std::string& name) {
AutoLock lock(lock_);
return SequenceToken(LockedGetNamedTokenID(name));
}
bool SequencedWorkerPool::Inner::PostTask(
const std::string* optional_token_name,
SequenceToken sequence_token,
WorkerShutdown shutdown_behavior,
const tracked_objects::Location& from_here,
const Closure& task,
TimeDelta delay) {
DCHECK(delay == TimeDelta() || shutdown_behavior == SKIP_ON_SHUTDOWN);
SequencedTask sequenced(from_here);
sequenced.sequence_token_id = sequence_token.id_;
sequenced.shutdown_behavior = shutdown_behavior;
sequenced.posted_from = from_here;
sequenced.task =
shutdown_behavior == BLOCK_SHUTDOWN ?
base::MakeCriticalClosure(task) : task;
sequenced.time_to_run = TimeTicks::Now() + delay;
int create_thread_id = 0;
{
AutoLock lock(lock_);
if (shutdown_called_) {
if (shutdown_behavior != BLOCK_SHUTDOWN ||
LockedCurrentThreadShutdownBehavior() == CONTINUE_ON_SHUTDOWN) {
return false;
}
if (max_blocking_tasks_after_shutdown_ <= 0) {
DLOG(WARNING) << "BLOCK_SHUTDOWN task disallowed";
return false;
}
max_blocking_tasks_after_shutdown_ -= 1;
}
// The trace_id is used for identifying the task in about:tracing.
sequenced.trace_id = trace_id_++;
TRACE_EVENT_FLOW_BEGIN0("task", "SequencedWorkerPool::PostTask",
TRACE_ID_MANGLE(GetTaskTraceID(sequenced, static_cast<void*>(this))));
sequenced.sequence_task_number = LockedGetNextSequenceTaskNumber();
// Now that we have the lock, apply the named token rules.
if (optional_token_name)
sequenced.sequence_token_id = LockedGetNamedTokenID(*optional_token_name);
pending_tasks_.insert(sequenced);
if (shutdown_behavior == BLOCK_SHUTDOWN)
blocking_shutdown_pending_task_count_++;
create_thread_id = PrepareToStartAdditionalThreadIfHelpful();
}
// Actually start the additional thread or signal an existing one now that
// we're outside the lock.
if (create_thread_id)
FinishStartingAdditionalThread(create_thread_id);
else
SignalHasWork();
return true;
}
bool SequencedWorkerPool::Inner::RunsTasksOnCurrentThread() const {
AutoLock lock(lock_);
return ContainsKey(threads_, PlatformThread::CurrentId());
}
bool SequencedWorkerPool::Inner::IsRunningSequenceOnCurrentThread(
SequenceToken sequence_token) const {
AutoLock lock(lock_);
ThreadMap::const_iterator found = threads_.find(PlatformThread::CurrentId());
if (found == threads_.end())
return false;
return sequence_token.Equals(found->second->running_sequence());
}
// See https://code.google.com/p/chromium/issues/detail?id=168415
void SequencedWorkerPool::Inner::CleanupForTesting() {
DCHECK(!RunsTasksOnCurrentThread());
base::ThreadRestrictions::ScopedAllowWait allow_wait;
AutoLock lock(lock_);
CHECK_EQ(CLEANUP_DONE, cleanup_state_);
if (shutdown_called_)
return;
if (pending_tasks_.empty() && waiting_thread_count_ == threads_.size())
return;
cleanup_state_ = CLEANUP_REQUESTED;
cleanup_idlers_ = 0;
has_work_cv_.Signal();
while (cleanup_state_ != CLEANUP_DONE)
cleanup_cv_.Wait();
}
void SequencedWorkerPool::Inner::SignalHasWorkForTesting() {
SignalHasWork();
}
void SequencedWorkerPool::Inner::Shutdown(
int max_new_blocking_tasks_after_shutdown) {
DCHECK_GE(max_new_blocking_tasks_after_shutdown, 0);
{
AutoLock lock(lock_);
// Cleanup and Shutdown should not be called concurrently.
CHECK_EQ(CLEANUP_DONE, cleanup_state_);
if (shutdown_called_)
return;
shutdown_called_ = true;
max_blocking_tasks_after_shutdown_ = max_new_blocking_tasks_after_shutdown;
// Tickle the threads. This will wake up a waiting one so it will know that
// it can exit, which in turn will wake up any other waiting ones.
SignalHasWork();
// There are no pending or running tasks blocking shutdown, we're done.
if (CanShutdown())
return;
}
// If we're here, then something is blocking shutdown. So wait for
// CanShutdown() to go to true.
if (testing_observer_)
testing_observer_->WillWaitForShutdown();
#if !defined(OS_NACL)
TimeTicks shutdown_wait_begin = TimeTicks::Now();
#endif
{
base::ThreadRestrictions::ScopedAllowWait allow_wait;
AutoLock lock(lock_);
while (!CanShutdown())
can_shutdown_cv_.Wait();
}
#if !defined(OS_NACL)
UMA_HISTOGRAM_TIMES("SequencedWorkerPool.ShutdownDelayTime",
TimeTicks::Now() - shutdown_wait_begin);
#endif
}
bool SequencedWorkerPool::Inner::IsShutdownInProgress() {
AutoLock lock(lock_);
return shutdown_called_;
}
void SequencedWorkerPool::Inner::ThreadLoop(Worker* this_worker) {
{
AutoLock lock(lock_);
DCHECK(thread_being_created_);
thread_being_created_ = false;
std::pair<ThreadMap::iterator, bool> result =
threads_.insert(
std::make_pair(this_worker->tid(), make_linked_ptr(this_worker)));
DCHECK(result.second);
while (true) {
#if defined(OS_MACOSX)
base::mac::ScopedNSAutoreleasePool autorelease_pool;
#endif
HandleCleanup();
// See GetWork for what delete_these_outside_lock is doing.
SequencedTask task;
TimeDelta wait_time;
std::vector<Closure> delete_these_outside_lock;
GetWorkStatus status =
GetWork(&task, &wait_time, &delete_these_outside_lock);
if (status == GET_WORK_FOUND) {
TRACE_EVENT_FLOW_END0("task", "SequencedWorkerPool::PostTask",
TRACE_ID_MANGLE(GetTaskTraceID(task, static_cast<void*>(this))));
TRACE_EVENT2("task", "SequencedWorkerPool::ThreadLoop",
"src_file", task.posted_from.file_name(),
"src_func", task.posted_from.function_name());
int new_thread_id = WillRunWorkerTask(task);
{
AutoUnlock unlock(lock_);
// There may be more work available, so wake up another
// worker thread. (Technically not required, since we
// already get a signal for each new task, but it doesn't
// hurt.)
SignalHasWork();
delete_these_outside_lock.clear();
// Complete thread creation outside the lock if necessary.
if (new_thread_id)
FinishStartingAdditionalThread(new_thread_id);
this_worker->set_running_task_info(
SequenceToken(task.sequence_token_id), task.shutdown_behavior);
tracked_objects::TrackedTime start_time =
tracked_objects::ThreadData::NowForStartOfRun(task.birth_tally);
task.task.Run();
tracked_objects::ThreadData::TallyRunOnNamedThreadIfTracking(task,
start_time, tracked_objects::ThreadData::NowForEndOfRun());
// Make sure our task is erased outside the lock for the
// same reason we do this with delete_these_oustide_lock.
// Also, do it before calling set_running_task_info() so
// that sequence-checking from within the task's destructor
// still works.
task.task = Closure();
this_worker->set_running_task_info(
SequenceToken(), CONTINUE_ON_SHUTDOWN);
}
DidRunWorkerTask(task); // Must be done inside the lock.
} else if (cleanup_state_ == CLEANUP_RUNNING) {
switch (status) {
case GET_WORK_WAIT: {
AutoUnlock unlock(lock_);
delete_these_outside_lock.clear();
}
break;
case GET_WORK_NOT_FOUND:
CHECK(delete_these_outside_lock.empty());
cleanup_state_ = CLEANUP_FINISHING;
cleanup_cv_.Broadcast();
break;
default:
NOTREACHED();
}
} else {
// When we're terminating and there's no more work, we can
// shut down, other workers can complete any pending or new tasks.
// We can get additional tasks posted after shutdown_called_ is set
// but only worker threads are allowed to post tasks at that time, and
// the workers responsible for posting those tasks will be available
// to run them. Also, there may be some tasks stuck behind running
// ones with the same sequence token, but additional threads won't
// help this case.
if (shutdown_called_ &&
blocking_shutdown_pending_task_count_ == 0)
break;
waiting_thread_count_++;
switch (status) {
case GET_WORK_NOT_FOUND:
has_work_cv_.Wait();
break;
case GET_WORK_WAIT:
has_work_cv_.TimedWait(wait_time);
break;
default:
NOTREACHED();
}
waiting_thread_count_--;
}
}
} // Release lock_.
// We noticed we should exit. Wake up the next worker so it knows it should
// exit as well (because the Shutdown() code only signals once).
SignalHasWork();
// Possibly unblock shutdown.
can_shutdown_cv_.Signal();
}
void SequencedWorkerPool::Inner::HandleCleanup() {
lock_.AssertAcquired();
if (cleanup_state_ == CLEANUP_DONE)
return;
if (cleanup_state_ == CLEANUP_REQUESTED) {
// We win, we get to do the cleanup as soon as the others wise up and idle.
cleanup_state_ = CLEANUP_STARTING;
while (thread_being_created_ ||
cleanup_idlers_ != threads_.size() - 1) {
has_work_cv_.Signal();
cleanup_cv_.Wait();
}
cleanup_state_ = CLEANUP_RUNNING;
return;
}
if (cleanup_state_ == CLEANUP_STARTING) {
// Another worker thread is cleaning up, we idle here until thats done.
++cleanup_idlers_;
cleanup_cv_.Broadcast();
while (cleanup_state_ != CLEANUP_FINISHING) {
cleanup_cv_.Wait();
}
--cleanup_idlers_;
cleanup_cv_.Broadcast();
return;
}
if (cleanup_state_ == CLEANUP_FINISHING) {
// We wait for all idlers to wake up prior to being DONE.
while (cleanup_idlers_ != 0) {
cleanup_cv_.Broadcast();
cleanup_cv_.Wait();
}
if (cleanup_state_ == CLEANUP_FINISHING) {
cleanup_state_ = CLEANUP_DONE;
cleanup_cv_.Signal();
}
return;
}
}
int SequencedWorkerPool::Inner::LockedGetNamedTokenID(
const std::string& name) {
lock_.AssertAcquired();
DCHECK(!name.empty());
std::map<std::string, int>::const_iterator found =
named_sequence_tokens_.find(name);
if (found != named_sequence_tokens_.end())
return found->second; // Got an existing one.
// Create a new one for this name.
SequenceToken result = GetSequenceToken();
named_sequence_tokens_.insert(std::make_pair(name, result.id_));
return result.id_;
}
int64 SequencedWorkerPool::Inner::LockedGetNextSequenceTaskNumber() {
lock_.AssertAcquired();
// We assume that we never create enough tasks to wrap around.
return next_sequence_task_number_++;
}
SequencedWorkerPool::WorkerShutdown
SequencedWorkerPool::Inner::LockedCurrentThreadShutdownBehavior() const {
lock_.AssertAcquired();
ThreadMap::const_iterator found = threads_.find(PlatformThread::CurrentId());
if (found == threads_.end())
return CONTINUE_ON_SHUTDOWN;
return found->second->running_shutdown_behavior();
}
SequencedWorkerPool::Inner::GetWorkStatus SequencedWorkerPool::Inner::GetWork(
SequencedTask* task,
TimeDelta* wait_time,
std::vector<Closure>* delete_these_outside_lock) {
lock_.AssertAcquired();
#if !defined(OS_NACL)
UMA_HISTOGRAM_COUNTS_100("SequencedWorkerPool.TaskCount",
static_cast<int>(pending_tasks_.size()));
#endif
// Find the next task with a sequence token that's not currently in use.
// If the token is in use, that means another thread is running something
// in that sequence, and we can't run it without going out-of-order.
//
// This algorithm is simple and fair, but inefficient in some cases. For
// example, say somebody schedules 1000 slow tasks with the same sequence
// number. We'll have to go through all those tasks each time we feel like
// there might be work to schedule. If this proves to be a problem, we
// should make this more efficient.
//
// One possible enhancement would be to keep a map from sequence ID to a
// list of pending but currently blocked SequencedTasks for that ID.
// When a worker finishes a task of one sequence token, it can pick up the
// next one from that token right away.
//
// This may lead to starvation if there are sufficient numbers of sequences
// in use. To alleviate this, we could add an incrementing priority counter
// to each SequencedTask. Then maintain a priority_queue of all runnable
// tasks, sorted by priority counter. When a sequenced task is completed
// we would pop the head element off of that tasks pending list and add it
// to the priority queue. Then we would run the first item in the priority
// queue.
GetWorkStatus status = GET_WORK_NOT_FOUND;
int unrunnable_tasks = 0;
PendingTaskSet::iterator i = pending_tasks_.begin();
// We assume that the loop below doesn't take too long and so we can just do
// a single call to TimeTicks::Now().
const TimeTicks current_time = TimeTicks::Now();
while (i != pending_tasks_.end()) {
if (!IsSequenceTokenRunnable(i->sequence_token_id)) {
unrunnable_tasks++;
++i;
continue;
}
if (shutdown_called_ && i->shutdown_behavior != BLOCK_SHUTDOWN) {
// We're shutting down and the task we just found isn't blocking
// shutdown. Delete it and get more work.
//
// Note that we do not want to delete unrunnable tasks. Deleting a task
// can have side effects (like freeing some objects) and deleting a
// task that's supposed to run after one that's currently running could
// cause an obscure crash.
//
// We really want to delete these tasks outside the lock in case the
// closures are holding refs to objects that want to post work from
// their destructorss (which would deadlock). The closures are
// internally refcounted, so we just need to keep a copy of them alive
// until the lock is exited. The calling code can just clear() the
// vector they passed to us once the lock is exited to make this
// happen.
delete_these_outside_lock->push_back(i->task);
pending_tasks_.erase(i++);
continue;
}
if (i->time_to_run > current_time) {
// The time to run has not come yet.
*wait_time = i->time_to_run - current_time;
status = GET_WORK_WAIT;
if (cleanup_state_ == CLEANUP_RUNNING) {
// Deferred tasks are deleted when cleaning up, see Inner::ThreadLoop.
delete_these_outside_lock->push_back(i->task);
pending_tasks_.erase(i);
}
break;
}
// Found a runnable task.
*task = *i;
pending_tasks_.erase(i);
if (task->shutdown_behavior == BLOCK_SHUTDOWN) {
blocking_shutdown_pending_task_count_--;
}
status = GET_WORK_FOUND;
break;
}
// Track the number of tasks we had to skip over to see if we should be
// making this more efficient. If this number ever becomes large or is
// frequently "some", we should consider the optimization above.
#if !defined(OS_NACL)
UMA_HISTOGRAM_COUNTS_100("SequencedWorkerPool.UnrunnableTaskCount",
unrunnable_tasks);
#endif
return status;
}
int SequencedWorkerPool::Inner::WillRunWorkerTask(const SequencedTask& task) {
lock_.AssertAcquired();
// Mark the task's sequence number as in use.
if (task.sequence_token_id)
current_sequences_.insert(task.sequence_token_id);
// Ensure that threads running tasks posted with either SKIP_ON_SHUTDOWN
// or BLOCK_SHUTDOWN will prevent shutdown until that task or thread
// completes.
if (task.shutdown_behavior != CONTINUE_ON_SHUTDOWN)
blocking_shutdown_thread_count_++;
// We just picked up a task. Since StartAdditionalThreadIfHelpful only
// creates a new thread if there is no free one, there is a race when posting
// tasks that many tasks could have been posted before a thread started
// running them, so only one thread would have been created. So we also check
// whether we should create more threads after removing our task from the
// queue, which also has the nice side effect of creating the workers from
// background threads rather than the main thread of the app.
//
// If another thread wasn't created, we want to wake up an existing thread
// if there is one waiting to pick up the next task.
//
// Note that we really need to do this *before* running the task, not
// after. Otherwise, if more than one task is posted, the creation of the
// second thread (since we only create one at a time) will be blocked by
// the execution of the first task, which could be arbitrarily long.
return PrepareToStartAdditionalThreadIfHelpful();
}
void SequencedWorkerPool::Inner::DidRunWorkerTask(const SequencedTask& task) {
lock_.AssertAcquired();
if (task.shutdown_behavior != CONTINUE_ON_SHUTDOWN) {
DCHECK_GT(blocking_shutdown_thread_count_, 0u);
blocking_shutdown_thread_count_--;
}
if (task.sequence_token_id)
current_sequences_.erase(task.sequence_token_id);
}
bool SequencedWorkerPool::Inner::IsSequenceTokenRunnable(
int sequence_token_id) const {
lock_.AssertAcquired();
return !sequence_token_id ||
current_sequences_.find(sequence_token_id) ==
current_sequences_.end();
}
int SequencedWorkerPool::Inner::PrepareToStartAdditionalThreadIfHelpful() {
lock_.AssertAcquired();
// How thread creation works:
//
// We'de like to avoid creating threads with the lock held. However, we
// need to be sure that we have an accurate accounting of the threads for
// proper Joining and deltion on shutdown.
//
// We need to figure out if we need another thread with the lock held, which
// is what this function does. It then marks us as in the process of creating
// a thread. When we do shutdown, we wait until the thread_being_created_
// flag is cleared, which ensures that the new thread is properly added to
// all the data structures and we can't leak it. Once shutdown starts, we'll
// refuse to create more threads or they would be leaked.
//
// Note that this creates a mostly benign race condition on shutdown that
// will cause fewer workers to be created than one would expect. It isn't
// much of an issue in real life, but affects some tests. Since we only spawn
// one worker at a time, the following sequence of events can happen:
//
// 1. Main thread posts a bunch of unrelated tasks that would normally be
// run on separate threads.
// 2. The first task post causes us to start a worker. Other tasks do not
// cause a worker to start since one is pending.
// 3. Main thread initiates shutdown.
// 4. No more threads are created since the shutdown_called_ flag is set.
//
// The result is that one may expect that max_threads_ workers to be created
// given the workload, but in reality fewer may be created because the
// sequence of thread creation on the background threads is racing with the
// shutdown call.
if (!shutdown_called_ &&
!thread_being_created_ &&
cleanup_state_ == CLEANUP_DONE &&
threads_.size() < max_threads_ &&
waiting_thread_count_ == 0) {
// We could use an additional thread if there's work to be done.
for (PendingTaskSet::const_iterator i = pending_tasks_.begin();
i != pending_tasks_.end(); ++i) {
if (IsSequenceTokenRunnable(i->sequence_token_id)) {
// Found a runnable task, mark the thread as being started.
thread_being_created_ = true;
return static_cast<int>(threads_.size() + 1);
}
}
}
return 0;
}
void SequencedWorkerPool::Inner::FinishStartingAdditionalThread(
int thread_number) {
// Called outside of the lock.
DCHECK(thread_number > 0);
// The worker is assigned to the list when the thread actually starts, which
// will manage the memory of the pointer.
new Worker(worker_pool_, thread_number, thread_name_prefix_);
}
void SequencedWorkerPool::Inner::SignalHasWork() {
has_work_cv_.Signal();
if (testing_observer_) {
testing_observer_->OnHasWork();
}
}
bool SequencedWorkerPool::Inner::CanShutdown() const {
lock_.AssertAcquired();
// See PrepareToStartAdditionalThreadIfHelpful for how thread creation works.
return !thread_being_created_ &&
blocking_shutdown_thread_count_ == 0 &&
blocking_shutdown_pending_task_count_ == 0;
}
base::StaticAtomicSequenceNumber
SequencedWorkerPool::Inner::g_last_sequence_number_;
// SequencedWorkerPool --------------------------------------------------------
// static
SequencedWorkerPool::SequenceToken
SequencedWorkerPool::GetSequenceTokenForCurrentThread() {
// Don't construct lazy instance on check.
if (g_lazy_tls_ptr == NULL)
return SequenceToken();
SequencedWorkerPool::SequenceToken* token = g_lazy_tls_ptr.Get().Get();
if (!token)
return SequenceToken();
return *token;
}
SequencedWorkerPool::SequencedWorkerPool(
size_t max_threads,
const std::string& thread_name_prefix)
: constructor_message_loop_(MessageLoopProxy::current()),
inner_(new Inner(this, max_threads, thread_name_prefix, NULL)) {
}
SequencedWorkerPool::SequencedWorkerPool(
size_t max_threads,
const std::string& thread_name_prefix,
TestingObserver* observer)
: constructor_message_loop_(MessageLoopProxy::current()),
inner_(new Inner(this, max_threads, thread_name_prefix, observer)) {
}
SequencedWorkerPool::~SequencedWorkerPool() {}
void SequencedWorkerPool::OnDestruct() const {
DCHECK(constructor_message_loop_.get());
// Avoid deleting ourselves on a worker thread (which would
// deadlock).
if (RunsTasksOnCurrentThread()) {
constructor_message_loop_->DeleteSoon(FROM_HERE, this);
} else {
delete this;
}
}
SequencedWorkerPool::SequenceToken SequencedWorkerPool::GetSequenceToken() {
return inner_->GetSequenceToken();
}
SequencedWorkerPool::SequenceToken SequencedWorkerPool::GetNamedSequenceToken(
const std::string& name) {
return inner_->GetNamedSequenceToken(name);
}
scoped_refptr<SequencedTaskRunner> SequencedWorkerPool::GetSequencedTaskRunner(
SequenceToken token) {
return GetSequencedTaskRunnerWithShutdownBehavior(token, BLOCK_SHUTDOWN);
}
scoped_refptr<SequencedTaskRunner>
SequencedWorkerPool::GetSequencedTaskRunnerWithShutdownBehavior(
SequenceToken token, WorkerShutdown shutdown_behavior) {
return new SequencedWorkerPoolSequencedTaskRunner(
this, token, shutdown_behavior);
}
scoped_refptr<TaskRunner>
SequencedWorkerPool::GetTaskRunnerWithShutdownBehavior(
WorkerShutdown shutdown_behavior) {
return new SequencedWorkerPoolTaskRunner(this, shutdown_behavior);
}
bool SequencedWorkerPool::PostWorkerTask(
const tracked_objects::Location& from_here,
const Closure& task) {
return inner_->PostTask(NULL, SequenceToken(), BLOCK_SHUTDOWN,
from_here, task, TimeDelta());
}
bool SequencedWorkerPool::PostDelayedWorkerTask(
const tracked_objects::Location& from_here,
const Closure& task,
TimeDelta delay) {
WorkerShutdown shutdown_behavior =
delay == TimeDelta() ? BLOCK_SHUTDOWN : SKIP_ON_SHUTDOWN;
return inner_->PostTask(NULL, SequenceToken(), shutdown_behavior,
from_here, task, delay);
}
bool SequencedWorkerPool::PostWorkerTaskWithShutdownBehavior(
const tracked_objects::Location& from_here,
const Closure& task,
WorkerShutdown shutdown_behavior) {
return inner_->PostTask(NULL, SequenceToken(), shutdown_behavior,
from_here, task, TimeDelta());
}
bool SequencedWorkerPool::PostSequencedWorkerTask(
SequenceToken sequence_token,
const tracked_objects::Location& from_here,
const Closure& task) {
return inner_->PostTask(NULL, sequence_token, BLOCK_SHUTDOWN,
from_here, task, TimeDelta());
}
bool SequencedWorkerPool::PostDelayedSequencedWorkerTask(
SequenceToken sequence_token,
const tracked_objects::Location& from_here,
const Closure& task,
TimeDelta delay) {
WorkerShutdown shutdown_behavior =
delay == TimeDelta() ? BLOCK_SHUTDOWN : SKIP_ON_SHUTDOWN;
return inner_->PostTask(NULL, sequence_token, shutdown_behavior,
from_here, task, delay);
}
bool SequencedWorkerPool::PostNamedSequencedWorkerTask(
const std::string& token_name,
const tracked_objects::Location& from_here,
const Closure& task) {
DCHECK(!token_name.empty());
return inner_->PostTask(&token_name, SequenceToken(), BLOCK_SHUTDOWN,
from_here, task, TimeDelta());
}
bool SequencedWorkerPool::PostSequencedWorkerTaskWithShutdownBehavior(
SequenceToken sequence_token,
const tracked_objects::Location& from_here,
const Closure& task,
WorkerShutdown shutdown_behavior) {
return inner_->PostTask(NULL, sequence_token, shutdown_behavior,
from_here, task, TimeDelta());
}
bool SequencedWorkerPool::PostDelayedTask(
const tracked_objects::Location& from_here,
const Closure& task,
TimeDelta delay) {
return PostDelayedWorkerTask(from_here, task, delay);
}
bool SequencedWorkerPool::RunsTasksOnCurrentThread() const {
return inner_->RunsTasksOnCurrentThread();
}
bool SequencedWorkerPool::IsRunningSequenceOnCurrentThread(
SequenceToken sequence_token) const {
return inner_->IsRunningSequenceOnCurrentThread(sequence_token);
}
void SequencedWorkerPool::FlushForTesting() {
inner_->CleanupForTesting();
}
void SequencedWorkerPool::SignalHasWorkForTesting() {
inner_->SignalHasWorkForTesting();
}
void SequencedWorkerPool::Shutdown(int max_new_blocking_tasks_after_shutdown) {
DCHECK(constructor_message_loop_->BelongsToCurrentThread());
inner_->Shutdown(max_new_blocking_tasks_after_shutdown);
}
bool SequencedWorkerPool::IsShutdownInProgress() {
return inner_->IsShutdownInProgress();
}
} // namespace base