lokinet/llarp/util/thread_pool.cpp

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#include <util/thread_pool.hpp>
namespace llarp
{
namespace thread
{
using LockGuard = std::unique_lock< std::mutex >;
void
ThreadPool::join()
{
for(auto& t : m_threads)
{
if(t.joinable())
{
t.join();
}
}
m_createdThreads = 0;
}
void
ThreadPool::runJobs()
{
while(m_status.load(std::memory_order_relaxed) == Status::Run)
{
auto functor = m_queue.tryPopFront();
if(functor.has_value())
{
functor.value()();
}
else
{
m_idleThreads++;
if(m_status == Status::Run && m_queue.empty())
{
m_semaphore.wait();
}
m_idleThreads.fetch_sub(1, std::memory_order_relaxed);
}
}
}
void
ThreadPool::drainQueue()
{
while(m_status.load(std::memory_order_relaxed) == Status::Drain)
{
auto functor = m_queue.tryPopFront();
if(!functor)
{
return;
}
functor.value()();
}
}
void
ThreadPool::waitThreads()
{
LockGuard lock(m_gateMutex);
m_threadsReadyCond.wait(
lock, [this]() { return m_numThreadsReady == m_threads.size(); });
}
void
ThreadPool::releaseThreads()
{
LockGuard lock(m_gateMutex);
m_numThreadsReady = 0;
++m_gateCount;
m_gateCond.notify_all();
}
void
ThreadPool::interrupt()
{
LockGuard lock(m_gateMutex);
size_t count = m_idleThreads;
for(size_t i = 0; i < count; ++i)
{
m_semaphore.notify();
}
}
void
ThreadPool::worker()
{
size_t gateCount = m_gateCount;
for(;;)
{
{
LockGuard lock(m_gateMutex);
++m_numThreadsReady;
m_threadsReadyCond.notify_one();
m_gateCond.wait(lock, [&]() { return gateCount != m_gateCount; });
gateCount = m_gateCount;
}
Status status = m_status.load(std::memory_order_relaxed);
// Can't use a switch here as we want to load and fall through.
if(status == Status::Run)
{
runJobs();
status = m_status;
}
if(status == Status::Drain)
{
drainQueue();
}
else if(status == Status::Suspend)
{
continue;
}
else
{
assert(status == Status::Stop);
return;
}
}
}
bool
ThreadPool::spawn()
{
try
{
m_threads.at(m_createdThreads) =
std::thread(std::bind(&ThreadPool::worker, this));
++m_createdThreads;
return true;
}
catch(const std::system_error&)
{
return false;
}
}
ThreadPool::ThreadPool(size_t numThreads, size_t maxJobs)
: m_queue(maxJobs)
, m_semaphore(0)
, m_idleThreads(0)
, m_status(Status::Stop)
, m_gateCount(0)
, m_numThreadsReady(0)
, m_threads(numThreads)
, m_createdThreads(0)
{
assert(numThreads != 0);
assert(maxJobs != 0);
disable();
}
ThreadPool::~ThreadPool()
{
shutdown();
}
bool
ThreadPool::addJob(const Job& job)
{
assert(job);
QueueReturn ret = m_queue.pushBack(job);
if(ret == QueueReturn::Success && m_idleThreads > 0)
{
m_semaphore.notify();
}
return ret == QueueReturn::Success;
}
bool
ThreadPool::addJob(Job&& job)
{
assert(job);
QueueReturn ret = m_queue.pushBack(std::move(job));
if(ret == QueueReturn::Success && m_idleThreads > 0)
{
m_semaphore.notify();
}
return ret == QueueReturn::Success;
}
bool
ThreadPool::tryAddJob(const Job& job)
{
assert(job);
QueueReturn ret = m_queue.tryPushBack(job);
if(ret == QueueReturn::Success && m_idleThreads > 0)
{
m_semaphore.notify();
}
return ret == QueueReturn::Success;
}
bool
ThreadPool::tryAddJob(Job&& job)
{
assert(job);
QueueReturn ret = m_queue.tryPushBack(std::move(job));
if(ret == QueueReturn::Success && m_idleThreads > 0)
{
m_semaphore.notify();
}
return ret == QueueReturn::Success;
}
void
ThreadPool::drain()
{
LockGuard lock(m_mutex);
if(m_status.load(std::memory_order_relaxed) == Status::Run)
{
m_status = Status::Drain;
interrupt();
waitThreads();
m_status = Status::Run;
releaseThreads();
}
}
void
ThreadPool::shutdown()
{
LockGuard lock(m_mutex);
if(m_status.load(std::memory_order_relaxed) == Status::Run)
{
m_queue.disable();
m_status = Status::Stop;
interrupt();
m_queue.removeAll();
join();
}
}
bool
ThreadPool::start()
{
LockGuard lock(m_mutex);
if(m_status.load(std::memory_order_relaxed) != Status::Stop)
{
return true;
}
for(auto it = (m_threads.begin() + m_createdThreads);
it != m_threads.end(); ++it)
{
if(!spawn())
{
releaseThreads();
join();
return false;
}
}
waitThreads();
m_queue.enable();
m_status = Status::Run;
// `releaseThreads` has a release barrier so workers don't return from
// wait and not see the above store.
releaseThreads();
return true;
}
void
ThreadPool::stop()
{
LockGuard lock(m_mutex);
if(m_status.load(std::memory_order_relaxed) == Status::Run)
{
m_queue.disable();
m_status = Status::Drain;
// `interrupt` has an acquire barrier (locks a mutex), so nothing will
// be executed before the above store to `status`.
interrupt();
waitThreads();
m_status = Status::Stop;
// `releaseThreads` has a release barrier so workers don't return from
// wait and not see the above store.
releaseThreads();
join();
}
}
} // namespace thread
} // namespace llarp