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CLK/Concurrency/AsyncTaskQueue.cpp

110 lines
2.6 KiB
C++

//
// AsyncTaskQueue.cpp
// Clock Signal
//
// Created by Thomas Harte on 07/10/2016.
// Copyright 2016 Thomas Harte. All rights reserved.
//
#include "AsyncTaskQueue.hpp"
using namespace Concurrency;
AsyncTaskQueue::AsyncTaskQueue()
#ifndef USE_GCD
:
should_destruct_(false),
thread_([this] () {
while(!should_destruct_) {
std::function<void(void)> next_function;
// Take lock, check for a new task.
std::unique_lock lock(queue_mutex_);
if(!pending_tasks_.empty()) {
next_function = pending_tasks_.front();
pending_tasks_.pop_front();
}
if(next_function) {
// If there is a task, release lock and perform it.
lock.unlock();
next_function();
} else {
// If there isn't a task, atomically block on the processing condition and release the lock
// until there's something pending (and then release it again via scope).
processing_condition_.wait(lock);
}
}
})
#else
: serial_dispatch_queue_(dispatch_queue_create("com.thomasharte.clocksignal.asyntaskqueue", DISPATCH_QUEUE_SERIAL))
#endif
{}
AsyncTaskQueue::~AsyncTaskQueue() {
#ifdef USE_GCD
flush();
dispatch_release(serial_dispatch_queue_);
#else
// Set should destruct, and then give the thread a bit of a nudge
// via an empty enqueue.
should_destruct_ = true;
enqueue([](){});
// Wait for the thread safely to terminate.
thread_.join();
#endif
}
void AsyncTaskQueue::enqueue(std::function<void(void)> function) {
#ifdef USE_GCD
dispatch_async(serial_dispatch_queue_, ^{function();});
#else
std::lock_guard lock(queue_mutex_);
pending_tasks_.push_back(function);
processing_condition_.notify_all();
#endif
}
void AsyncTaskQueue::flush() {
#ifdef USE_GCD
dispatch_sync(serial_dispatch_queue_, ^{});
#else
auto flush_mutex = std::make_shared<std::mutex>();
auto flush_condition = std::make_shared<std::condition_variable>();
std::unique_lock lock(*flush_mutex);
enqueue([=] () {
std::unique_lock inner_lock(*flush_mutex);
flush_condition->notify_all();
});
flush_condition->wait(lock);
#endif
}
DeferringAsyncTaskQueue::~DeferringAsyncTaskQueue() {
perform();
flush();
}
void DeferringAsyncTaskQueue::defer(std::function<void(void)> function) {
if(!deferred_tasks_) {
deferred_tasks_ = std::make_unique<TaskList>();
}
deferred_tasks_->push_back(function);
}
void DeferringAsyncTaskQueue::perform() {
if(!deferred_tasks_) return;
enqueue([deferred_tasks_raw = deferred_tasks_.release()] {
std::unique_ptr<TaskList> deferred_tasks(deferred_tasks_raw);
for(const auto &function : *deferred_tasks) {
function();
}
});
}
void DeferringAsyncTaskQueue::flush() {
perform();
AsyncTaskQueue::flush();
}