thirdparty/rocksdb/util/timer_queue.h - nifi-minifi-cpp - Git at Google

 //  Portions Copyright (c) 2011-present, Facebook, Inc.  All rights reserved.
 //  This source code is licensed under both the GPLv2 (found in the
 //  COPYING file in the root directory) and Apache 2.0 License
 //  (found in the LICENSE.Apache file in the root directory).
 //
 // Borrowed from
 // http://www.crazygaze.com/blog/2016/03/24/portable-c-timer-queue/
 // Timer Queue
 //
 // License
 //
 // The source code in this article is licensed under the CC0 license, so feel
 // free to copy, modify, share, do whatever you want with it.
 // No attribution is required, but Ill be happy if you do.
 // CC0 license

 // The person who associated a work with this deed has dedicated the work to the
 // public domain by waiving all of his or her rights to the work worldwide
 // under copyright law, including all related and neighboring rights, to the
 // extent allowed by law.  You can copy, modify, distribute and perform the
 // work, even for commercial purposes, all without asking permission.

 #pragma once

 #include "port/port.h"

 #include <assert.h>
 #include <chrono>
 #include <condition_variable>
 #include <functional>
 #include <queue>
 #include <thread>
 #include <utility>
 #include <vector>

 // Allows execution of handlers at a specified time in the future
 // Guarantees:
 //  - All handlers are executed ONCE, even if cancelled (aborted parameter will
 // be set to true)
 //      - If TimerQueue is destroyed, it will cancel all handlers.
 //  - Handlers are ALWAYS executed in the Timer Queue worker thread.
 //  - Handlers execution order is NOT guaranteed
 //
 ////////////////////////////////////////////////////////////////////////////////
 // borrowed from
 // http://www.crazygaze.com/blog/2016/03/24/portable-c-timer-queue/
 class TimerQueue {
  public:
   TimerQueue() : m_th(&TimerQueue::run, this) {}

   ~TimerQueue() {
     cancelAll();
     // Abusing the timer queue to trigger the shutdown.
     add(0, [this](bool) {
       m_finish = true;
       return std::make_pair(false, 0);
     });
     m_th.join();
   }

   // Adds a new timer
   // \return
   //  Returns the ID of the new timer. You can use this ID to cancel the
   // timer
   uint64_t add(int64_t milliseconds,
                std::function<std::pair<bool, int64_t>(bool)> handler) {
     WorkItem item;
     Clock::time_point tp = Clock::now();
     item.end = tp + std::chrono::milliseconds(milliseconds);
     item.period = milliseconds;
     item.handler = std::move(handler);

     std::unique_lock<std::mutex> lk(m_mtx);
     uint64_t id = ++m_idcounter;
     item.id = id;
     m_items.push(std::move(item));

     // Something changed, so wake up timer thread
     m_checkWork.notify_one();
     return id;
   }

   // Cancels the specified timer
   // \return
   //  1 if the timer was cancelled.
   //  0 if you were too late to cancel (or the timer ID was never valid to
   // start with)
   size_t cancel(uint64_t id) {
     // Instead of removing the item from the container (thus breaking the
     // heap integrity), we set the item as having no handler, and put
     // that handler on a new item at the top for immediate execution
     // The timer thread will then ignore the original item, since it has no
     // handler.
     std::unique_lock<std::mutex> lk(m_mtx);
     for (auto&& item : m_items.getContainer()) {
       if (item.id == id && item.handler) {
         WorkItem newItem;
         // Zero time, so it stays at the top for immediate execution
         newItem.end = Clock::time_point();
         newItem.id = 0;  // Means it is a canceled item
         // Move the handler from item to newitem (thus clearing item)
         newItem.handler = std::move(item.handler);
         m_items.push(std::move(newItem));

         // Something changed, so wake up timer thread
         m_checkWork.notify_one();
         return 1;
       }
     }
     return 0;
   }

   // Cancels all timers
   // \return
   //  The number of timers cancelled
   size_t cancelAll() {
     // Setting all "end" to 0 (for immediate execution) is ok,
     // since it maintains the heap integrity
     std::unique_lock<std::mutex> lk(m_mtx);
     m_cancel = true;
     for (auto&& item : m_items.getContainer()) {
       if (item.id && item.handler) {
         item.end = Clock::time_point();
         item.id = 0;
       }
     }
     auto ret = m_items.size();

     m_checkWork.notify_one();
     return ret;
   }

  private:
   using Clock = std::chrono::steady_clock;
   TimerQueue(const TimerQueue&) = delete;
   TimerQueue& operator=(const TimerQueue&) = delete;

   void run() {
     std::unique_lock<std::mutex> lk(m_mtx);
     while (!m_finish) {
       auto end = calcWaitTime_lock();
       if (end.first) {
         // Timers found, so wait until it expires (or something else
         // changes)
         m_checkWork.wait_until(lk, end.second);
       } else {
         // No timers exist, so wait forever until something changes
         m_checkWork.wait(lk);
       }

       // Check and execute as much work as possible, such as, all expired
       // timers
       checkWork(&lk);
     }

     // If we are shutting down, we should not have any items left,
     // since the shutdown cancels all items
     assert(m_items.size() == 0);
   }

   std::pair<bool, Clock::time_point> calcWaitTime_lock() {
     while (m_items.size()) {
       if (m_items.top().handler) {
         // Item present, so return the new wait time
         return std::make_pair(true, m_items.top().end);
       } else {
         // Discard empty handlers (they were cancelled)
         m_items.pop();
       }
     }

     // No items found, so return no wait time (causes the thread to wait
     // indefinitely)
     return std::make_pair(false, Clock::time_point());
   }

   void checkWork(std::unique_lock<std::mutex>* lk) {
     while (m_items.size() && m_items.top().end <= Clock::now()) {
       WorkItem item(m_items.top());
       m_items.pop();

       if (item.handler) {
         (*lk).unlock();
         auto reschedule_pair = item.handler(item.id == 0);
         (*lk).lock();
         if (!m_cancel && reschedule_pair.first) {
           int64_t new_period = (reschedule_pair.second == -1)
                                    ? item.period
                                    : reschedule_pair.second;

           item.period = new_period;
           item.end = Clock::now() + std::chrono::milliseconds(new_period);
           m_items.push(std::move(item));
         }
       }
     }
   }

   bool m_finish = false;
   bool m_cancel = false;
   uint64_t m_idcounter = 0;
   std::condition_variable m_checkWork;

   struct WorkItem {
     Clock::time_point end;
     int64_t period;
     uint64_t id;  // id==0 means it was cancelled
     std::function<std::pair<bool, int64_t>(bool)> handler;
     bool operator>(const WorkItem& other) const { return end > other.end; }
   };

   std::mutex m_mtx;
   // Inheriting from priority_queue, so we can access the internal container
   class Queue : public std::priority_queue<WorkItem, std::vector<WorkItem>,
                                            std::greater<WorkItem>> {
    public:
     std::vector<WorkItem>& getContainer() { return this->c; }
   } m_items;
   rocksdb::port::Thread m_th;
 };
	// Portions Copyright (c) 2011-present, Facebook, Inc. All rights reserved.
	// This source code is licensed under both the GPLv2 (found in the
	// COPYING file in the root directory) and Apache 2.0 License
	// (found in the LICENSE.Apache file in the root directory).
	//
	// Borrowed from
	// http://www.crazygaze.com/blog/2016/03/24/portable-c-timer-queue/
	// Timer Queue
	//
	// License
	//
	// The source code in this article is licensed under the CC0 license, so feel
	// free to copy, modify, share, do whatever you want with it.
	// No attribution is required, but Ill be happy if you do.
	// CC0 license

	// The person who associated a work with this deed has dedicated the work to the
	// public domain by waiving all of his or her rights to the work worldwide
	// under copyright law, including all related and neighboring rights, to the
	// extent allowed by law. You can copy, modify, distribute and perform the
	// work, even for commercial purposes, all without asking permission.

	#pragma once

	#include "port/port.h"

	#include <assert.h>
	#include <chrono>
	#include <condition_variable>
	#include <functional>
	#include <queue>
	#include <thread>
	#include <utility>
	#include <vector>

	// Allows execution of handlers at a specified time in the future
	// Guarantees:
	// - All handlers are executed ONCE, even if cancelled (aborted parameter will
	// be set to true)
	// - If TimerQueue is destroyed, it will cancel all handlers.
	// - Handlers are ALWAYS executed in the Timer Queue worker thread.
	// - Handlers execution order is NOT guaranteed
	//
	////////////////////////////////////////////////////////////////////////////////
	// borrowed from
	// http://www.crazygaze.com/blog/2016/03/24/portable-c-timer-queue/
	class TimerQueue {
	public:
	TimerQueue() : m_th(&TimerQueue::run, this) {}

	~TimerQueue() {
	cancelAll();
	// Abusing the timer queue to trigger the shutdown.
	add(0, [this](bool) {
	m_finish = true;
	return std::make_pair(false, 0);
	});
	m_th.join();
	}

	// Adds a new timer
	// \return
	// Returns the ID of the new timer. You can use this ID to cancel the
	// timer
	uint64_t add(int64_t milliseconds,
	std::function<std::pair<bool, int64_t>(bool)> handler) {
	WorkItem item;
	Clock::time_point tp = Clock::now();
	item.end = tp + std::chrono::milliseconds(milliseconds);
	item.period = milliseconds;
	item.handler = std::move(handler);

	std::unique_lock<std::mutex> lk(m_mtx);
	uint64_t id = ++m_idcounter;
	item.id = id;
	m_items.push(std::move(item));

	// Something changed, so wake up timer thread
	m_checkWork.notify_one();
	return id;
	}

	// Cancels the specified timer
	// \return
	// 1 if the timer was cancelled.
	// 0 if you were too late to cancel (or the timer ID was never valid to
	// start with)
	size_t cancel(uint64_t id) {
	// Instead of removing the item from the container (thus breaking the
	// heap integrity), we set the item as having no handler, and put
	// that handler on a new item at the top for immediate execution
	// The timer thread will then ignore the original item, since it has no
	// handler.
	std::unique_lock<std::mutex> lk(m_mtx);
	for (auto&& item : m_items.getContainer()) {
	if (item.id == id && item.handler) {
	WorkItem newItem;
	// Zero time, so it stays at the top for immediate execution
	newItem.end = Clock::time_point();
	newItem.id = 0; // Means it is a canceled item
	// Move the handler from item to newitem (thus clearing item)
	newItem.handler = std::move(item.handler);
	m_items.push(std::move(newItem));

	// Something changed, so wake up timer thread
	m_checkWork.notify_one();
	return 1;
	}
	}
	return 0;
	}

	// Cancels all timers
	// \return
	// The number of timers cancelled
	size_t cancelAll() {
	// Setting all "end" to 0 (for immediate execution) is ok,
	// since it maintains the heap integrity
	std::unique_lock<std::mutex> lk(m_mtx);
	m_cancel = true;
	for (auto&& item : m_items.getContainer()) {
	if (item.id && item.handler) {
	item.end = Clock::time_point();
	item.id = 0;
	}
	}
	auto ret = m_items.size();

	m_checkWork.notify_one();
	return ret;
	}

	private:
	using Clock = std::chrono::steady_clock;
	TimerQueue(const TimerQueue&) = delete;
	TimerQueue& operator=(const TimerQueue&) = delete;

	void run() {
	std::unique_lock<std::mutex> lk(m_mtx);
	while (!m_finish) {
	auto end = calcWaitTime_lock();
	if (end.first) {
	// Timers found, so wait until it expires (or something else
	// changes)
	m_checkWork.wait_until(lk, end.second);
	} else {
	// No timers exist, so wait forever until something changes
	m_checkWork.wait(lk);
	}

	// Check and execute as much work as possible, such as, all expired
	// timers
	checkWork(&lk);
	}

	// If we are shutting down, we should not have any items left,
	// since the shutdown cancels all items
	assert(m_items.size() == 0);
	}

	std::pair<bool, Clock::time_point> calcWaitTime_lock() {
	while (m_items.size()) {
	if (m_items.top().handler) {
	// Item present, so return the new wait time
	return std::make_pair(true, m_items.top().end);
	} else {
	// Discard empty handlers (they were cancelled)
	m_items.pop();
	}
	}

	// No items found, so return no wait time (causes the thread to wait
	// indefinitely)
	return std::make_pair(false, Clock::time_point());
	}

	void checkWork(std::unique_lock<std::mutex>* lk) {
	while (m_items.size() && m_items.top().end <= Clock::now()) {
	WorkItem item(m_items.top());
	m_items.pop();

	if (item.handler) {
	(*lk).unlock();
	auto reschedule_pair = item.handler(item.id == 0);
	(*lk).lock();
	if (!m_cancel && reschedule_pair.first) {
	int64_t new_period = (reschedule_pair.second == -1)
	? item.period
	: reschedule_pair.second;

	item.period = new_period;
	item.end = Clock::now() + std::chrono::milliseconds(new_period);
	m_items.push(std::move(item));
	}
	}
	}
	}

	bool m_finish = false;
	bool m_cancel = false;
	uint64_t m_idcounter = 0;
	std::condition_variable m_checkWork;

	struct WorkItem {
	Clock::time_point end;
	int64_t period;
	uint64_t id; // id==0 means it was cancelled
	std::function<std::pair<bool, int64_t>(bool)> handler;
	bool operator>(const WorkItem& other) const { return end > other.end; }
	};

	std::mutex m_mtx;
	// Inheriting from priority_queue, so we can access the internal container
	class Queue : public std::priority_queue<WorkItem, std::vector<WorkItem>,
	std::greater<WorkItem>> {
	public:
	std::vector<WorkItem>& getContainer() { return this->c; }
	} m_items;
	rocksdb::port::Thread m_th;
	};