src/main/java/net/floodlightcontroller/counter/ConcurrentCounter.java - spring-open - Gitiles

 /**
 *    Copyright 2011, Big Switch Networks, Inc.
 *    Originally created by David Erickson, Stanford University
 *
 *    Licensed under the Apache License, Version 2.0 (the "License"); you may
 *    not use this file except in compliance with the License. You may obtain
 *    a copy of the License at
 *
 *         http://www.apache.org/licenses/LICENSE-2.0
 *
 *    Unless required by applicable law or agreed to in writing, software
 *    distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
 *    WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
 *    License for the specific language governing permissions and limitations
 *    under the License.
 **/

 /**
  *
  */
 package net.floodlightcontroller.counter;

 import java.util.Collections;
 import java.util.Date;
 import java.util.HashMap;
 import java.util.Map;
 import java.util.Queue;
 import java.util.Set;
 import java.util.concurrent.ConcurrentLinkedQueue;
 import java.util.concurrent.ConcurrentHashMap;
 import java.util.concurrent.Executors;
 import java.util.concurrent.TimeUnit;

 import net.floodlightcontroller.counter.CounterValue.CounterType;


 /**
  * This module needs to be updated with CounterValue.
  *
  * This is a crumby attempt at a highly concurrent implementation of the Counter interface.
  *
  * (Help! Help!  Someone please re-write me!  This will almost certainly break at high loads.)
  *
  * The gist is that this class, ConcurrentCounter, keeps an internal highly transient buffer that is occasionally flushed
  * in to a set of CountBuffers (circular buffers) which store a longer term historical view of the count values at different
  * moments in time.
  *
  * This Counter implementation may be a bit over-engineered...  The goal here was to present an implementation that is very
  * predictable with respect to memory and CPU time and, at the same time, present a very fast increment() method.  The reasoning
  * here is that this will be a go-to class when it comes to debugging, particularly in high-load situations where logging
  * may introduce so much variability to the system that it foils the results.
  *
  * @author kyle
  *
  */
 public class ConcurrentCounter implements ICounter {

   protected static final Map<DateSpan, Integer> MAX_HISTORY = new HashMap<DateSpan, Integer>();
   static {
     MAX_HISTORY.put(DateSpan.REALTIME, new Integer(1));
     MAX_HISTORY.put(DateSpan.SECONDS, new Integer(120));
     MAX_HISTORY.put(DateSpan.MINUTES, new Integer(60));
     MAX_HISTORY.put(DateSpan.HOURS, new Integer(48));
     MAX_HISTORY.put(DateSpan.DAYS, new Integer(60));
     MAX_HISTORY.put(DateSpan.WEEKS, new Integer(2));
   }

   protected static Set<ConcurrentCounter> liveCounters;

   static {
     liveCounters = Collections.newSetFromMap(new ConcurrentHashMap<ConcurrentCounter, Boolean>()); //nifty way to get concurrent hash set
     //Set a background thread to flush any liveCounters every 100 milliseconds
     Executors.newScheduledThreadPool(1).scheduleAtFixedRate(new Runnable() {
         public void run() {
             for(ConcurrentCounter c : liveCounters) {
                 c.flush();
             }
         }}, 100, 100, TimeUnit.MILLISECONDS);
   }

   /**
    * Very simple data structure to store off a single count entry at a single point in time
    * @author kyle
    *
    */
   protected static final class CountAtom {
     protected Date date;
     protected Long delta;

     protected CountAtom(Date date, Long delta) {
       this.date = date;
       this.delta = delta;
     }

     public String toString() {
       return "[" + this.date + ": " + this.delta + "]";
     }
   }


   protected Queue<CountAtom> unprocessedCountBuffer;
   protected Map<DateSpan, CountBuffer> counts;
   protected Date startDate;

   /**
    * Factory method to create a new counter instance.  (Design note -
    * use a factory pattern here as it may be necessary to hook in other
    * registrations around counter objects as they are created.)
    *
    * @param startDate
    * @return
    */
   public static ICounter createCounter(Date startDate) {
     ConcurrentCounter cc = new ConcurrentCounter(startDate);
     ConcurrentCounter.liveCounters.add(cc);
     return cc;

   }

   /**
    * Protected constructor - use createCounter factory method instead
    * @param startDate
    */
   protected ConcurrentCounter(Date startDate) {
     init(startDate);
   }

   protected void init(Date startDate) {
     this.startDate = startDate;
     this.unprocessedCountBuffer = new ConcurrentLinkedQueue<CountAtom>();
     this.counts = new HashMap<DateSpan, CountBuffer>();

     for(DateSpan ds : DateSpan.values()) {
       CountBuffer cb = new CountBuffer(startDate, ds, MAX_HISTORY.get(ds));
       counts.put(ds, cb);
     }
   }
   /**
    * This is the key method that has to be both fast and very thread-safe.
    */
   @Override
   public void increment() {
     this.increment(new Date(), (long)1);
   }

   @Override
   public void increment(Date d, long delta) {
     this.unprocessedCountBuffer.add(new CountAtom(d, delta));
   }

   @Override
   public void setCounter(Date d, CounterValue value) {
       // To be done later
   }

   /**
    * Reset the value.
    */
   @Override
   public void reset(Date startDate) {
     init(startDate);
   }

   /**
    * Flushes values out of the internal buffer and in to structures
    * that can be fetched with a call to snapshot()
    */
   public synchronized void flush() {
     for(CountAtom c = this.unprocessedCountBuffer.poll(); c != null; c = this.unprocessedCountBuffer.poll()) {
       for(DateSpan ds : DateSpan.values()) {
         CountBuffer cb = counts.get(ds);
         cb.increment(c.date, c.delta);
       }
     }
   }

   @Override
   public CounterValue getCounterValue() {
       // To be done later
       //CountSeries cs = counts.get(DateSpan.REALTIME).snapshot();
       //return cs.getSeries()[0];
       return new CounterValue(CounterType.LONG);
   }

   @Override
   public Date getCounterDate() {
       // To be done later
       //CountSeries cs = counts.get(DateSpan.REALTIME).snapshot();
       //return cs.getSeries()[0];
       return new Date();
   }

   @Override
   /**
    * This method returns a disconnected copy of the underlying CountSeries corresponding to dateSpan.
    */
   public CountSeries snapshot(DateSpan dateSpan) {
     flush();
     CountSeries cs = counts.get(dateSpan).snapshot();
     return cs;
   }


 }
	/**
	* Copyright 2011, Big Switch Networks, Inc.
	* Originally created by David Erickson, Stanford University
	*
	* Licensed under the Apache License, Version 2.0 (the "License"); you may
	* not use this file except in compliance with the License. You may obtain
	* a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
	* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
	* License for the specific language governing permissions and limitations
	* under the License.
	**/

	/**
	*
	*/
	package net.floodlightcontroller.counter;

	import java.util.Collections;
	import java.util.Date;
	import java.util.HashMap;
	import java.util.Map;
	import java.util.Queue;
	import java.util.Set;
	import java.util.concurrent.ConcurrentLinkedQueue;
	import java.util.concurrent.ConcurrentHashMap;
	import java.util.concurrent.Executors;
	import java.util.concurrent.TimeUnit;

	import net.floodlightcontroller.counter.CounterValue.CounterType;


	/**
	* This module needs to be updated with CounterValue.
	*
	* This is a crumby attempt at a highly concurrent implementation of the Counter interface.
	*
	* (Help! Help! Someone please re-write me! This will almost certainly break at high loads.)
	*
	* The gist is that this class, ConcurrentCounter, keeps an internal highly transient buffer that is occasionally flushed
	* in to a set of CountBuffers (circular buffers) which store a longer term historical view of the count values at different
	* moments in time.
	*
	* This Counter implementation may be a bit over-engineered... The goal here was to present an implementation that is very
	* predictable with respect to memory and CPU time and, at the same time, present a very fast increment() method. The reasoning
	* here is that this will be a go-to class when it comes to debugging, particularly in high-load situations where logging
	* may introduce so much variability to the system that it foils the results.
	*
	* @author kyle
	*
	*/
	public class ConcurrentCounter implements ICounter {

	protected static final Map<DateSpan, Integer> MAX_HISTORY = new HashMap<DateSpan, Integer>();
	static {
	MAX_HISTORY.put(DateSpan.REALTIME, new Integer(1));
	MAX_HISTORY.put(DateSpan.SECONDS, new Integer(120));
	MAX_HISTORY.put(DateSpan.MINUTES, new Integer(60));
	MAX_HISTORY.put(DateSpan.HOURS, new Integer(48));
	MAX_HISTORY.put(DateSpan.DAYS, new Integer(60));
	MAX_HISTORY.put(DateSpan.WEEKS, new Integer(2));
	}

	protected static Set<ConcurrentCounter> liveCounters;

	static {
	liveCounters = Collections.newSetFromMap(new ConcurrentHashMap<ConcurrentCounter, Boolean>()); //nifty way to get concurrent hash set
	//Set a background thread to flush any liveCounters every 100 milliseconds
	Executors.newScheduledThreadPool(1).scheduleAtFixedRate(new Runnable() {
	public void run() {
	for(ConcurrentCounter c : liveCounters) {
	c.flush();
	}
	}}, 100, 100, TimeUnit.MILLISECONDS);
	}

	/**
	* Very simple data structure to store off a single count entry at a single point in time
	* @author kyle
	*
	*/
	protected static final class CountAtom {
	protected Date date;
	protected Long delta;

	protected CountAtom(Date date, Long delta) {
	this.date = date;
	this.delta = delta;
	}

	public String toString() {
	return "[" + this.date + ": " + this.delta + "]";
	}
	}


	protected Queue<CountAtom> unprocessedCountBuffer;
	protected Map<DateSpan, CountBuffer> counts;
	protected Date startDate;

	/**
	* Factory method to create a new counter instance. (Design note -
	* use a factory pattern here as it may be necessary to hook in other
	* registrations around counter objects as they are created.)
	*
	* @param startDate
	* @return
	*/
	public static ICounter createCounter(Date startDate) {
	ConcurrentCounter cc = new ConcurrentCounter(startDate);
	ConcurrentCounter.liveCounters.add(cc);
	return cc;

	}

	/**
	* Protected constructor - use createCounter factory method instead
	* @param startDate
	*/
	protected ConcurrentCounter(Date startDate) {
	init(startDate);
	}

	protected void init(Date startDate) {
	this.startDate = startDate;
	this.unprocessedCountBuffer = new ConcurrentLinkedQueue<CountAtom>();
	this.counts = new HashMap<DateSpan, CountBuffer>();

	for(DateSpan ds : DateSpan.values()) {
	CountBuffer cb = new CountBuffer(startDate, ds, MAX_HISTORY.get(ds));
	counts.put(ds, cb);
	}
	}
	/**
	* This is the key method that has to be both fast and very thread-safe.
	*/
	@Override
	public void increment() {
	this.increment(new Date(), (long)1);
	}

	@Override
	public void increment(Date d, long delta) {
	this.unprocessedCountBuffer.add(new CountAtom(d, delta));
	}

	@Override
	public void setCounter(Date d, CounterValue value) {
	// To be done later
	}

	/**
	* Reset the value.
	*/
	@Override
	public void reset(Date startDate) {
	init(startDate);
	}

	/**
	* Flushes values out of the internal buffer and in to structures
	* that can be fetched with a call to snapshot()
	*/
	public synchronized void flush() {
	for(CountAtom c = this.unprocessedCountBuffer.poll(); c != null; c = this.unprocessedCountBuffer.poll()) {
	for(DateSpan ds : DateSpan.values()) {
	CountBuffer cb = counts.get(ds);
	cb.increment(c.date, c.delta);
	}
	}
	}

	@Override
	public CounterValue getCounterValue() {
	// To be done later
	//CountSeries cs = counts.get(DateSpan.REALTIME).snapshot();
	//return cs.getSeries()[0];
	return new CounterValue(CounterType.LONG);
	}

	@Override
	public Date getCounterDate() {
	// To be done later
	//CountSeries cs = counts.get(DateSpan.REALTIME).snapshot();
	//return cs.getSeries()[0];
	return new Date();
	}

	@Override
	/**
	* This method returns a disconnected copy of the underlying CountSeries corresponding to dateSpan.
	*/
	public CountSeries snapshot(DateSpan dateSpan) {
	flush();
	CountSeries cs = counts.get(dateSpan).snapshot();
	return cs;
	}



	}