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/**
 *  Copyright Terracotta, Inc.
 *
 *  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.sf.ehcache.concurrent;

/**
 * @version $Id: Sync.java 5594 2012-05-07 16:04:31Z cdennis $
 * @author Doug Lea
 * Main interface for locks, gates, and conditions.
 * 

* Sync objects isolate waiting and notification for particular * logical states, resource availability, events, and the like that are * shared across multiple threads. Use of Syncs sometimes * (but by no means always) adds flexibility and efficiency * compared to the use of plain java monitor methods * and locking, and are sometimes (but by no means always) * simpler to program with. *

*

* Most Syncs are intended to be used primarily (although * not exclusively) in before/after constructions such as: *

 * class X {
 *   Sync gate;
 *   // ...
 * 

* public void m() { * try { * gate.acquire(); // block until condition holds * try { * // ... method body * } * finally { * gate.release() * } * } * catch (InterruptedException ex) { * // ... evasive action * } * } *

* public void m2(Sync cond) { // use supplied condition * try { * if (cond.attempt(10)) { // try the condition for 10 ms * try { * // ... method body * } * finally { * cond.release() * } * } * } * catch (InterruptedException ex) { * // ... evasive action * } * } * } *

* Syncs may be used in somewhat tedious but more flexible replacements * for built-in Java synchronized blocks. For example: *
 * class HandSynched {
 *   private double state_ = 0.0;
 *   private final Sync lock;  // use lock type supplied in constructor
 *   public HandSynched(Sync l) { lock = l; }
 * 

* public void changeState(double d) { * try { * lock.acquire(); * try { state_ = updateFunction(d); } * finally { lock.release(); } * } * catch(InterruptedException ex) { } * } *

* public double getState() { * double d = 0.0; * try { * lock.acquire(); * try { d = accessFunction(state_); } * finally { lock.release(); } * } * catch(InterruptedException ex){} * return d; * } * private double updateFunction(double d) { ... } * private double accessFunction(double d) { ... } * } *

* If you have a lot of such methods, and they take a common * form, you can standardize this using wrappers. Some of these * wrappers are standardized in LockedExecutor, but you can make others. * For example: *
 * class HandSynchedV2 {
 *   private double state_ = 0.0;
 *   private final Sync lock;  // use lock type supplied in constructor
 *   public HandSynchedV2(Sync l) { lock = l; }
 * 

* protected void runSafely(Runnable r) { * try { * lock.acquire(); * try { r.run(); } * finally { lock.release(); } * } * catch (InterruptedException ex) { // propagate without throwing * Thread.currentThread().interrupt(); * } * } *

* public void changeState(double d) { * runSafely(new Runnable() { * public void run() { state_ = updateFunction(d); } * }); * } * // ... * } *

*

* One reason to bother with such constructions is to use deadlock- * avoiding back-offs when dealing with locks involving multiple objects. * For example, here is a Cell class that uses attempt to back-off * and retry if two Cells are trying to swap values with each other * at the same time. *

 * class Cell {
 *   long value;
 *   Sync lock = ... // some sync implementation class
 *   void swapValue(Cell other) {
 *     for (;;) {
 *       try {
 *         lock.acquire();
 *         try {
 *           if (other.lock.attempt(100)) {
 *             try {
 *               long t = value;
 *               value = other.value;
 *               other.value = t;
 *               return;
 *             }
 *             finally { other.lock.release(); }
 *           }
 *         }
 *         finally { lock.release(); }
 *       }
 *       catch (InterruptedException ex) { return; }
 *     }
 *   }
 * }
 * 
*

* Here is an even fancier version, that uses lock re-ordering * upon conflict: *

 * class Cell {
 *   long value;
 *   Sync lock = ...;
 *   private static boolean trySwap(Cell a, Cell b) {
 *     a.lock.acquire();
 *     try {
 *       if (!b.lock.attempt(0))
 *         return false;
 *       try {
 *         long t = a.value;
 *         a.value = b.value;
 *         b.value = t;
 *         return true;
 *       }
 *       finally { other.lock.release(); }
 *     }
 *     finally { lock.release(); }
 *     return false;
 *   }
 * 

* void swapValue(Cell other) { * try { * while (!trySwap(this, other) && * !tryswap(other, this)) * Thread.sleep(1); * } * catch (InterruptedException ex) { return; } * } * } *

*

* Interruptions are in general handled as early as possible. * Normally, InterruptionExceptions are thrown * in acquire and attempt(msec) if interruption * is detected upon entry to the method, as well as in any * later context surrounding waits. * However, interruption status is ignored in release(); *

* Timed versions of attempt report failure via return value. * If so desired, you can transform such constructions to use exception * throws via *

 *   if (!c.attempt(timeval)) throw new TimeoutException(timeval);
 * 
*

* The TimoutSync wrapper class can be used to automate such usages. *

* All time values are expressed in milliseconds as longs, which have a maximum * value of Long.MAX_VALUE, or almost 300,000 centuries. It is not * known whether JVMs actually deal correctly with such extreme values. * For convenience, some useful time values are defined as static constants. *

* All implementations of the three Sync methods guarantee to * somehow employ Java synchronized methods or blocks, * and so entail the memory operations described in JLS * chapter 17 which ensure that variables are loaded and flushed * within before/after constructions. *

* Syncs may also be used in spinlock constructions. Although * it is normally best to just use acquire(), various forms * of busy waits can be implemented. For a simple example * (but one that would probably never be preferable to using acquire()): *

 * class X {
 *   Sync lock = ...
 *   void spinUntilAcquired() throws InterruptedException {
 *     // Two phase.
 *     // First spin without pausing.
 *     int purespins = 10;
 *     for (int i = 0; i < purespins; ++i) {
 *       if (lock.attempt(0))
 *         return true;
 *     }
 *     // Second phase - use timed waits
 *     long waitTime = 1; // 1 millisecond
 *     for (;;) {
 *       if (lock.attempt(waitTime))
 *         return true;
 *       else
 *         waitTime = waitTime * 3 / 2 + 1; // increase 50%
 *     }
 *   }
 * }
 * 
*

* In addition pure synchronization control, Syncs * may be useful in any context requiring before/after methods. * For example, you can use an ObservableSync * (perhaps as part of a LayeredSync) in order to obtain callbacks * before and after each method invocation for a given class. *

*

*

[ Introduction to this package. ] */ public interface Sync { /** * One second, in milliseconds; convenient as a time-out value * */ long ONE_SECOND = 1000; /** * One minute, in milliseconds; convenient as a time-out value * */ long ONE_MINUTE = 60 * ONE_SECOND; /** * One hour, in milliseconds; convenient as a time-out value * */ long ONE_HOUR = 60 * ONE_MINUTE; /** * One day, in milliseconds; convenient as a time-out value * */ long ONE_DAY = 24 * ONE_HOUR; /** * One week, in milliseconds; convenient as a time-out value * */ long ONE_WEEK = 7 * ONE_DAY; /** * One year in milliseconds; convenient as a time-out value * Not that it matters, but there is some variation across * standard sources about value at msec precision. * The value used is the same as in java.util.GregorianCalendar */ long ONE_YEAR = (long) (365.2425 * ONE_DAY); /** * One century in milliseconds; convenient as a time-out value */ long ONE_CENTURY = 100 * ONE_YEAR; /** * Acquire lock of LockType.READ or WRITE * @param type the lock type to acquire */ void lock(LockType type); /** * Tries to acquire a LockType.READ or WRITE for a certain period * @param type the lock type to acquire * @param msec timeout * @return true if the lock got acquired, false otherwise * @throws InterruptedException Should the thread be interrupted */ boolean tryLock(LockType type, long msec) throws InterruptedException; /** * Releases the lock held by the current Thread. * In case of a LockType.WRITE, should the lock not be held by the current Thread, nothing happens * @param type the lock type to acquire */ void unlock(LockType type); /** * Returns true is this is lock is held at given level by the current thread. * * @param type the lock type to test * @return true if the lock is held */ boolean isHeldByCurrentThread(LockType type); }





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