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The core library for Fibers on Java, compatible with Java 11-16. Forked from puniverse/quasar

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/*
 * Quasar: lightweight strands and actors for the JVM.
 * Copyright (c) 2013-2014, Parallel Universe Software Co. All rights reserved.
 * 
 * This program and the accompanying materials are dual-licensed under
 * either the terms of the Eclipse Public License v1.0 as published by
 * the Eclipse Foundation
 *  
 *   or (per the licensee's choosing)
 *  
 * under the terms of the GNU Lesser General Public License version 3.0
 * as published by the Free Software Foundation.
 */
/*
 * Based on code:
 */
/*
 * Written by Doug Lea with assistance from members of JCP JSR-166
 * Expert Group and released to the public domain, as explained at
 * http://creativecommons.org/publicdomain/zero/1.0/
 */
package co.paralleluniverse.strands.concurrent;

import co.paralleluniverse.fibers.SuspendExecution;
import co.paralleluniverse.fibers.Suspendable;
import co.paralleluniverse.strands.Strand;
import java.lang.invoke.MethodHandles;
import java.lang.invoke.VarHandle;
import java.util.concurrent.ThreadLocalRandom;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.locks.Condition;
import java.util.concurrent.locks.Lock;
import java.util.concurrent.locks.ReadWriteLock;

/**
 * A capability-based lock with three modes for controlling read/write
 * access. The state of a StampedLock consists of a version and mode.
 * Lock acquisition methods return a stamp that represents and
 * controls access with respect to a lock state; "try" versions of
 * these methods may instead return the special value zero to
 * represent failure to acquire access. Lock release and conversion
 * methods require stamps as arguments, and fail if they do not match
 * the state of the lock. The three modes are:
 *
 * 
    * *
  • Writing. Method {@link #writeLock} possibly blocks * waiting for exclusive access, returning a stamp that can be used * in method {@link #unlockWrite} to release the lock. Untimed and * timed versions of {@code tryWriteLock} are also provided. When * the lock is held in write mode, no read locks may be obtained, * and all optimistic read validations will fail.
  • * *
  • Reading. Method {@link #readLock} possibly blocks * waiting for non-exclusive access, returning a stamp that can be * used in method {@link #unlockRead} to release the lock. Untimed * and timed versions of {@code tryReadLock} are also provided.
  • * *
  • Optimistic Reading. Method {@link #tryOptimisticRead} * returns a non-zero stamp only if the lock is not currently held * in write mode. Method {@link #validate} returns true if the lock * has not been acquired in write mode since obtaining a given * stamp. This mode can be thought of as an extremely weak version * of a read-lock, that can be broken by a writer at any time. The * use of optimistic mode for short read-only code segments often * reduces contention and improves throughput. However, its use is * inherently fragile. Optimistic read sections should only read * fields and hold them in local variables for later use after * validation. Fields read while in optimistic mode may be wildly * inconsistent, so usage applies only when you are familiar enough * with data representations to check consistency and/or repeatedly * invoke method {@code validate()}. For example, such steps are * typically required when first reading an object or array * reference, and then accessing one of its fields, elements or * methods.
  • * *
* *

This class also supports methods that conditionally provide * conversions across the three modes. For example, method {@link * #tryConvertToWriteLock} attempts to "upgrade" a mode, returning * a valid write stamp if (1) already in writing mode (2) in reading * mode and there are no other readers or (3) in optimistic mode and * the lock is available. The forms of these methods are designed to * help reduce some of the code bloat that otherwise occurs in * retry-based designs. * *

StampedLocks are designed for use as internal utilities in the * development of strand-safe components. Their use relies on * knowledge of the internal properties of the data, objects, and * methods they are protecting. They are not reentrant, so locked * bodies should not call other unknown methods that may try to * re-acquire locks (although you may pass a stamp to other methods * that can use or convert it). The use of read lock modes relies on * the associated code sections being side-effect-free. Unvalidated * optimistic read sections cannot call methods that are not known to * tolerate potential inconsistencies. Stamps use finite * representations, and are not cryptographically secure (i.e., a * valid stamp may be guessable). Stamp values may recycle after (no * sooner than) one year of continuous operation. A stamp held without * use or validation for longer than this period may fail to validate * correctly. StampedLocks are serializable, but always deserialize * into initial unlocked state, so they are not useful for remote * locking. * *

The scheduling policy of StampedLock does not consistently * prefer readers over writers or vice versa. All "try" methods are * best-effort and do not necessarily conform to any scheduling or * fairness policy. A zero return from any "try" method for acquiring * or converting locks does not carry any information about the state * of the lock; a subsequent invocation may succeed. * *

Because it supports coordinated usage across multiple lock * modes, this class does not directly implement the {@link Lock} or * {@link ReadWriteLock} interfaces. However, a StampedLock may be * viewed {@link #asReadLock()}, {@link #asWriteLock()}, or {@link * #asReadWriteLock()} in applications requiring only the associated * set of functionality. * *

Sample Usage. The following illustrates some usage idioms * in a class that maintains simple two-dimensional points. The sample * code illustrates some try/catch conventions even though they are * not strictly needed here because no exceptions can occur in their * bodies.
* *

{@code
 * class Point {
 *   private double x, y;
 *   private final StampedLock sl = new StampedLock();
 *
 *   void move(double deltaX, double deltaY) { // an exclusively locked method
 *     long stamp = sl.writeLock();
 *     try {
 *       x += deltaX;
 *       y += deltaY;
 *     } finally {
 *       sl.unlockWrite(stamp);
 *     }
 *   }
 *
 *   double distanceFromOriginV1() { // A read-only method
 *     long stamp;
 *     if ((stamp = sl.tryOptimisticRead()) != 0L) { // optimistic
 *       double currentX = x;
 *       double currentY = y;
 *       if (sl.validate(stamp))
 *         return Math.sqrt(currentX * currentX + currentY * currentY);
 *     }
 *     stamp = sl.readLock(); // fall back to read lock
 *     try {
 *       double currentX = x;
 *       double currentY = y;
 *         return Math.sqrt(currentX * currentX + currentY * currentY);
 *     } finally {
 *       sl.unlockRead(stamp);
 *     }
 *   }
 *
 *   double distanceFromOriginV2() { // combines code paths
 *     double currentX = 0.0, currentY = 0.0;
 *     for (long stamp = sl.tryOptimisticRead(); ; stamp = sl.readLock()) {
 *       try {
 *         currentX = x;
 *         currentY = y;
 *       } finally {
 *         if (sl.tryConvertToOptimisticRead(stamp) != 0L) // unlock or validate
 *           break;
 *       }
 *     }
 *     return Math.sqrt(currentX * currentX + currentY * currentY);
 *   }
 *
 *   void moveIfAtOrigin(double newX, double newY) { // upgrade
 *     // Could instead start with optimistic, not read mode
 *     long stamp = sl.readLock();
 *     try {
 *       while (x == 0.0 && y == 0.0) {
 *         long ws = sl.tryConvertToWriteLock(stamp);
 *         if (ws != 0L) {
 *           stamp = ws;
 *           x = newX;
 *           y = newY;
 *           break;
 *         }
 *         else {
 *           sl.unlockRead(stamp);
 *           stamp = sl.writeLock();
 *         }
 *       }
 *     } finally {
 *       sl.unlock(stamp);
 *     }
 * }
 * }}
* * @since 1.8 * @author Doug Lea */ public class StampedLock implements java.io.Serializable { /* * Algorithmic notes: * * The design employs elements of Sequence locks * (as used in linux kernels; see Lameter's * http://www.lameter.com/gelato2005.pdf * and elsewhere; see * Boehm's http://www.hpl.hp.com/techreports/2012/HPL-2012-68.html) * and Ordered RW locks (see Shirako et al * http://dl.acm.org/citation.cfm?id=2312015) * * Conceptually, the primary state of the lock includes a sequence * number that is odd when write-locked and even otherwise. * However, this is offset by a reader count that is non-zero when * read-locked. The read count is ignored when validating * "optimistic" seqlock-reader-style stamps. Because we must use * a small finite number of bits (currently 7) for readers, a * supplementary reader overflow word is used when the number of * readers exceeds the count field. We do this by treating the max * reader count value (RBITS) as a spinlock protecting overflow * updates. * * Waiters use a modified form of CLH lock used in * AbstractQueuedSynchronizer (see its internal documentation for * a fuller account), where each node is tagged (field mode) as * either a reader or writer. Sets of waiting readers are grouped * (linked) under a common node (field cowait) so act as a single * node with respect to most CLH mechanics. By virtue of the * queue structure, wait nodes need not actually carry sequence * numbers; we know each is greater than its predecessor. This * simplifies the scheduling policy to a mainly-FIFO scheme that * incorporates elements of Phase-Fair locks (see Brandenburg & * Anderson, especially http://www.cs.unc.edu/~bbb/diss/). In * particular, we use the phase-fair anti-barging rule: If an * incoming reader arrives while read lock is held but there is a * queued writer, this incoming reader is queued. (This rule is * responsible for some of the complexity of method acquireRead, * but without it, the lock becomes highly unfair.) * * These rules apply to strands actually queued. All tryLock forms * opportunistically try to acquire locks regardless of preference * rules, and so may "barge" their way in. Randomized spinning is * used in the acquire methods to reduce (increasingly expensive) * context switching while also avoiding sustained memory * thrashing among many strands. We limit spins to the head of * queue. A strand spin-waits up to SPINS times (where each * iteration decreases spin count with 50% probability) before * blocking. If, upon wakening it fails to obtain lock, and is * still (or becomes) the first waiting strand (which indicates * that some other strand barged and obtained lock), it escalates * spins (up to MAX_HEAD_SPINS) to reduce the likelihood of * continually losing to barging strands. * * Nearly all of these mechanics are carried out in methods * acquireWrite and acquireRead, that, as typical of such code, * sprawl out because actions and retries rely on consistent sets * of locally cached reads. * * As noted in Boehm's paper (above), sequence validation (mainly * method validate()) requires stricter ordering rules than apply * to normal volatile reads (of "state"). In the absence of (but * continual hope for) explicit JVM support of intrinsics with * double-sided reordering prohibition, or corresponding fence * intrinsics, we for now uncomfortably rely on the fact that the * Unsafe.getXVolatile intrinsic must have this property * (syntactic volatile reads do not) for internal purposes anyway, * even though it is not documented. * * The memory layout keeps lock state and queue pointers together * (normally on the same cache line). This usually works well for * read-mostly loads. In most other cases, the natural tendency of * adaptive-spin CLH locks to reduce memory contention lessens * motivation to further spread out contended locations, but might * be subject to future improvements. */ private static final long serialVersionUID = -6001602636862214147L; /** * Number of processors, for spin control */ private static final int NCPU = Runtime.getRuntime().availableProcessors(); /** * Maximum number of retries before blocking on acquisition */ private static final int SPINS = (NCPU > 1) ? 1 << 6 : 0; /** * Maximum number of retries before re-blocking */ private static final int MAX_HEAD_SPINS = (NCPU > 1) ? 1 << 12 : 0; /** * The period for yielding when waiting for overflow spinlock */ private static final int OVERFLOW_YIELD_RATE = 7; // must be power 2 - 1 /** * The number of bits to use for reader count before overflowing */ private static final int LG_READERS = 7; // Values for lock state and stamp operations private static final long RUNIT = 1L; private static final long WBIT = 1L << LG_READERS; private static final long RBITS = WBIT - 1L; private static final long RFULL = RBITS - 1L; private static final long ABITS = RBITS | WBIT; private static final long SBITS = ~RBITS; // note overlap with ABITS // Initial value for lock state; avoid failure value zero private static final long ORIGIN = WBIT << 1; // Special value from cancelled acquire methods so caller can throw IE private static final long INTERRUPTED = 1L; // Values for node status; order matters private static final int WAITING = -1; private static final int CANCELLED = 1; // Modes for nodes (int not boolean to allow arithmetic) private static final int RMODE = 0; private static final int WMODE = 1; /** * Wait nodes */ static final class WNode { volatile WNode prev; volatile WNode next; volatile WNode cowait; // list of linked readers volatile Strand strand; // non-null while possibly parked volatile int status; // 0, WAITING, or CANCELLED final int mode; // RMODE or WMODE WNode(int m, WNode p) { mode = m; prev = p; } } /** * Head of CLH queue */ private transient volatile WNode whead; /** * Tail (last) of CLH queue */ private transient volatile WNode wtail; // views transient ReadLockView readLockView; transient WriteLockView writeLockView; transient ReadWriteLockView readWriteLockView; /** * Lock sequence/state */ private transient volatile long state; /** * extra reader count when state read count saturated */ private transient int readerOverflow; /** * Creates a new lock, initially in unlocked state. */ public StampedLock() { state = ORIGIN; } /** * Exclusively acquires the lock, blocking if necessary * until available. * * @return a stamp that can be used to unlock or convert mode */ @Suspendable public long writeLock() { try { long s, next; // bypass acquireWrite in fully unlocked case only return ((((s = state) & ABITS) == 0L && STATE.compareAndSet(this, s, next = s + WBIT)) ? next : acquireWrite(false, 0L)); } catch (SuspendExecution e) { throw new AssertionError(); } } /** * Exclusively acquires the lock if it is immediately available. * * @return a stamp that can be used to unlock or convert mode, * or zero if the lock is not available */ public long tryWriteLock() { long s, next; return ((((s = state) & ABITS) == 0L && STATE.compareAndSet(this, s, next = s + WBIT)) ? next : 0L); } /** * Exclusively acquires the lock if it is available within the * given time and the current strand has not been interrupted. * Behavior under timeout and interruption matches that specified * for method {@link Lock#tryLock(long,TimeUnit)}. * * @return a stamp that can be used to unlock or convert mode, * or zero if the lock is not available * @throws InterruptedException if the current strand is interrupted * before acquiring the lock */ @Suspendable public long tryWriteLock(long time, TimeUnit unit) throws InterruptedException { try { long nanos = unit.toNanos(time); if (!Strand.interrupted()) { long next, deadline; if ((next = tryWriteLock()) != 0L) return next; if (nanos <= 0L) return 0L; if ((deadline = System.nanoTime() + nanos) == 0L) deadline = 1L; if ((next = acquireWrite(true, deadline)) != INTERRUPTED) return next; } throw new InterruptedException(); } catch (SuspendExecution e) { throw new AssertionError(); } } /** * Exclusively acquires the lock, blocking if necessary * until available or the current strand is interrupted. * Behavior under interruption matches that specified * for method {@link Lock#lockInterruptibly()}. * * @return a stamp that can be used to unlock or convert mode * @throws InterruptedException if the current strand is interrupted * before acquiring the lock */ @Suspendable public long writeLockInterruptibly() throws InterruptedException { try { long next; if (!Strand.interrupted() && (next = acquireWrite(true, 0L)) != INTERRUPTED) return next; throw new InterruptedException(); } catch (SuspendExecution e) { throw new AssertionError(); } } /** * Non-exclusively acquires the lock, blocking if necessary * until available. * * @return a stamp that can be used to unlock or convert mode */ @Suspendable public long readLock() { try { long s, next; // bypass acquireRead on fully unlocked case only return ((((s = state) & ABITS) == 0L && STATE.compareAndSet(this, s, next = s + RUNIT)) ? next : acquireRead(false, 0L)); } catch (SuspendExecution e) { throw new AssertionError(); } } /** * Non-exclusively acquires the lock if it is immediately available. * * @return a stamp that can be used to unlock or convert mode, * or zero if the lock is not available */ public long tryReadLock() { for (;;) { long s, m, next; if ((m = (s = state) & ABITS) == WBIT) return 0L; else if (m < RFULL) { if (STATE.compareAndSet(this, s, next = s + RUNIT)) return next; } else if ((next = tryIncReaderOverflow(s)) != 0L) return next; } } /** * Non-exclusively acquires the lock if it is available within the * given time and the current strand has not been interrupted. * Behavior under timeout and interruption matches that specified * for method {@link Lock#tryLock(long,TimeUnit)}. * * @return a stamp that can be used to unlock or convert mode, * or zero if the lock is not available * @throws InterruptedException if the current strand is interrupted * before acquiring the lock */ @Suspendable public long tryReadLock(long time, TimeUnit unit) throws InterruptedException { try { long s, m, next, deadline; long nanos = unit.toNanos(time); if (!Strand.interrupted()) { if ((m = (s = state) & ABITS) != WBIT) { if (m < RFULL) { if (STATE.compareAndSet(this, s, next = s + RUNIT)) return next; } else if ((next = tryIncReaderOverflow(s)) != 0L) return next; } if (nanos <= 0L) return 0L; if ((deadline = System.nanoTime() + nanos) == 0L) deadline = 1L; if ((next = acquireRead(true, deadline)) != INTERRUPTED) return next; } throw new InterruptedException(); } catch (SuspendExecution e) { throw new AssertionError(); } } /** * Non-exclusively acquires the lock, blocking if necessary * until available or the current strand is interrupted. * Behavior under interruption matches that specified * for method {@link Lock#lockInterruptibly()}. * * @return a stamp that can be used to unlock or convert mode * @throws InterruptedException if the current strand is interrupted * before acquiring the lock */ @Suspendable public long readLockInterruptibly() throws InterruptedException { try { long next; if (!Strand.interrupted() && (next = acquireRead(true, 0L)) != INTERRUPTED) return next; throw new InterruptedException(); } catch (SuspendExecution e) { throw new AssertionError(); } } /** * Returns a stamp that can later be validated, or zero * if exclusively locked. * * @return a stamp, or zero if exclusively locked */ public long tryOptimisticRead() { long s; return (((s = state) & WBIT) == 0L) ? (s & SBITS) : 0L; } /** * Returns true if the lock has not been exclusively acquired * since issuance of the given stamp. Always returns false if the * stamp is zero. Always returns true if the stamp represents a * currently held lock. Invoking this method with a value not * obtained from {@link #tryOptimisticRead} or a locking method * for this lock has no defined effect or result. * * @return true if the lock has not been exclusively acquired * since issuance of the given stamp; else false */ public boolean validate(long stamp) { // See above about current use of getLongVolatile here return (stamp & SBITS) == ((long)STATE.getVolatile(this) & SBITS); } /** * If the lock state matches the given stamp, releases the * exclusive lock. * * @param stamp a stamp returned by a write-lock operation * @throws IllegalMonitorStateException if the stamp does * not match the current state of this lock */ public void unlockWrite(long stamp) { WNode h; if (state != stamp || (stamp & WBIT) == 0L) throw new IllegalMonitorStateException(); state = (stamp += WBIT) == 0L ? ORIGIN : stamp; if ((h = whead) != null && h.status != 0) release(h); } /** * If the lock state matches the given stamp, releases the * non-exclusive lock. * * @param stamp a stamp returned by a read-lock operation * @throws IllegalMonitorStateException if the stamp does * not match the current state of this lock */ public void unlockRead(long stamp) { long s, m; WNode h; for (;;) { if (((s = state) & SBITS) != (stamp & SBITS) || (stamp & ABITS) == 0L || (m = s & ABITS) == 0L || m == WBIT) throw new IllegalMonitorStateException(); if (m < RFULL) { if (STATE.compareAndSet(this, s, s - RUNIT)) { if (m == RUNIT && (h = whead) != null && h.status != 0) release(h); break; } } else if (tryDecReaderOverflow(s) != 0L) break; } } /** * If the lock state matches the given stamp, releases the * corresponding mode of the lock. * * @param stamp a stamp returned by a lock operation * @throws IllegalMonitorStateException if the stamp does * not match the current state of this lock */ public void unlock(long stamp) { long a = stamp & ABITS, m, s; WNode h; while (((s = state) & SBITS) == (stamp & SBITS)) { if ((m = s & ABITS) == 0L) break; else if (m == WBIT) { if (a != m) break; state = (s += WBIT) == 0L ? ORIGIN : s; if ((h = whead) != null && h.status != 0) release(h); return; } else if (a == 0L || a >= WBIT) break; else if (m < RFULL) { if (STATE.compareAndSet(this, s, s - RUNIT)) { if (m == RUNIT && (h = whead) != null && h.status != 0) release(h); return; } } else if (tryDecReaderOverflow(s) != 0L) return; } throw new IllegalMonitorStateException(); } /** * If the lock state matches the given stamp, performs one of * the following actions. If the stamp represents holding a write * lock, returns it. Or, if a read lock, if the write lock is * available, releases the read lock and returns a write stamp. * Or, if an optimistic read, returns a write stamp only if * immediately available. This method returns zero in all other * cases. * * @param stamp a stamp * @return a valid write stamp, or zero on failure */ public long tryConvertToWriteLock(long stamp) { long a = stamp & ABITS, m, s, next; while (((s = state) & SBITS) == (stamp & SBITS)) { if ((m = s & ABITS) == 0L) { if (a != 0L) break; if (STATE.compareAndSet(this, s, next = s + WBIT)) return next; } else if (m == WBIT) { if (a != m) break; return stamp; } else if (m == RUNIT && a != 0L) { if (STATE.compareAndSet(this, s, next = s - RUNIT + WBIT)) return next; } else break; } return 0L; } /** * If the lock state matches the given stamp, performs one of * the following actions. If the stamp represents holding a write * lock, releases it and obtains a read lock. Or, if a read lock, * returns it. Or, if an optimistic read, acquires a read lock and * returns a read stamp only if immediately available. This method * returns zero in all other cases. * * @param stamp a stamp * @return a valid read stamp, or zero on failure */ public long tryConvertToReadLock(long stamp) { long a = stamp & ABITS, m, s, next; WNode h; while (((s = state) & SBITS) == (stamp & SBITS)) { if ((m = s & ABITS) == 0L) { if (a != 0L) break; else if (m < RFULL) { if (STATE.compareAndSet(this, s, next = s + RUNIT)) return next; } else if ((next = tryIncReaderOverflow(s)) != 0L) return next; } else if (m == WBIT) { if (a != m) break; state = next = s + (WBIT + RUNIT); if ((h = whead) != null && h.status != 0) release(h); return next; } else if (a != 0L && a < WBIT) return stamp; else break; } return 0L; } /** * If the lock state matches the given stamp then, if the stamp * represents holding a lock, releases it and returns an * observation stamp. Or, if an optimistic read, returns it if * validated. This method returns zero in all other cases, and so * may be useful as a form of "tryUnlock". * * @param stamp a stamp * @return a valid optimistic read stamp, or zero on failure */ public long tryConvertToOptimisticRead(long stamp) { long a = stamp & ABITS, m, s, next; WNode h; for (;;) { s = (long)STATE.getVolatile(this); // see above if ((s & SBITS) != (stamp & SBITS)) break; if ((m = s & ABITS) == 0L) { if (a != 0L) break; return s; } else if (m == WBIT) { if (a != m) break; state = next = (s += WBIT) == 0L ? ORIGIN : s; if ((h = whead) != null && h.status != 0) release(h); return next; } else if (a == 0L || a >= WBIT) break; else if (m < RFULL) { if (STATE.compareAndSet(this, s, next = s - RUNIT)) { if (m == RUNIT && (h = whead) != null && h.status != 0) release(h); return next & SBITS; } } else if ((next = tryDecReaderOverflow(s)) != 0L) return next & SBITS; } return 0L; } /** * Releases the write lock if it is held, without requiring a * stamp value. This method may be useful for recovery after * errors. * * @return true if the lock was held, else false */ public boolean tryUnlockWrite() { long s; WNode h; if (((s = state) & WBIT) != 0L) { state = (s += WBIT) == 0L ? ORIGIN : s; if ((h = whead) != null && h.status != 0) release(h); return true; } return false; } /** * Releases one hold of the read lock if it is held, without * requiring a stamp value. This method may be useful for recovery * after errors. * * @return true if the read lock was held, else false */ public boolean tryUnlockRead() { long s, m; WNode h; while ((m = (s = state) & ABITS) != 0L && m < WBIT) { if (m < RFULL) { if (STATE.compareAndSet(this, s, s - RUNIT)) { if (m == RUNIT && (h = whead) != null && h.status != 0) release(h); return true; } } else if (tryDecReaderOverflow(s) != 0L) return true; } return false; } /** * Returns true if the lock is currently held exclusively. * * @return true if the lock is currently held exclusively */ public boolean isWriteLocked() { return (state & WBIT) != 0L; } /** * Returns true if the lock is currently held non-exclusively. * * @return true if the lock is currently held non-exclusively */ public boolean isReadLocked() { return (state & RBITS) != 0L; } private void readObject(java.io.ObjectInputStream s) throws java.io.IOException, ClassNotFoundException { s.defaultReadObject(); state = ORIGIN; // reset to unlocked state } /** * Returns a plain {@link Lock} view of this StampedLock in which * the {@link Lock#lock} method is mapped to {@link #readLock}, * and similarly for other methods. The returned Lock does not * support a {@link Condition}; method {@link * Lock#newCondition()} throws {@code * UnsupportedOperationException}. * * @return the lock */ public Lock asReadLock() { ReadLockView v; return ((v = readLockView) != null ? v : (readLockView = new ReadLockView())); } /** * Returns a plain {@link Lock} view of this StampedLock in which * the {@link Lock#lock} method is mapped to {@link #writeLock}, * and similarly for other methods. The returned Lock does not * support a {@link Condition}; method {@link * Lock#newCondition()} throws {@code * UnsupportedOperationException}. * * @return the lock */ public Lock asWriteLock() { WriteLockView v; return ((v = writeLockView) != null ? v : (writeLockView = new WriteLockView())); } /** * Returns a {@link ReadWriteLock} view of this StampedLock in * which the {@link ReadWriteLock#readLock()} method is mapped to * {@link #asReadLock()}, and {@link ReadWriteLock#writeLock()} to * {@link #asWriteLock()}. * * @return the lock */ public ReadWriteLock asReadWriteLock() { ReadWriteLockView v; return ((v = readWriteLockView) != null ? v : (readWriteLockView = new ReadWriteLockView())); } // view classes final class ReadLockView implements Lock { @Suspendable public void lock() { readLock(); } @Suspendable public void lockInterruptibly() throws InterruptedException { readLockInterruptibly(); } public boolean tryLock() { return tryReadLock() != 0L; } @Suspendable public boolean tryLock(long time, TimeUnit unit) throws InterruptedException { return tryReadLock(time, unit) != 0L; } public void unlock() { unstampedUnlockRead(); } public Condition newCondition() { throw new UnsupportedOperationException(); } } final class WriteLockView implements Lock { @Suspendable public void lock() { writeLock(); } @Suspendable public void lockInterruptibly() throws InterruptedException { writeLockInterruptibly(); } public boolean tryLock() { return tryWriteLock() != 0L; } @Suspendable public boolean tryLock(long time, TimeUnit unit) throws InterruptedException { return tryWriteLock(time, unit) != 0L; } public void unlock() { unstampedUnlockWrite(); } public Condition newCondition() { throw new UnsupportedOperationException(); } } final class ReadWriteLockView implements ReadWriteLock { public Lock readLock() { return asReadLock(); } public Lock writeLock() { return asWriteLock(); } } // Unlock methods without stamp argument checks for view classes. // Needed because view-class lock methods throw away stamps. final void unstampedUnlockWrite() { WNode h; long s; if (((s = state) & WBIT) == 0L) throw new IllegalMonitorStateException(); state = (s += WBIT) == 0L ? ORIGIN : s; if ((h = whead) != null && h.status != 0) release(h); } final void unstampedUnlockRead() { for (;;) { long s, m; WNode h; if ((m = (s = state) & ABITS) == 0L || m >= WBIT) throw new IllegalMonitorStateException(); else if (m < RFULL) { if (STATE.compareAndSet(this, s, s - RUNIT)) { if (m == RUNIT && (h = whead) != null && h.status != 0) release(h); break; } } else if (tryDecReaderOverflow(s) != 0L) break; } } // internals /** * Tries to increment readerOverflow by first setting state * access bits value to RBITS, indicating hold of spinlock, * then updating, then releasing. * * @param s a reader overflow stamp: (s & ABITS) >= RFULL * @return new stamp on success, else zero */ private long tryIncReaderOverflow(long s) { // assert (s & ABITS) >= RFULL if ((s & ABITS) == RFULL) { if (STATE.compareAndSet(this, s, s | RBITS)) { ++readerOverflow; state = s; return s; } } else if ((ThreadLocalRandom.current().nextInt() & OVERFLOW_YIELD_RATE) == 0) if (!Strand.isCurrentFiber()) Thread.yield();//Strand.yield(); return 0L; } /** * Tries to decrement readerOverflow. * * @param s a reader overflow stamp: (s & ABITS) >= RFULL * @return new stamp on success, else zero */ private long tryDecReaderOverflow(long s) { // assert (s & ABITS) >= RFULL if ((s & ABITS) == RFULL) { if (STATE.compareAndSet(this, s, s | RBITS)) { int r; long next; if ((r = readerOverflow) > 0) { readerOverflow = r - 1; next = s; } else next = s - RUNIT; state = next; return next; } } else if ((ThreadLocalRandom.current().nextInt() & OVERFLOW_YIELD_RATE) == 0) if (!Strand.isCurrentFiber()) Thread.yield();//Strand.yield(); return 0L; } /** * Wakes up the successor of h (normally whead). This is normally * just h.next, but may require traversal from wtail if next * pointers are lagging. This may fail to wake up an acquiring * strand when one or more have been cancelled, but the cancel * methods themselves provide extra safeguards to ensure liveness. */ private void release(WNode h) { if (h != null) { WNode q; Strand w; WSTATUS.compareAndSet(h, WAITING, 0); if ((q = h.next) == null || q.status == CANCELLED) { for (WNode t = wtail; t != null && t != h; t = t.prev) if (t.status <= 0) q = t; } if (q != null) { for (WNode r = q;;) { // release co-waiters too if ((w = r.strand) != null) { r.strand = null; w.unpark(); } if ((r = q.cowait) == null) break; WCOWAIT.compareAndSet(q, r, r.cowait); } } } } /** * See above for explanation. * * @param interruptible true if should check interrupts and if so * return INTERRUPTED * @param deadline if nonzero, the System.nanoTime value to timeout * at (and return zero) * @return next state, or INTERRUPTED */ private long acquireWrite(boolean interruptible, long deadline) throws SuspendExecution { WNode node = null, p; for (int spins = -1;;) { // spin while enqueuing long s, ns; if (((s = state) & ABITS) == 0L) { if (STATE.compareAndSet(this, s, ns = s + WBIT)) return ns; } else if (spins > 0) { if (ThreadLocalRandom.current().nextInt() >= 0) --spins; } else if ((p = wtail) == null) { // initialize queue WNode h = new WNode(WMODE, null); if (WHEAD.compareAndSet(this, null, h)) wtail = h; } else if (spins < 0) spins = (p == whead) ? SPINS : 0; else if (node == null) node = new WNode(WMODE, p); else if (node.prev != p) node.prev = p; else if (WTAIL.compareAndSet(this, p, node)) { p.next = node; break; } } for (int spins = SPINS;;) { WNode np, pp; int ps; long s, ns; Strand w; while ((np = node.prev) != p && np != null) (p = np).next = node; // stale if (whead == p) { for (int k = spins;;) { // spin at head if (((s = state) & ABITS) == 0L) { if (STATE.compareAndSet(this, s, ns = s + WBIT)) { whead = node; node.prev = null; return ns; } } else if (ThreadLocalRandom.current().nextInt() >= 0 && --k <= 0) break; } if (spins < MAX_HEAD_SPINS) spins <<= 1; } if ((ps = p.status) == 0) WSTATUS.compareAndSet(p, 0, WAITING); else if (ps == CANCELLED) { if ((pp = p.prev) != null) { node.prev = pp; pp.next = node; } } else { long time; // 0 argument to park means no timeout if (deadline == 0L) time = 0L; else if ((time = deadline - System.nanoTime()) <= 0L) return cancelWaiter(node, node, false); node.strand = Strand.currentStrand(); if (node.prev == p && p.status == WAITING && // recheck (p != whead || (state & ABITS) != 0L)) park(time); node.strand = null; if (interruptible && Strand.interrupted()) return cancelWaiter(node, node, true); } } } /** * See above for explanation. * * @param interruptible true if should check interrupts and if so * return INTERRUPTED * @param deadline if nonzero, the System.nanoTime value to timeout * at (and return zero) * @return next state, or INTERRUPTED */ private long acquireRead(boolean interruptible, long deadline) throws SuspendExecution { WNode node = null, group = null, p; for (int spins = -1;;) { for (;;) { long s, m, ns; WNode h, q; Strand w; // anti-barging guard if (group == null && (h = whead) != null && (q = h.next) != null && q.mode != RMODE) break; if ((m = (s = state) & ABITS) < RFULL ? STATE.compareAndSet(this, s, ns = s + RUNIT) : (m < WBIT && (ns = tryIncReaderOverflow(s)) != 0L)) { if (group != null) { // help release others for (WNode r = group;;) { if ((w = r.strand) != null) { r.strand = null; w.unpark(); } if ((r = group.cowait) == null) break; WCOWAIT.compareAndSet(group, r, r.cowait); } } return ns; } if (m >= WBIT) break; } if (spins > 0) { if (ThreadLocalRandom.current().nextInt() >= 0) --spins; } else if ((p = wtail) == null) { WNode h = new WNode(WMODE, null); if (WHEAD.compareAndSet(this, null, h)) wtail = h; } else if (spins < 0) spins = (p == whead) ? SPINS : 0; else if (node == null) node = new WNode(WMODE, p); else if (node.prev != p) node.prev = p; else if (p.mode == RMODE && p != whead) { WNode pp = p.prev; // become co-waiter with group p if (pp != null && p == wtail && WCOWAIT.compareAndSet(p, node.cowait = p.cowait, node)) { node.strand = Strand.currentStrand(); for (long time;;) { if (interruptible && Strand.interrupted()) return cancelWaiter(node, p, true); if (deadline == 0L) time = 0L; else if ((time = deadline - System.nanoTime()) <= 0L) return cancelWaiter(node, p, false); if (node.strand == null) break; if (p.prev != pp || p.status == CANCELLED || p == whead || p.prev != pp) { node.strand = null; break; } if (node.strand == null) // must recheck break; park(time); } group = p; } node = null; // throw away } else if (WTAIL.compareAndSet(this, p, node)) { p.next = node; break; } } for (int spins = SPINS;;) { WNode np, pp, r; int ps; long m, s, ns; Strand w; while ((np = node.prev) != p && np != null) (p = np).next = node; if (whead == p) { for (int k = spins;;) { if ((m = (s = state) & ABITS) != WBIT) { if (m < RFULL ? STATE.compareAndSet(this, s, ns = s + RUNIT) : (ns = tryIncReaderOverflow(s)) != 0L) { whead = node; node.prev = null; while ((r = node.cowait) != null) { if (WCOWAIT.compareAndSet(node, r, r.cowait) && (w = r.strand) != null) { r.strand = null; w.unpark(); // release co-waiter } } return ns; } } else if (ThreadLocalRandom.current().nextInt() >= 0 && --k <= 0) break; } if (spins < MAX_HEAD_SPINS) spins <<= 1; } if ((ps = p.status) == 0) WSTATUS.compareAndSet(p, 0, WAITING); else if (ps == CANCELLED) { if ((pp = p.prev) != null) { node.prev = pp; pp.next = node; } } else { long time; if (deadline == 0L) time = 0L; else if ((time = deadline - System.nanoTime()) <= 0L) return cancelWaiter(node, node, false); node.strand = Strand.currentStrand(); if (node.prev == p && p.status == WAITING && (p != whead || (state & ABITS) != WBIT)) park(time); node.strand = null; if (interruptible && Strand.interrupted()) return cancelWaiter(node, node, true); } } } /** * If node non-null, forces cancel status and unsplices it from * queue if possible and wakes up any cowaiters (of the node, or * group, as applicable), and in any case helps release current * first waiter if lock is free. (Calling with null arguments * serves as a conditional form of release, which is not currently * needed but may be needed under possible future cancellation * policies). This is a variant of cancellation methods in * AbstractQueuedSynchronizer (see its detailed explanation in AQS * internal documentation). * * @param node if nonnull, the waiter * @param group either node or the group node is cowaiting with * @param interrupted if already interrupted * @return INTERRUPTED if interrupted or Strand.interrupted, else zero */ private long cancelWaiter(WNode node, WNode group, boolean interrupted) { if (node != null && group != null) { Strand w; node.status = CANCELLED; node.strand = null; // unsplice cancelled nodes from group for (WNode p = group, q; (q = p.cowait) != null;) { if (q.status == CANCELLED) WNEXT.compareAndSet(p, q, q.next); else p = q; } if (group == node) { WNode r; // detach and wake up uncancelled co-waiters while ((r = node.cowait) != null) { if (WCOWAIT.compareAndSet(node, r, r.cowait) && (w = r.strand) != null) { r.strand = null; w.unpark(); } } for (WNode pred = node.prev; pred != null;) { // unsplice WNode succ, pp; // find valid successor while ((succ = node.next) == null || succ.status == CANCELLED) { WNode q = null; // find successor the slow way for (WNode t = wtail; t != null && t != node; t = t.prev) if (t.status != CANCELLED) q = t; // don't link if succ cancelled if (succ == q || // ensure accurate successor WNEXT.compareAndSet(node, succ, succ = q)) { if (succ == null && node == wtail) WTAIL.compareAndSet(this, node, pred); break; } } if (pred.next == node) // unsplice pred link WNEXT.compareAndSet(pred, node, succ); if (succ != null && (w = succ.strand) != null) { succ.strand = null; w.unpark(); // wake up succ to observe new pred } if (pred.status != CANCELLED || (pp = pred.prev) == null) break; node.prev = pp; // repeat if new pred wrong/cancelled WNEXT.compareAndSet(pp, pred, succ); pred = pp; } } } WNode h; // Possibly release first waiter while ((h = whead) != null) { long s; WNode q; // similar to release() but check eligibility if ((q = h.next) == null || q.status == CANCELLED) { for (WNode t = wtail; t != null && t != h; t = t.prev) if (t.status <= 0) q = t; } if (h == whead) { if (q != null && h.status == 0 && ((s = state) & ABITS) != WBIT && // waiter is eligible (s == 0L || q.mode == RMODE)) release(h); break; } } return (interrupted || Strand.interrupted()) ? INTERRUPTED : 0L; } private static final VarHandle STATE; private static final VarHandle WHEAD; private static final VarHandle WTAIL; private static final VarHandle WNEXT; private static final VarHandle WSTATUS; private static final VarHandle WCOWAIT; static { try { Class k = StampedLock.class; Class wk = WNode.class; MethodHandles.Lookup l = MethodHandles.lookup(); STATE = l.findVarHandle(k, "state", long.class); WHEAD = l.findVarHandle(k, "whead", WNode.class); WTAIL = l.findVarHandle(k, "wtail", WNode.class); WSTATUS = l.findVarHandle(wk, "status", int.class); WNEXT = l.findVarHandle(wk, "next", WNode.class); WCOWAIT = l.findVarHandle(wk, "cowait", WNode.class); } catch (ReflectiveOperationException e) { throw new ExceptionInInitializerError(e); } } // // Unsafe mechanics // private static final sun.misc.Unsafe U; // private static final long STATE; // private static final long WHEAD; // private static final long WTAIL; // private static final long WNEXT; // private static final long WSTATUS; // private static final long WCOWAIT; // // static { // try { // U = UtilUnsafe.getUnsafe(); // Class k = StampedLock.class; // Class wk = WNode.class; // STATE = U.objectFieldOffset(k.getDeclaredField("state")); // WHEAD = U.objectFieldOffset(k.getDeclaredField("whead")); // WTAIL = U.objectFieldOffset(k.getDeclaredField("wtail")); // WSTATUS = U.objectFieldOffset(wk.getDeclaredField("status")); // WNEXT = U.objectFieldOffset(wk.getDeclaredField("next")); // WCOWAIT = U.objectFieldOffset(wk.getDeclaredField("cowait")); // // } catch (Exception e) { // throw new Error(e); // } // } private static void park(long time) throws SuspendExecution { if (time != 0) Strand.parkNanos(time); else Strand.park(); } }




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