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/*
 * 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 org.jctools.queues.atomic;

import org.jctools.queues.IndexedQueueSizeUtil.IndexedQueue;
import org.jctools.util.PortableJvmInfo;
import org.jctools.util.Pow2;
import org.jctools.util.RangeUtil;
import java.util.AbstractQueue;
import java.util.Iterator;
import java.util.NoSuchElementException;
import java.util.concurrent.atomic.AtomicReferenceFieldUpdater;
import java.util.concurrent.atomic.AtomicLongFieldUpdater;
import java.util.concurrent.atomic.AtomicReferenceArray;
import org.jctools.queues.MessagePassingQueue;
import org.jctools.queues.MessagePassingQueue.Supplier;
import org.jctools.queues.MessagePassingQueueUtil;
import org.jctools.queues.QueueProgressIndicators;
import org.jctools.queues.IndexedQueueSizeUtil;
import static org.jctools.queues.atomic.AtomicQueueUtil.*;

/**
 * NOTE: This class was automatically generated by org.jctools.queues.atomic.JavaParsingAtomicLinkedQueueGenerator
 * which can found in the jctools-build module. The original source file is BaseMpscLinkedArrayQueue.java.
 */
abstract class BaseMpscLinkedAtomicArrayQueuePad1 extends AbstractQueue implements IndexedQueue {

    // 8b
    byte b000, b001, b002, b003, b004, b005, b006, b007;

    // 16b
    byte b010, b011, b012, b013, b014, b015, b016, b017;

    // 24b
    byte b020, b021, b022, b023, b024, b025, b026, b027;

    // 32b
    byte b030, b031, b032, b033, b034, b035, b036, b037;

    // 40b
    byte b040, b041, b042, b043, b044, b045, b046, b047;

    // 48b
    byte b050, b051, b052, b053, b054, b055, b056, b057;

    // 56b
    byte b060, b061, b062, b063, b064, b065, b066, b067;

    // 64b
    byte b070, b071, b072, b073, b074, b075, b076, b077;

    // 72b
    byte b100, b101, b102, b103, b104, b105, b106, b107;

    // 80b
    byte b110, b111, b112, b113, b114, b115, b116, b117;

    // 88b
    byte b120, b121, b122, b123, b124, b125, b126, b127;

    // 96b
    byte b130, b131, b132, b133, b134, b135, b136, b137;

    // 104b
    byte b140, b141, b142, b143, b144, b145, b146, b147;

    // 112b
    byte b150, b151, b152, b153, b154, b155, b156, b157;

    // 120b
    byte b160, b161, b162, b163, b164, b165, b166, b167;

    // 128b
    byte b170, b171, b172, b173, b174, b175, b176, b177;
}

/**
 * NOTE: This class was automatically generated by org.jctools.queues.atomic.JavaParsingAtomicLinkedQueueGenerator
 * which can found in the jctools-build module. The original source file is BaseMpscLinkedArrayQueue.java.
 */
abstract class BaseMpscLinkedAtomicArrayQueueProducerFields extends BaseMpscLinkedAtomicArrayQueuePad1 {

    private static final AtomicLongFieldUpdater P_INDEX_UPDATER = AtomicLongFieldUpdater.newUpdater(BaseMpscLinkedAtomicArrayQueueProducerFields.class, "producerIndex");

    private volatile long producerIndex;

    @Override
    public final long lvProducerIndex() {
        return producerIndex;
    }

    final void soProducerIndex(long newValue) {
        P_INDEX_UPDATER.lazySet(this, newValue);
    }

    final boolean casProducerIndex(long expect, long newValue) {
        return P_INDEX_UPDATER.compareAndSet(this, expect, newValue);
    }
}

/**
 * NOTE: This class was automatically generated by org.jctools.queues.atomic.JavaParsingAtomicLinkedQueueGenerator
 * which can found in the jctools-build module. The original source file is BaseMpscLinkedArrayQueue.java.
 */
abstract class BaseMpscLinkedAtomicArrayQueuePad2 extends BaseMpscLinkedAtomicArrayQueueProducerFields {

    // 8b
    byte b000, b001, b002, b003, b004, b005, b006, b007;

    // 16b
    byte b010, b011, b012, b013, b014, b015, b016, b017;

    // 24b
    byte b020, b021, b022, b023, b024, b025, b026, b027;

    // 32b
    byte b030, b031, b032, b033, b034, b035, b036, b037;

    // 40b
    byte b040, b041, b042, b043, b044, b045, b046, b047;

    // 48b
    byte b050, b051, b052, b053, b054, b055, b056, b057;

    // 56b
    byte b060, b061, b062, b063, b064, b065, b066, b067;

    // 64b
    byte b070, b071, b072, b073, b074, b075, b076, b077;

    // 72b
    byte b100, b101, b102, b103, b104, b105, b106, b107;

    // 80b
    byte b110, b111, b112, b113, b114, b115, b116, b117;

    // 88b
    byte b120, b121, b122, b123, b124, b125, b126, b127;

    // 96b
    byte b130, b131, b132, b133, b134, b135, b136, b137;

    // 104b
    byte b140, b141, b142, b143, b144, b145, b146, b147;

    // 112b
    byte b150, b151, b152, b153, b154, b155, b156, b157;

    // 120b
    byte b160, b161, b162, b163, b164, b165, b166, b167;

    // 128b
    byte b170, b171, b172, b173, b174, b175, b176, b177;
}

/**
 * NOTE: This class was automatically generated by org.jctools.queues.atomic.JavaParsingAtomicLinkedQueueGenerator
 * which can found in the jctools-build module. The original source file is BaseMpscLinkedArrayQueue.java.
 */
abstract class BaseMpscLinkedAtomicArrayQueueConsumerFields extends BaseMpscLinkedAtomicArrayQueuePad2 {

    private static final AtomicLongFieldUpdater C_INDEX_UPDATER = AtomicLongFieldUpdater.newUpdater(BaseMpscLinkedAtomicArrayQueueConsumerFields.class, "consumerIndex");

    private volatile long consumerIndex;

    protected long consumerMask;

    protected AtomicReferenceArray consumerBuffer;

    @Override
    public final long lvConsumerIndex() {
        return consumerIndex;
    }

    final long lpConsumerIndex() {
        return consumerIndex;
    }

    final void soConsumerIndex(long newValue) {
        C_INDEX_UPDATER.lazySet(this, newValue);
    }
}

/**
 * NOTE: This class was automatically generated by org.jctools.queues.atomic.JavaParsingAtomicLinkedQueueGenerator
 * which can found in the jctools-build module. The original source file is BaseMpscLinkedArrayQueue.java.
 */
abstract class BaseMpscLinkedAtomicArrayQueuePad3 extends BaseMpscLinkedAtomicArrayQueueConsumerFields {

    // 8b
    byte b000, b001, b002, b003, b004, b005, b006, b007;

    // 16b
    byte b010, b011, b012, b013, b014, b015, b016, b017;

    // 24b
    byte b020, b021, b022, b023, b024, b025, b026, b027;

    // 32b
    byte b030, b031, b032, b033, b034, b035, b036, b037;

    // 40b
    byte b040, b041, b042, b043, b044, b045, b046, b047;

    // 48b
    byte b050, b051, b052, b053, b054, b055, b056, b057;

    // 56b
    byte b060, b061, b062, b063, b064, b065, b066, b067;

    // 64b
    byte b070, b071, b072, b073, b074, b075, b076, b077;

    // 72b
    byte b100, b101, b102, b103, b104, b105, b106, b107;

    // 80b
    byte b110, b111, b112, b113, b114, b115, b116, b117;

    // 88b
    byte b120, b121, b122, b123, b124, b125, b126, b127;

    // 96b
    byte b130, b131, b132, b133, b134, b135, b136, b137;

    // 104b
    byte b140, b141, b142, b143, b144, b145, b146, b147;

    // 112b
    byte b150, b151, b152, b153, b154, b155, b156, b157;

    // 120b
    byte b160, b161, b162, b163, b164, b165, b166, b167;

    // 128b
    byte b170, b171, b172, b173, b174, b175, b176, b177;
}

/**
 * NOTE: This class was automatically generated by org.jctools.queues.atomic.JavaParsingAtomicLinkedQueueGenerator
 * which can found in the jctools-build module. The original source file is BaseMpscLinkedArrayQueue.java.
 */
abstract class BaseMpscLinkedAtomicArrayQueueColdProducerFields extends BaseMpscLinkedAtomicArrayQueuePad3 {

    private static final AtomicLongFieldUpdater P_LIMIT_UPDATER = AtomicLongFieldUpdater.newUpdater(BaseMpscLinkedAtomicArrayQueueColdProducerFields.class, "producerLimit");

    private volatile long producerLimit;

    protected long producerMask;

    protected AtomicReferenceArray producerBuffer;

    final long lvProducerLimit() {
        return producerLimit;
    }

    final boolean casProducerLimit(long expect, long newValue) {
        return P_LIMIT_UPDATER.compareAndSet(this, expect, newValue);
    }

    final void soProducerLimit(long newValue) {
        P_LIMIT_UPDATER.lazySet(this, newValue);
    }
}

/**
 * NOTE: This class was automatically generated by org.jctools.queues.atomic.JavaParsingAtomicLinkedQueueGenerator
 * which can found in the jctools-build module. The original source file is BaseMpscLinkedArrayQueue.java.
 *
 * An MPSC array queue which starts at initialCapacity and grows to maxCapacity in linked chunks
 * of the initial size. The queue grows only when the current buffer is full and elements are not copied on
 * resize, instead a link to the new buffer is stored in the old buffer for the consumer to follow.
 */
abstract class BaseMpscLinkedAtomicArrayQueue extends BaseMpscLinkedAtomicArrayQueueColdProducerFields implements MessagePassingQueue, QueueProgressIndicators {

    // No post padding here, subclasses must add
    private static final Object JUMP = new Object();

    private static final Object BUFFER_CONSUMED = new Object();

    private static final int CONTINUE_TO_P_INDEX_CAS = 0;

    private static final int RETRY = 1;

    private static final int QUEUE_FULL = 2;

    private static final int QUEUE_RESIZE = 3;

    /**
     * @param initialCapacity the queue initial capacity. If chunk size is fixed this will be the chunk size.
     *                        Must be 2 or more.
     */
    public BaseMpscLinkedAtomicArrayQueue(final int initialCapacity) {
        RangeUtil.checkGreaterThanOrEqual(initialCapacity, 2, "initialCapacity");
        int p2capacity = Pow2.roundToPowerOfTwo(initialCapacity);
        // leave lower bit of mask clear
        long mask = (p2capacity - 1) << 1;
        // need extra element to point at next array
        AtomicReferenceArray buffer = allocateRefArray(p2capacity + 1);
        producerBuffer = buffer;
        producerMask = mask;
        consumerBuffer = buffer;
        consumerMask = mask;
        // we know it's all empty to start with
        soProducerLimit(mask);
    }

    @Override
    public int size() {
        // NOTE: because indices are on even numbers we cannot use the size util.
        /*
         * It is possible for a thread to be interrupted or reschedule between the read of the producer and
         * consumer indices, therefore protection is required to ensure size is within valid range. In the
         * event of concurrent polls/offers to this method the size is OVER estimated as we read consumer
         * index BEFORE the producer index.
         */
        long after = lvConsumerIndex();
        long size;
        while (true) {
            final long before = after;
            final long currentProducerIndex = lvProducerIndex();
            after = lvConsumerIndex();
            if (before == after) {
                size = ((currentProducerIndex - after) >> 1);
                break;
            }
        }
        // indexed queues.
        if (size > Integer.MAX_VALUE) {
            return Integer.MAX_VALUE;
        } else {
            return (int) size;
        }
    }

    @Override
    public boolean isEmpty() {
        // nothing we can do to make this an exact method.
        return (this.lvConsumerIndex() == this.lvProducerIndex());
    }

    @Override
    public String toString() {
        return this.getClass().getName();
    }

    @Override
    public boolean offer(final E e) {
        if (null == e) {
            throw new NullPointerException();
        }
        long mask;
        AtomicReferenceArray buffer;
        long pIndex;
        while (true) {
            long producerLimit = lvProducerLimit();
            pIndex = lvProducerIndex();
            // lower bit is indicative of resize, if we see it we spin until it's cleared
            if ((pIndex & 1) == 1) {
                continue;
            }
            // pIndex is even (lower bit is 0) -> actual index is (pIndex >> 1)
            // mask/buffer may get changed by resizing -> only use for array access after successful CAS.
            mask = this.producerMask;
            buffer = this.producerBuffer;
            // assumption behind this optimization is that queue is almost always empty or near empty
            if (producerLimit <= pIndex) {
                int result = offerSlowPath(mask, pIndex, producerLimit);
                switch(result) {
                    case CONTINUE_TO_P_INDEX_CAS:
                        break;
                    case RETRY:
                        continue;
                    case QUEUE_FULL:
                        return false;
                    case QUEUE_RESIZE:
                        resize(mask, buffer, pIndex, e, null);
                        return true;
                }
            }
            if (casProducerIndex(pIndex, pIndex + 2)) {
                break;
            }
        }
        // INDEX visible before ELEMENT
        final int offset = modifiedCalcCircularRefElementOffset(pIndex, mask);
        // release element e
        soRefElement(buffer, offset, e);
        return true;
    }

    /**
     * {@inheritDoc}
     * 

* This implementation is correct for single consumer thread use only. */ @SuppressWarnings("unchecked") @Override public E poll() { final AtomicReferenceArray buffer = consumerBuffer; final long index = lpConsumerIndex(); final long mask = consumerMask; final int offset = modifiedCalcCircularRefElementOffset(index, mask); Object e = lvRefElement(buffer, offset); if (e == null) { if (index != lvProducerIndex()) { // visible. do { e = lvRefElement(buffer, offset); } while (e == null); } else { return null; } } if (e == JUMP) { final AtomicReferenceArray nextBuffer = nextBuffer(buffer, mask); return newBufferPoll(nextBuffer, index); } // release element null soRefElement(buffer, offset, null); // release cIndex soConsumerIndex(index + 2); return (E) e; } /** * {@inheritDoc} *

* This implementation is correct for single consumer thread use only. */ @SuppressWarnings("unchecked") @Override public E peek() { final AtomicReferenceArray buffer = consumerBuffer; final long index = lpConsumerIndex(); final long mask = consumerMask; final int offset = modifiedCalcCircularRefElementOffset(index, mask); Object e = lvRefElement(buffer, offset); if (e == null && index != lvProducerIndex()) { // check the producer index. If the queue is indeed not empty we spin until element is visible. do { e = lvRefElement(buffer, offset); } while (e == null); } if (e == JUMP) { return newBufferPeek(nextBuffer(buffer, mask), index); } return (E) e; } /** * We do not inline resize into this method because we do not resize on fill. */ private int offerSlowPath(long mask, long pIndex, long producerLimit) { final long cIndex = lvConsumerIndex(); long bufferCapacity = getCurrentBufferCapacity(mask); if (cIndex + bufferCapacity > pIndex) { if (!casProducerLimit(producerLimit, cIndex + bufferCapacity)) { // retry from top return RETRY; } else { // continue to pIndex CAS return CONTINUE_TO_P_INDEX_CAS; } } else // full and cannot grow if (availableInQueue(pIndex, cIndex) <= 0) { // offer should return false; return QUEUE_FULL; } else // grab index for resize -> set lower bit if (casProducerIndex(pIndex, pIndex + 1)) { // trigger a resize return QUEUE_RESIZE; } else { // failed resize attempt, retry from top return RETRY; } } /** * @return available elements in queue * 2 */ protected abstract long availableInQueue(long pIndex, long cIndex); @SuppressWarnings("unchecked") private AtomicReferenceArray nextBuffer(final AtomicReferenceArray buffer, final long mask) { final int offset = nextArrayOffset(mask); final AtomicReferenceArray nextBuffer = (AtomicReferenceArray) lvRefElement(buffer, offset); consumerBuffer = nextBuffer; consumerMask = (length(nextBuffer) - 2) << 1; soRefElement(buffer, offset, BUFFER_CONSUMED); return nextBuffer; } private static int nextArrayOffset(long mask) { return modifiedCalcCircularRefElementOffset(mask + 2, Long.MAX_VALUE); } private E newBufferPoll(AtomicReferenceArray nextBuffer, long index) { final int offset = modifiedCalcCircularRefElementOffset(index, consumerMask); final E n = lvRefElement(nextBuffer, offset); if (n == null) { throw new IllegalStateException("new buffer must have at least one element"); } soRefElement(nextBuffer, offset, null); soConsumerIndex(index + 2); return n; } private E newBufferPeek(AtomicReferenceArray nextBuffer, long index) { final int offset = modifiedCalcCircularRefElementOffset(index, consumerMask); final E n = lvRefElement(nextBuffer, offset); if (null == n) { throw new IllegalStateException("new buffer must have at least one element"); } return n; } @Override public long currentProducerIndex() { return lvProducerIndex() / 2; } @Override public long currentConsumerIndex() { return lvConsumerIndex() / 2; } @Override public abstract int capacity(); @Override public boolean relaxedOffer(E e) { return offer(e); } @SuppressWarnings("unchecked") @Override public E relaxedPoll() { final AtomicReferenceArray buffer = consumerBuffer; final long index = lpConsumerIndex(); final long mask = consumerMask; final int offset = modifiedCalcCircularRefElementOffset(index, mask); Object e = lvRefElement(buffer, offset); if (e == null) { return null; } if (e == JUMP) { final AtomicReferenceArray nextBuffer = nextBuffer(buffer, mask); return newBufferPoll(nextBuffer, index); } soRefElement(buffer, offset, null); soConsumerIndex(index + 2); return (E) e; } @SuppressWarnings("unchecked") @Override public E relaxedPeek() { final AtomicReferenceArray buffer = consumerBuffer; final long index = lpConsumerIndex(); final long mask = consumerMask; final int offset = modifiedCalcCircularRefElementOffset(index, mask); Object e = lvRefElement(buffer, offset); if (e == JUMP) { return newBufferPeek(nextBuffer(buffer, mask), index); } return (E) e; } @Override public int fill(Supplier s) { // result is a long because we want to have a safepoint check at regular intervals long result = 0; final int capacity = capacity(); do { final int filled = fill(s, PortableJvmInfo.RECOMENDED_OFFER_BATCH); if (filled == 0) { return (int) result; } result += filled; } while (result <= capacity); return (int) result; } @Override public int fill(Supplier s, int limit) { if (null == s) throw new IllegalArgumentException("supplier is null"); if (limit < 0) throw new IllegalArgumentException("limit is negative:" + limit); if (limit == 0) return 0; long mask; AtomicReferenceArray buffer; long pIndex; int claimedSlots; while (true) { long producerLimit = lvProducerLimit(); pIndex = lvProducerIndex(); // lower bit is indicative of resize, if we see it we spin until it's cleared if ((pIndex & 1) == 1) { continue; } // pIndex is even (lower bit is 0) -> actual index is (pIndex >> 1) // NOTE: mask/buffer may get changed by resizing -> only use for array access after successful CAS. // Only by virtue offloading them between the lvProducerIndex and a successful casProducerIndex are they // safe to use. mask = this.producerMask; buffer = this.producerBuffer; // a successful CAS ties the ordering, lv(pIndex) -> [mask/buffer] -> cas(pIndex) // we want 'limit' slots, but will settle for whatever is visible to 'producerLimit' // -> producerLimit >= batchIndex long batchIndex = Math.min(producerLimit, pIndex + 2l * limit); if (pIndex >= producerLimit) { int result = offerSlowPath(mask, pIndex, producerLimit); switch(result) { case CONTINUE_TO_P_INDEX_CAS: // offer slow path verifies only one slot ahead, we cannot rely on indication here case RETRY: continue; case QUEUE_FULL: return 0; case QUEUE_RESIZE: resize(mask, buffer, pIndex, null, s); return 1; } } // claim limit slots at once if (casProducerIndex(pIndex, batchIndex)) { claimedSlots = (int) ((batchIndex - pIndex) / 2); break; } } for (int i = 0; i < claimedSlots; i++) { final int offset = modifiedCalcCircularRefElementOffset(pIndex + 2l * i, mask); soRefElement(buffer, offset, s.get()); } return claimedSlots; } @Override public void fill(Supplier s, WaitStrategy wait, ExitCondition exit) { MessagePassingQueueUtil.fill(this, s, wait, exit); } @Override public int drain(Consumer c) { return drain(c, capacity()); } @Override public int drain(Consumer c, int limit) { return MessagePassingQueueUtil.drain(this, c, limit); } @Override public void drain(Consumer c, WaitStrategy wait, ExitCondition exit) { MessagePassingQueueUtil.drain(this, c, wait, exit); } /** * Get an iterator for this queue. This method is thread safe. *

* The iterator provides a best-effort snapshot of the elements in the queue. * The returned iterator is not guaranteed to return elements in queue order, * and races with the consumer thread may cause gaps in the sequence of returned elements. * Like {link #relaxedPoll}, the iterator may not immediately return newly inserted elements. * * @return The iterator. */ @Override public Iterator iterator() { return new WeakIterator(consumerBuffer, lvConsumerIndex(), lvProducerIndex()); } /** * NOTE: This class was automatically generated by org.jctools.queues.atomic.JavaParsingAtomicLinkedQueueGenerator * which can found in the jctools-build module. The original source file is BaseMpscLinkedArrayQueue.java. */ private static class WeakIterator implements Iterator { private final long pIndex; private long nextIndex; private E nextElement; private AtomicReferenceArray currentBuffer; private int mask; WeakIterator(AtomicReferenceArray currentBuffer, long cIndex, long pIndex) { this.pIndex = pIndex >> 1; this.nextIndex = cIndex >> 1; setBuffer(currentBuffer); nextElement = getNext(); } @Override public void remove() { throw new UnsupportedOperationException("remove"); } @Override public boolean hasNext() { return nextElement != null; } @Override public E next() { final E e = nextElement; if (e == null) { throw new NoSuchElementException(); } nextElement = getNext(); return e; } private void setBuffer(AtomicReferenceArray buffer) { this.currentBuffer = buffer; this.mask = length(buffer) - 2; } private E getNext() { while (nextIndex < pIndex) { long index = nextIndex++; E e = lvRefElement(currentBuffer, calcCircularRefElementOffset(index, mask)); // skip removed/not yet visible elements if (e == null) { continue; } // not null && not JUMP -> found next element if (e != JUMP) { return e; } // need to jump to the next buffer int nextBufferIndex = mask + 1; Object nextBuffer = lvRefElement(currentBuffer, calcRefElementOffset(nextBufferIndex)); if (nextBuffer == BUFFER_CONSUMED || nextBuffer == null) { // Consumer may have passed us, or the next buffer is not visible yet: drop out early return null; } setBuffer((AtomicReferenceArray) nextBuffer); // now with the new array retry the load, it can't be a JUMP, but we need to repeat same index e = lvRefElement(currentBuffer, calcCircularRefElementOffset(index, mask)); // skip removed/not yet visible elements if (e == null) { continue; } else { return e; } } return null; } } private void resize(long oldMask, AtomicReferenceArray oldBuffer, long pIndex, E e, Supplier s) { assert (e != null && s == null) || (e == null || s != null); int newBufferLength = getNextBufferSize(oldBuffer); final AtomicReferenceArray newBuffer; try { newBuffer = allocateRefArray(newBufferLength); } catch (OutOfMemoryError oom) { assert lvProducerIndex() == pIndex + 1; soProducerIndex(pIndex); throw oom; } producerBuffer = newBuffer; final int newMask = (newBufferLength - 2) << 1; producerMask = newMask; final int offsetInOld = modifiedCalcCircularRefElementOffset(pIndex, oldMask); final int offsetInNew = modifiedCalcCircularRefElementOffset(pIndex, newMask); // element in new array soRefElement(newBuffer, offsetInNew, e == null ? s.get() : e); // buffer linked soRefElement(oldBuffer, nextArrayOffset(oldMask), newBuffer); // ASSERT code final long cIndex = lvConsumerIndex(); final long availableInQueue = availableInQueue(pIndex, cIndex); RangeUtil.checkPositive(availableInQueue, "availableInQueue"); // Invalidate racing CASs // We never set the limit beyond the bounds of a buffer soProducerLimit(pIndex + Math.min(newMask, availableInQueue)); // make resize visible to the other producers soProducerIndex(pIndex + 2); // INDEX visible before ELEMENT, consistent with consumer expectation // make resize visible to consumer soRefElement(oldBuffer, offsetInOld, JUMP); } /** * @return next buffer size(inclusive of next array pointer) */ protected abstract int getNextBufferSize(AtomicReferenceArray buffer); /** * @return current buffer capacity for elements (excluding next pointer and jump entry) * 2 */ protected abstract long getCurrentBufferCapacity(long mask); }





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