All Downloads are FREE. Search and download functionalities are using the official Maven repository.

org.jctools.queues.atomic.unpadded.SpscAtomicUnpaddedArrayQueue Maven / Gradle / Ivy

There is a newer version: 1.52.1
Show newest version
/*
 * 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.unpadded;

import org.jctools.util.SpscLookAheadUtil;
import java.util.concurrent.atomic.*;
import org.jctools.queues.*;
import static org.jctools.queues.atomic.AtomicQueueUtil.*;
import org.jctools.queues.atomic.AtomicReferenceArrayQueue;
import org.jctools.queues.atomic.SequencedAtomicReferenceArrayQueue;

/**
 * NOTE: This class was automatically generated by org.jctools.queues.atomic.unpadded.JavaParsingAtomicUnpaddedArrayQueueGenerator
 * which can found in the jctools-build module. The original source file is SpscArrayQueue.java.
 */
abstract class SpscAtomicUnpaddedArrayQueueColdField extends AtomicReferenceArrayQueue {

    final int lookAheadStep;

    SpscAtomicUnpaddedArrayQueueColdField(int capacity) {
        super(capacity);
        int actualCapacity = capacity();
        lookAheadStep = SpscLookAheadUtil.computeLookAheadStep(actualCapacity);
    }
}

/**
 * NOTE: This class was automatically generated by org.jctools.queues.atomic.unpadded.JavaParsingAtomicUnpaddedArrayQueueGenerator
 * which can found in the jctools-build module. The original source file is SpscArrayQueue.java.
 */
abstract class SpscAtomicUnpaddedArrayQueueL1Pad extends SpscAtomicUnpaddedArrayQueueColdField {

    SpscAtomicUnpaddedArrayQueueL1Pad(int capacity) {
        super(capacity);
    }
}

/**
 * NOTE: This class was automatically generated by org.jctools.queues.atomic.unpadded.JavaParsingAtomicUnpaddedArrayQueueGenerator
 * which can found in the jctools-build module. The original source file is SpscArrayQueue.java.
 */
abstract class SpscAtomicUnpaddedArrayQueueProducerIndexFields extends SpscAtomicUnpaddedArrayQueueL1Pad {

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

    private volatile long producerIndex;

    protected long producerLimit;

    SpscAtomicUnpaddedArrayQueueProducerIndexFields(int capacity) {
        super(capacity);
    }

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

    final long lpProducerIndex() {
        return producerIndex;
    }

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

/**
 * NOTE: This class was automatically generated by org.jctools.queues.atomic.unpadded.JavaParsingAtomicUnpaddedArrayQueueGenerator
 * which can found in the jctools-build module. The original source file is SpscArrayQueue.java.
 */
abstract class SpscAtomicUnpaddedArrayQueueL2Pad extends SpscAtomicUnpaddedArrayQueueProducerIndexFields {

    SpscAtomicUnpaddedArrayQueueL2Pad(int capacity) {
        super(capacity);
    }
}

/**
 * NOTE: This class was automatically generated by org.jctools.queues.atomic.unpadded.JavaParsingAtomicUnpaddedArrayQueueGenerator
 * which can found in the jctools-build module. The original source file is SpscArrayQueue.java.
 */
abstract class SpscAtomicUnpaddedArrayQueueConsumerIndexField extends SpscAtomicUnpaddedArrayQueueL2Pad {

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

    private volatile long consumerIndex;

    SpscAtomicUnpaddedArrayQueueConsumerIndexField(int capacity) {
        super(capacity);
    }

    public final long lvConsumerIndex() {
        return consumerIndex;
    }

    final long lpConsumerIndex() {
        return consumerIndex;
    }

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

/**
 * NOTE: This class was automatically generated by org.jctools.queues.atomic.unpadded.JavaParsingAtomicUnpaddedArrayQueueGenerator
 * which can found in the jctools-build module. The original source file is SpscArrayQueue.java.
 */
abstract class SpscAtomicUnpaddedArrayQueueL3Pad extends SpscAtomicUnpaddedArrayQueueConsumerIndexField {

    SpscAtomicUnpaddedArrayQueueL3Pad(int capacity) {
        super(capacity);
    }
}

/**
 * NOTE: This class was automatically generated by org.jctools.queues.atomic.unpadded.JavaParsingAtomicUnpaddedArrayQueueGenerator
 * which can found in the jctools-build module. The original source file is SpscArrayQueue.java.
 *
 * A Single-Producer-Single-Consumer queue backed by a pre-allocated buffer.
 * 

* This implementation is a mashup of the Fast Flow * algorithm with an optimization of the offer method taken from the BQueue algorithm (a variation on Fast * Flow), and adjusted to comply with Queue.offer semantics with regards to capacity.
* For convenience the relevant papers are available in the `resources` folder:
* * 2010 - Pisa - SPSC Queues on Shared Cache Multi-Core Systems.pdf
* 2012 - Junchang- BQueue- Efficient and Practical Queuing.pdf
*
* This implementation is wait free. */ public class SpscAtomicUnpaddedArrayQueue extends SpscAtomicUnpaddedArrayQueueL3Pad { public SpscAtomicUnpaddedArrayQueue(final int capacity) { super(Math.max(capacity, 4)); } /** * {@inheritDoc} *

* This implementation is correct for single producer thread use only. */ @Override public boolean offer(final E e) { if (null == e) { throw new NullPointerException(); } // local load of field to avoid repeated loads after volatile reads final AtomicReferenceArray buffer = this.buffer; final int mask = this.mask; final long producerIndex = this.lpProducerIndex(); if (producerIndex >= producerLimit && !offerSlowPath(buffer, mask, producerIndex)) { return false; } final int offset = calcCircularRefElementOffset(producerIndex, mask); soRefElement(buffer, offset, e); // ordered store -> atomic and ordered for size() soProducerIndex(producerIndex + 1); return true; } private boolean offerSlowPath(final AtomicReferenceArray buffer, final int mask, final long producerIndex) { final int lookAheadStep = this.lookAheadStep; if (null == lvRefElement(buffer, calcCircularRefElementOffset(producerIndex + lookAheadStep, mask))) { producerLimit = producerIndex + lookAheadStep; } else { final int offset = calcCircularRefElementOffset(producerIndex, mask); if (null != lvRefElement(buffer, offset)) { return false; } } return true; } /** * {@inheritDoc} *

* This implementation is correct for single consumer thread use only. */ @Override public E poll() { final long consumerIndex = this.lpConsumerIndex(); final int offset = calcCircularRefElementOffset(consumerIndex, mask); // local load of field to avoid repeated loads after volatile reads final AtomicReferenceArray buffer = this.buffer; final E e = lvRefElement(buffer, offset); if (null == e) { return null; } soRefElement(buffer, offset, null); // ordered store -> atomic and ordered for size() soConsumerIndex(consumerIndex + 1); return e; } /** * {@inheritDoc} *

* This implementation is correct for single consumer thread use only. */ @Override public E peek() { return lvRefElement(buffer, calcCircularRefElementOffset(lpConsumerIndex(), mask)); } @Override public boolean relaxedOffer(final E message) { return offer(message); } @Override public E relaxedPoll() { return poll(); } @Override public E relaxedPeek() { return peek(); } @Override public int drain(final Consumer c) { return drain(c, capacity()); } @Override public int fill(final Supplier s) { return fill(s, capacity()); } @Override public int drain(final Consumer c, final int limit) { if (null == c) throw new IllegalArgumentException("c is null"); if (limit < 0) throw new IllegalArgumentException("limit is negative: " + limit); if (limit == 0) return 0; final AtomicReferenceArray buffer = this.buffer; final int mask = this.mask; final long consumerIndex = this.lpConsumerIndex(); for (int i = 0; i < limit; i++) { final long index = consumerIndex + i; final int offset = calcCircularRefElementOffset(index, mask); final E e = lvRefElement(buffer, offset); if (null == e) { return i; } soRefElement(buffer, offset, null); // ordered store -> atomic and ordered for size() soConsumerIndex(index + 1); c.accept(e); } return limit; } @Override public int fill(final Supplier s, final 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; final AtomicReferenceArray buffer = this.buffer; final int mask = this.mask; final int lookAheadStep = this.lookAheadStep; final long producerIndex = this.lpProducerIndex(); for (int i = 0; i < limit; i++) { final long index = producerIndex + i; final int lookAheadElementOffset = calcCircularRefElementOffset(index + lookAheadStep, mask); if (null == lvRefElement(buffer, lookAheadElementOffset)) { int lookAheadLimit = Math.min(lookAheadStep, limit - i); for (int j = 0; j < lookAheadLimit; j++) { final int offset = calcCircularRefElementOffset(index + j, mask); soRefElement(buffer, offset, s.get()); // ordered store -> atomic and ordered for size() soProducerIndex(index + j + 1); } i += lookAheadLimit - 1; } else { final int offset = calcCircularRefElementOffset(index, mask); if (null != lvRefElement(buffer, offset)) { return i; } soRefElement(buffer, offset, s.get()); // ordered store -> atomic and ordered for size() soProducerIndex(index + 1); } } return limit; } @Override public void drain(final Consumer c, final WaitStrategy w, final ExitCondition exit) { if (null == c) throw new IllegalArgumentException("c is null"); if (null == w) throw new IllegalArgumentException("wait is null"); if (null == exit) throw new IllegalArgumentException("exit condition is null"); final AtomicReferenceArray buffer = this.buffer; final int mask = this.mask; long consumerIndex = this.lpConsumerIndex(); int counter = 0; while (exit.keepRunning()) { for (int i = 0; i < 4096; i++) { final int offset = calcCircularRefElementOffset(consumerIndex, mask); final E e = lvRefElement(buffer, offset); if (null == e) { counter = w.idle(counter); continue; } consumerIndex++; counter = 0; soRefElement(buffer, offset, null); // ordered store -> atomic and ordered for size() soConsumerIndex(consumerIndex); c.accept(e); } } } @Override public void fill(final Supplier s, final WaitStrategy w, final ExitCondition e) { if (null == w) throw new IllegalArgumentException("waiter is null"); if (null == e) throw new IllegalArgumentException("exit condition is null"); if (null == s) throw new IllegalArgumentException("supplier is null"); final AtomicReferenceArray buffer = this.buffer; final int mask = this.mask; final int lookAheadStep = this.lookAheadStep; long producerIndex = this.lpProducerIndex(); int counter = 0; while (e.keepRunning()) { final int lookAheadElementOffset = calcCircularRefElementOffset(producerIndex + lookAheadStep, mask); if (null == lvRefElement(buffer, lookAheadElementOffset)) { for (int j = 0; j < lookAheadStep; j++) { final int offset = calcCircularRefElementOffset(producerIndex, mask); producerIndex++; soRefElement(buffer, offset, s.get()); // ordered store -> atomic and ordered for size() soProducerIndex(producerIndex); } } else { final int offset = calcCircularRefElementOffset(producerIndex, mask); if (null != lvRefElement(buffer, offset)) { counter = w.idle(counter); continue; } producerIndex++; counter = 0; soRefElement(buffer, offset, s.get()); // ordered store -> atomic and ordered for size() soProducerIndex(producerIndex); } } } }





© 2015 - 2024 Weber Informatics LLC | Privacy Policy