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view src/org/eclipse/jetty/util/BlockingArrayQueue.java @ 851:08ac7e9e59e6
remove DebugHandler
author | Franklin Schmidt <fschmidt@gmail.com> |
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date | Mon, 19 Sep 2016 19:57:00 -0600 |
parents | 3428c60d7cfc |
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// // ======================================================================== // Copyright (c) 1995-2014 Mort Bay Consulting Pty. Ltd. // ------------------------------------------------------------------------ // All rights reserved. This program and the accompanying materials // are made available under the terms of the Eclipse Public License v1.0 // and Apache License v2.0 which accompanies this distribution. // // The Eclipse Public License is available at // http://www.eclipse.org/legal/epl-v10.html // // The Apache License v2.0 is available at // http://www.opensource.org/licenses/apache2.0.php // // You may elect to redistribute this code under either of these licenses. // ======================================================================== // package org.eclipse.jetty.util; import java.util.AbstractList; import java.util.Collection; import java.util.NoSuchElementException; import java.util.concurrent.BlockingQueue; import java.util.concurrent.TimeUnit; import java.util.concurrent.atomic.AtomicInteger; import java.util.concurrent.locks.Condition; import java.util.concurrent.locks.ReentrantLock; /* ------------------------------------------------------------ */ /** Queue backed by a circular array. * * This queue is uses a variant of the two lock queue algorithm to * provide an efficient queue or list backed by a growable circular * array. This queue also has a partial implementation of * {@link java.util.concurrent.BlockingQueue}, specifically the {@link #take()} and * {@link #poll(long, TimeUnit)} methods. * Unlike {@link java.util.concurrent.ArrayBlockingQueue}, this class is * able to grow and provides a blocking put call. * <p> * The queue has both a capacity (the size of the array currently allocated) * and a limit (the maximum size that may be allocated), which defaults to * {@link Integer#MAX_VALUE}. * * @param <E> The element type */ public class BlockingArrayQueue<E> extends AbstractList<E> implements BlockingQueue<E> { public final int DEFAULT_CAPACITY=128; public final int DEFAULT_GROWTH=64; private final int _limit; private final AtomicInteger _size=new AtomicInteger(); private final int _growCapacity; private volatile int _capacity; private Object[] _elements; private final ReentrantLock _headLock = new ReentrantLock(); private final Condition _notEmpty = _headLock.newCondition(); private int _head; // spacers created to prevent false sharing between head and tail http://en.wikipedia.org/wiki/False_sharing // TODO verify this has benefits private long _space0; private long _space1; private long _space2; private long _space3; private long _space4; private long _space5; private long _space6; private long _space7; private final ReentrantLock _tailLock = new ReentrantLock(); private int _tail; /* ------------------------------------------------------------ */ /** Create a growing partially blocking Queue * */ public BlockingArrayQueue() { _elements=new Object[DEFAULT_CAPACITY]; _growCapacity=DEFAULT_GROWTH; _capacity=_elements.length; _limit=Integer.MAX_VALUE; } /* ------------------------------------------------------------ */ /** Create a fixed size partially blocking Queue * @param limit The initial capacity and the limit. */ public BlockingArrayQueue(int limit) { _elements=new Object[limit]; _capacity=_elements.length; _growCapacity=-1; _limit=limit; } /* ------------------------------------------------------------ */ /** Create a growing partially blocking Queue. * @param capacity Initial capacity * @param growBy Incremental capacity. */ public BlockingArrayQueue(int capacity,int growBy) { _elements=new Object[capacity]; _capacity=_elements.length; _growCapacity=growBy; _limit=Integer.MAX_VALUE; } /* ------------------------------------------------------------ */ /** Create a growing limited partially blocking Queue. * @param capacity Initial capacity * @param growBy Incremental capacity. * @param limit maximum capacity. */ public BlockingArrayQueue(int capacity,int growBy,int limit) { if (capacity>limit) throw new IllegalArgumentException(); _elements=new Object[capacity]; _capacity=_elements.length; _growCapacity=growBy; _limit=limit; } /* ------------------------------------------------------------ */ public int getCapacity() { return _capacity; } /* ------------------------------------------------------------ */ public int getLimit() { return _limit; } /* ------------------------------------------------------------ */ @Override public boolean add(E e) { return offer(e); } /* ------------------------------------------------------------ */ public E element() { E e = peek(); if (e==null) throw new NoSuchElementException(); return e; } /* ------------------------------------------------------------ */ @SuppressWarnings("unchecked") public E peek() { if (_size.get() == 0) return null; E e = null; _headLock.lock(); // Size cannot shrink try { if (_size.get() > 0) e = (E)_elements[_head]; } finally { _headLock.unlock(); } return e; } /* ------------------------------------------------------------ */ public boolean offer(E e) { if (e == null) throw new NullPointerException(); boolean not_empty=false; _tailLock.lock(); // size cannot grow... only shrink try { if (_size.get() >= _limit) return false; // should we expand array? if (_size.get()==_capacity) { _headLock.lock(); // Need to grow array try { if (!grow()) return false; } finally { _headLock.unlock(); } } // add the element _elements[_tail]=e; _tail=(_tail+1)%_capacity; not_empty=0==_size.getAndIncrement(); } finally { _tailLock.unlock(); } if (not_empty) { _headLock.lock(); try { _notEmpty.signal(); } finally { _headLock.unlock(); } } return true; } /* ------------------------------------------------------------ */ @SuppressWarnings("unchecked") public E poll() { if (_size.get() == 0) return null; E e = null; _headLock.lock(); // Size cannot shrink try { if (_size.get() > 0) { final int head=_head; e = (E)_elements[head]; _elements[head]=null; _head=(head+1)%_capacity; if (_size.decrementAndGet()>0) _notEmpty.signal(); } } finally { _headLock.unlock(); } return e; } /* ------------------------------------------------------------ */ /** * Retrieves and removes the head of this queue, waiting * if no elements are present on this queue. * @return the head of this queue * @throws InterruptedException if interrupted while waiting. */ @SuppressWarnings("unchecked") public E take() throws InterruptedException { E e = null; _headLock.lockInterruptibly(); // Size cannot shrink try { try { while (_size.get() == 0) { _notEmpty.await(); } } catch (InterruptedException ie) { _notEmpty.signal(); throw ie; } final int head=_head; e = (E)_elements[head]; _elements[head]=null; _head=(head+1)%_capacity; if (_size.decrementAndGet()>0) _notEmpty.signal(); } finally { _headLock.unlock(); } return e; } /* ------------------------------------------------------------ */ /** * Retrieves and removes the head of this queue, waiting * if necessary up to the specified wait time if no elements are * present on this queue. * @param time how long to wait before giving up, in units of * <tt>unit</tt> * @param unit a <tt>TimeUnit</tt> determining how to interpret the * <tt>timeout</tt> parameter * @return the head of this queue, or <tt>null</tt> if the * specified waiting time elapses before an element is present. * @throws InterruptedException if interrupted while waiting. */ @SuppressWarnings("unchecked") public E poll(long time, TimeUnit unit) throws InterruptedException { E e = null; long nanos = unit.toNanos(time); _headLock.lockInterruptibly(); // Size cannot shrink try { try { while (_size.get() == 0) { if (nanos<=0) return null; nanos = _notEmpty.awaitNanos(nanos); } } catch (InterruptedException ie) { _notEmpty.signal(); throw ie; } e = (E)_elements[_head]; _elements[_head]=null; _head=(_head+1)%_capacity; if (_size.decrementAndGet()>0) _notEmpty.signal(); } finally { _headLock.unlock(); } return e; } /* ------------------------------------------------------------ */ public E remove() { E e=poll(); if (e==null) throw new NoSuchElementException(); return e; } /* ------------------------------------------------------------ */ @Override public void clear() { _tailLock.lock(); try { _headLock.lock(); try { _head=0; _tail=0; _size.set(0); } finally { _headLock.unlock(); } } finally { _tailLock.unlock(); } } /* ------------------------------------------------------------ */ @Override public boolean isEmpty() { return _size.get()==0; } /* ------------------------------------------------------------ */ @Override public int size() { return _size.get(); } /* ------------------------------------------------------------ */ @SuppressWarnings("unchecked") @Override public E get(int index) { _tailLock.lock(); try { _headLock.lock(); try { if (index<0 || index>=_size.get()) throw new IndexOutOfBoundsException("!("+0+"<"+index+"<="+_size+")"); int i = _head+index; if (i>=_capacity) i-=_capacity; return (E)_elements[i]; } finally { _headLock.unlock(); } } finally { _tailLock.unlock(); } } /* ------------------------------------------------------------ */ @Override public E remove(int index) { _tailLock.lock(); try { _headLock.lock(); try { if (index<0 || index>=_size.get()) throw new IndexOutOfBoundsException("!("+0+"<"+index+"<="+_size+")"); int i = _head+index; if (i>=_capacity) i-=_capacity; @SuppressWarnings("unchecked") E old=(E)_elements[i]; if (i<_tail) { System.arraycopy(_elements,i+1,_elements,i,_tail-i); _tail--; _size.decrementAndGet(); } else { System.arraycopy(_elements,i+1,_elements,i,_capacity-i-1); if (_tail>0) { _elements[_capacity]=_elements[0]; System.arraycopy(_elements,1,_elements,0,_tail-1); _tail--; } else _tail=_capacity-1; _size.decrementAndGet(); } return old; } finally { _headLock.unlock(); } } finally { _tailLock.unlock(); } } /* ------------------------------------------------------------ */ @Override public E set(int index, E e) { if (e == null) throw new NullPointerException(); _tailLock.lock(); try { _headLock.lock(); try { if (index<0 || index>=_size.get()) throw new IndexOutOfBoundsException("!("+0+"<"+index+"<="+_size+")"); int i = _head+index; if (i>=_capacity) i-=_capacity; @SuppressWarnings("unchecked") E old=(E)_elements[i]; _elements[i]=e; return old; } finally { _headLock.unlock(); } } finally { _tailLock.unlock(); } } /* ------------------------------------------------------------ */ @Override public void add(int index, E e) { if (e == null) throw new NullPointerException(); _tailLock.lock(); try { _headLock.lock(); try { if (index<0 || index>_size.get()) throw new IndexOutOfBoundsException("!("+0+"<"+index+"<="+_size+")"); if (index==_size.get()) { add(e); } else { if (_tail==_head) if (!grow()) throw new IllegalStateException("full"); int i = _head+index; if (i>=_capacity) i-=_capacity; _size.incrementAndGet(); _tail=(_tail+1)%_capacity; if (i<_tail) { System.arraycopy(_elements,i,_elements,i+1,_tail-i); _elements[i]=e; } else { if (_tail>0) { System.arraycopy(_elements,0,_elements,1,_tail); _elements[0]=_elements[_capacity-1]; } System.arraycopy(_elements,i,_elements,i+1,_capacity-i-1); _elements[i]=e; } } } finally { _headLock.unlock(); } } finally { _tailLock.unlock(); } } /* ------------------------------------------------------------ */ private boolean grow() { if (_growCapacity<=0) return false; _tailLock.lock(); try { _headLock.lock(); try { final int head=_head; final int tail=_tail; final int new_tail; Object[] elements=new Object[_capacity+_growCapacity]; if (head<tail) { new_tail=tail-head; System.arraycopy(_elements,head,elements,0,new_tail); } else if (head>tail || _size.get()>0) { new_tail=_capacity+tail-head; int cut=_capacity-head; System.arraycopy(_elements,head,elements,0,cut); System.arraycopy(_elements,0,elements,cut,tail); } else { new_tail=0; } _elements=elements; _capacity=_elements.length; _head=0; _tail=new_tail; return true; } finally { _headLock.unlock(); } } finally { _tailLock.unlock(); } } /* ------------------------------------------------------------ */ public int drainTo(Collection<? super E> c) { throw new UnsupportedOperationException(); } /* ------------------------------------------------------------ */ public int drainTo(Collection<? super E> c, int maxElements) { throw new UnsupportedOperationException(); } /* ------------------------------------------------------------ */ public boolean offer(E o, long timeout, TimeUnit unit) throws InterruptedException { throw new UnsupportedOperationException(); } /* ------------------------------------------------------------ */ public void put(E o) throws InterruptedException { if (!add(o)) throw new IllegalStateException("full"); } /* ------------------------------------------------------------ */ public int remainingCapacity() { _tailLock.lock(); try { _headLock.lock(); try { return getCapacity()-size(); } finally { _headLock.unlock(); } } finally { _tailLock.unlock(); } } /* ------------------------------------------------------------ */ long sumOfSpace() { // this method exists to stop clever optimisers removing the spacers return _space0++ +_space1++ +_space2++ +_space3++ +_space4++ +_space5++ +_space6++ +_space7++; } }