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1065 lines
46 KiB
1065 lines
46 KiB
// kelondroRowCollection.java
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// (C) 2006 by Michael Peter Christen; mc@yacy.net, Frankfurt a. M., Germany
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// first published 12.01.2006 on http://www.anomic.de
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//
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// $LastChangedDate: 2006-04-02 22:40:07 +0200 (So, 02 Apr 2006) $
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// $LastChangedRevision: 1986 $
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// $LastChangedBy: orbiter $
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//
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// LICENSE
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//
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// This program is free software; you can redistribute it and/or modify
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// it under the terms of the GNU General Public License as published by
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// the Free Software Foundation; either version 2 of the License, or
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// (at your option) any later version.
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//
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// This program is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU General Public License for more details.
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//
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// You should have received a copy of the GNU General Public License
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// along with this program; if not, write to the Free Software
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// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
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package de.anomic.kelondro.index;
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import java.io.File;
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import java.io.IOException;
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import java.util.ArrayList;
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import java.util.Iterator;
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import java.util.List;
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import java.util.Random;
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import java.util.Set;
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import java.util.concurrent.Callable;
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import java.util.concurrent.ExecutionException;
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import java.util.concurrent.ExecutorService;
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import java.util.concurrent.Executors;
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import java.util.concurrent.Future;
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import de.anomic.kelondro.order.Base64Order;
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import de.anomic.kelondro.order.ByteOrder;
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import de.anomic.kelondro.order.NaturalOrder;
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import de.anomic.kelondro.util.MemoryControl;
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import de.anomic.kelondro.util.NamePrefixThreadFactory;
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import de.anomic.kelondro.util.kelondroException;
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import de.anomic.kelondro.util.Log;
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import de.anomic.kelondro.util.FileUtils;
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import de.anomic.server.serverProcessor;
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public class RowCollection implements Iterable<Row.Entry> {
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public static final double growfactor = 1.4;
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private static final int isortlimit = 20;
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static final Integer dummy = 0;
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public static final ExecutorService sortingthreadexecutor = (serverProcessor.useCPU > 1) ? Executors.newCachedThreadPool(new NamePrefixThreadFactory("sorting")) : null;
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public static final ExecutorService partitionthreadexecutor = (serverProcessor.useCPU > 1) ? Executors.newCachedThreadPool(new NamePrefixThreadFactory("partition")) : null;
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protected byte[] chunkcache;
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protected int chunkcount;
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protected long lastTimeRead, lastTimeWrote;
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public Row rowdef;
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protected int sortBound;
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private static final int exp_chunkcount = 0;
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private static final int exp_last_read = 1;
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private static final int exp_last_wrote = 2;
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private static final int exp_order_type = 3;
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private static final int exp_order_bound = 4;
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private static final int exp_collection = 5;
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public RowCollection(final RowCollection rc) {
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this.rowdef = rc.rowdef;
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this.chunkcache = rc.chunkcache;
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this.chunkcount = rc.chunkcount;
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this.sortBound = rc.sortBound;
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this.lastTimeRead = rc.lastTimeRead;
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this.lastTimeWrote = rc.lastTimeWrote;
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}
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public RowCollection(final Row rowdef, final int objectCount) {
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this.rowdef = rowdef;
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this.chunkcache = new byte[objectCount * rowdef.objectsize];
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this.chunkcount = 0;
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this.sortBound = 0;
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this.lastTimeRead = System.currentTimeMillis();
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this.lastTimeWrote = System.currentTimeMillis();
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}
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public RowCollection(final Row rowdef, final int objectCount, final byte[] cache, final int sortBound) {
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this.rowdef = rowdef;
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this.chunkcache = cache;
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this.chunkcount = objectCount;
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this.sortBound = sortBound;
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this.lastTimeRead = System.currentTimeMillis();
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this.lastTimeWrote = System.currentTimeMillis();
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}
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public RowCollection(final Row rowdef, final Row.Entry exportedCollectionRowEnvironment) {
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final int chunkcachelength = exportedCollectionRowEnvironment.cellwidth(1) - exportOverheadSize;
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final Row.Entry exportedCollection = exportRow(chunkcachelength).newEntry(exportedCollectionRowEnvironment, 1);
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this.rowdef = rowdef;
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this.chunkcount = (int) exportedCollection.getColLong(exp_chunkcount);
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if ((this.chunkcount > chunkcachelength / rowdef.objectsize)) {
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Log.logWarning("RowCollection", "corrected wrong chunkcount; chunkcount = " + this.chunkcount + ", chunkcachelength = " + chunkcachelength + ", rowdef.objectsize = " + rowdef.objectsize);
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this.chunkcount = chunkcachelength / rowdef.objectsize; // patch problem
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}
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this.lastTimeRead = (exportedCollection.getColLong(exp_last_read) + 10957) * day;
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this.lastTimeWrote = (exportedCollection.getColLong(exp_last_wrote) + 10957) * day;
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final String sortOrderKey = exportedCollection.getColString(exp_order_type, null);
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ByteOrder oldOrder = null;
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if ((sortOrderKey == null) || (sortOrderKey.equals("__"))) {
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oldOrder = null;
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} else {
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oldOrder = NaturalOrder.bySignature(sortOrderKey);
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if (oldOrder == null) oldOrder = Base64Order.bySignature(sortOrderKey);
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}
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if ((rowdef.objectOrder != null) && (oldOrder != null) && (!(rowdef.objectOrder.signature().equals(oldOrder.signature()))))
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throw new kelondroException("old collection order does not match with new order; objectOrder.signature = " + rowdef.objectOrder.signature() + ", oldOrder.signature = " + oldOrder.signature());
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this.sortBound = (int) exportedCollection.getColLong(exp_order_bound);
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if (sortBound > chunkcount) {
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Log.logWarning("RowCollection", "corrected wrong sortBound; sortBound = " + sortBound + ", chunkcount = " + chunkcount);
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this.sortBound = chunkcount;
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}
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this.chunkcache = exportedCollection.getColBytes(exp_collection);
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}
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public void reset() {
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this.chunkcache = new byte[0];
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this.chunkcount = 0;
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this.sortBound = 0;
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}
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private static final Row exportMeasureRow = exportRow(0 /* no relevance */);
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public static final int sizeOfExportedCollectionRows(final Row.Entry exportedCollectionRowEnvironment, final int columnInEnvironment) {
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final Row.Entry exportedCollectionEntry = exportMeasureRow.newEntry(exportedCollectionRowEnvironment, columnInEnvironment);
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final int chunkcount = (int) exportedCollectionEntry.getColLong(exp_chunkcount);
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return chunkcount;
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}
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private static final long day = 1000 * 60 * 60 * 24;
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public static int daysSince2000(final long time) {
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return (int) (time / day) - 10957;
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}
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private static Row exportRow(final int chunkcachelength) {
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// find out the size of this collection
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return new Row(
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"int size-4 {b256}," +
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"short lastread-2 {b256}," + // as daysSince2000
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"short lastwrote-2 {b256}," + // as daysSince2000
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"byte[] orderkey-2," +
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"int orderbound-4 {b256}," +
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"byte[] collection-" + chunkcachelength,
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NaturalOrder.naturalOrder, 0
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);
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}
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public static final int exportOverheadSize = 14;
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public synchronized byte[] exportCollection() {
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// returns null if the collection is empty
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trim(false);
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assert this.size() * this.rowdef.objectsize == this.chunkcache.length : "this.size() = " + this.size() + ", objectsize = " + this.rowdef.objectsize + ", chunkcache.length = " + this.chunkcache.length;
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final Row row = exportRow(chunkcache.length);
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final Row.Entry entry = row.newEntry();
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assert (sortBound <= chunkcount) : "sortBound = " + sortBound + ", chunkcount = " + chunkcount;
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assert (this.chunkcount <= chunkcache.length / rowdef.objectsize) : "chunkcount = " + this.chunkcount + ", chunkcache.length = " + chunkcache.length + ", rowdef.objectsize = " + rowdef.objectsize;
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entry.setCol(exp_chunkcount, this.chunkcount);
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entry.setCol(exp_last_read, daysSince2000(this.lastTimeRead));
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entry.setCol(exp_last_wrote, daysSince2000(this.lastTimeWrote));
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entry.setCol(exp_order_type, (this.rowdef.objectOrder == null) ? "__".getBytes() :this.rowdef.objectOrder.signature().getBytes());
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entry.setCol(exp_order_bound, this.sortBound);
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entry.setCol(exp_collection, this.chunkcache);
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return entry.bytes();
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}
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public void saveCollection(final File file) throws IOException {
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FileUtils.copy(exportCollection(), file);
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}
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public Row row() {
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return this.rowdef;
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}
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protected final void ensureSize(final int elements) {
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final int needed = elements * rowdef.objectsize;
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if (chunkcache.length >= needed) return;
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byte[] newChunkcache = new byte[(int) (needed * growfactor)]; // increase space
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System.arraycopy(chunkcache, 0, newChunkcache, 0, chunkcache.length);
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chunkcache = newChunkcache;
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}
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/**
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* compute the needed memory in case of a cache extension. That is, if the cache is full and must
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* be copied into a new cache which is larger. In such a case the Collection needs more than the double size
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* than is necessary to store the data. This method coputes the extra memory that is needed to perform this task.
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* @return
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*/
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public final long memoryNeededForGrow() {
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return (long) ((((long) (chunkcount + 1)) * ((long) rowdef.objectsize)) * growfactor);
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}
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public synchronized void trim(final boolean plusGrowFactor) {
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if (chunkcache.length == 0) return;
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int needed = chunkcount * rowdef.objectsize;
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if (plusGrowFactor) needed = (int) (needed * growfactor);
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if (needed >= chunkcache.length)
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return; // in case that the growfactor causes that the cache would
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// grow instead of shrink, simply ignore the growfactor
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if (MemoryControl.available() + 1000 < needed)
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return; // if the swap buffer is not available, we must give up.
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// This is not critical. Otherwise we provoke a serious
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// problem with OOM
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byte[] newChunkcache = new byte[needed];
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System.arraycopy(chunkcache, 0, newChunkcache, 0, Math.min(
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chunkcache.length, newChunkcache.length));
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chunkcache = newChunkcache;
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}
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public final long lastRead() {
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return lastTimeRead;
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}
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public final long lastWrote() {
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return lastTimeWrote;
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}
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public synchronized final byte[] getKey(final int index) {
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assert (index >= 0) : "get: access with index " + index + " is below zero";
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assert (index < chunkcount) : "get: access with index " + index + " is above chunkcount " + chunkcount + "; sortBound = " + sortBound;
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assert (index * rowdef.objectsize < chunkcache.length);
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if ((chunkcache == null) || (rowdef == null)) return null; // case may appear during shutdown
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if (index >= chunkcount) return null;
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if ((index + 1) * rowdef.objectsize > chunkcache.length) return null; // the whole chunk does not fit into the chunkcache
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this.lastTimeRead = System.currentTimeMillis();
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final byte[] b = new byte[this.rowdef.width(0)];
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System.arraycopy(chunkcache, index * rowdef.objectsize, b, 0, b.length);
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return b;
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}
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public synchronized final Row.Entry get(final int index, final boolean clone) {
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assert (index >= 0) : "get: access with index " + index + " is below zero";
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assert (index < chunkcount) : "get: access with index " + index + " is above chunkcount " + chunkcount + "; sortBound = " + sortBound;
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assert (chunkcache != null && index * rowdef.objectsize < chunkcache.length);
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assert sortBound <= chunkcount : "sortBound = " + sortBound + ", chunkcount = " + chunkcount;
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if ((chunkcache == null) || (rowdef == null)) return null; // case may appear during shutdown
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Row.Entry entry;
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final int addr = index * rowdef.objectsize;
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synchronized (this) {
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if (index >= chunkcount) return null;
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if (addr + rowdef.objectsize > chunkcache.length) return null; // the whole chunk does not fit into the chunkcache
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entry = rowdef.newEntry(chunkcache, addr, clone);
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}
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this.lastTimeRead = System.currentTimeMillis();
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return entry;
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}
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public synchronized final void set(final int index, final Row.Entry a) {
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assert (index >= 0) : "set: access with index " + index + " is below zero";
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ensureSize(index + 1);
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boolean sameKey = match(a.bytes(), 0, a.cellwidth(0), index);
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//if (sameKey) System.out.print("$");
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a.writeToArray(chunkcache, index * rowdef.objectsize);
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if (index >= this.chunkcount) this.chunkcount = index + 1;
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if (!sameKey && index < this.sortBound) this.sortBound = index;
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this.lastTimeWrote = System.currentTimeMillis();
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}
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public final void insertUnique(final int index, final Row.Entry a) {
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assert (a != null);
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if (index < chunkcount) {
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// make room
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ensureSize(chunkcount + 1);
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System.arraycopy(chunkcache, rowdef.objectsize * index, chunkcache, rowdef.objectsize * (index + 1), (chunkcount - index) * rowdef.objectsize);
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chunkcount++;
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}
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// insert entry into gap
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set(index, a);
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}
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public synchronized void addUnique(final Row.Entry row) {
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final byte[] r = row.bytes();
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addUnique(r, 0, r.length);
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}
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public synchronized void addUniqueMultiple(final List<Row.Entry> rows) {
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assert this.sortBound == 0 : "sortBound = " + this.sortBound + ", chunkcount = " + this.chunkcount;
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final Iterator<Row.Entry> i = rows.iterator();
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while (i.hasNext()) addUnique(i.next());
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}
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public synchronized void add(final byte[] a) {
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assert a.length == this.rowdef.objectsize;
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addUnique(a, 0, a.length);
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}
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private final void addUnique(final byte[] a, final int astart, final int alength) {
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assert (a != null);
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assert (astart >= 0) && (astart < a.length) : " astart = " + astart;
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assert (!(Log.allZero(a, astart, alength))) : "a = " + NaturalOrder.arrayList(a, astart, alength);
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assert (alength > 0);
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assert (astart + alength <= a.length);
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assert alength == rowdef.objectsize : "alength =" + alength + ", rowdef.objectsize = " + rowdef.objectsize;
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final int l = Math.min(rowdef.objectsize, Math.min(alength, a.length - astart));
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ensureSize(chunkcount + 1);
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System.arraycopy(a, astart, chunkcache, rowdef.objectsize * chunkcount, l);
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chunkcount++;
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// if possible, increase the sortbound value to suppress unnecessary sorting
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if (this.chunkcount == 1) {
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assert this.sortBound == 0;
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this.sortBound = 1;
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} else if (
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this.sortBound + 1 == chunkcount &&
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this.rowdef.objectOrder.compare(chunkcache, rowdef.objectsize * (chunkcount - 2), rowdef.primaryKeyLength,
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chunkcache, rowdef.objectsize * (chunkcount - 1), rowdef.primaryKeyLength) == -1) {
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this.sortBound = chunkcount;
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}
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this.lastTimeWrote = System.currentTimeMillis();
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}
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protected final void addSorted(final byte[] a, final int astart, final int alength) {
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assert (a != null);
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assert (astart >= 0) && (astart < a.length) : " astart = " + astart;
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assert (!(Log.allZero(a, astart, alength))) : "a = " + NaturalOrder.arrayList(a, astart, alength);
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assert (alength > 0);
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assert (astart + alength <= a.length);
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assert alength == rowdef.objectsize : "alength =" + alength + ", rowdef.objectsize = " + rowdef.objectsize;
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final int l = Math.min(rowdef.objectsize, Math.min(alength, a.length - astart));
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ensureSize(chunkcount + 1);
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System.arraycopy(a, astart, chunkcache, rowdef.objectsize * chunkcount, l);
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this.chunkcount++;
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this.sortBound = this.chunkcount;
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this.lastTimeWrote = System.currentTimeMillis();
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}
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public synchronized final void addAllUnique(final RowCollection c) {
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if (c == null) return;
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assert(rowdef.objectsize == c.rowdef.objectsize);
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ensureSize(chunkcount + c.size());
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System.arraycopy(c.chunkcache, 0, chunkcache, rowdef.objectsize * chunkcount, rowdef.objectsize * c.size());
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chunkcount += c.size();
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}
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/**
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* This method removes the entry at position p ensuring the order of the remaining
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* entries if specified by keepOrder.
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* Note: Keeping the order is expensive. If you want to remove more than one element in
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* a batch with this method, it'd be better to do the removes without order keeping and doing
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* the sort after all the removes are done.
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*
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* @param p element at this position will be removed
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* @param keepOrder keep the order of remaining entries
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*/
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public synchronized final void removeRow(final int p, final boolean keepOrder) {
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assert p >= 0 : "p = " + p;
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assert p < chunkcount : "p = " + p + ", chunkcount = " + chunkcount;
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assert chunkcount > 0 : "chunkcount = " + chunkcount;
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assert sortBound <= chunkcount : "sortBound = " + sortBound + ", chunkcount = " + chunkcount;
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if (keepOrder && (p < sortBound)) {
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// remove by shift (quite expensive for big collections)
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final int addr = p * this.rowdef.objectsize;
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System.arraycopy(
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chunkcache, addr + this.rowdef.objectsize,
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chunkcache, addr,
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(chunkcount - p - 1) * this.rowdef.objectsize);
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sortBound--; // this is only correct if p < sortBound, but this was already checked above
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} else {
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// remove by copying the top-element to the remove position
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if (p != chunkcount - 1) {
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System.arraycopy(
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chunkcache, (chunkcount - 1) * this.rowdef.objectsize,
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chunkcache, p * this.rowdef.objectsize,
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this.rowdef.objectsize);
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}
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// we moved the last element to the remove position: (p+1)st element
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// only the first p elements keep their order (element p is already outside the order)
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if (sortBound > p) sortBound = p;
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}
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chunkcount--;
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this.lastTimeWrote = System.currentTimeMillis();
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}
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/**
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* removes the last entry from the collection
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* @return
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*/
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public synchronized Row.Entry removeOne() {
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if (chunkcount == 0) return null;
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final Row.Entry r = get(chunkcount - 1, true);
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if (chunkcount == sortBound) sortBound--;
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chunkcount--;
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this.lastTimeWrote = System.currentTimeMillis();
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return r;
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}
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public synchronized void clear() {
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if (this.chunkcache.length == 0) return;
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this.chunkcache = new byte[0];
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this.chunkcount = 0;
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this.sortBound = 0;
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this.lastTimeWrote = System.currentTimeMillis();
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}
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public int size() {
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return this.chunkcount;
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}
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public int sorted() {
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return this.sortBound;
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}
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public synchronized Iterator<byte[]> keys(boolean keepOrderWhenRemoving) {
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// iterates byte[] - type entries
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return new keyIterator(keepOrderWhenRemoving);
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}
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/**
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* Iterator for kelondroRowCollection.
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* It supports remove() though it doesn't contain the order of the underlying
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* collection during removes.
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*
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*/
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public class keyIterator implements Iterator<byte[]> {
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private int p;
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private boolean keepOrderWhenRemoving;
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public keyIterator(boolean keepOrderWhenRemoving) {
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this.p = 0;
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this.keepOrderWhenRemoving = keepOrderWhenRemoving;
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}
|
|
|
|
public boolean hasNext() {
|
|
return p < chunkcount;
|
|
}
|
|
|
|
public byte[] next() {
|
|
return getKey(p++);
|
|
}
|
|
|
|
public void remove() {
|
|
p--;
|
|
removeRow(p, keepOrderWhenRemoving);
|
|
}
|
|
}
|
|
|
|
/**
|
|
* return an iterator for the row entries in this object
|
|
*/
|
|
public Iterator<Row.Entry> iterator() {
|
|
// iterates kelondroRow.Entry - type entries
|
|
return new rowIterator();
|
|
}
|
|
|
|
/**
|
|
* Iterator for kelondroRowCollection.
|
|
* It supports remove() and keeps the order of the underlying
|
|
* collection during removes.
|
|
*/
|
|
public class rowIterator implements Iterator<Row.Entry> {
|
|
|
|
private int p;
|
|
|
|
public rowIterator() {
|
|
p = 0;
|
|
}
|
|
|
|
public boolean hasNext() {
|
|
return p < chunkcount;
|
|
}
|
|
|
|
public Row.Entry next() {
|
|
return get(p++, true);
|
|
}
|
|
|
|
public void remove() {
|
|
p--;
|
|
removeRow(p, true);
|
|
}
|
|
|
|
}
|
|
|
|
public synchronized void select(final Set<String> keys) {
|
|
// removes all entries but the ones given by urlselection
|
|
if ((keys == null) || (keys.isEmpty())) return;
|
|
final Iterator<Row.Entry> i = iterator();
|
|
Row.Entry row;
|
|
while (i.hasNext()) {
|
|
row = i.next();
|
|
if (!(keys.contains(row.getColString(0, null)))) i.remove();
|
|
}
|
|
}
|
|
|
|
public synchronized final void sort() {
|
|
assert (this.rowdef.objectOrder != null);
|
|
if (this.sortBound == this.chunkcount) return; // this is already sorted
|
|
if (this.chunkcount < isortlimit) {
|
|
isort(0, this.chunkcount, new byte[this.rowdef.objectsize]);
|
|
this.sortBound = this.chunkcount;
|
|
assert this.isSorted();
|
|
return;
|
|
}
|
|
final byte[] swapspace = new byte[this.rowdef.objectsize];
|
|
final int p = partition(0, this.chunkcount, this.sortBound, swapspace);
|
|
if ((sortingthreadexecutor != null) &&
|
|
(!sortingthreadexecutor.isShutdown()) &&
|
|
(serverProcessor.useCPU > 1) &&
|
|
(this.chunkcount > 8000)) {
|
|
// sort this using multi-threading
|
|
final Future<Integer> part0 = partitionthreadexecutor.submit(new partitionthread(this, 0, p, 0));
|
|
final Future<Integer> part1 = partitionthreadexecutor.submit(new partitionthread(this, p, this.chunkcount, p));
|
|
try {
|
|
final int p0 = part0.get().intValue();
|
|
final Future<Object> sort0 = sortingthreadexecutor.submit(new qsortthread(this, 0, p0, 0));
|
|
final Future<Object> sort1 = sortingthreadexecutor.submit(new qsortthread(this, p0, p, p0));
|
|
final int p1 = part1.get().intValue();
|
|
final Future<Object> sort2 = sortingthreadexecutor.submit(new qsortthread(this, p, p1, p));
|
|
final Future<Object> sort3 = sortingthreadexecutor.submit(new qsortthread(this, p1, this.chunkcount, p1));
|
|
sort0.get();
|
|
sort1.get();
|
|
sort2.get();
|
|
sort3.get();
|
|
} catch (final InterruptedException e) {
|
|
e.printStackTrace();
|
|
} catch (final ExecutionException e) {
|
|
e.printStackTrace();
|
|
}
|
|
} else {
|
|
qsort(0, p, 0, swapspace);
|
|
qsort(p + 1, this.chunkcount, 0, swapspace);
|
|
}
|
|
this.sortBound = this.chunkcount;
|
|
//assert this.isSorted();
|
|
}
|
|
|
|
public synchronized final void sort2() {
|
|
assert (this.rowdef.objectOrder != null);
|
|
if (this.sortBound == this.chunkcount) return; // this is already sorted
|
|
if (this.chunkcount < isortlimit) {
|
|
isort(0, this.chunkcount, new byte[this.rowdef.objectsize]);
|
|
this.sortBound = this.chunkcount;
|
|
assert this.isSorted();
|
|
return;
|
|
}
|
|
final byte[] swapspace = new byte[this.rowdef.objectsize];
|
|
final int p = partition(0, this.chunkcount, this.sortBound, swapspace);
|
|
if ((sortingthreadexecutor != null) &&
|
|
(!sortingthreadexecutor.isShutdown()) &&
|
|
(serverProcessor.useCPU > 1) &&
|
|
(this.chunkcount > 4000)) {
|
|
// sort this using multi-threading
|
|
final Future<Object> part = sortingthreadexecutor.submit(new qsortthread(this, 0, p, 0));
|
|
//CompletionService<Object> sortingthreadcompletion = new ExecutorCompletionService<Object>(sortingthreadexecutor);
|
|
//Future<Object> part = sortingthreadcompletion.submit(new qsortthread(this, 0, p, 0));
|
|
qsort(p + 1, this.chunkcount, 0, swapspace);
|
|
try {
|
|
part.get();
|
|
} catch (final InterruptedException e) {
|
|
e.printStackTrace();
|
|
} catch (final ExecutionException e) {
|
|
e.printStackTrace();
|
|
}
|
|
} else {
|
|
qsort(0, p, 0, swapspace);
|
|
qsort(p + 1, this.chunkcount, 0, swapspace);
|
|
}
|
|
this.sortBound = this.chunkcount;
|
|
//assert this.isSorted();
|
|
}
|
|
|
|
public static class qsortthread implements Callable<Object> {
|
|
RowCollection rc;
|
|
int L, R, S;
|
|
|
|
public qsortthread(final RowCollection rc, final int L, final int R, final int S) {
|
|
this.rc = rc;
|
|
this.L = L;
|
|
this.R = R;
|
|
this.S = S;
|
|
}
|
|
|
|
public Object call() throws Exception {
|
|
rc.qsort(L, R, S, new byte[rc.rowdef.objectsize]);
|
|
return null;
|
|
}
|
|
}
|
|
|
|
final void qsort(final int L, final int R, final int S, final byte[] swapspace) {
|
|
if (R - L < isortlimit) {
|
|
isort(L, R, swapspace);
|
|
return;
|
|
}
|
|
assert R > L: "L = " + L + ", R = " + R + ", S = " + S;
|
|
final int p = partition(L, R, S, swapspace);
|
|
assert p >= L: "L = " + L + ", R = " + R + ", S = " + S + ", p = " + p;
|
|
assert p < R: "L = " + L + ", R = " + R + ", S = " + S + ", p = " + p;
|
|
qsort(L, p, 0, swapspace);
|
|
qsort(p + 1, R, 0, swapspace);
|
|
}
|
|
|
|
public static class partitionthread implements Callable<Integer> {
|
|
RowCollection rc;
|
|
int L, R, S;
|
|
|
|
public partitionthread(final RowCollection rc, final int L, final int R, final int S) {
|
|
this.rc = rc;
|
|
this.L = L;
|
|
this.R = R;
|
|
this.S = S;
|
|
}
|
|
|
|
public Integer call() throws Exception {
|
|
return Integer.valueOf(rc.partition(L, R, S, new byte[rc.rowdef.objectsize]));
|
|
}
|
|
}
|
|
|
|
/**
|
|
* @param L is the first element in the sequence
|
|
* @param R is the right bound of the sequence, and outside of the sequence
|
|
* @param S is the bound of the sorted elements in the sequence
|
|
* @param swapspace
|
|
* @return
|
|
*/
|
|
final int partition(final int L, final int R, int S, final byte[] swapspace) {
|
|
assert (L < R - 1): "L = " + L + ", R = " + R + ", S = " + S;
|
|
assert (R - L >= isortlimit): "L = " + L + ", R = " + R + ", S = " + S;
|
|
|
|
int p = L;
|
|
int q = R - 1;
|
|
int pivot = pivot(L, R, S, swapspace);
|
|
int oldpivot = -1;
|
|
byte[] compiledPivot = null;
|
|
if (this.rowdef.objectOrder instanceof Base64Order) {
|
|
while (p <= q) {
|
|
// wenn pivot < S: pivot befindet sich in sortierter Sequenz von L bis S - 1
|
|
// d.h. alle Werte von L bis pivot sind kleiner als das pivot
|
|
// zu finden ist ein minimales p <= q so dass chunk[p] >= pivot
|
|
if (compiledPivot == null) compiledPivot = compilePivot(pivot);
|
|
if ((pivot < S) && (p < pivot)) {
|
|
//System.out.println("+++ saved " + (pivot - p) + " comparisments");
|
|
p = pivot;
|
|
S = 0;
|
|
} else {
|
|
while ((p < R - 1) && (comparePivot(compiledPivot, p) >= 0)) p++; // chunkAt[p] < pivot
|
|
}
|
|
// nun gilt chunkAt[p] >= pivot
|
|
while ((q > L) && (comparePivot(compiledPivot, q) <= 0)) q--; // chunkAt[q] > pivot
|
|
if (p <= q) {
|
|
oldpivot = pivot;
|
|
pivot = swap(p, q, pivot, swapspace);
|
|
if (pivot != oldpivot && compiledPivot != null) compiledPivot = null; // must be computed again
|
|
p++;
|
|
q--;
|
|
}
|
|
}
|
|
} else {
|
|
while (p <= q) {
|
|
if ((pivot < S) && (p < pivot)) {
|
|
p = pivot;
|
|
S = 0;
|
|
} else {
|
|
while ((p < R - 1) && (compare(pivot, p) >= 0)) p++; // chunkAt[p] < pivot
|
|
}
|
|
while ((q > L) && (compare(pivot, q) <= 0)) q--; // chunkAt[q] > pivot
|
|
if (p <= q) {
|
|
pivot = swap(p, q, pivot, swapspace);
|
|
p++;
|
|
q--;
|
|
}
|
|
}
|
|
}
|
|
// now p is the beginning of the upper sequence
|
|
// finally, the pivot element should be exactly between the two sequences
|
|
// distinguish two cases: pivot in lower and upper sequence
|
|
// to do this it is sufficient to compare the index, not the entry content
|
|
if (pivot < p) {
|
|
// switch the pivot with the element _below_ p, the element in p belongs to the upper sequence
|
|
// and does not fit into the lower sequence
|
|
swap(pivot, p - 1, pivot, swapspace);
|
|
return p - 1;
|
|
} else if (pivot > p) {
|
|
// switch the pivot with p, they are both in the same sequence
|
|
swap(pivot, p, pivot, swapspace);
|
|
return p;
|
|
}
|
|
assert pivot == p;
|
|
return p;
|
|
}
|
|
|
|
private final int pivot(final int L, final int R, final int S, final byte[] swapspace) {
|
|
if ((S == 0) || (S < L)) {
|
|
// the collection has no ordering
|
|
// or
|
|
// the collection has an ordering, but this is not relevant for this pivot
|
|
// because the ordered zone is outside of ordering zone
|
|
final int m = picMiddle(new int[]{L, (3 * L + R - 1) / 4, (L + R - 1) / 2, (L + 3 * R - 3) / 4, R - 1}, 5);
|
|
assert L <= m;
|
|
assert m < R;
|
|
return m;
|
|
}
|
|
if (S < R) {
|
|
// the collection has an ordering
|
|
// and part of the ordered zone is inside the to-be-ordered zone
|
|
final int m = picMiddle(new int[]{L, L + (S - L) / 3, (L + R - 1) / 2, S, R - 1}, 5);
|
|
assert L <= m;
|
|
assert m < R;
|
|
return m;
|
|
}
|
|
// use the sorted set to find good pivot:
|
|
// the sort range is fully inside the sorted area:
|
|
// the middle element must be the best
|
|
// (however, it should be skipped because there is no point in sorting this)
|
|
return (L + R - 1) / 2;
|
|
}
|
|
|
|
private final int picMiddle(final int[] list, int len) {
|
|
assert len % 2 != 0;
|
|
assert len <= list.length;
|
|
final int cut = list.length / 2;
|
|
for (int i = 0; i < cut; i++) {remove(list, len, min(list, len)); len--;}
|
|
for (int i = 0; i < cut; i++) {remove(list, len, max(list, len)); len--;}
|
|
// the remaining element must be the middle element
|
|
assert len == 1;
|
|
return list[0];
|
|
}
|
|
|
|
private final void remove(final int[] list, final int len, final int idx) {
|
|
if (idx == len - 1) return;
|
|
list[idx] = list[len - 1]; // shift last element to front
|
|
}
|
|
|
|
private final int min(final int[] list, int len) {
|
|
assert len > 0;
|
|
int f = 0;
|
|
while (len-- > 0) {
|
|
if (compare(list[f], list[len]) > 0) f = len;
|
|
}
|
|
return f;
|
|
}
|
|
|
|
private final int max(final int[] list, int len) {
|
|
assert len > 0;
|
|
int f = 0;
|
|
while (len-- > 0) {
|
|
if (compare(list[f], list[len]) < 0) f = len;
|
|
}
|
|
return f;
|
|
}
|
|
|
|
private final void isort(final int L, final int R, final byte[] swapspace) {
|
|
for (int i = L + 1; i < R; i++)
|
|
for (int j = i; j > L && compare(j - 1, j) > 0; j--)
|
|
swap(j, j - 1, 0, swapspace);
|
|
}
|
|
|
|
private final int swap(final int i, final int j, final int p, final byte[] swapspace) {
|
|
if (i == j) return p;
|
|
System.arraycopy(chunkcache, this.rowdef.objectsize * i, swapspace, 0, this.rowdef.objectsize);
|
|
System.arraycopy(chunkcache, this.rowdef.objectsize * j, chunkcache, this.rowdef.objectsize * i, this.rowdef.objectsize);
|
|
System.arraycopy(swapspace, 0, chunkcache, this.rowdef.objectsize * j, this.rowdef.objectsize);
|
|
if (i == p) return j; else if (j == p) return i; else return p;
|
|
}
|
|
|
|
public synchronized void uniq() {
|
|
assert (this.rowdef.objectOrder != null);
|
|
// removes double-occurrences of chunks
|
|
// this works only if the collection was ordered with sort before
|
|
// if the collection is large and the number of deletions is also large,
|
|
// then this method may run a long time with 100% CPU load which is caused
|
|
// by the large number of memory movements.
|
|
if (chunkcount < 2) return;
|
|
int i = chunkcount - 2;
|
|
final long t = System.currentTimeMillis(); // for time-out
|
|
int d = 0;
|
|
boolean u = true;
|
|
try {
|
|
while (i >= 0) {
|
|
if (compare(i, i + 1) == 0) {
|
|
removeRow(i + 1, false);
|
|
d++;
|
|
if (i + 1 < chunkcount - 1) u = false;
|
|
}
|
|
i--;
|
|
if (System.currentTimeMillis() - t > 10000) {
|
|
throw new RuntimeException("uniq() time-out at " + i + " (backwards) from " + chunkcount + " elements after " + (System.currentTimeMillis() - t) + " milliseconds; " + d + " deletions so far");
|
|
}
|
|
}
|
|
} catch (final RuntimeException e) {
|
|
Log.logWarning("kelondroRowCollection", e.getMessage(), e);
|
|
} finally {
|
|
if (!u) this.sort();
|
|
}
|
|
}
|
|
|
|
public synchronized ArrayList<RowCollection> removeDoubles() {
|
|
assert (this.rowdef.objectOrder != null);
|
|
// removes double-occurrences of chunks
|
|
// in contrast to uniq() this removes also the remaining, non-double entry that had a double-occurrence to the others
|
|
// all removed chunks are returned in an array
|
|
this.sort();
|
|
final ArrayList<RowCollection> report = new ArrayList<RowCollection>();
|
|
if (chunkcount < 2) return report;
|
|
int i = chunkcount - 2;
|
|
int d = 0;
|
|
boolean u = true;
|
|
RowCollection collection = new RowCollection(this.rowdef, 2);
|
|
try {
|
|
while (i >= 0) {
|
|
if (compare(i, i + 1) == 0) {
|
|
collection.addUnique(get(i + 1, false));
|
|
removeRow(i + 1, false);
|
|
d++;
|
|
if (i + 1 < chunkcount - 1) u = false;
|
|
} else if (collection.size() > 0) {
|
|
// finish collection of double occurrences
|
|
collection.addUnique(get(i + 1, false));
|
|
removeRow(i + 1, false);
|
|
d++;
|
|
if (i + 1 < chunkcount - 1) u = false;
|
|
collection.trim(false);
|
|
report.add(collection);
|
|
collection = new RowSet(this.rowdef, 2);
|
|
}
|
|
i--;
|
|
}
|
|
} catch (final RuntimeException e) {
|
|
Log.logWarning("kelondroRowCollection", e.getMessage(), e);
|
|
} finally {
|
|
if (!u) this.sort();
|
|
}
|
|
return report;
|
|
}
|
|
|
|
public synchronized boolean isSorted() {
|
|
assert (this.rowdef.objectOrder != null);
|
|
if (chunkcount <= 1) return true;
|
|
if (chunkcount != this.sortBound) return false;
|
|
/*
|
|
for (int i = 0; i < chunkcount - 1; i++) {
|
|
//System.out.println("*" + new String(get(i).getColBytes(0)));
|
|
if (compare(i, i + 1) > 0) {
|
|
System.out.println("?" + new String(get(i + 1, false).getColBytes(0)));
|
|
return false;
|
|
}
|
|
}
|
|
*/
|
|
return true;
|
|
}
|
|
|
|
public synchronized String toString() {
|
|
final StringBuilder s = new StringBuilder();
|
|
final Iterator<Row.Entry> i = iterator();
|
|
if (i.hasNext()) s.append(i.next().toString());
|
|
while (i.hasNext()) s.append(", " + (i.next()).toString());
|
|
return new String(s);
|
|
}
|
|
|
|
private final int compare(final int i, final int j) {
|
|
assert (chunkcount * this.rowdef.objectsize <= chunkcache.length) : "chunkcount = " + chunkcount + ", objsize = " + this.rowdef.objectsize + ", chunkcache.length = " + chunkcache.length;
|
|
assert (i >= 0) && (i < chunkcount) : "i = " + i + ", chunkcount = " + chunkcount;
|
|
assert (j >= 0) && (j < chunkcount) : "j = " + j + ", chunkcount = " + chunkcount;
|
|
assert (this.rowdef.objectOrder != null);
|
|
if (i == j) return 0;
|
|
assert (this.rowdef.primaryKeyIndex == 0) : "this.sortColumn = " + this.rowdef.primaryKeyIndex;
|
|
final int colstart = (this.rowdef.primaryKeyIndex <= 0) ? 0 : this.rowdef.colstart[this.rowdef.primaryKeyIndex];
|
|
//assert (!bugappearance(chunkcache, i * this.rowdef.objectsize + colstart, this.rowdef.primaryKeyLength));
|
|
//assert (!bugappearance(chunkcache, j * this.rowdef.objectsize + colstart, this.rowdef.primaryKeyLength));
|
|
final int c = this.rowdef.objectOrder.compare(
|
|
chunkcache,
|
|
i * this.rowdef.objectsize + colstart,
|
|
this.rowdef.primaryKeyLength,
|
|
chunkcache,
|
|
j * this.rowdef.objectsize + colstart,
|
|
this.rowdef.primaryKeyLength);
|
|
return c;
|
|
}
|
|
|
|
protected final byte[] compilePivot(final int i) {
|
|
assert (i >= 0) && (i < chunkcount) : "i = " + i + ", chunkcount = " + chunkcount;
|
|
assert (this.rowdef.objectOrder != null);
|
|
assert (this.rowdef.objectOrder instanceof Base64Order);
|
|
assert (this.rowdef.primaryKeyIndex == 0) : "this.sortColumn = " + this.rowdef.primaryKeyIndex;
|
|
final int colstart = (this.rowdef.primaryKeyIndex <= 0) ? 0 : this.rowdef.colstart[this.rowdef.primaryKeyIndex];
|
|
//assert (!bugappearance(chunkcache, i * this.rowdef.objectsize + colstart, this.rowdef.primaryKeyLength));
|
|
return ((Base64Order) this.rowdef.objectOrder).compilePivot(chunkcache, i * this.rowdef.objectsize + colstart, this.rowdef.primaryKeyLength);
|
|
}
|
|
|
|
protected final byte[] compilePivot(final byte[] a, final int astart, final int alength) {
|
|
assert (this.rowdef.objectOrder != null);
|
|
assert (this.rowdef.objectOrder instanceof Base64Order);
|
|
assert (this.rowdef.primaryKeyIndex == 0) : "this.sortColumn = " + this.rowdef.primaryKeyIndex;
|
|
return ((Base64Order) this.rowdef.objectOrder).compilePivot(a, astart, alength);
|
|
}
|
|
|
|
protected final int comparePivot(final byte[] compiledPivot, final int j) {
|
|
assert (chunkcount * this.rowdef.objectsize <= chunkcache.length) : "chunkcount = " + chunkcount + ", objsize = " + this.rowdef.objectsize + ", chunkcache.length = " + chunkcache.length;
|
|
assert (j >= 0) && (j < chunkcount) : "j = " + j + ", chunkcount = " + chunkcount;
|
|
assert (this.rowdef.objectOrder != null);
|
|
assert (this.rowdef.objectOrder instanceof Base64Order);
|
|
assert (this.rowdef.primaryKeyIndex == 0) : "this.sortColumn = " + this.rowdef.primaryKeyIndex;
|
|
final int colstart = (this.rowdef.primaryKeyIndex <= 0) ? 0 : this.rowdef.colstart[this.rowdef.primaryKeyIndex];
|
|
//assert (!bugappearance(chunkcache, j * this.rowdef.objectsize + colstart, this.rowdef.primaryKeyLength));
|
|
final int c = ((Base64Order) this.rowdef.objectOrder).comparePivot(
|
|
compiledPivot,
|
|
chunkcache,
|
|
j * this.rowdef.objectsize + colstart,
|
|
this.rowdef.primaryKeyLength);
|
|
return c;
|
|
}
|
|
|
|
protected synchronized int compare(final byte[] a, final int astart, final int alength, final int chunknumber) {
|
|
assert (chunknumber < chunkcount);
|
|
final int l = Math.min(this.rowdef.primaryKeyLength, Math.min(a.length - astart, alength));
|
|
return rowdef.objectOrder.compare(a, astart, l, chunkcache, chunknumber * this.rowdef.objectsize + ((rowdef.primaryKeyIndex <= 0) ? 0 : this.rowdef.colstart[rowdef.primaryKeyIndex]), this.rowdef.primaryKeyLength);
|
|
}
|
|
|
|
protected synchronized boolean match(final byte[] a, final int astart, final int alength, final int chunknumber) {
|
|
if (chunknumber >= chunkcount) return false;
|
|
int i = 0;
|
|
int p = chunknumber * this.rowdef.objectsize + ((rowdef.primaryKeyIndex <= 0) ? 0 : this.rowdef.colstart[rowdef.primaryKeyIndex]);
|
|
final int len = Math.min(this.rowdef.primaryKeyLength, Math.min(alength, a.length - astart));
|
|
while (i < len) if (a[astart + i++] != chunkcache[p++]) return false;
|
|
return ((len == this.rowdef.primaryKeyLength) || (chunkcache[len] == 0)) ;
|
|
}
|
|
|
|
public synchronized void close() {
|
|
chunkcache = null;
|
|
}
|
|
|
|
private static long d(final long a, final long b) {
|
|
if (b == 0) return a;
|
|
return a / b;
|
|
}
|
|
|
|
private static Random random = null;
|
|
private static String randomHash() {
|
|
return
|
|
Base64Order.enhancedCoder.encodeLong(random.nextLong(), 4) +
|
|
Base64Order.enhancedCoder.encodeLong(random.nextLong(), 4) +
|
|
Base64Order.enhancedCoder.encodeLong(random.nextLong(), 4);
|
|
}
|
|
|
|
public static void test(final int testsize) {
|
|
final Row r = new Row(new Column[]{
|
|
new Column("hash", Column.celltype_string, Column.encoder_bytes, 12, "hash")},
|
|
Base64Order.enhancedCoder, 0);
|
|
|
|
RowCollection a = new RowCollection(r, testsize);
|
|
a.add("AAAAAAAAAAAA".getBytes());
|
|
a.add("BBBBBBBBBBBB".getBytes());
|
|
a.add("BBBBBBBBBBBB".getBytes());
|
|
a.add("BBBBBBBBBBBB".getBytes());
|
|
a.add("CCCCCCCCCCCC".getBytes());
|
|
final ArrayList<RowCollection> del = a.removeDoubles();
|
|
System.out.println(del + "rows double");
|
|
final Iterator<Row.Entry> j = a.iterator();
|
|
while (j.hasNext()) System.out.println(new String(j.next().bytes()));
|
|
|
|
System.out.println("kelondroRowCollection test with size = " + testsize);
|
|
a = new RowCollection(r, testsize);
|
|
long t0 = System.nanoTime();
|
|
random = new Random(0);
|
|
for (int i = 0; i < testsize; i++) a.add(randomHash().getBytes());
|
|
random = new Random(0);
|
|
for (int i = 0; i < testsize; i++) a.add(randomHash().getBytes());
|
|
a.sort();
|
|
a.uniq();
|
|
long t1 = System.nanoTime();
|
|
System.out.println("create a : " + (t1 - t0) + " nanoseconds, " + d(testsize, (t1 - t0)) + " entries/nanoseconds; a.size() = " + a.size());
|
|
|
|
final RowCollection c = new RowCollection(r, testsize);
|
|
random = new Random(0);
|
|
t0 = System.nanoTime();
|
|
for (int i = 0; i < testsize; i++) {
|
|
c.add(randomHash().getBytes());
|
|
}
|
|
t1 = System.nanoTime();
|
|
System.out.println("create c : " + (t1 - t0) + " nanoseconds, " + d(testsize, (t1 - t0)) + " entries/nanoseconds");
|
|
final RowCollection d = new RowCollection(r, testsize);
|
|
for (int i = 0; i < testsize; i++) {
|
|
d.add(c.get(i, false).getColBytes(0));
|
|
}
|
|
final long t2 = System.nanoTime();
|
|
System.out.println("copy c -> d: " + (t2 - t1) + " nanoseconds, " + d(testsize, (t2 - t1)) + " entries/nanoseconds");
|
|
serverProcessor.useCPU = 1;
|
|
c.sort();
|
|
final long t3 = System.nanoTime();
|
|
System.out.println("sort c (1) : " + (t3 - t2) + " nanoseconds, " + d(testsize, (t3 - t2)) + " entries/nanoseconds");
|
|
serverProcessor.useCPU = 2;
|
|
d.sort();
|
|
final long t4 = System.nanoTime();
|
|
System.out.println("sort d (2) : " + (t4 - t3) + " nanoseconds, " + d(testsize, (t4 - t3)) + " entries/nanoseconds");
|
|
c.uniq();
|
|
final long t5 = System.nanoTime();
|
|
System.out.println("uniq c : " + (t5 - t4) + " nanoseconds, " + d(testsize, (t5 - t4)) + " entries/nanoseconds");
|
|
d.uniq();
|
|
final long t6 = System.nanoTime();
|
|
System.out.println("uniq d : " + (t6 - t5) + " nanoseconds, " + d(testsize, (t6 - t5)) + " entries/nanoseconds");
|
|
random = new Random(0);
|
|
final RowSet e = new RowSet(r, testsize);
|
|
for (int i = 0; i < testsize; i++) {
|
|
e.put(r.newEntry(randomHash().getBytes()));
|
|
}
|
|
final long t7 = System.nanoTime();
|
|
System.out.println("create e : " + (t7 - t6) + " nanoseconds, " + d(testsize, (t7 - t6)) + " entries/nanoseconds");
|
|
e.sort();
|
|
final long t8 = System.nanoTime();
|
|
System.out.println("sort e (2) : " + (t8 - t7) + " nanoseconds, " + d(testsize, (t8 - t7)) + " entries/nanoseconds");
|
|
e.uniq();
|
|
final long t9 = System.nanoTime();
|
|
System.out.println("uniq e : " + (t9 - t8) + " nanoseconds, " + d(testsize, (t9 - t8)) + " entries/nanoseconds");
|
|
final boolean cis = c.isSorted();
|
|
final long t10 = System.nanoTime();
|
|
System.out.println("c isSorted = " + ((cis) ? "true" : "false") + ": " + (t10 - t9) + " nanoseconds");
|
|
final boolean dis = d.isSorted();
|
|
final long t11 = System.nanoTime();
|
|
System.out.println("d isSorted = " + ((dis) ? "true" : "false") + ": " + (t11 - t10) + " nanoseconds");
|
|
final boolean eis = e.isSorted();
|
|
final long t12 = System.nanoTime();
|
|
System.out.println("e isSorted = " + ((eis) ? "true" : "false") + ": " + (t12 - t11) + " nanoseconds");
|
|
random = new Random(0);
|
|
boolean allfound = true;
|
|
for (int i = 0; i < testsize; i++) {
|
|
final String rh = randomHash();
|
|
if (e.get(rh.getBytes()) == null) {
|
|
allfound = false;
|
|
System.out.println("not found hash " + rh + " at attempt " + i);
|
|
break;
|
|
}
|
|
}
|
|
final long t13 = System.nanoTime();
|
|
System.out.println("e allfound = " + ((allfound) ? "true" : "false") + ": " + (t13 - t12) + " nanoseconds");
|
|
boolean noghosts = true;
|
|
for (int i = 0; i < testsize; i++) {
|
|
if (e.get(randomHash().getBytes()) != null) {
|
|
noghosts = false;
|
|
break;
|
|
}
|
|
}
|
|
final long t14 = System.nanoTime();
|
|
System.out.println("e noghosts = " + ((noghosts) ? "true" : "false") + ": " + (t14 - t13) + " nanoseconds");
|
|
System.out.println("Result size: c = " + c.size() + ", d = " + d.size() + ", e = " + e.size());
|
|
System.out.println();
|
|
if (sortingthreadexecutor != null) sortingthreadexecutor.shutdown();
|
|
}
|
|
|
|
public static void main(final String[] args) {
|
|
//test(1000);
|
|
test(50000);
|
|
//test(100000);
|
|
//test(1000000);
|
|
|
|
/*
|
|
System.out.println(new java.util.Date(10957 * day));
|
|
System.out.println(new java.util.Date(0));
|
|
System.out.println(daysSince2000(System.currentTimeMillis()));
|
|
*/
|
|
}
|
|
}
|