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yacy_search_server/source/de/anomic/kelondro/kelondroRowSet.java

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// kelondroRowSet.java
// (C) 2006 by Michael Peter Christen; mc@anomic.de, Frankfurt a. M., Germany
// first published 20.06.2006 on http://www.anomic.de
//
// $LastChangedDate: 2006-04-02 22:40:07 +0200 (So, 02 Apr 2006) $
// $LastChangedRevision: 1986 $
// $LastChangedBy: orbiter $
//
// LICENSE
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
package de.anomic.kelondro;
import java.io.IOException;
import java.util.Date;
import java.util.Iterator;
import java.util.List;
import java.util.Random;
import java.util.TreeMap;
import de.anomic.server.logging.serverLog;
public class kelondroRowSet extends kelondroRowCollection implements kelondroIndex {
private static final int collectionReSortLimit = 90;
private static final int removeMaxSize = 100;
private kelondroProfile profile;
private TreeMap removeMarker;
public kelondroRowSet(kelondroRow rowdef, int objectCount, byte[] cache, int sortBound) {
super(rowdef, objectCount, cache, sortBound);
this.removeMarker = new TreeMap();
this.profile = new kelondroProfile();
}
public kelondroRowSet(kelondroRowSet rs) {
super(rs);
this.profile = rs.profile;
this.removeMarker = rs.removeMarker;
}
public kelondroRowSet(kelondroRow rowdef, int objectCount) {
super(rowdef, objectCount);
this.removeMarker = new TreeMap();
this.profile = new kelondroProfile();
}
public kelondroRowSet(kelondroRow rowdef, byte[] exportedCollectionRowinstance) {
super(rowdef, exportedCollectionRowinstance);
this.removeMarker = new TreeMap();
this.profile = new kelondroProfile();
}
public boolean has(byte[] key) throws IOException {
return (get(key) != null);
}
public kelondroRow.Entry get(byte[] key) {
return get(key, 0, key.length);
}
private kelondroRow.Entry get(byte[] key, int astart, int alength) {
long handle = profile.startRead();
kelondroRow.Entry entry = null;
synchronized (chunkcache) {
int index = find(key, astart, alength);
if ((index >= 0) && (!(isMarkedRemoved(index)))) entry = get(index);
}
profile.stopRead(handle);
return entry;
}
public void addUnique(kelondroRow.Entry row) {
// add an entry without doing a double-occurrence test
if (removeMarker.size() == 0) {
super.addUnique(row);
} else {
this.put(row);
}
}
public void addUnique(kelondroRow.Entry row, Date entryDate) {
if (removeMarker.size() == 0) {
super.addUnique(row, entryDate);
} else {
this.put(row, entryDate);
}
}
public void addUniqueMultiple(List rows, Date entryDate) throws IOException {
if (removeMarker.size() == 0) {
super.addUniqueMultiple(rows, entryDate);
} else {
Iterator i = rows.iterator();
while (i.hasNext()) addUnique((kelondroRow.Entry) i.next(), entryDate);
}
}
public synchronized void putMultiple(List rows, Date entryDate) throws IOException {
Iterator i = rows.iterator();
while (i.hasNext()) put((kelondroRow.Entry) i.next(), entryDate);
}
public kelondroRow.Entry put(kelondroRow.Entry row, Date entryDate) {
return put(row);
}
public kelondroRow.Entry put(kelondroRow.Entry entry) {
assert (entry != null);
assert (entry.getColBytes(rowdef.primaryKey) != null);
//assert (!(serverLog.allZero(entry.getColBytes(super.sortColumn))));
long handle = profile.startWrite();
int index = -1;
kelondroRow.Entry oldentry = null;
synchronized (chunkcache) {
index = find(entry.bytes(), super.rowdef.colstart[rowdef.primaryKey], super.rowdef.width(rowdef.primaryKey));
if (isMarkedRemoved(index)) {
set(index, entry);
removeMarker.remove(new Integer(index));
} else if (index < 0) {
super.addUnique(entry);
} else {
oldentry = get(index);
set(index, entry);
}
}
profile.stopWrite(handle);
return oldentry;
}
public int size() {
return super.size() - removeMarker.size();
}
public kelondroRow.Entry remove(byte[] a) {
return removeMarked(a, 0, a.length);
}
private kelondroRow.Entry removeMarked(byte[] a, int astart, int alength) {
if (chunkcount == 0) return null;
long handle = profile.startDelete();
// check if it is contained in chunkcache
kelondroRow.Entry entry = null;
synchronized(chunkcache) {
int p = find(a, astart, alength);
if (p < 0) {
// the entry is not there
profile.stopDelete(handle);
return null;
} else {
// there is an entry
entry = get(p);
if (p < sortBound) {
// mark entry as to-be-deleted
removeMarker.put(new Integer(p), entry.getColBytes(rowdef.primaryKey));
if (removeMarker.size() > removeMaxSize) resolveMarkedRemoved();
} else {
// remove directly by swap
super.copytop(p);
chunkcount--;
}
profile.stopDelete(handle);
return entry;
}
}
}
private boolean isMarkedRemoved(int index) {
return removeMarker.containsKey(new Integer(index));
}
public void shape() {
assert (rowdef.objectOrder != null); // we cannot shape without an object order
synchronized (chunkcache) {
try {
resolveMarkedRemoved();
super.sort();
} catch (kelondroException e) {
// bad bug, cannot be fixed. We abandon all data
serverLog.logSevere("kelondroRowSet", "abandoned row");
this.clear();
}
//if (super.rowdef.column(0).cellwidth() == 4) System.out.println("TABLE OF " + super.rowdef.toString() + "\n" + serverLog.table(super.chunkcache, super.rowdef.objectsize, 0)); // DEBUG
}
}
private void resolveMarkedRemoved() {
if (removeMarker.size() == 0) return;
// check case when complete chunkcache is marked as deleted
if (removeMarker.size() == chunkcount) {
this.clear();
removeMarker.clear();
return;
}
Integer nxt = (Integer) removeMarker.firstKey();
removeMarker.remove(nxt);
int idx = nxt.intValue();
assert (idx < sortBound) : "idx = " + idx + ", sortBound = " + sortBound;
int d = 1;
byte[] a;
while (removeMarker.size() > 0) {
nxt = (Integer) removeMarker.firstKey();
a = (byte[]) removeMarker.remove(nxt);
assert kelondroNaturalOrder.compares(a, 0, a.length, get(nxt.intValue()).getColBytes(rowdef.primaryKey), 0, a.length) == 0;
assert (nxt.intValue() < sortBound);
super.removeShift(idx, d, nxt.intValue());
idx = nxt.intValue() - d;
d++;
}
super.removeShift(idx, d, chunkcount);
chunkcount -= d;
sortBound -= d; // there are all markers below the sortBound
removeMarker.clear();
}
public void removeMarkedAll(kelondroRowCollection c) {
long handle = profile.startDelete();
Iterator i = c.rows();
kelondroRow.Entry entry;
while (i.hasNext()) {
entry = (kelondroRow.Entry) i.next();
removeMarked(entry.bytes(), 0, entry.bytes().length);
}
profile.stopDelete(handle);
}
public void setOrdering(kelondroOrder newOrder, int newColumn) {
if ((rowdef.objectOrder == null) ||
(!(rowdef.objectOrder.signature().equals(newOrder.signature()))) ||
(newColumn != rowdef.primaryKey)) {
resolveMarkedRemoved();
rowdef.setOrdering(newOrder, newColumn);
assert (removeMarker.size() == 0);
this.sortBound = 0;
}
}
private int find(byte[] a, int astart, int alength) {
// returns the chunknumber; -1 if not found
if (rowdef.objectOrder == null) return iterativeSearch(a, astart, alength, 0, this.chunkcount);
// check if a re-sorting make sense
if ((this.chunkcount - this.sortBound) > collectionReSortLimit) shape();
// first try to find in sorted area
int p = binarySearch(a, astart, alength);
if (p >= 0) return p;
// then find in unsorted area
return iterativeSearch(a, astart, alength, this.sortBound, this.chunkcount);
}
private int iterativeSearch(byte[] key, int astart, int alength, int leftBorder, int rightBound) {
// returns the chunknumber
if (rowdef.objectOrder == null) {
for (int i = leftBorder; i < rightBound; i++) {
if (match(key, astart, alength, i)) return i;
}
return -1;
} else {
for (int i = leftBorder; i < rightBound; i++) {
if (compare(key, astart, alength, i) == 0) return i;
}
return -1;
}
}
private int binarySearch(byte[] key, int astart, int alength) {
// returns the exact position of the key if the key exists,
// or -1 if the key does not exist
assert (rowdef.objectOrder != null);
int l = 0;
int rbound = this.sortBound;
int p = 0;
int d;
while (l < rbound) {
p = l + ((rbound - l) >> 1);
d = compare(key, astart, alength, p);
if (d == 0) return p;
else if (d < 0) rbound = p;
else l = p + 1;
}
return -1;
}
public int binaryPosition(byte[] key, int astart, int alength) {
// returns the exact position of the key if the key exists,
// or a position of an entry that is greater than the key if the
// key does not exist
assert (rowdef.objectOrder != null);
int l = 0;
int rbound = this.sortBound;
int p = 0;
int d;
while (l < rbound) {
p = l + ((rbound - l) >> 1);
d = compare(key, astart, alength, p);
if (d == 0) return p;
else if (d < 0) rbound = p;
else l = p + 1;
}
return l;
}
private int compare(byte[] a, int astart, int alength, int chunknumber) {
assert (chunknumber < chunkcount);
int l = Math.min(this.rowdef.width(rowdef.primaryKey), Math.min(a.length - astart, alength));
return rowdef.objectOrder.compare(a, astart, l, chunkcache, chunknumber * this.rowdef.objectsize() + this.rowdef.colstart[rowdef.primaryKey], this.rowdef.width(rowdef.primaryKey));
}
private boolean match(byte[] a, int astart, int alength, int chunknumber) {
if (chunknumber >= chunkcount) return false;
int i = 0;
int p = chunknumber * this.rowdef.objectsize() + this.rowdef.colstart[rowdef.primaryKey];
final int len = Math.min(this.rowdef.width(rowdef.primaryKey), Math.min(alength, a.length - astart));
while (i < len) if (a[astart + i++] != chunkcache[p++]) return false;
return ((len == this.rowdef.width(rowdef.primaryKey)) || (chunkcache[len] == 0)) ;
}
public kelondroProfile profile() {
return profile;
}
public Iterator rows() {
shape();
return super.rows();
}
public Iterator rows(boolean up, boolean rotating, byte[] firstKey) {
return new rowIterator(up, rotating, firstKey);
}
public class rowIterator implements Iterator {
private boolean up, rot;
private byte[] first;
private int p, bound;
public rowIterator(boolean up, boolean rotating, byte[] firstKey) {
// see that all elements are sorted
shape();
this.up = up;
this.rot = rotating;
this.first = firstKey;
this.bound = sortBound;
if (first == null) {
p = 0;
} else {
p = binaryPosition(first, 0, first.length);
}
}
public boolean hasNext() {
if (rot) return true;
if (up) {
return p < bound;
} else {
return p >= 0;
}
}
public Object next() {
kelondroRow.Entry entry = get(p);
if (up) p++; else p--;
if (rot) {
if (p == bound) p = 0;
if (p < 0) p = bound - 1;
}
return entry;
}
public void remove() {
throw new UnsupportedOperationException();
}
}
public void close() {
// just for compatibility with kelondroIndex interface; do nothing
}
public final int cacheObjectChunkSize() {
// dummy method
return -1;
}
public long[] cacheObjectStatus() {
// dummy method
return null;
}
public final int cacheNodeChunkSize() {
// returns the size that the node cache uses for a single entry
return -1;
}
public final int[] cacheNodeStatus() {
// a collection of different node cache status values
return new int[]{0,0,0,0,0,0,0,0,0,0};
}
public static void main(String[] args) {
/*
String[] test = { "eins", "zwei", "drei", "vier", "fuenf", "sechs", "sieben", "acht", "neun", "zehn" };
kelondroRowSet c = new kelondroRowSet(new kelondroRow(new int[]{10, 3}));
c.setOrdering(kelondroNaturalOrder.naturalOrder, 0);
for (int i = 0; i < test.length; i++) c.add(test[i].getBytes());
for (int i = 0; i < test.length; i++) c.add(test[i].getBytes());
c.shape();
c.removeMarked("fuenf".getBytes(), 0, 5);
Iterator i = c.elements();
String s;
System.out.print("INPUT-ITERATOR: ");
while (i.hasNext()) {
s = new String((byte[]) i.next()).trim();
System.out.print(s + ", ");
if (s.equals("drei")) i.remove();
}
System.out.println("");
System.out.println("INPUT-TOSTRING: " + c.toString());
c.shape();
System.out.println("SORTED : " + c.toString());
c.uniq();
System.out.println("UNIQ : " + c.toString());
c.trim();
System.out.println("TRIM : " + c.toString());
*/
/*
// second test
c = new kelondroRowSet(new kelondroRow(new int[]{10, 3}));
c.setOrdering(kelondroNaturalOrder.naturalOrder, 0);
Random rand = new Random(0);
long start = System.currentTimeMillis();
long t, d = 0;
String w;
for (long k = 0; k < 60000; k++) {
t = System.currentTimeMillis();
w = "a" + Long.toString(rand.nextLong());
c.add(w.getBytes());
if (k % 10000 == 0)
System.out.println("added " + k + " entries in " +
((t - start) / 1000) + " seconds, " +
(((t - start) > 1000) ? (k / ((t - start) / 1000)) : k) +
" entries/second, size = " + c.size());
}
System.out.println("bevore sort: " + ((System.currentTimeMillis() - start) / 1000) + " seconds");
c.shape();
System.out.println("after sort: " + ((System.currentTimeMillis() - start) / 1000) + " seconds");
c.uniq();
System.out.println("after uniq: " + ((System.currentTimeMillis() - start) / 1000) + " seconds");
System.out.println("RESULT SIZE: " + c.size());
System.out.println();
// third test
c = new kelondroRowSet(new kelondroRow(new int[]{10, 3}), 60000);
c.setOrdering(kelondroNaturalOrder.naturalOrder, 0);
rand = new Random(0);
start = System.currentTimeMillis();
d = 0;
for (long k = 0; k < 60000; k++) {
t = System.currentTimeMillis();
w = "a" + Long.toString(rand.nextLong());
if (c.get(w.getBytes(), 0, 10) == null) c.add(w.getBytes()); else d++;
if (k % 10000 == 0)
System.out.println("added " + k + " entries in " +
((t - start) / 1000) + " seconds, " +
(((t - start) > 1000) ? (k / ((t - start) / 1000)) : k) +
" entries/second, " + d + " double, size = " + c.size() +
", sum = " + (c.size() + d));
}
System.out.println("RESULT SIZE: " + c.size());
*/
/*
// performance test for put
long start = System.currentTimeMillis();
kelondroRowSet c = new kelondroRowSet(new kelondroRow("byte[] a-12, byte[] b-12"), 0);
Random random = new Random(0);
byte[] key;
for (int i = 0; i < 100000; i++) {
key = randomHash(random);
c.put(c.rowdef.newEntry(new byte[][]{key, key}));
if (i % 1000 == 0) System.out.println(i + " entries. ");
}
System.out.println("RESULT SIZE: " + c.size());
System.out.println("Time: " + ((System.currentTimeMillis() - start) / 1000) + " seconds");
*/
// remove test
long start = System.currentTimeMillis();
kelondroRowSet c = new kelondroRowSet(new kelondroRow("byte[] a-12, byte[] b-12", kelondroBase64Order.enhancedCoder, 0), 0);
byte[] key;
int testsize = 5000;
byte[][] delkeys = new byte[testsize / 5][];
Random random = new Random(0);
for (int i = 0; i < testsize; i++) {
key = randomHash(random);
if (i % 5 != 0) continue;
delkeys[i / 5] = key;
}
random = new Random(0);
for (int i = 0; i < testsize; i++) {
key = randomHash(random);
c.put(c.rowdef.newEntry(new byte[][]{key, key}));
if (i % 1000 == 0) {
for (int j = 0; j < delkeys.length; j++) c.remove(delkeys[j]);
c.shape();
}
}
for (int j = 0; j < delkeys.length; j++) c.remove(delkeys[j]);
c.shape();
random = new Random(0);
for (int i = 0; i < testsize; i++) {
key = randomHash(random);
if (i % 5 == 0) continue;
if (c.get(key) == null) System.out.println("missing entry " + new String(key));
}
c.shape();
System.out.println("RESULT SIZE: " + c.size());
System.out.println("Time: " + ((System.currentTimeMillis() - start) / 1000) + " seconds");
}
public static byte[] randomHash(final long r0, final long r1) {
// a long can have 64 bit, but a 12-byte hash can have 6 * 12 = 72 bits
// so we construct a generic Hash using two long values
return (kelondroBase64Order.enhancedCoder.encodeLong(Math.abs(r0), 11).substring(5) +
kelondroBase64Order.enhancedCoder.encodeLong(Math.abs(r1), 11).substring(5)).getBytes();
}
public static byte[] randomHash(Random r) {
return randomHash(r.nextLong(), r.nextLong());
}
public String filename() {
return null;
}
}