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RocksDB fat jar that contains .so files for linux64, jnilib files
for Mac OSX, and a .dll for Windows x64. It contains the Yamcs merge operator for the Parameter Archive
// Copyright (c) 2011-present, Facebook, Inc. All rights reserved.
// This source code is licensed under both the GPLv2 (found in the
// COPYING file in the root directory) and Apache 2.0 License
// (found in the LICENSE.Apache file in the root directory).
package org.rocksdb.util;
import org.rocksdb.*;
import java.nio.ByteBuffer;
import static org.rocksdb.util.ByteUtil.memcmp;
/**
* This is a Java Native implementation of the C++
* equivalent BytewiseComparatorImpl using {@link Slice}
*
* The performance of Comparators implemented in Java is always
* less than their C++ counterparts due to the bridging overhead,
* as such you likely don't want to use this apart from benchmarking
* and you most likely instead wanted
* {@link org.rocksdb.BuiltinComparator#BYTEWISE_COMPARATOR}
*/
public final class BytewiseComparator extends AbstractComparator {
public BytewiseComparator(final ComparatorOptions copt) {
super(copt);
}
@Override
public String name() {
return "rocksdb.java.BytewiseComparator";
}
@Override
public int compare(final ByteBuffer a, final ByteBuffer b) {
return _compare(a, b);
}
static int _compare(final ByteBuffer a, final ByteBuffer b) {
assert(a != null && b != null);
final int minLen = a.remaining() < b.remaining() ?
a.remaining() : b.remaining();
int r = memcmp(a, b, minLen);
if (r == 0) {
if (a.remaining() < b.remaining()) {
r = -1;
} else if (a.remaining() > b.remaining()) {
r = +1;
}
}
return r;
}
@SuppressWarnings("PMD.EmptyControlStatement")
@Override
public void findShortestSeparator(final ByteBuffer start, final ByteBuffer limit) {
// Find length of common prefix
final int minLength = Math.min(start.remaining(), limit.remaining());
int diffIndex = 0;
while (diffIndex < minLength &&
start.get(diffIndex) == limit.get(diffIndex)) {
diffIndex++;
}
if (diffIndex >= minLength) {
// Do not shorten if one string is a prefix of the other
} else {
final int startByte = start.get(diffIndex) & 0xff;
final int limitByte = limit.get(diffIndex) & 0xff;
if (startByte >= limitByte) {
// Cannot shorten since limit is smaller than start or start is
// already the shortest possible.
return;
}
assert(startByte < limitByte);
if (diffIndex < limit.remaining() - 1 || startByte + 1 < limitByte) {
start.put(diffIndex, (byte)((start.get(diffIndex) & 0xff) + 1));
start.limit(diffIndex + 1);
} else {
// v
// A A 1 A A A
// A A 2
//
// Incrementing the current byte will make start bigger than limit, we
// will skip this byte, and find the first non 0xFF byte in start and
// increment it.
diffIndex++;
while (diffIndex < start.remaining()) {
// Keep moving until we find the first non 0xFF byte to
// increment it
if ((start.get(diffIndex) & 0xff) <
0xff) {
start.put(diffIndex, (byte)((start.get(diffIndex) & 0xff) + 1));
start.limit(diffIndex + 1);
break;
}
diffIndex++;
}
}
assert(compare(start.duplicate(), limit.duplicate()) < 0);
}
}
@Override
public void findShortSuccessor(final ByteBuffer key) {
// Find first character that can be incremented
final int n = key.remaining();
for (int i = 0; i < n; i++) {
final int byt = key.get(i) & 0xff;
if (byt != 0xff) {
key.put(i, (byte)(byt + 1));
key.limit(i+1);
return;
}
}
// *key is a run of 0xffs. Leave it alone.
}
}