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/*
* Licensed to Elasticsearch under one or more contributor
* license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright
* ownership. Elasticsearch licenses this file to you under
* the Apache License, Version 2.0 (the "License"); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing,
* software distributed under the License is distributed on an
* "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
* KIND, either express or implied. See the License for the
* specific language governing permissions and limitations
* under the License.
*/
package org.elasticsearch.common;
import java.util.Base64;
import java.util.concurrent.atomic.AtomicInteger;
/**
* These are essentially flake ids but we use 6 (not 8) bytes for timestamp, and use 3 (not 2) bytes for sequence number. We also reorder
* bytes in a way that does not make ids sort in order anymore, but is more friendly to the way that the Lucene terms dictionary is
* structured.
* For more information about flake ids, check out
* https://archive.fo/2015.07.08-082503/http://www.boundary.com/blog/2012/01/flake-a-decentralized-k-ordered-unique-id-generator-in-erlang/
*/
class TimeBasedUUIDGenerator implements UUIDGenerator {
// We only use bottom 3 bytes for the sequence number. Paranoia: init with random int so that if JVM/OS/machine goes down, clock slips
// backwards, and JVM comes back up, we are less likely to be on the same sequenceNumber at the same time:
private final AtomicInteger sequenceNumber = new AtomicInteger(SecureRandomHolder.INSTANCE.nextInt());
// Used to ensure clock moves forward:
private long lastTimestamp;
private static final byte[] SECURE_MUNGED_ADDRESS = MacAddressProvider.getSecureMungedAddress();
static {
assert SECURE_MUNGED_ADDRESS.length == 6;
}
// protected for testing
protected long currentTimeMillis() {
return System.currentTimeMillis();
}
// protected for testing
protected byte[] macAddress() {
return SECURE_MUNGED_ADDRESS;
}
@Override
public String getBase64UUID() {
final int sequenceId = sequenceNumber.incrementAndGet() & 0xffffff;
long timestamp = currentTimeMillis();
synchronized (this) {
// Don't let timestamp go backwards, at least "on our watch" (while this JVM is running). We are still vulnerable if we are
// shut down, clock goes backwards, and we restart... for this we randomize the sequenceNumber on init to decrease chance of
// collision:
timestamp = Math.max(lastTimestamp, timestamp);
if (sequenceId == 0) {
// Always force the clock to increment whenever sequence number is 0, in case we have a long time-slip backwards:
timestamp++;
}
lastTimestamp = timestamp;
}
final byte[] uuidBytes = new byte[15];
int i = 0;
// We have auto-generated ids, which are usually used for append-only workloads.
// So we try to optimize the order of bytes for indexing speed (by having quite
// unique bytes close to the beginning of the ids so that sorting is fast) and
// compression (by making sure we share common prefixes between enough ids),
// but not necessarily for lookup speed (by having the leading bytes identify
// segments whenever possible)
// Blocks in the block tree have between 25 and 48 terms. So all prefixes that
// are shared by ~30 terms should be well compressed. I first tried putting the
// two lower bytes of the sequence id in the beginning of the id, but compression
// is only triggered when you have at least 30*2^16 ~= 2M documents in a segment,
// which is already quite large. So instead, we are putting the 1st and 3rd byte
// of the sequence number so that compression starts to be triggered with smaller
// segment sizes and still gives pretty good indexing speed. We use the sequenceId
// rather than the timestamp because the distribution of the timestamp depends too
// much on the indexing rate, so it is less reliable.
uuidBytes[i++] = (byte) sequenceId;
// changes every 65k docs, so potentially every second if you have a steady indexing rate
uuidBytes[i++] = (byte) (sequenceId >>> 16);
// Now we start focusing on compression and put bytes that should not change too often.
uuidBytes[i++] = (byte) (timestamp >>> 16); // changes every ~65 secs
uuidBytes[i++] = (byte) (timestamp >>> 24); // changes every ~4.5h
uuidBytes[i++] = (byte) (timestamp >>> 32); // changes every ~50 days
uuidBytes[i++] = (byte) (timestamp >>> 40); // changes every 35 years
byte[] macAddress = macAddress();
assert macAddress.length == 6;
System.arraycopy(macAddress, 0, uuidBytes, i, macAddress.length);
i += macAddress.length;
// Finally we put the remaining bytes, which will likely not be compressed at all.
uuidBytes[i++] = (byte) (timestamp >>> 8);
uuidBytes[i++] = (byte) (sequenceId >>> 8);
uuidBytes[i++] = (byte) timestamp;
assert i == uuidBytes.length;
return Base64.getUrlEncoder().withoutPadding().encodeToString(uuidBytes);
}
}