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The Apache Cassandra Project develops a highly scalable second-generation distributed database, bringing together Dynamo's fully distributed design and Bigtable's ColumnFamily-based data model.

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/*
 * Licensed to the Apache Software Foundation (ASF) under one
 * or more contributor license agreements.  See the NOTICE file
 * distributed with this work for additional information
 * regarding copyright ownership.  The ASF 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.apache.cassandra.utils;

import java.net.InetAddress;
import java.nio.ByteBuffer;
import java.security.MessageDigest;
import java.security.NoSuchAlgorithmException;
import java.security.SecureRandom;
import java.util.Collection;
import java.util.Random;
import java.util.UUID;

import com.google.common.annotations.VisibleForTesting;
import com.google.common.base.Charsets;


/**
 * The goods are here: www.ietf.org/rfc/rfc4122.txt.
 */
public class UUIDGen
{
    // A grand day! millis at 00:00:00.000 15 Oct 1582.
    private static final long START_EPOCH = -12219292800000L;
    private static final long clockSeqAndNode = makeClockSeqAndNode();

    /*
     * The min and max possible lsb for a UUID.
     * Note that his is not 0 and all 1's because Cassandra TimeUUIDType
     * compares the lsb parts as a signed byte array comparison. So the min
     * value is 8 times -128 and the max is 8 times +127.
     *
     * Note that we ignore the uuid variant (namely, MIN_CLOCK_SEQ_AND_NODE
     * have variant 2 as it should, but MAX_CLOCK_SEQ_AND_NODE have variant 0).
     * I don't think that has any practical consequence and is more robust in
     * case someone provides a UUID with a broken variant.
     */
    private static final long MIN_CLOCK_SEQ_AND_NODE = 0x8080808080808080L;
    private static final long MAX_CLOCK_SEQ_AND_NODE = 0x7f7f7f7f7f7f7f7fL;

    private static final SecureRandom secureRandom = new SecureRandom();

    // placement of this singleton is important.  It needs to be instantiated *AFTER* the other statics.
    private static final UUIDGen instance = new UUIDGen();

    private long lastNanos;

    private UUIDGen()
    {
        // make sure someone didn't whack the clockSeqAndNode by changing the order of instantiation.
        if (clockSeqAndNode == 0) throw new RuntimeException("singleton instantiation is misplaced.");
    }

    /**
     * Creates a type 1 UUID (time-based UUID).
     *
     * @return a UUID instance
     */
    public static UUID getTimeUUID()
    {
        return new UUID(instance.createTimeSafe(), clockSeqAndNode);
    }

    /**
     * Creates a type 1 UUID (time-based UUID) with the timestamp of @param when, in milliseconds.
     *
     * @return a UUID instance
     */
    public static UUID getTimeUUID(long when)
    {
        return new UUID(createTime(fromUnixTimestamp(when)), clockSeqAndNode);
    }

    /**
     * Returns a version 1 UUID using the provided timestamp and the local clock and sequence.
     * 

* Note that this method is generally only safe to use if you can guarantee that the provided * parameter is unique across calls (otherwise the returned UUID won't be unique accross calls). * * @param whenInMicros a unix time in microseconds. * @return a new UUID {@code id} such that {@code microsTimestamp(id) == whenInMicros}. Please not that * multiple calls to this method with the same value of {@code whenInMicros} will return the same * UUID. */ public static UUID getTimeUUIDFromMicros(long whenInMicros) { long whenInMillis = whenInMicros / 1000; long nanos = (whenInMicros - (whenInMillis * 1000)) * 10; return getTimeUUID(whenInMillis, nanos); } /** * Similar to {@link getTimeUUIDFromMicros}, but randomize (using SecureRandom) the clock and sequence. *

* If you can guarantee that the {@code whenInMicros} argument is unique (for this JVM instance) for * every call, then you should prefer {@link getTimeUUIDFromMicros} which is faster. If you can't * guarantee this however, this method will ensure the returned UUID are still unique (accross calls) * through randomization. * * @param whenInMicros a unix time in microseconds. * @return a new UUID {@code id} such that {@code microsTimestamp(id) == whenInMicros}. The UUID returned * by different calls will be unique even if {@code whenInMicros} is not. */ public static UUID getRandomTimeUUIDFromMicros(long whenInMicros) { long whenInMillis = whenInMicros / 1000; long nanos = (whenInMicros - (whenInMillis * 1000)) * 10; return new UUID(createTime(fromUnixTimestamp(whenInMillis, nanos)), secureRandom.nextLong()); } public static UUID getTimeUUID(long when, long nanos) { return new UUID(createTime(fromUnixTimestamp(when, nanos)), clockSeqAndNode); } @VisibleForTesting public static UUID getTimeUUID(long when, long nanos, long clockSeqAndNode) { return new UUID(createTime(fromUnixTimestamp(when, nanos)), clockSeqAndNode); } /** creates a type 1 uuid from raw bytes. */ public static UUID getUUID(ByteBuffer raw) { return new UUID(raw.getLong(raw.position()), raw.getLong(raw.position() + 8)); } /** decomposes a uuid into raw bytes. */ public static byte[] decompose(UUID uuid) { long most = uuid.getMostSignificantBits(); long least = uuid.getLeastSignificantBits(); byte[] b = new byte[16]; for (int i = 0; i < 8; i++) { b[i] = (byte)(most >>> ((7-i) * 8)); b[8+i] = (byte)(least >>> ((7-i) * 8)); } return b; } /** * Returns a 16 byte representation of a type 1 UUID (a time-based UUID), * based on the current system time. * * @return a type 1 UUID represented as a byte[] */ public static byte[] getTimeUUIDBytes() { return createTimeUUIDBytes(instance.createTimeSafe()); } /** * Returns the smaller possible type 1 UUID having the provided timestamp. * * Warning: this method should only be used for querying as this * doesn't at all guarantee the uniqueness of the resulting UUID. */ public static UUID minTimeUUID(long timestamp) { return new UUID(createTime(fromUnixTimestamp(timestamp)), MIN_CLOCK_SEQ_AND_NODE); } /** * Returns the biggest possible type 1 UUID having the provided timestamp. * * Warning: this method should only be used for querying as this * doesn't at all guarantee the uniqueness of the resulting UUID. */ public static UUID maxTimeUUID(long timestamp) { // unix timestamp are milliseconds precision, uuid timestamp are 100's // nanoseconds precision. If we ask for the biggest uuid have unix // timestamp 1ms, then we should not extend 100's nanoseconds // precision by taking 10000, but rather 19999. long uuidTstamp = fromUnixTimestamp(timestamp + 1) - 1; return new UUID(createTime(uuidTstamp), MAX_CLOCK_SEQ_AND_NODE); } /** * @param uuid * @return milliseconds since Unix epoch */ public static long unixTimestamp(UUID uuid) { return (uuid.timestamp() / 10000) + START_EPOCH; } /** * @param uuid * @return microseconds since Unix epoch */ public static long microsTimestamp(UUID uuid) { return (uuid.timestamp() / 10) + START_EPOCH * 1000; } /** * @param timestamp milliseconds since Unix epoch * @return */ private static long fromUnixTimestamp(long timestamp) { return fromUnixTimestamp(timestamp, 0L); } private static long fromUnixTimestamp(long timestamp, long nanos) { return ((timestamp - START_EPOCH) * 10000) + nanos; } /** * Converts a 100-nanoseconds precision timestamp into the 16 byte representation * of a type 1 UUID (a time-based UUID). * * To specify a 100-nanoseconds precision timestamp, one should provide a milliseconds timestamp and * a number 0 <= n < 10000 such that n*100 is the number of nanoseconds within that millisecond. * *

Warning: This method is not guaranteed to return unique UUIDs; Multiple * invocations using identical timestamps will result in identical UUIDs.

* * @return a type 1 UUID represented as a byte[] */ public static byte[] getTimeUUIDBytes(long timeMillis, int nanos) { if (nanos >= 10000) throw new IllegalArgumentException(); return createTimeUUIDBytes(instance.createTimeUnsafe(timeMillis, nanos)); } private static byte[] createTimeUUIDBytes(long msb) { long lsb = clockSeqAndNode; byte[] uuidBytes = new byte[16]; for (int i = 0; i < 8; i++) uuidBytes[i] = (byte) (msb >>> 8 * (7 - i)); for (int i = 8; i < 16; i++) uuidBytes[i] = (byte) (lsb >>> 8 * (7 - i)); return uuidBytes; } /** * Returns a milliseconds-since-epoch value for a type-1 UUID. * * @param uuid a type-1 (time-based) UUID * @return the number of milliseconds since the unix epoch * @throws IllegalArgumentException if the UUID is not version 1 */ public static long getAdjustedTimestamp(UUID uuid) { if (uuid.version() != 1) throw new IllegalArgumentException("incompatible with uuid version: "+uuid.version()); return (uuid.timestamp() / 10000) + START_EPOCH; } private static long makeClockSeqAndNode() { long clock = new Random(System.currentTimeMillis()).nextLong(); long lsb = 0; lsb |= 0x8000000000000000L; // variant (2 bits) lsb |= (clock & 0x0000000000003FFFL) << 48; // clock sequence (14 bits) lsb |= makeNode(); // 6 bytes return lsb; } // needs to return two different values for the same when. // we can generate at most 10k UUIDs per ms. private synchronized long createTimeSafe() { long nanosSince = (System.currentTimeMillis() - START_EPOCH) * 10000; if (nanosSince > lastNanos) lastNanos = nanosSince; else nanosSince = ++lastNanos; return createTime(nanosSince); } private long createTimeUnsafe(long when, int nanos) { long nanosSince = ((when - START_EPOCH) * 10000) + nanos; return createTime(nanosSince); } private static long createTime(long nanosSince) { long msb = 0L; msb |= (0x00000000ffffffffL & nanosSince) << 32; msb |= (0x0000ffff00000000L & nanosSince) >>> 16; msb |= (0xffff000000000000L & nanosSince) >>> 48; msb |= 0x0000000000001000L; // sets the version to 1. return msb; } private static long makeNode() { /* * We don't have access to the MAC address but need to generate a node part * that identify this host as uniquely as possible. * The spec says that one option is to take as many source that identify * this node as possible and hash them together. That's what we do here by * gathering all the ip of this host. * Note that FBUtilities.getBroadcastAddress() should be enough to uniquely * identify the node *in the cluster* but it triggers DatabaseDescriptor * instanciation and the UUID generator is used in Stress for instance, * where we don't want to require the yaml. */ Collection localAddresses = FBUtilities.getAllLocalAddresses(); if (localAddresses.isEmpty()) throw new RuntimeException("Cannot generate the node component of the UUID because cannot retrieve any IP addresses."); // ideally, we'd use the MAC address, but java doesn't expose that. byte[] hash = hash(localAddresses); long node = 0; for (int i = 0; i < Math.min(6, hash.length); i++) node |= (0x00000000000000ff & (long)hash[i]) << (5-i)*8; assert (0xff00000000000000L & node) == 0; // Since we don't use the mac address, the spec says that multicast // bit (least significant bit of the first octet of the node ID) must be 1. return node | 0x0000010000000000L; } private static byte[] hash(Collection data) { try { // Identify the host. MessageDigest messageDigest = MessageDigest.getInstance("MD5"); for(InetAddress addr : data) messageDigest.update(addr.getAddress()); // Identify the process on the load: we use both the PID and class loader hash. long pid = SigarLibrary.instance.getPid(); if (pid < 0) pid = new Random(System.currentTimeMillis()).nextLong(); FBUtilities.updateWithLong(messageDigest, pid); ClassLoader loader = UUIDGen.class.getClassLoader(); int loaderId = loader != null ? System.identityHashCode(loader) : 0; FBUtilities.updateWithInt(messageDigest, loaderId); return messageDigest.digest(); } catch (NoSuchAlgorithmException nsae) { throw new RuntimeException("MD5 digest algorithm is not available", nsae); } } } // for the curious, here is how I generated START_EPOCH // Calendar c = Calendar.getInstance(TimeZone.getTimeZone("GMT-0")); // c.set(Calendar.YEAR, 1582); // c.set(Calendar.MONTH, Calendar.OCTOBER); // c.set(Calendar.DAY_OF_MONTH, 15); // c.set(Calendar.HOUR_OF_DAY, 0); // c.set(Calendar.MINUTE, 0); // c.set(Calendar.SECOND, 0); // c.set(Calendar.MILLISECOND, 0); // long START_EPOCH = c.getTimeInMillis();




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