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/* JUG Java Uuid Generator
*
* Copyright (c) 2002 Tatu Saloranta, [email protected]
*
* Licensed under the License specified in the file LICENSE which is
* included with the source code.
* You may not use this file except in compliance with the License.
*
* 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 com.fasterxml.uuid;
import java.io.*;
import java.util.*;
import com.fasterxml.uuid.impl.LoggerFacade;
import com.fasterxml.uuid.impl.UUIDUtil;
/**
* UUIDTimer produces the time stamps required for time-based UUIDs.
* It works as outlined in the UUID specification, with following
* implementation:
*
*- Java classes can only product time stamps with maximum resolution
* of one millisecond (at least before JDK 1.5).
* To compensate, an additional counter is used,
* so that more than one UUID can be generated between java clock
* updates. Counter may be used to generate up to 10000 UUIDs for
* each distinct java clock value.
*
- Due to even lower clock resolution on some platforms (older
* Windows versions use 55 msec resolution), timestamp value can
* also advanced ahead of physical value within limits (by default,
* up 100 millisecond ahead of reported), if necessary (ie. 10000
* instances created before clock time advances).
*
- As an additional precaution, counter is initialized not to 0
* but to a random 8-bit number, and each time clock changes, lowest
* 8-bits of counter are preserved. The purpose it to make likelyhood
* of multi-JVM multi-instance generators to collide, without significantly
* reducing max. UUID generation speed. Note though that using more than
* one generator (from separate JVMs) is strongly discouraged, so
* hopefully this enhancement isn't needed.
* This 8-bit offset has to be reduced from total max. UUID count to
* preserve ordering property of UUIDs (ie. one can see which UUID
* was generated first for given UUID generator); the resulting
* 9500 UUIDs isn't much different from the optimal choice.
*
- Finally, as of version 2.0 and onwards, optional external timestamp
* synchronization can be done. This is done similar to the way UUID
* specification suggests; except that since there is no way to
* lock the whole system, file-based locking is used. This works
* between multiple JVMs and Jug instances.
*
*
*Some additional assumptions about calculating the timestamp:
*
*- System.currentTimeMillis() is assumed to give time offset in UTC,
* or at least close enough thing to get correct timestamps. The
* alternate route would have to go through calendar object, use
* TimeZone offset to get to UTC, and then modify. Using currentTimeMillis
* should be much faster to allow rapid UUID creation.
*
- Similarly, the constant used for time offset between 1.1.1970 and
* start of Gregorian calendar is assumed to be correct (which seems
* to be the case when testing with Java calendars).
*
*
* Note about synchronization: main synchronization point (as of version
* 3.1.1 and above) is {@link #getTimestamp}, so caller need not
* synchronize access explicitly.
*/
public class UUIDTimer
{
private final LoggerFacade _logger = LoggerFacade.getLogger(getClass());
// // // Constants
/**
* Since System.longTimeMillis() returns time from january 1st 1970,
* and UUIDs need time from the beginning of gregorian calendar
* (15-oct-1582), need to apply the offset:
*/
private final static long kClockOffset = 0x01b21dd213814000L;
/**
* Also, instead of getting time in units of 100nsecs, we get something
* with max resolution of 1 msec... and need the multiplier as well
*/
private final static int kClockMultiplier = 10000;
private final static long kClockMultiplierL = 10000L;
/**
* Let's allow "virtual" system time to advance at most 100 milliseconds
* beyond actual physical system time, before adding delays.
*/
private final static long kMaxClockAdvance = 100L;
// // // Configuration
/**
* Object used to reliably ensure that no multiple JVMs
* generate UUIDs, and also that the time stamp value used for
* generating time-based UUIDs is monotonically increasing
* even if system clock moves backwards over a reboot (usually
* due to some system level problem).
*
* See {@link TimestampSynchronizer} for details.
*/
protected final TimestampSynchronizer _syncer;
/**
* Random number generator used to generate additional information
* to further reduce probability of collisions.
*/
protected final Random _random;
/**
* Clock used to get the time when a timestamp is requested.
*
* @since 3.3
*/
protected final UUIDClock _clock;
// // // Clock state:
/**
* Additional state information used to protect against anomalous
* cases (clock time going backwards, node id getting mixed up).
* Third byte is actually used for seeding counter on counter
* overflow.
* Note that only lowermost 16 bits are actually used as sequence
*/
private int _clockSequence;
/**
* Last physical timestamp value System.currentTimeMillis()
* returned: used to catch (and report) cases where system clock
* goes backwards. Is also used to limit "drifting", that is, amount
* timestamps used can differ from the system time value. This value
* is not guaranteed to be monotonically increasing.
*/
private long _lastSystemTimestamp = 0L;
/**
* Timestamp value last used for generating a UUID (along with
* {@link #_clockCounter}. Usually the same as
* {@link #_lastSystemTimestamp}, but not always (system clock
* moved backwards). Note that this value is guaranteed to be
* monotonically increasing; that is, at given absolute time points
* t1 and t2 (where t2 is after t1), t1 <= t2 will always hold true.
*/
private long _lastUsedTimestamp = 0L;
/**
* First timestamp that can NOT be used without synchronizing
* using synchronization object ({@link #_syncer}). Only used when
* external timestamp synchronization (and persistence) is used,
* ie. when {@link #_syncer} is not null.
*/
private long _firstUnsafeTimestamp = Long.MAX_VALUE;
/**
* Counter used to compensate inadequate resolution of JDK system
* timer.
*/
private int _clockCounter = 0;
public UUIDTimer(Random rnd, TimestampSynchronizer sync) throws IOException
{
this(rnd, sync, UUIDClock.systemTimeClock());
}
/**
* @param rnd Random-number generator to use
* @param sync Synchronizer needed for multi-threaded timestamp access
* @param clock Provider for milli-second resolution timestamp
*
* @throws IOException if initialization of {@code sync} fails due to problem related
* to reading of persisted last-used timestamp
*
* @since 3.3
*/
public UUIDTimer(Random rnd, TimestampSynchronizer sync, UUIDClock clock) throws IOException
{
_random = rnd;
_syncer = sync;
_clock = clock;
initCounters(rnd);
_lastSystemTimestamp = 0L;
// This may get overwritten by the synchronizer
_lastUsedTimestamp = 0L;
/* Ok, now; synchronizer can tell us what is the first timestamp
* value that definitely was NOT used by the previous incarnation.
* This can serve as the last used time stamp, assuming it is not
* less than value we are using now.
*/
if (sync != null) {
long lastSaved = sync.initialize();
if (lastSaved > _lastUsedTimestamp) {
_lastUsedTimestamp = lastSaved;
}
}
/* Also, we need to make sure there are now no safe values (since
* synchronizer is not yet requested to allocate any):
*/
_firstUnsafeTimestamp = 0L; // ie. will always trigger sync.update()
}
private void initCounters(Random rnd)
{
/* Let's generate the clock sequence field now; as with counter,
* this reduces likelihood of collisions (as explained in UUID specs)
*/
_clockSequence = rnd.nextInt();
/* Ok, let's also initialize the counter...
* Counter is used to make it slightly less likely that
* two instances of UUIDGenerator (from separate JVMs as no more
* than one can be created in one JVM) would produce colliding
* time-based UUIDs. The practice of using multiple generators,
* is strongly discouraged, of course, but just in case...
*/
_clockCounter = (_clockSequence >> 16) & 0xFF;
}
public int getClockSequence() {
return (_clockSequence & 0xFFFF);
}
/**
* Method that constructs unique timestamp suitable for use for
* constructing UUIDs. Default implementation is fully synchronized;
* sub-classes may choose to implement alternate strategies but
* due to existing usage and expectations should also be synchronized
* unless usage is specifically known not to require it.
*
* @return 64-bit timestamp to use for constructing UUID
*/
public synchronized long getTimestamp()
{
long systime = _clock.currentTimeMillis();
/* Let's first verify that the system time is not going backwards;
* independent of whether we can use it:
*/
if (systime < _lastSystemTimestamp) {
_logger.warn("System time going backwards! (got value %d, last %d)",
systime, _lastSystemTimestamp);
// Let's write it down, still
_lastSystemTimestamp = systime;
}
/* But even without it going backwards, it may be less than the
* last one used (when generating UUIDs fast with coarse clock
* resolution; or if clock has gone backwards over reboot etc).
*/
if (systime <= _lastUsedTimestamp) {
/* Can we just use the last time stamp (ok if the counter
* hasn't hit max yet)
*/
if (_clockCounter < kClockMultiplier) { // yup, still have room
systime = _lastUsedTimestamp;
} else { // nope, have to roll over to next value and maybe wait
long actDiff = _lastUsedTimestamp - systime;
long origTime = systime;
systime = _lastUsedTimestamp + 1L;
_logger.warn("Timestamp over-run: need to reinitialize random sequence");
/* Clock counter is now at exactly the multiplier; no use
* just anding its value. So, we better get some random
* numbers instead...
*/
initCounters(_random);
/* But do we also need to slow down? (to try to keep virtual
* time close to physical time; i.e. either catch up when
* system clock has been moved backwards, or when coarse
* clock resolution has forced us to advance virtual timer
* too far)
*/
if (actDiff >= kMaxClockAdvance) {
slowDown(origTime, actDiff);
}
}
} else {
/* Clock has advanced normally; just need to make sure counter is
* reset to a low value (need not be 0; good to leave a small
* residual to further decrease collisions)
*/
_clockCounter &= 0xFF;
}
_lastUsedTimestamp = systime;
/* Ok, we have consistent clock (virtual or physical) value that
* we can and should use.
* But do we need to check external syncing now?
*/
if (_syncer != null && systime >= _firstUnsafeTimestamp) {
try {
_firstUnsafeTimestamp = _syncer.update(systime);
} catch (IOException ioe) {
throw new RuntimeException("Failed to synchronize timestamp: "+ioe);
}
}
/* Now, let's translate the timestamp to one UUID needs, 100ns
* unit offset from the beginning of Gregorian calendar...
*/
systime *= kClockMultiplierL;
systime += kClockOffset;
// Plus add the clock counter:
systime += _clockCounter;
// and then increase
++_clockCounter;
return systime;
}
/**
* Converts a UUID v1 or v6 timestamp (where unit is 100 nanoseconds),
* to Unix epoch timestamp (milliseconds since 01-Jan-1970 UTC)
*
* @param timestamp Timestamp used to create UUID versions 1 and 6
*
* @return Unix epoch timestamp
*
* @since 5.1
*/
public static long timestampToEpoch(long timestamp) {
return (timestamp - kClockOffset) / kClockMultiplierL;
}
/*
/**********************************************************************
/* Test-support methods
/**********************************************************************
*/
/* Method for accessing timestamp to use for creating UUIDs.
* Used ONLY by unit tests, hence protected.
*/
protected final void getAndSetTimestamp(byte[] uuidBytes)
{
long timestamp = getTimestamp();
uuidBytes[UUIDUtil.BYTE_OFFSET_CLOCK_SEQUENCE] = (byte) _clockSequence;
uuidBytes[UUIDUtil.BYTE_OFFSET_CLOCK_SEQUENCE+1] = (byte) (_clockSequence >> 8);
// Time fields aren't nicely split across the UUID, so can't just
// linearly dump the stamp:
int clockHi = (int) (timestamp >>> 32);
int clockLo = (int) timestamp;
uuidBytes[UUIDUtil.BYTE_OFFSET_CLOCK_HI] = (byte) (clockHi >>> 24);
uuidBytes[UUIDUtil.BYTE_OFFSET_CLOCK_HI+1] = (byte) (clockHi >>> 16);
uuidBytes[UUIDUtil.BYTE_OFFSET_CLOCK_MID] = (byte) (clockHi >>> 8);
uuidBytes[UUIDUtil.BYTE_OFFSET_CLOCK_MID+1] = (byte) clockHi;
uuidBytes[UUIDUtil.BYTE_OFFSET_CLOCK_LO] = (byte) (clockLo >>> 24);
uuidBytes[UUIDUtil.BYTE_OFFSET_CLOCK_LO+1] = (byte) (clockLo >>> 16);
uuidBytes[UUIDUtil.BYTE_OFFSET_CLOCK_LO+2] = (byte) (clockLo >>> 8);
uuidBytes[UUIDUtil.BYTE_OFFSET_CLOCK_LO+3] = (byte) clockLo;
}
/*
/**********************************************************************
/* Private methods
/**********************************************************************
*/
private static final int MAX_WAIT_COUNT = 50;
/**
* Simple utility method to use to wait for couple of milliseconds,
* to let system clock hopefully advance closer to the virtual
* timestamps used. Delay is kept to just a millisecond or two,
* to prevent excessive blocking; but that should be enough to
* eventually synchronize physical clock with virtual clock values
* used for UUIDs.
*
* @param actDiff Number of milliseconds to wait for from current
* time point, to catch up
*/
protected void slowDown(long startTime, long actDiff)
{
/* First, let's determine how long we'd like to wait.
* This is based on how far ahead are we as of now.
*/
long ratio = actDiff / kMaxClockAdvance;
long delay;
if (ratio < 2L) { // 200 msecs or less
delay = 1L;
} else if (ratio < 10L) { // 1 second or less
delay = 2L;
} else if (ratio < 600L) { // 1 minute or less
delay = 3L;
} else {
delay = 5L;
}
_logger.warn("Need to wait for %d milliseconds; virtual clock advanced too far in the future", delay);
long waitUntil = startTime + delay;
int counter = 0;
do {
try {
Thread.sleep(delay);
} catch (InterruptedException ie) { }
delay = 1L;
/* This is just a sanity check: don't want an "infinite"
* loop if clock happened to be moved backwards by, say,
* an hour...
*/
if (++counter > MAX_WAIT_COUNT) {
break;
}
} while (System.currentTimeMillis() < waitUntil);
}
}