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I have a web based Java application that generates random UUIDs for session information. One of our testers is claiming up to 350ms to generate UUIDs based upon his own profiling, but I have not yet been able to replicate his results. He points to this article http://www.cowtowncoder.com/blog/archives/2010/10/entry_429.html to help back up his results. I wanted to see if anyone else has ran into this limitation with Java's built-in UUID generation capability in either Java 6 or Java 7 applications.

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350ms to generate one UUID? How is he backing that up with the article you are linking to? –  jarnbjo Jan 26 '13 at 1:52
    
It is the profiling tool he is using. I haven't been able to replicate on my end yet. That is why I wanted to check to see if there is a similar problem anyone else has experienced. It could be an issue with a profiling tool or maybe it be an odd combination of Java with runtime environment. It seemed odd to me as well. –  Shawn H Jan 26 '13 at 2:14
    
Once again: Does he claim that it takes 350ms to generate one UUID (as you write UUIDs in plural, without actually specifying how many)? How is he backing that up with the article you are linking to? There is nothing in that article suggesting that the UUID generator is so slow. Another question: Which OS is the tester running it's test on? Java on Linux uses the /dev/urandom generator, which can be rather slow if there is not much activity (e.g. user input or network traffic) on that system. –  jarnbjo Jan 26 '13 at 2:23
    
The claim was 350ms to generate a single UUID. Our default systems are Macbook Pros running Mountain Lion. Production systems are the latest version of CentOS. –  Shawn H Jan 26 '13 at 2:30
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6 Answers

up vote 2 down vote accepted

I tested it

    for (;;) {
        long t0 = System.currentTimeMillis();
        for (int i = 0; i < 1000000; i++) {
            UUID.randomUUID();
        }
        System.out.println(System.currentTimeMillis() - t0);
    }

on my PC it is ~1100 ms, which is pretty slow. UUID.randomUUID() uses SecureRandom internally, to make it faster we can use regular java.util.Random

    Random r = new Random();
    for (;;) {
            ..
            new UUID(r.nextLong(), r.nextLong());

it's ~80 ms

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Those numbers don't pass the smell test. 1110ms to generate 1 million random UUIDs sounds way fast. But 1110ms to generat 1 UUID sounds way too slow. –  Stephen C Jan 26 '13 at 7:36
    
By me the speed of both methods is similar, but it's the Windows machine. –  Łukasz 웃 L ツ Jan 26 '13 at 18:37
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The random form of UUID requires a source of "cryptography strength" random numbers. (If it didn't then there could be the probability that a given UUID is reissued could increase to worrying levels.)

Typical crypto-strength random number generators use a source of entropy that is external to the application. It might be a hardware random number generator, but more commonly it is accumulated "randomness" that is harvested by the operating system in normal operation. The problem is that sources of entropy have a rate limit. If you exceed that rate over a period of time, you can drain the source. What happens next is system dependent, but on some systems the syscall to read entropy will stall ... until more is available.

I expect that is what is happening on your client's system.

One workaround (for Linux systems) is to install the rngd daemon and configure it to "top up" the entropy pool using a pseudo-random number generator. The downside is that this might compromise your UUID generator's randomness.

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I think we have run into the "lack of entropy" problem as well. The UUID generation starts out fast but after a few hours can come to a crawl. Running on a headless VM may be contributing to the problem as the OS has less sources of entropy. See stackoverflow.com/questions/137212/… for more info. –  Mike Hopper Sep 18 '13 at 9:08
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A junit test run under jdk 1.7.0_40:

package org.corba.util;

import org.junit.Test;
import org.springframework.util.StopWatch;

import java.util.UUID;

/**
 * Test of performance of Java's UUID generation
 * @author Corba Da Geek
 * Date: 1/6/14
 * Time: 3:48 PM
 */
public class TestRandomUUID {
    private static final int ITERATIONS = 1000000;

    @Test
    public void testRandomUUID() throws Exception {
        // Set up data
        StopWatch stopWatch = new StopWatch();
        stopWatch.start();

        // Run test
        for (int i = 0; i < ITERATIONS; i++)
            UUID.randomUUID();

        // Check results
        stopWatch.stop();
        final long totalTimeMillis = stopWatch.getTotalTimeMillis();
        System.out.println("Number of milliseconds: " + totalTimeMillis + " for " + ITERATIONS + " iterations.");
        System.out.println(String.format("Average time per iteration: %.7f ms", (float)totalTimeMillis/ITERATIONS));
    }
}

And the results on my i5 laptop were:

-------------------------------------------------------
 T E S T S
-------------------------------------------------------
Running org.corba.util.TestRandomUUID
Number of milliseconds: 677 for 1000000 iterations.
Average time per iteration: 0.0006770 ms
Tests run: 1, Failures: 0, Errors: 0, Skipped: 0, Time elapsed: 0.746 sec

Results :

Tests run: 1, Failures: 0, Errors: 0, Skipped: 0

0.0006770 ms per invocation.

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Use Version 1 Instead of 4

How about using Version 1 type of UUID?

Version 1 is based on MAC address and current time ("space and time"). Much less likely to have collisions than Version 4.

Version 4 is based on entirely being generated from random numbers using a cryptographically strong random generator.

The Oracle JVM does not provide a Version 1 generator, apparently because of security and privacy concerns. The JVM does not provide access to the MAC address of host machine.

JUG Library

There is at least one third-party library available that doe provide Version 1 UUIDs, as well as other versions: JUG – Java UUID Generator. They say features introduced in Java 6 let them get access to the MAC address.

Test Results: 20x

Read a discussion of performance with test results using Java UUID Generator version 3 in the 2010 article, More on Java UUID Generator (JUG), a word on performance. Tatu Saloranta tested various kinds of UUIDs on his MacBook.

Upshot: MAC+Time version is 20 times faster that random version.

Time-based variant (Ethernet address plus timestamp) is much faster -- almost 20 times as fast as Random-based default variant -- generating about 5 million UUIDs per second.

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Here is a test run in beta 127.

Keep in mind that this test is unrealistic, beyond any worst-case scenario I can imagine. My goal was to quiet those who bad-mouth use of UUIDs without the facts to back up their criticism.

Scenario:

  • A tight loop of a million calls to java.util.UUID.randomUUID()
    • One test with just that alone. (no contention)
    • One test with contention, where 2 other threads are in a tight loop making ten million calls.
  • Java 8 beta 127
    • java version "1.8.0"
    • Java(TM) SE Runtime Environment (build 1.8.0-b127)
    • Java HotSpot(TM) 64-Bit Server VM (build 25.0-b69, mixed mode)
  • Run from Netbeans 7.4 IDE
  • Executing inside a virtual machine
  • Mac mini (late 2012)

Without Contention

Running one loop in one thread, so no contention over the synchronized methods/classes.

// Warm the random generator.
java.util.UUID uuid;
uuid = java.util.UUID.randomUUID();

long stop = 0;
long start = System.nanoTime();

int loops = 1000000;  // One million.
for ( int i = 0; i < loops; i++ ) {
    uuid = java.util.UUID.randomUUID();
}

stop = System.nanoTime();

long elapsed = ( stop - start );

System.out.println( "UUIDs: " + loops );
System.out.println( "Nanos: " + elapsed );
System.out.println( "Nanos per uuid: " + ( elapsed / loops ) + " ( millis per: " + ( elapsed / loops / 1000 ) + " )" );

Results

About 2 milliseconds per UUID.

With Contention

Similar to above, but while doing a loop of a million calls, we have two other threads running where each makes ten million calls.

// Warm the random generator.
java.util.UUID uuid;
uuid = java.util.UUID.randomUUID();

int pass = 10000000;  // Ten million.
MyThread t1 = new MyThread( pass );
MyThread t2 = new MyThread( pass );


t1.start();
t2.start();
t3.start();

long stop = 0;
long start = System.nanoTime();

int loops = 1000000;  // One million.
for ( int i = 0; i < loops; i++ ) {
    uuid = java.util.UUID.randomUUID();
}

stop = System.nanoTime();

long elapsed = ( stop - start );

System.out.println( "UUIDs: " + loops );
System.out.println( "Nanos: " + elapsed );
System.out.println( "Nanos per uuid: " + ( elapsed / loops ) + " ( millis per: " + ( elapsed / loops / 1000 ) + " )" );

And the class defining each thread…

class MyThread extends Thread {

    private int loops;

    public MyThread( int loops ) {
        this.loops = loops;
    }

    @Override
    public void run() {
        java.util.UUID uuid;
        for ( int i = 0; i < this.loops; i++ ) {
            uuid = java.util.UUID.randomUUID();
        }

    }
}

Results

About 20 milliseconds per UUID.

Runs were 14, 20, 20, 23, and 24 milliseconds per UUID (not in that order). So under extreme contention was only about 10 times worse, with 20 milliseconds being acceptable in any real-world usage I've known.

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The number of threads has a huge impact on the performance of the generation of UUIDs:

public class UuidGenerationInThreads {

     public static void main(final String[] args) throws Exception {
        final int[] numberOfThreads = {
            1, 20, 50, 100, 200, 500, 1000, 1200, 1500, 2000
        };
        final int N = 1000000;

        for (int indexOfThreads = 0, n = numberOfThreads.length; indexOfThreads < n; indexOfThreads++) {
            final int nThreads = numberOfThreads[indexOfThreads];
            System.out.printf("Testing with %4d thread(s)", nThreads);
            final ExecutorService executorService = Executors.newFixedThreadPool(nThreads);

            final CountDownLatch doneSignal = new CountDownLatch(N);

            final long t0 = System.currentTimeMillis();
            for (int i = 0; i < N; ++i) {
                executorService.execute(new Runnable() {
                    @Override
                    public void run() {
                        UUID.randomUUID();
                        doneSignal.countDown();
                    }
                });
            }
            doneSignal.await(); // wait for all to finish
            final long delta = System.currentTimeMillis() - t0;
            System.out.printf(" => took %6d ms for %6d iterations, %.7f ms per calculation\n", delta, N, (float) delta / N);
            executorService.shutdown();
        }
    }
}

This results to following output (iMac 2.5 GHz Intel Core i5 processor with 4 cores, 4 GB):

Testing with    1 thread(s) => took   3109 ms for 1000000 iterations, 0.0031090 ms per calculation
Testing with   20 thread(s) => took   4318 ms for 1000000 iterations, 0.0043180 ms per calculation
Testing with   50 thread(s) => took   4097 ms for 1000000 iterations, 0.0040970 ms per calculation
Testing with  100 thread(s) => took   4561 ms for 1000000 iterations, 0.0045610 ms per calculation
Testing with  200 thread(s) => took   5486 ms for 1000000 iterations, 0.0054860 ms per calculation
Testing with  500 thread(s) => took   9270 ms for 1000000 iterations, 0.0092700 ms per calculation
Testing with 1000 thread(s) => took   8553 ms for 1000000 iterations, 0.0085530 ms per calculation
Testing with 1200 thread(s) => took  11395 ms for 1000000 iterations, 0.0113950 ms per calculation
Testing with 1500 thread(s) => took  21563 ms for 1000000 iterations, 0.0215630 ms per calculation
Testing with 2000 thread(s) => took  28169 ms for 1000000 iterations, 0.0281690 ms per calculation

This can be explained by looking at the implementation of SecureRandom#nextBytes(byte[] which generates the random numbers for UUID.randomUUID():

synchronized public void nextBytes(byte[] bytes) {
    secureRandomSpi.engineNextBytes(bytes);
}

nextBytes is synchronized which leads to significant performance loss when accessed by a great number of threads as seen in my tests.

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