5

I know that Hashtable is synchronized so it is safe to be used in multithread app and HashMap is not.

I am wondering if there is any performance difference between these two in a single thread app.

(Or, when to use one over the other?)

3
  • Are you talking about a specific language/library? If yes, which one?
    – svick
    Jul 1, 2011 at 20:50
  • 2
    Hashtable isn't inherently safe to use with mutlithreaded access -- only the methods are synchronized; it does not implicitly create any larger atomic constructs which may be required. Consider also Collections.synchronizedMap to get Hashtable-like semantics from a HashMap.
    – user166390
    Jul 1, 2011 at 20:53
  • It's tagged as Java (it may not have been when you asked).
    – Zéychin
    Jul 1, 2011 at 20:53

7 Answers 7

5

If you want a thread safe collection you can use ConcurrentHashMap or Collections.synchronizedMap() with LinkedHashMap or HashMap. If you don't need a thread safe collection you can use just the last two. Hashtable has been retro fitted to support Map with generics but it also comes with alot of legacy methods which do the same thing or much the same thing.

Hashtable can be used, however IMHO using one of the many other options which have been developed later would be a cleaner solution. If you have a library which needs a Hashtable, then you need to use it, but otherwise I would use a class which does what you need, follows best practice with a minimum of legacy methods.

The performance difference is likely to be about 0.5 us per call. This may or may not be significant.

However, if you don't need a type to be thread safe, there is no good reason to use the synchronized version. If you need a type to be thread safe, you can't use a type which is not without some thread safety guard.

2
  • 1
    But Hashtable has been retrofitted with generics and conforms to Map<K,V> -- how is it (currently) legacy then?
    – user166390
    Jul 1, 2011 at 21:25
  • I need to clarify what I mean. Jul 2, 2011 at 10:59
5

Differences

  • HashMap allows null values, Hashtable doesn't.
  • Hashtable is synchronized, HashMap is not. (But it can still be used for multithreaded reads if it is not modified, f.e. - initialize once on start and only read from it for some static caches)

Performance

Here are some single-thread tests to compare them. 5 tries of 100 mill ops (1st try may be considered warm-up) put is 100% collisions, get is 50% hits.

1 HashMap put/get -->   419.80  /   354.09  ms
2 HashMap put/get -->   983.02  /   305.54  ms
3 HashMap put/get -->   976.26  /   358.72  ms
4 HashMap put/get -->   989.04  /   375.18  ms
5 HashMap put/get -->   974.13  /   360.73  ms

1 Hashtable put/get -->   776.97  /   708.39  ms
2 Hashtable put/get -->   776.26  /   736.23  ms
3 Hashtable put/get -->   794.01  /   740.07  ms
4 Hashtable put/get -->   784.23  /   734.40  ms
5 Hashtable put/get -->   782.45  /   729.48  ms

1 Synced-HashMap put/get -->  1523.61  /  1215.63  ms
2 Synced-HashMap put/get -->  1491.59  /  1090.83  ms
3 Synced-HashMap put/get -->  1442.67  /  1095.62  ms
4 Synced-HashMap put/get -->  1439.19  /  1082.57  ms
5 Synced-HashMap put/get -->  1450.04  /  1101.53  ms
  • Single-thread
    HashMap is generally faster. Its get is 2x faster than Hashtable. However, its put is 25% slower.
  • Concurrent use
    Hashtable if no null values are required, or Collections.synchronizedMap(new HashMap<>()) if nulls are required. Note that Synchronized-HashMap is slower than Hashtable (puts 2x slower, gets 50% slower)

The code used for the test as a JUnit:

import java.util.Collections;
import java.util.HashMap;
import java.util.Hashtable;
import java.util.Map;

import org.junit.Test;

public class MapsPerfTest {

    @Test
    public void testMaps() {
        testMap("HashMap", new HashMap<>());
        testMap("Hashtable", new Hashtable<>());
        testMap("Synced-HashMap", Collections.synchronizedMap(new HashMap<>()));
    }

    void testMap(String name, Map<Integer, String> h) {
        for(int i=1; i<=tries; ++i) {
            long t1 = timeit(() -> testMapPut(h));
            long t2 = timeit(() -> testMapGet(h));
            System.out.println(String.format("%d %s put/get -->  %7.2f  /  %7.2f  ms",
                    i, name, t1/1000/1000.0, t2/1000/1000.0));
        }
    }

    long timeit(Runnable r) {
        System.gc();
        long t = System.nanoTime();
        r.run();
        return System.nanoTime() - t;
    }

    static final int tries = 5;
    static final int count = 100000000;

    static final String VALUE = "-";

    static final int putSpace = 100;
    static final int getSpace = putSpace*2;
    static final Integer[] numbers = new Integer[getSpace+1];

    static {
        for(int i=getSpace; i>=0; --i)
            numbers[i] = i;
    }

    void testMapPut(Map<Integer, String> m) {
        for(int i=count; i>0; --i)
            m.put(numbers[i%putSpace], VALUE);
    }

    void testMapGet(Map<Integer, String> m) {
        for(int i=count; i>0; --i)
            m.get(numbers[i%getSpace]);
    }
}
2

Taking what @svick mentions in the comment. If you are talking about the Hashtable and HashMap included with the Java SDK, there is definitely a performance difference, as HashMap doesn't have to use the synchronized blocks, which have an overhead.

As per pst's request, here is some reading about synchronized performance and here is something a bit more recent, regarding Java 1.4 vs Java 6 on one machine.

5
  • But what is the overhead in a non-contention environment? Have benchmarks or a link to such? :)
    – user166390
    Jul 1, 2011 at 20:53
  • even though hashtable is used in a single thread app, will there be a significant performance issue?
    – caesarkim
    Jul 1, 2011 at 20:55
  • @pst: ibm.com/developerworks/java/library/j-threads1/index.html That said, I was simply suggesting that of course there will be additional overhead, even if it is mostly trivial... Jul 1, 2011 at 20:57
  • @nicholas.hauschild So no more than 2x overhead (but most average of less than 1.5) over 10,000,000 iterations on very old VMs :-) Retrieving values is also <= the cost of an update, so overall the overhead should be even less than recorded there. Nice article find, however.
    – user166390
    Jul 1, 2011 at 21:00
  • Note that those overheads are for empty methods, and that the article is dated 2001.
    – user207421
    Jul 3, 2011 at 4:15
1

Since Java 7 claims that it may do escape analysis, and remove uncontended sync in some cases, I gave it a test

public static void main(String[] args)
{
    for(int i=0; i<100; i++)
    {
        System.out.println("-------------------");
        testS();
    }
}
static int N = 100_000_000;
static void testS()
{
    Object o = new Object();
    long t0 = System.nanoTime();
    for(int i=0; i<N; i++)
        synchronized (o){}
    long t = System.nanoTime() - t0;
    System.out.printf("time: %,d%n", t);
}

I can't think of a simpler example for escape analysis. However, obviously Java 7 does not optimize the sync off in my test; each synchronized (o){} consume some time.

Amazingly, it only consumes about 1 CPU cycle, which is too fast to believe. It should contain at least two compare-and-set instructions; accessing L1 cache normally takes 10 cycles. Apparently there's some hardware optimization kicking in.

This is a tight loop, not real application. It's too difficult to discuss real apps in general; difficult to analyze even for a concrete application. Then we probably should prefer HashMap if possible, which at least won't be slower than Hashtable in any case, as far as we know.

2
  • This might not be escape analysis, but rather loop removal...?
    – user166390
    Jul 1, 2011 at 22:36
  • it needs escape analysis first, to reason that o is not visible to anyone else, so synchronized(o) has no effect, before it can remove the statement. Jul 1, 2011 at 23:22
0

Yes. That's the (one of) the points of HashMap not being synchronized by default (use synchronizedMap() to make it synchronized; although note that depending on your usage, just simple synchronization may not be enough to keep integrity over all operations you might want to do).

2
  • Very true. Any benchmarks (or other reasons) to argue use of one over the other? ;-) What about a SynchronizedMap (created with Collections.synchronizedMap) vs Hashtable?
    – user166390
    Jul 1, 2011 at 20:55
  • I imagine the numbers will differ by JVM vendor, and a well optimized implementation is probably not going to be a big overhead, however, I can't imagine an implementation that has no overhead that is actually correct. As far as I know synchronizedMap() just makes operations on the Map synchronized in the same way a Hashtable does, so I'd imagine it is similar. (Note that there are other differences between Hashtable and HashMap related to storing/retrieving nulls - the API javadoc covers it I think). Jul 1, 2011 at 21:01
0

I would be astonished if you could even measure a difference in a real-world test. If you measure zillions of operations, maybe, but you won't be doing zillions, you'll be hard pressed to attain even the first million.

0

If have no numbers on Hashtable vs. HashMap, but some years ago I compared Vector with ArrayList, where there is a similar issue.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.