4

Are get(Key) method calls for a a standard HashMap and a ConcurrentHashMap equal in performance when no modifications happen for the underlaying Map (so only get() operations are performed.)

Update with Background:

Concurrency is quite a komplex topic: I do nead "concurrency/threadsafety" but only on puts, that happen extremely seldom. And for the puts I could swap the Map Associations itself (which is atomic and threadsafe). Therefore I am asking I am doing a lot of gets (and have the option to either implement it with a HashMap (create a temporary Hashmap, Copy Data into new HashMap, and swap association) or using a ConcurrentHashMap... As my App really doeas a lot of gets I want to learn more how performance is lost with both different gets. As silly this sounds, the internet has so much unnecessary information around but this is something I think could be of interest to a lot more people. So if someone knows the inner workings of ConcurrentHashMap for gets it would be great to answer the question.

Thanks very much!

  • 2
    ConcurrentHashMap is thread safe. That comes with an overhead for every operation on it. But you wouldn't notice the difference, unless your app spends 90% of its time retrieving values from it. – user684934 Jan 29 '12 at 3:29
  • Hello, why do I get a downvote? Please explain why! – user1145216 Jan 29 '12 at 3:30
  • Have you look at the API? It clearly states that writes are synchronized and retrievals aren't. What else is there to know? – blackcompe Jan 29 '12 at 6:34
  • the code for get in either case is not particularly complex, just read the code and make an informed decision – Matt Jan 29 '12 at 9:13
2

You could look at the source code. (I'm looking at JDK 6) HashMap.get() is pretty simple:

public V get(Object key) {
        if (key == null)
            return getForNullKey();
        int hash = hash(key.hashCode());
        for (Entry<K,V> e = table[indexFor(hash, table.length)];
             e != null;
             e = e.next) {
            Object k;
            if (e.hash == hash && ((k = e.key) == key || key.equals(k)))
                return e.value;
        }
        return null;
    }

Where hash() does some extra shifting and XORing to "improve" your hash code.

ConcurrentHashMap.get() is a bit more complex, but not a lot

public V get(Object key) {
    int hash = hash(key.hashCode());
    return segmentFor(hash).get(key, hash);
}

Again, hash() does some shifting and XORing. setMentFor(int hash) does a simple array lookup. The only complex stuff is in Segment.get(). But even that doesn't look like rocket science:

V get(Object key, int hash) {
   if (count != 0) { // read-volatile
      HashEntry<K,V> e = getFirst(hash);
      while (e != null) {
         if (e.hash == hash && key.equals(e.key)) {
            V v = e.value;
            if (v != null)
               return v;
            return readValueUnderLock(e); // recheck
          }
          e = e.next;
      }
 }
  return null;
}

The one place where is gets a lock is readValueUnderLock(). The comments say that this is technically legal under the memory model but never known to occur.

Overall, looks like the code is pretty similar for both. Just a bit better organized in ConcurrentHashMap. So I'd guess that the performance is similar enough.

That said, if puts really are extremely rare, you could consider implementing a "copy on write" type of mechanism.

3

You're asking the wrong question.

If you need concurrency, you need it no matter the performance impact.

A correctly behaving program almost always ranks more highly than a faster program. I say "almost always" because there may be business reasons to release software with bugs rather than holding back until the bugs are fixed.

2

According to the ConcurrentHashMap API, there is no locking for retrieval methods. So, I'd say they are equal in performance.

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