While working on a memory benchmark of some high-throughput data structures, I realized I could use an ImmutableMap with only a little refactoring.

Thinking this would be an improvement, I threw it into the mix and was surprised to discover that not only was it slower than HashMap, in a single-threaded environment it appears to be consistently slower even than ConcurrentHashMap!

You can see the full benchmark

The meat of the test is pretty simple, time how long it takes to get a large number of random strings that may exist in the map.

public static void timeAccess(Map<String,String> map) {
    Random rnd = new Random(seed);
    int foundCount = 0;

    long start = System.nanoTime();

    for(int i = 0; i < loop; i++) {
        String s = map.get(RndString.build(rnd));
        if(s != null)

    long stop = System.nanoTime() - start;

    System.out.println("Found "+foundCount+" strings out of "+loop+" attempts - "+
        String.format("%.2f",100.0*foundCount/loop)+" success rate.");
    System.out.println(map.getClass().getSimpleName()+" took "+
        String.format("%.4f", stop/1_000_000_000.0)+" seconds.");

And running this against a HashMap, a ConcurrentHashMap, and an ImmutableMap, all containing the same values, consistently showed a dramatic slowdown when using ImmutableMap - often upwards of 15% slower. The more sparse the map (i.e. the more often map.get() returned null) the greater the disparity. Here's the result of a sample run:

Found 35312152 strings out of 100000000 attempts - 35.31 success rate.
HashMap took 29.4538 seconds.

Found 35312152 strings out of 100000000 attempts - 35.31 success rate.
ConcurrentHashMap took 32.1465 seconds.

Found 35312152 strings out of 100000000 attempts - 35.31 success rate.
RegularImmutableMap took 37.9709 seconds.

Is this a documented / expected issue? The Guava Docs indicate Immutable*** is more memory efficient, but says nothing about speed. For slowdowns of this magnitude, I'm inclined to deal with the memory costs and avoid Immutable*** when speed is an issue (and when isn't it?!). Am I missing something?

See also: https://groups.google.com/forum/?fromgroups=#!topic/guava-discuss/I7yPpa5Hlpg

  • 11
    The issues mentioned in that mailing list thread definitely still apply to your benchmarks. Additionally, see the ImmutableMap Javadoc: "unlike HashMap, ImmutableMap is not optimized for element types that have slow Object.equals(java.lang.Object) or Object.hashCode() implementations. You can get better performance by having your element type cache its own hash codes, and by making use of the cached values to short-circuit a slow equals algorithm." That is certainly an issue with String. Finally, the ImmutableMap implementation is largely the same as HashMap's. Apr 2, 2013 at 6:40
  • If you like, you can experiment with some of Guava's benchmarks: code.google.com/p/guava-libraries/source/browse/guava-tests/… Apr 2, 2013 at 6:43
  • Also, "dealing with the memory costs" may result in significantly increased GC load, which can slow down your program just as much as a slower but more compact implementation. There's really no substitute for profiling with your specific real-world application. Apr 2, 2013 at 6:45
  • @LouisWasserman #1 - String has inefficient equals() and hashCode() methods? That seems like a huge issue - it's the primary type used as a map key... My impression looking at the code was that ImmutableMap is largely similar to HashMap like you said, but the access times I'm seeing don't agree. #2 thanks, I'll take a look at that.
    – dimo414
    Apr 2, 2013 at 12:48
  • 3
    #1: String has a linear-time equals method -- I wouldn't call that a "huge issue," it's just the laws of algorithms -- and it doesn't use its hashCode cache to short-circuit, which is...not ideal, but arguable either way. #3: granted, that's true for your use case, but ImmutableMap is optimized to be a generalist, to be good-if-not-perfect at many different use cases. (For example, Android applications benefit significantly from ImmutableMap's compact design.) Apr 2, 2013 at 15:21

2 Answers 2


As Louis Wasserman said, ImmutableMap is not optimized for objects with slow equals method. I think the main difference is here:


if (e.hash == hash && ((k = e.key) == key || key.equals(k)))
    return e.value;


if (key.equals(candidateKey)) {
    return entry.getValue();

As you can see, to check for collisions, HashMap first check the hashes. This allows to reject values with different hashes fast. Since String doesn't make this check in its equals method, this makes HashMap faster. ImmutableMap doesn't use this optimization because it would make the test slower when equals is already optimized.

  • Ah, that makes more sense, I understand what he was saying. Fascinating that String caches the hash value in String.hashCode() but doesn't take advantage of that data in String.equals()...
    – dimo414
    Apr 30, 2013 at 16:55
  • 2
    This definitely seems to be a large part of the issue, adding a Holder wrapper to the key that caches the object's hash code dropped the ImmutableMap's time from ~35 seconds to ~32. Yet HashMap still performed measurably faster at ~28 seconds. It seems Guava's assumption that keys will/should be well-behaved is a pretty poor one if String, vastly the most common map key, doesn't fit that assumption.
    – dimo414
    Apr 30, 2013 at 18:59

Some possible reasons:

  1. Could that depend on your implementation of RndString.build()?

  2. And have a look at the get() implementation of both maps: com.google.common.collect.RegularImmutableMap.get(Object) java.util.HashMap.getEntry(Object) java.util.HashMap tries to compare with "==" first. RegularImmutableMap doesn't. That may speed up

  3. Could a different load factor be responsible for that? Perhaps the RegularImmutableMap needs more iterations to find the correct entry.

  • 1. There's a link to the full code in my question. RndString.build() should use minimal memory and always uses the same seed for map access. It certainly could cause some bias, but I'm not aware of how.
    – dimo414
    Apr 7, 2013 at 2:31
  • 2. Good point, but RegularImmutableMap.get() says the following: "If we did [an == check], it would just make things worse for the most performance-conscious [equals methods]". Since String.equals() first does an == check, it (supposedly) should be faster than == && .equals()
    – dimo414
    Apr 7, 2013 at 2:37
  • 3. It's certainly possible (HashMap defaults to .75 where ImmutableMap dynamically picks a value no larger than 1.2) however even changing my buildMap() method to use new HashMap<>(16,1.2f) which should be worse than ImmutableMap's implementation, HashMap was still notably faster, if slightly slower than the original benchmark. Also worth noting the comment in RegularImmutableMap that says "Closed addressing tends to perform well even with high load factors.... [T]he table is still likely to be relatively sparse (hence it misses fast) while saving space."
    – dimo414
    Apr 7, 2013 at 2:51

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