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I have been observing the heap-add function

void add(double a, int b);

to run slower than

void add(Double a, Integer b);

but it is expected to be the other way around. Unboxed types must always be faster. I have made sure the data does not get boxed later either. None of my Hotspot debugging approaches led to any insight.

Update: With Java 8, the nicer code (using primitives) is finally as fast as the ugly code with wasted Objects. If you are seeing a similar thing, try Java 8 or any other newer JDK. Apparently I have been bitten by a particularly bad JDK version. Switching to a different JDK (including debugging versions of Java 7) made the problem go away.

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Could it be that without the boxing, the JITter doesn't see it as a bottleneck and doesn't try to optimise it at all or not as hard? – Daniel Fischer Sep 23 '12 at 15:30
Well, even if it recognizes the extra add(DoubleDistance, id) as bottleneck, the optimization would likely still need to call the same add(double, id) function after optimization. :-( – Anony-Mousse Sep 23 '12 at 15:34
Notice that double takes 64 bit while object reference to DoubleDistance only 32 (on 32-bit JVM and 64 bit with compressed pointers). Allocation is cheap, maybe smaller amount of data on stack is improving performance? – Tomasz Nurkiewicz Sep 23 '12 at 15:36
I'm using Linux, there is no client VM for Linux/amd64. My benchmark JVM (that I use for regression testing) settings are: -Xshare:off -XX:+UseFastAccessorMethods -XX:CompileThreshold=1000 -XX:+AggressiveOpts. I havn't benchmarked with default settings yet, I will do so later. I will also try openjdk 7, because apparently the benchmarking system is running openjdk 6. Sharing the full code is messy because of all the dependencies. The heap is actually 4 times subclassed adding the functionality needed. But in particular, the faster "add" method is really only doing unboxing. – Anony-Mousse Sep 24 '12 at 7:48
Can you paste the compiled bytecode snippets for each method you are benchmarking? Also, If you run in interpreted mode using '-Xint', do you see the same result? These two pieces of information will either point towards the Java source to bytecode compiler or the JIT. – James Branigan Sep 24 '12 at 8:46

The code

heap.add(distance, id);

actually compiles to

heap.add(Double.valueOf(distance), id);

where Double.valueOf() is:

public static Double valueOf(double d) {
    return new Double(d);

Since you do only method calls where (-> no other expensive operations), the cost of the method calls is important. I'm a bit surprised, though, that JIT can't optimize the method call away since Double is final.

The second effect is that you can't access the value directly anymore. I'm pretty sure the JIT can't optimize the indirection away so every time you use the value, an additional pointer de-reference will happen.

This is one of the limitations of Java's autoboxing. I don't know a solution which will magically fix this. You will probably have to write new Double() in a few places to preserve performance or change the API to work with double primitives.

Another solution is to always use the type Double so you rarely have to convert (and most conversions will be downcasts to double which are pretty fast). But that will only save the upcast; you still need to create thousands of Double instances (they aren't cached) and you will pay for the indirect value access each time you use it.

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There is an add(double, id) method, too. There is no auto-boxing happening here. Profiling shows this, there are no Double object allocated in a full hprof run. – Anony-Mousse Sep 24 '12 at 12:48
Please try to achieve the same effect with a minimal example (just the 2-5 methods involved). I think something else happens here. – Aaron Digulla Sep 24 '12 at 12:52
So far my isolated test code does not show this effect. Obviously it has a much less deep call stack. – Anony-Mousse Sep 24 '12 at 16:10
In that case, the code inside of add(double) and add(Double) must be different. What happens if you move the common code into a new method? – Aaron Digulla Sep 24 '12 at 16:13
The code in add(Double) just calls add(double) - that is where the common code already is... – Anony-Mousse Sep 24 '12 at 16:17

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