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When measuring elapsed time on a low level, I have the choice of using any of these:

System.currentTimeMillis();
System.nanoTime();

Both methods are implemented native. Before digging into any C code, does anyone know if there is any substantial overhead calling one or the other? I mean, if I don't really care about the extra precision, which one would be expected to be less CPU time consuming?

N.B: I'm using the standard Java 1.6 JDK, but the question may be valid for any JRE...

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1  
Be aware that nanoTime does not map to real time and should only be used for measuring how long something took. –  Powerlord Apr 12 '11 at 19:31
    
@R.Bemrose, thanks, I know. It's really for measuring how long something takes. –  Lukas Eder Apr 12 '11 at 19:40

6 Answers 6

up vote 19 down vote accepted

I don't believe you need to worry about the overhead of either. It's so minimal it's barely measurable itself. Here's a quick micro-benchmark of both:

for (int j = 0; j < 5; j++) {
    long time = System.nanoTime();
    for (int i = 0; i < 1000000; i++) {
        long x = System.currentTimeMillis();
    }
    System.out.println((System.nanoTime() - time) + "ns per million");

    time = System.nanoTime();
    for (int i = 0; i < 1000000; i++) {
        long x = System.nanoTime();
    }
    System.out.println((System.nanoTime() - time) + "ns per million");

    System.out.println();
}

And the last result:

14297079ns per million
29206842ns per million

It does appear that System.currentTimeMillis() is twice as fast as System.nanoTime(). However 29ns is going to be much shorter than anything else you'd be measuring anyhow. I'd go for System.nanoTime() for precision and accuracy since it's not associated with clocks.

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Nice benchmark. On my computer, it's the inverse though. I get this output: 17258920ns per million, 14974586ns per million. Which means it really depends on JVM's, processors, operating systems, etc. Apart from that the difference is almost irrelevant. Thanks for the nice answer! –  Lukas Eder Apr 12 '11 at 19:35
    
No problem. Yeah, I'm sure there are all sorts of factors that will make it vary. Either way it appears you'd have to be calling it millions of times per second on a modern machine for it to be causing a noticeable timing overhead. –  WhiteFang34 Apr 12 '11 at 19:40
    
Underlying OS would be interesting. I suspect that iif the implementation uses POSIX's clock_gettime(), the difference would be ~0. –  ninjalj Apr 12 '11 at 19:40
    
True. But your outer loop seems to show that the results are somewhat consistent on the same system. Apart from the first iteration, which may have some JVM overhead, all iterations produce roughly the same values... So it's safe to choose nanoTime() and get the little extra precision. –  Lukas Eder Apr 12 '11 at 19:42
    
@ninjalj: I'm using Windows 7. God knows how many MSDOS 6.23, Windows 3.11 for Workgroups, and Windows ME clocks are still running in parallel :) –  Lukas Eder Apr 12 '11 at 19:42

You should only ever use System.nanoTime() for measuring how long it takes something to run. It's not just a matter of the nanosecond precision, System.currentTimeMillis() is "wall clock time" while System.nanoTime() is intended for timing things and doesn't have the "real world time" quirks that the other does. From the Javadoc of System.nanoTime():

This method can only be used to measure elapsed time and is not related to any other notion of system or wall-clock time.

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Yes, I know the Javadoc mentions this. But both can be used equivalently if you measure things between 1-10ms lots of times. What do you mean by "real world time quirks"? –  Lukas Eder Apr 12 '11 at 19:31
3  
@Lukas: The problem is that System.currentTimeMillis() can (I believe) do things like insert small clock adjustments which would throw off timings. Rare, probably, but nanoTime() is intended for measurements that shouldn't be affected by that sort of thing. –  ColinD Apr 12 '11 at 19:37
    
that makes sense –  Lukas Eder Apr 12 '11 at 19:43
    
@Lukas: Actually, it basically just reflects the system time your computer shows. Change the date on your computer to a week ago during a timing using currentTimeMillis() and you'll get a nice negative number! =) Not so for nanoTime(). –  ColinD Apr 12 '11 at 19:45
1  
It's not just manually changing the time that you have to worry about. There is also daylight savings, and clocks that auto adjust themselves after checking with a server on the internet. –  Jonathan Feb 23 at 4:29

The answer marked correct on this page is actually not correct. That is not a valid way to write a benchmark because of JVM dead code elimination (DCE), on-stack replacement (OSR), loop unrolling, etc. Only a framework like Oracle's JMH micro-benchmarking framework can measure something like that properly. Read this post if you have any doubts about the validity of such micro benchmarks.

Here is a JMH benchmark for System.currentTimeMillis() vs System.nanoTime():

@BenchmarkMode(Mode.AverageTime)
@OutputTimeUnit(TimeUnit.NANOSECONDS)
@State(Scope.Benchmark)
public class NanoBench {
   @GenerateMicroBenchmark
   public long currentTimeMillis() {
      return System.currentTimeMillis();
   }

   @GenerateMicroBenchmark
   public long nanoTime() {
    return System.nanoTime();
   }
}

And here are the results (on an Intel Core i5):

Benchmark                            Mode  Samples      Mean   Mean err    Units
c.z.h.b.NanoBench.currentTimeMillis  avgt       16   122.976      1.748    ns/op
c.z.h.b.NanoBench.nanoTime           avgt       16   117.948      3.075    ns/op

Which shows that System.nanoTime() is slightly faster at ~118ns per invocation compared to ~123ns. However, it is also clear that once the mean error is taken into account, there is very little difference between the two. The results are also likely to vary by operating system. But the general takeaway should be that they are essentially equivalent in terms of overhead.

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Wonderful use of JMH! I wish more microbenchmarks on this site took advantage of it. –  Joe C Jun 20 at 19:29

If you have time, watch this talk by Cliff Click, he speaks about price of System.currentTimeMillis as well as other things.

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Nice, thanks. I'll look into it –  Lukas Eder Apr 13 '11 at 6:48

System.currentTimeMillis() is usually really fast (afaik 5-6 cpu cycles but i don't know where i have read this any more), but it's resolution varies on different plattforms.

So if you need high precision go for nanoTime(), if you are worried about overhead go for currentTimeMillis().

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Good point. Check out WhiteFang34's answer. They seem to be somewhat equally fast, depending on the system used to benchmark them. –  Lukas Eder Apr 12 '11 at 19:39

At a theoretical level, for a VM that uses native threads, and sits on a modern preemptive operating system, the currentTimeMillis can be implemented to be read only once per timeslice. Presumably, nanoTime implementations would not sacrifice the precision.

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That's a good point about precision. If you're right, then currentTimeMillis() couldn't be more precise. Or because it doesn't need to be precise, it can be implemented that way. But on the other hand, that doesn't say which one is faster... –  Lukas Eder Apr 12 '11 at 19:45

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