Based on performance alone, approximately how many "simple" lines of java is the equivalent performance hit of making a JNI call?

Or to try to express the question in a more concrete way, if a simple java operation such as

someIntVar1 = someIntVar2 + someIntVar3;

was given a "CPU work" index of 1, what would be the typical (ballpark) "CPU work" index of the overhead of making the JNI call?

This question ignores the time taken waiting for the native code to execute. In telephonic parlance, it is strictly about the "flag fall" part of the call, not the "call rate".

The reason for asking this question is to have a "rule of thumb" to know when to bother attempting coding a JNI call when you know the native cost (from direct testing) and the java cost of a given operation. It could help you quickly avoid the hassle to coding the JNI call only to find that the callout overhead consumed any benefit of using native code.


Some folks are getting hung up on variations in CPU, RAM etc. These are all virtually irrelevant to the question - I'm asking for the relative cost to lines of java code. If CPU and RAM are poor, they are poor for both java and JNI so environmental considerations should balance out. The JVM version falls into the "irrelevant" category too.

This question isn't asking for an absolute timing in nanoseconds, but rather a ball park "work effort" in units of "lines of simple java code".

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    Did you take a look at What makes JNI calls slow? Dec 20, 2012 at 13:18
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    @AviramSegal Yes, but there's nothing there about how much it costs, only why it costs
    – Bohemian
    Dec 20, 2012 at 13:21
  • 2
    I think the question should involve "what factors contribute to the overhead and by how much" because I doubt that there is a unique answer for any JNI call. Dec 20, 2012 at 13:25
  • 1
    Which JVM are you investigating? Differences between implementations are huge; also, timing differs tremendously depending on the CPU and RAM choices.
    – Alex Cohn
    Dec 20, 2012 at 15:55
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    @Bohemian: your assumptions may not hold. First of all, JNI call is always a call; inline Java code does not involve the "function call overhead", which depends on the CPU architecture (x86 in 32 bit mode vs. x86 in 64 bit mode vs. ARM, and more). Second, the question of memory cache misses (or matches) is very important. Finally, you don't expect Sun/Oracle Java work the same way as Android (Dalvik)
    – Alex Cohn
    Dec 21, 2012 at 14:34

3 Answers 3


Quick profiler test yields:

Java class:

public class Main {
    private static native int zero();

    private static int testNative() {
        return Main.zero();

    private static int test() {
        return 0;

    public static void main(String[] args) {

    static {

C library:

#include <jni.h>
#include "Main.h"

Java_Main_zero(JNIEnv *env, jobject obj)
    return 0;


single invocation 10 calls in a loop 100 calls in a loop

System details:

java version "1.7.0_09"
OpenJDK Runtime Environment (IcedTea7 2.3.3) (7u9-2.3.3-1)
OpenJDK Server VM (build 23.2-b09, mixed mode)
Linux visor 3.2.0-4-686-pae #1 SMP Debian 3.2.32-1 i686 GNU/Linux

Update: Caliper micro-benchmarks for x86 (32/64 bit) and ARMv6 are as follows:

Java class:

public class Main extends SimpleBenchmark {
    private static native int zero();
    private Random random;
    private int[] primes;

    public int timeJniCall(int reps) {
        int r = 0;
        for (int i = 0; i < reps; i++) r += Main.zero();
        return r;

    public int timeAddIntOperation(int reps) {
        int p = primes[random.nextInt(1) + 54];   // >= 257
        for (int i = 0; i < reps; i++) p += i;
        return p;

    public long timeAddLongOperation(int reps) {
        long p = primes[random.nextInt(3) + 54];  // >= 257
        long inc = primes[random.nextInt(3) + 4]; // >= 11
        for (int i = 0; i < reps; i++) p += inc;
        return p;

    protected void setUp() throws Exception {
        random = new Random();
        primes = getPrimes(1000);

    public static void main(String[] args) {
        Runner.main(Main.class, args);        

    public static int[] getPrimes(int limit) {
        // returns array of primes under $limit, off-topic here

    static {

Results (x86/i7500/Hotspot/Linux):

Scenario{benchmark=JniCall} 11.34 ns; σ=0.02 ns @ 3 trials
Scenario{benchmark=AddIntOperation} 0.47 ns; σ=0.02 ns @ 10 trials
Scenario{benchmark=AddLongOperation} 0.92 ns; σ=0.02 ns @ 10 trials

       benchmark     ns linear runtime
         JniCall 11.335 ==============================
 AddIntOperation  0.466 =
AddLongOperation  0.921 ==

Results (amd64/phenom 960T/Hostspot/Linux):

Scenario{benchmark=JniCall} 6.66 ns; σ=0.22 ns @ 10 trials
Scenario{benchmark=AddIntOperation} 0.29 ns; σ=0.00 ns @ 3 trials
Scenario{benchmark=AddLongOperation} 0.26 ns; σ=0.00 ns @ 3 trials

   benchmark    ns linear runtime
         JniCall 6.657 ==============================
 AddIntOperation 0.291 =
AddLongOperation 0.259 =

Results (armv6/BCM2708/Zero/Linux):

Scenario{benchmark=JniCall} 678.59 ns; σ=1.44 ns @ 3 trials
Scenario{benchmark=AddIntOperation} 183.46 ns; σ=0.54 ns @ 3 trials
Scenario{benchmark=AddLongOperation} 199.36 ns; σ=0.65 ns @ 3 trials

   benchmark  ns linear runtime
         JniCall 679 ==============================
 AddIntOperation 183 ========
AddLongOperation 199 ========

To summarize things a bit, it seems that JNI call is roughly equivalent to 10-25 java ops on typical (x86) hardware and Hotspot VM. At no surprise, under much less optimized Zero VM, the results are quite different (3-4 ops).

Thanks go to @Giovanni Azua and @Marko Topolnik for participation and hints.

  • 2
    8.5 includes both test and testNative :/ besides you don't ever want to give performance comparison results like that. First you never compare performance of A is faster than B using a profiler, you need to compile in release mode and microbenchmark. Second without averaging and accounting for dispersion the number means nothing e.g. 8.5 but the variability is 6.8 then your mean elapsed time assumption is BS.
    – SkyWalker
    Dec 20, 2012 at 19:25
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    You're close to answering this question. Try this: 1) make sure JIT has compiled the test code. 2) keep adding simple lines that do simple arithmetic to the java version until the two timings are equal, then post how much code to took to make the two calls "cost" the same. That is the answer I seek
    – Bohemian
    Dec 20, 2012 at 20:05
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    @GiovanniAzua: i'd not consider this a final answer, rather a warm-up :) Thanks for comment (i really appreciate that), it is becoming interesting :)
    – barti_ddu
    Dec 20, 2012 at 20:34
  • @Bohemian: does int addition from pre-generated random set count as simple arithmetic?
    – barti_ddu
    Dec 20, 2012 at 20:35
  • 1
    @barti_ddu You don't want to involve too much memory in this because then you are skewing this by cache misses (and that's a tremendous difference). I propose iteratively adding a large-ish prime int, starting out from a randomly generated initial value, and using that value somehow (typically return it from the tested method). This can't be optimized away and only uses the stack. Dec 21, 2012 at 6:49

So I just tested the "latency" for a JNI call to C on Windows 8.1, 64-bit, using the Eclipse Mars IDE, JDK 1.8.0_74, and VirtualVM profiler 1.3.8 with the Profile Startup add-on.

Setup: (two methods)
SOMETHING() passes arguments, does stuff, and returns arguments
NOTHING() passes in the same arguments, does nothing with them, and returns same arguments.

(each gets called 270 times)
Total run time for SOMETHING(): 6523ms
Total run time for NOTHING(): 0.102ms

Thus in my case the JNI calls are quite negligible.

  • Although this isn't quite what I was asking, it is nevertheless an interesting and relevant finding.
    – Bohemian
    Mar 22, 2016 at 1:07
  • Ah yes; I was reading Azua's answer about "latency" and ended up testing that instead :)
    – VeraKozya
    Mar 22, 2016 at 23:44
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    I agree with what you wrote, but 0.1 ms translates into 10,000 calls per second, or 20 million cycles. That's enormous. Jan 27, 2017 at 22:18
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    0.1 ms are the total time for 270 calls, which gives 0.4 µs per single call to NOTHING(). That is, 2.7 million calls per second. Aug 25, 2017 at 7:10

You should actually test it yourself what the "latency" is. Latency is defined in engineering as the time it takes to send a message of zero length. In this context, it would correspond to writing the smallest Java program that invokes a do_nothing empty C++ function and compute mean and stddev of the elapsed time over 30 measurements (do couple of extra warm up calls). You might be surprised of the different average results doing the same for different JDK versions and platforms.

Only doing so will give you the final answer of whether using JNI makes sense for your target environment.

  • 2
    I'm basically asking if anyone has done this and could they share what they found :/
    – Bohemian
    Dec 20, 2012 at 13:27
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    it is irrelevant, I would expect major differences due to the underlying platform and JDK versions. Those number will mean nothing.
    – SkyWalker
    Dec 20, 2012 at 13:28
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    Machine differences (eg CPU and RAM) are virtualy irrelevant to this question. I asked for the cost in terms of "lines of java code". This cancels out any machine issues - if java is slow, JNI will be slow etc - which is why I asked the question the way I did. It should cancel out JVM issues too, for the same reason
    – Bohemian
    Dec 20, 2012 at 19:59
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    @Bohemian: i think, it would be fair if you include mbench code in your answer; thanks anyway.
    – barti_ddu
    Dec 20, 2012 at 22:29
  • @GiovanniAzua: the previous comment was dedicated to you, actually; sorry for misaddressing.
    – barti_ddu
    Dec 21, 2012 at 8:35

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