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I have run a simple test to measure the AES-GCM performance in Java 9, by encrypting byte buffers in a loop. The results were somewhat confusing. The native (hardware) acceleration seems to work - but not always. More specifically,

  1. When encrypting 1MB buffers in a loop, the speed is ~60 MB/sec for the first ~50 seconds. Then it jumps to 1100 MB/sec, and stays there. Does JVM decide to activate the hardware acceleration after 50 seconds (or 3GB of data)? can it be configured? Where can I read about the new AES-GCM implementation (besides here).
  2. When encrypting 100MB buffers, the hardware acceleration doesn't kick in at all. The speed is a flat 60 MB/sec.

My test code looks like this:

int plen = 1024*1024;
byte[] input = new byte[plen];
for (int i=0; i < input.length; i++) { input[i] = (byte)i;}
byte[] nonce = new byte[12];
...
// Uses SunJCE provider
Cipher cipher = Cipher.getInstance("AES/GCM/NoPadding");
byte[] key_code = {0,1,2,3,4,5,6,7,8,9,10,11,12,13,14,15};
SecretKey key = new SecretKeySpec(key_code, "AES");
SecureRandom random = new SecureRandom();

long total = 0;
while (true) {
  random.nextBytes(nonce);
  GCMParameterSpec spec = new GCMParameterSpec(GCM_TAG_LENGTH * 8, nonce);
  cipher.init(Cipher.ENCRYPT_MODE, key, spec);
  byte[] cipherText = cipher.doFinal(input);
  total += plen;
  // print delta_total/delta_time, once in a while
}

Feb 2019 update: HotSpot had been modified to address this issue. The fix is applied in Java 13, and also backported to Java 11 and 12.

https://bugs.java.com/bugdatabase/view_bug.do?bug_id=JDK-8201633, https://hg.openjdk.java.net/jdk/jdk/rev/f35a8aaabcb9

July 16, 2019 update: The newly released Java version (Java 11.0.4) fixes this problem.

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  • 4
    I think your should read about How to write a correct micro-benchmark in Java and apply the techniques that are described there. Them you will probably have a better idea about what you are measuring. You should for example include a warm up phase in your benchmark. The things you are seeing could be because the JIT compiler kicks in and optimises your code after 50 sec.
    – Lii
    Feb 21, 2018 at 12:10
  • 4
    It seems the number of invocations matters for the optimization trigger and, of course, processing lots of small buffers implies more invocations than processing a few big buffers, considering the same amount of time. Mind the possibility to process a big buffer by repeatedly invoking update for a small portion of it and finally invoking doFinal for the last chunk…
    – Holger
    Feb 21, 2018 at 17:36
  • 1
    @Lii You're right, warmup would most probably help, but this is no microbenchmark, it takes quite some time and should work better.
    – maaartinus
    Feb 21, 2018 at 18:00
  • 3
    @Eugene it’s not about taking different branches. I tried it with different buffer sizes and also varying buffer sizes. You can warm up the code in a second by executing it often enough with a tiny buffer to get the optimization, followed by calling the same code with a huge buffer, still benefiting from the already applied optimization. This indicates that it is merely the number of invocations that matters. When you refactor the code to always process an equally small part of the buffer via repeated update operations followed by doFinal, the total buffer size becomes irrelevant…
    – Holger
    Feb 22, 2018 at 8:33
  • 1
    @gg123 This should be IMHO reported as a bug. The encryption of huge blocks should be splitt automatically and for decryption some solution should be found.
    – maaartinus
    Feb 23, 2018 at 16:44

4 Answers 4

10

Thanks @Holger for pointing in the right direction. Prepending cipher.doFinal with multiple cipher.update calls will trigger the hardware acceleration almost immediately.

Based on this reference, GCM Analysis , I'm using 4KB chunks in each update. Now both 1MB and 100MB buffers are encrypted at 1100 MB/sec speed (after a few dozen milliseconds) .

The solution is to replace

byte[] cipherText = cipher.doFinal(input);

with

int clen = plen + GCM_TAG_LENGTH;
byte[] cipherText = new byte[clen];

int chunkLen = 4 * 1024;
int left = plen;
int inputOffset = 0;
int outputOffset = 0;

while (left > chunkLen) {
  int written = cipher.update(input, inputOffset, chunkLen, cipherText, outputOffset);
  inputOffset += chunkLen;
  outputOffset += written;
  left -= chunkLen;
}

cipher.doFinal(input, inputOffset, left, cipherText, outputOffset);
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A couple of updates on this issue.

  1. The Java 10, released in late March, has the same problem, that can be bypassed with the same workaround - for data encryption only.

  2. The workaround basically doesn't work for data decryption - in both Java 9 and Java 10.

I've submitted a bug report to the Java platform. It had been evaluated and published as JDK-8201633.

1
2

This problem is fixed in Java 13. The fix is also backported to Java 11 and 12.

https://bugs.java.com/bugdatabase/view_bug.do?bug_id=JDK-8201633, https://hg.openjdk.java.net/jdk/jdk/rev/f35a8aaabcb9

0

The Java version, released on July 16, 2019 (Java 11.0.4), fixes this problem.

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