I'm currently looking into String concat options and the penalty they have on the overall performance. And my test-case creates results that blow my mind, I'm not sure if I'm overlooking something.

Here is the deal: Doing "something"+"somethingElse" in java will (at compile-time) create a new StringBuilder every time this is done.

For my test-case, I'm loading a file from my HDD that has 1661 lines of example data (classic "Lorem Ipsum"). This question is not about the I/O performance, but about the performance of the different string concat methods.

public class InefficientStringConcat {

    public static void main(String[] agrs) throws Exception{
        // Get a file with example data:

        System.out.println("Starting benchmark");
        // Read an measure:
        for (int i = 0; i < 10; i++){
            BufferedReader in = new BufferedReader(
                    new InputStreamReader(new FileInputStream(new File("data.txt")))

            long start = System.currentTimeMillis();
            // Un-comment method to test:
            long end = System.currentTimeMillis();
            System.out.println("Took "+(end-start)+"ms");



    public static String betterRead(BufferedReader in) throws IOException{
        StringBuilder b = new StringBuilder();
        String line;
        while ((line = in.readLine()) != null){
        return b.toString();

    public static String inefficientRead(BufferedReader in) throws IOException {
        String everything = "", line;
        while ((line = in.readLine()) != null){
            everything += line;
        return everything;

As you can see, the setup is the same for both tests. Here are the results:

Using inefficientRead()-method:

Starting benchmark
#1 Took 658ms
#2 Took 590ms
#3 Took 569ms
#4 Took 567ms
#5 Took 562ms
#6 Took 570ms
#7 Took 563ms
#8 Took 568ms
#9 Took 560ms
#10 Took 568ms

Using betterRead()-method

Starting benchmark
#1 Took 42ms
#2 Took 10ms
#3 Took 5ms
#4 Took 7ms
#5 Took 16ms
#6 Took 3ms
#7 Took 4ms
#8 Took 5ms
#9 Took 5ms
#10 Took 13ms

I'm running the tests with no extra parameters to the java-command. I'm running a MacMini3,1 from early 2009 and Sun JDK 7:

[luke@BlackBox ~]$ java -version
java version "1.7.0_09"
Java(TM) SE Runtime Environment (build 1.7.0_09-b05)
Java HotSpot(TM) Client VM (build 23.5-b02, mixed mode)

This strikes me as a very heavy difference. Am I doing something wrong in measuring this, or is this supposed to happen?

  • Well, 10 iterations is not nearly enough for a benchmark, but apart from that it seems fine. Try increasing the number of iterations to, say, 100,000 and add a "warm-up" phase where you call the method 10,000 times (without timing it) to let the JIT do some inlining. – Cameron Skinner Mar 2 '13 at 18:43
  • @CameronSkinner Apparently you don't take into account that each high-level iteration already consists of 1661 method invocations. – Marko Topolnik Mar 2 '13 at 18:46
  • @MarkoTopolnik: The benchmark is being measured across the betterRead or inefficientRead methods, so those are the methods that you should call multiple times. So you are correct: You don't take into account the implementation details of the methods under test. – Cameron Skinner Mar 2 '13 at 18:54
  • @CameronSkinner At least the advice to call those methods 10,000 times just to warm up is unequivocally wrong: the JVM JITs according to the number of passes across any single line of code, which here happens before the tenth outer iteration. Starting from that, your request for 100,000 executions of the complete file-loading procedure is quite irrational. A sample size of a maximum of 100 would satisfy even the stringest statistician. – Marko Topolnik Mar 2 '13 at 19:03
  • @MarkoTopolnik: We can agree to disagree. But I'd recommend that you read more into what the JIT can do in terms of inlining entire method calls and whatnot. – Cameron Skinner Mar 2 '13 at 19:17

Am I doing something wrong in measuring this, or is this supposed to happen?

It's supposed to happen. Constructing a long string using repeated string concatenation is a known performance anti-pattern: every concatenation has to create a new string with a copy of the original string and also a copy of the additional string. You end up with O(N2) performance. When you use StringBuilder, most of the time you're just copying the additional string into a buffer. Occasionally the buffer will need to run out space and need to be expanded (by copying the existing data into a new buffer) but that doesn't happen often (due to the buffer expansion strategy).

See my article on string concatenation for details - it's a very old article, so predates StringBuilder, but the fundamentals haven't changed. (Basically StringBuilder is like StringBuffer, but without synchronization.)

  • 4
    Nice, now where can I pick up my "Got answered by Jon Skeet" T-Shirt? – Lukas Knuth Mar 2 '13 at 18:51
  • What Jon said was great. To backtrack a step, if one wasn't familiar, String is final and immutable. – vikingsteve Mar 2 '13 at 19:12

This is exactly what should happen. betterRead takes linear time; inefficientRead takes quadratic time.

  • @MarkoTopolnik: You misunderstand what big-O complexity means. It measures the rate of increase of cost, not the absolute cost. If you added Thread.sleep(1000) to the betterRead method it is still O(n) but will take much longer in wall-clock time than the O(n^2) method, at least until n gets larger. – Cameron Skinner Mar 2 '13 at 18:56
  • 1
    @MarkoTopolnik: I certainly would imply that the constant factor is just irrelevant. – Louis Wasserman Mar 2 '13 at 19:08
  • 3
    From first caring about the asymptotics, and only much later optimizing constant factors. – Louis Wasserman Mar 2 '13 at 19:41
  • No different algorithms end up with exactly the same constant factors, and I'm entirely comfortable leaving out a discussion of why they differ here. – Louis Wasserman Mar 3 '13 at 0:21

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