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Purely out of interest I've been looking at how the Oracle Java compiler handles String concatenation and I'm seeing something I didn't expect.

Given the following code:

public class StringTest {
    public static void main(String... args) {
        String s = "Test" + getSpace() + "String.";
        System.out.println(s.toString());
    }

    // Stops the compiler optimising the concatenations down to a
    // single string literal.
    static String getSpace() {
        return " ";
    }
}

I expected that the compiler would optimise it to the equivalent of:

String s = new StringBuilder("Test").append(getSpace())
                   .append("String.").toString();

But it actually compiles down to the equivalent of:

String s = new StringBuilder().append("Test").append(getSpace())
                   .append("String.").toString();

I'm compiling this using the 32-bit jdk1.7.0_55 release. This is the output of javap -v -l:

public class StringTest
  SourceFile: "StringTest.java"
  minor version: 0
  major version: 51
  flags: ACC_PUBLIC, ACC_SUPER
Constant pool:
   #1 = Methodref          #14.#25        //  java/lang/Object."<init>":()V
   #2 = Class              #26            //  java/lang/StringBuilder
   #3 = Methodref          #2.#25         //  java/lang/StringBuilder."<init>":()V
   #4 = String             #27            //  Test
   #5 = Methodref          #2.#28         //  java/lang/StringBuilder.append:(Ljava/lang/String;)Ljava/lang/StringBuilder;
   #6 = Methodref          #13.#29        //  StringTest.getSpace:()Ljava/lang/String;
   #7 = String             #30            //  String.
   #8 = Methodref          #2.#31         //  java/lang/StringBuilder.toString:()Ljava/lang/String;
   #9 = Fieldref           #32.#33        //  java/lang/System.out:Ljava/io/PrintStream;
  #10 = Methodref          #34.#31        //  java/lang/String.toString:()Ljava/lang/String;
  #11 = Methodref          #35.#36        //  java/io/PrintStream.println:(Ljava/lang/String;)V
  #12 = String             #37            //
  #13 = Class              #38            //  StringTest
  #14 = Class              #39            //  java/lang/Object
  #15 = Utf8               <init>
  #16 = Utf8               ()V
  #17 = Utf8               Code
  #18 = Utf8               LineNumberTable
  #19 = Utf8               main
  #20 = Utf8               ([Ljava/lang/String;)V
  #21 = Utf8               getSpace
  #22 = Utf8               ()Ljava/lang/String;
  #23 = Utf8               SourceFile
  #24 = Utf8               StringTest.java
  #25 = NameAndType        #15:#16        //  "<init>":()V
  #26 = Utf8               java/lang/StringBuilder
  #27 = Utf8               Test
  #28 = NameAndType        #40:#41        //  append:(Ljava/lang/String;)Ljava/lang/StringBuilder;
  #29 = NameAndType        #21:#22        //  getSpace:()Ljava/lang/String;
  #30 = Utf8               String.
  #31 = NameAndType        #42:#22        //  toString:()Ljava/lang/String;
  #32 = Class              #43            //  java/lang/System
  #33 = NameAndType        #44:#45        //  out:Ljava/io/PrintStream;
  #34 = Class              #46            //  java/lang/String
  #35 = Class              #47            //  java/io/PrintStream
  #36 = NameAndType        #48:#49        //  println:(Ljava/lang/String;)V
  #37 = Utf8
  #38 = Utf8               StringTest
  #39 = Utf8               java/lang/Object
  #40 = Utf8               append
  #41 = Utf8               (Ljava/lang/String;)Ljava/lang/StringBuilder;
  #42 = Utf8               toString
  #43 = Utf8               java/lang/System
  #44 = Utf8               out
  #45 = Utf8               Ljava/io/PrintStream;
  #46 = Utf8               java/lang/String
  #47 = Utf8               java/io/PrintStream
  #48 = Utf8               println
  #49 = Utf8               (Ljava/lang/String;)V
{
  public StringTest();
    flags: ACC_PUBLIC
    LineNumberTable:
      line 2: 0
    Code:
      stack=1, locals=1, args_size=1
         0: aload_0
         1: invokespecial #1                  // Method java/lang/Object."<init>":()V
         4: return
      LineNumberTable:
        line 2: 0

  public static void main(java.lang.String...);
    flags: ACC_PUBLIC, ACC_STATIC, ACC_VARARGS
    LineNumberTable:
      line 4: 0
      line 5: 27
      line 6: 37
    Code:
      stack=2, locals=2, args_size=1
         0: new           #2                  // class java/lang/StringBuilder
         3: dup
         4: invokespecial #3                  // Method java/lang/StringBuilder."<init>":()V
         7: ldc           #4                  // String Test
         9: invokevirtual #5                  // Method java/lang/StringBuilder.append:(Ljava/lang/String;)Ljava/lang/StringBuilder;
        12: invokestatic  #6                  // Method getSpace:()Ljava/lang/String;
        15: invokevirtual #5                  // Method java/lang/StringBuilder.append:(Ljava/lang/String;)Ljava/lang/StringBuilder;
        18: ldc           #7                  // String String.
        20: invokevirtual #5                  // Method java/lang/StringBuilder.append:(Ljava/lang/String;)Ljava/lang/StringBuilder;
        23: invokevirtual #8                  // Method java/lang/StringBuilder.toString:()Ljava/lang/String;
        26: astore_1
        27: getstatic     #9                  // Field java/lang/System.out:Ljava/io/PrintStream;
        30: aload_1
        31: invokevirtual #10                 // Method java/lang/String.toString:()Ljava/lang/String;
        34: invokevirtual #11                 // Method java/io/PrintStream.println:(Ljava/lang/String;)V
        37: return
      LineNumberTable:
        line 4: 0
        line 5: 27
        line 6: 37

  static java.lang.String getSpace();
    flags: ACC_STATIC
    LineNumberTable:
      line 10: 0
    Code:
      stack=1, locals=0, args_size=0
         0: ldc           #12                 // String
         2: areturn
      LineNumberTable:
        line 10: 0
}

Anecdotally, I've read here that the ECJ compiler does actually compile down to the argumented constructor (although I haven't verified it for myself), so my question is why doesn't Oracle's compiler make that same optimisation?


Based on the comments I ran another test using a longer String so as to immediately exceed the default length of the StringBuilder's backing char[]:

public class StringTest {
    public static void main(String... args) {
        String s = "Testing a much, much longer " + getSpace() + "String.";
        System.out.println(s.toString());
    }

    // Stops the compiler optimising the concatenations down to a single string literal
    static String getSpace() {
        return " ";
    }
}

With the exception of the contents of the literals being slightly different, the generated bytecode is exactly the same, still using the no-args constructor to instantiate the StringBuilder before appending to it. In this situation the argumented constructor version of the code should out-perform the no-args one as far as I can tell. This is due to the need to re-size the backing char[] at the first call to append(), and then potentially needing to do it again on the next append() if the appended String was particularly large.


On AnubianNoob's suggestion I did a quick performance test of System.arraycopy(...) to see if it was indeed optimised for empty arrays. This is the code used:

public class ArrayCopyTest {
    public static void main(String... args) {

        char[] array = new char[16];
        final long test1Start = System.nanoTime();
        for (int i = 0; i < 1000000; i++) {
            System.arraycopy(array, 0, array, 0, array.length);
        }

        final long test1End = System.nanoTime();
        System.out.println("Elapsed Time (empty array copies)");
        System.out.println("=================================");
        System.out.println((test1End - test1Start) + "ns");

        char[] array2 = new char[] {'0', '1', '2', '3', '4', '5', '6', '7', '8',
             '9', 'a', 'b', 'c', 'd', 'e', 'f'};

        final long test2Start = System.nanoTime();
        for (int i = 0; i < 1000000; i++) {
            System.arraycopy(array2, 0, array2, 0, array2.length);
        }

        final long test2End = System.nanoTime();
        System.out.println("Elapsed Time (non-empty array copies)");
        System.out.println("=====================================");
        System.out.println((test2End - test2Start) + "ns");
    }
}

Running this on a Windows 7.1 32-bit machine with an i7-2600 CPU @ 3.40 GHz 3.39 GHz and 3.24 GB of usable RAM produced:

Elapsed Time (empty array copies)
=================================
26660199ns
Elapsed Time (non-empty array copies)
=====================================
19431962ns

I ran this about five times just to be sure. It actually appears that it performs better over a million iterations when the array isn't empty. As Mike Strobel correctly pointed out, the above isn't a meaningful benchmark.

share|improve this question
2  
Why do you believe that to be an optimisation? The only difference between the two is the capacity, which is larger when using the string-based constructor. –  Duncan May 29 '14 at 14:00
    
@Duncan I'm not suggesting that one version is necessarily better than the other (I haven't delved deep enough to form an informed opinion on that), I'm just interested to know why Oracle prefers the no-args constructor when ECJ prefers the argumented one. If I were to write the code manually I would have used the argumented constructor, so I (perhaps naively) assumed that that's what the compiler would do as well. –  JonK May 29 '14 at 14:05
    
@Duncan Having looked a little more closely, if the initial String that gets appended to the StringBuilder is longer than 16 characters then the backing char[] will be expanded immediately to a length of at least 34, with some spare capacity if the String is shorter than 34 characters. If it's longer than 34 characters then the new array will be exactly long enough to fit the new contents, meaning that the next call to append() will again cause the array to be resized. Given that, I'd argue that the parameterised constructor would be a better option for the compiler to pick... –  JonK May 29 '14 at 15:00
    
...because it ensures that it's large enough to hold the initial String to begin with and has 16 characters of spare capacity left over at the end. –  JonK May 29 '14 at 15:02
1  
I'm afraid that's not a meaningful benchmark. Benchmarking with Java is tricky business, and you have to account for things like delayed JIT. If the first test case consistently runs slower, I'd bet you lunch that the results would change if you swapped the order of the tests :). –  Mike Strobel May 29 '14 at 16:44

5 Answers 5

up vote 4 down vote accepted

I think this is just laziness. Why? Since if you pick the arg-constructor, you need further checks. You have to check whether the first expression to be concatenated is a string, if so, you can use the arg constructor, otherwise, you have to fall back to the no-arg constructor. This is just a lot more logic than simply always taking the no-arg constructor.

If I was that compiler developer, I would have chosen the easy way, too, since implicit string concatenation is surely not the bottleneck in many applications and the difference is so small that it is just not worth the hassle.

Most people think of compilers as magic programs designed by super humans that always do the best things. But this is not true, compilers are also written by usual programmers which do not always think hours about what is the best way to compile any specific thing. They have tight schedules and need features to get done, so the easiest solution is often the one of choice.

share|improve this answer
1  
This is probably the reason. Perhaps not incidentally, if you always use the same pattern, optimizing the operation at runtime becomes easier too. –  Mike Strobel May 29 '14 at 16:47
    
I do find myself curious why there are no String constructors that accept either multiple arguments or a String[]. Given a String constructor with a String[] argument, constructing and populating a String[] and passing it to that constructor would probably be faster than using StringBuilder every scenario (it would only require constructing a total of one temporary object). –  supercat Jan 23 at 21:39

Probably because the String constructor calls append() anyways:

public StringBuilder(String str) {
    super(str.length() + 16);
    append(str);
}
share|improve this answer
    
So, you are saying that there is no difference and Oracle just picks a random solution. Right? –  Val May 29 '14 at 14:02
    
@Val Possibly? There could be some reasoning as to letting the capacity expand "naturally" instead of setting it directly, or some way the JIT compiler is written, but a more specific reason I'm not aware of. –  user3580294 May 29 '14 at 14:12
    
If you do not know then how do you answer? The question asks for what you do not know. –  Val May 30 '14 at 9:28
1  
Because I can provide a reasonable guess, I suppose? Only someone who actually wrote the compiler code dealing with this can give an authoritative answer, unfortunately. –  user3580294 May 30 '14 at 16:18

This is probably because JVM optimizes String concatination and it is probably better for it to recognize String concatination pattern in bytecode the way it is implemented now.

share|improve this answer
    
Do you mean that it might be easier to spot an empty StringBuilder constructor call? –  Duncan May 29 '14 at 14:33
    
This is my guess –  Evgeniy Dorofeev May 29 '14 at 14:55
1  
It's probably not so much that it's easier to spot an empty constructor call, but it simplifies the pattern recognition if you only have one pattern to look for. The compiler couldn't use the parameterized constructor in all cases (e.g., for 1 + "one"), but it can use the empty constructor in all cases. –  Mike Strobel May 29 '14 at 16:40
    
@MikeStrobel That does make a lot of sense, I hadn't thought about it that way. Thanks for the insight. –  JonK May 30 '14 at 16:30

As another person has mentioned, the StringBuilder class calls append() in its constructor, and it's a lot more readable and consistent to have an append yourself.

Consider:

new StringBuilder("Hello").append("World");
new StringBuilder().append("Hello").append("World");

This might not be the best example, but two appends is a lot simpler to see than passing it into the constructor. And the speed is the same.

share|improve this answer
    
I agree that the speed would be the same in this specific example (and in my own example as well), but if your initial String was longer than 16 characters it would cause the AbstractStringBuilder to reallocate its char[] to hold the String, which wouldn't be required if using the parameterised constructor. –  JonK May 29 '14 at 15:12
    
@JonK Actually what happens if you do it with a String longer than 16 characters? –  Anubian Noob May 29 '14 at 15:13
    
append() calls out to AbstractStringBuilder#ensureCapacity(int) first using the input String's length as an argument. The no-args constructor sets the initial capacity to 16, so if the String is longer than that then it will call expandCapacity(int) and increase the array's capacity to 34 or the String's length, whichever is the greater. Or did you mean in terms of the generated bytecode? –  JonK May 29 '14 at 15:17
    
The bytecode... Hmm I can't test it right now though... –  Anubian Noob May 29 '14 at 15:19
    
I just did a quick test with a longer String and the generated bytecode was the same (with the obvious exception that the String's contents were different) - it still uses the no-args constructor. I'll update the question accordingly. –  JonK May 29 '14 at 15:21

By the way, there are related issues in JDK issue tracker: JDK-4059189 and related. The initial proposal is dated 1997! And there are not much discussion there. This means that this issue is either considered unimportant or this case is optimized by JIT.

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