1

The following small programs which compute the sum of all numbers from 1 to 1 billion we're written in C++ and Java as closely as I could write them. My understanding is that C++ is the "faster" language, but the java version of this code completes in ~.5 seconds vs ~3 seconds for C++.

C++ (GCC Compiler):

int main(){
    long long x = 0;
    for (long i=0;i<1000000001;i++){
    x=x+i;
    }
    cout << x << endl;
    return 0;
}

JAVA:

public class Main {
    public static void main(String[] args)  {
        long x=0;
        for (long i=0;i<1000000001;i++){
            x=x+i;
        }
        System.out.println(x);

    }

}

How would one optimize the C++ code to be as fast as the JAVA version? Is it even possible?

17
  • 10
    Did you turn on optimizations when you compiled the C++ code? Sep 11, 2017 at 19:52
  • 7
    cout << (1000000001)*(1000000002)/2 << endl; Sep 11, 2017 at 19:55
  • 5
    Neither language has any inherent speed advantages over the other. Different implementations of either language may be faster or slower, and the answer might also depend on implementation-specific compile-time and/or run-time options that you might choose. Back when Java was new, the only real Java implementation was slower than pretty much any C implementation on the same hardware, but that was decades ago. Sep 11, 2017 at 19:58
  • 3
    Obligatory: How do I write a correct micro-benchmark in Java? Sep 11, 2017 at 20:07
  • 3
    Except that optimizing compilers can identify and handle certain loops. So it's more like suggesting that racers in Star Trek who are allowed to use the teleporter, should do so. And they should.
    – yshavit
    Sep 11, 2017 at 20:08

3 Answers 3

8

This question is a perfect example of what not to do. The whole loop is equivalent to a single assignment and any optimizing compiler knows it. So you're measuring how long it takes to start the program and output a line.

Then Java must lose by any factor you wish as running the Java code includes starting the JVM and that's pretty slow. Moreover, it includes the optimizing compilation. What javac did is just the compilation from Java source to Java bytecode and there's no attempt to optimize anything. All the optimizations happen at runtime (bytecode to machine code). 1

So we can conclude that Java is terribly slow for any task taking less than a few seconds. You can get a factor of 20 or infinity (division by zero), if you try hard enough.

The more important conclusion is that it makes no sense. See How do I write a correct micro-benchmark in Java?, if you want a meaningful result.


1 This holds for desktop Java. On Android, it's different.

5

If you compile with optimizations, then the C++ version is considerably faster.

Java:

javac Main.java

$ time java Main
500000000500000000

real    0m0.727s
user    0m0.724s
sys     0m0.004s

C++:

clang -O3 main.cpp -o cpp

$ time ./cpp 
500000000500000000

real    0m0.003s
user    0m0.000s
sys     0m0.000s

My Clang version:

$ clang --version
clang version 4.0.0-1ubuntu1 (tags/RELEASE_400/rc1)
Target: x86_64-pc-linux-gnu
Thread model: posix
InstalledDir: /usr/bin

My Java version:

$ javac -version
javac 1.8.0_144

The reason for this is that optimization is a slow process; you get quicker compilation times if you turn optimizations off. This is better for development, so this is the defaults that the Clang developers chose. Java is probably faster because it does more optimizations at run-time. JVM bytecode is not that different to the source-code it compiled from!

6
  • 1
    JVM bytecode is about as relevant for the speed as the source code. No contemporary java source to java bytecode compiler even attempts to make any optimizations; they all happen at runtime. Your 0.727 s are partly the time for the JVM start and partly the compilation time (bytecode to machine code). OK, some execution time is there, too.
    – maaartinus
    Sep 13, 2017 at 12:56
  • ...and I strongly suspect that clang also converted the loop to a constant at compile time (like gcc did in this answer)
    – Hulk
    Sep 15, 2017 at 9:19
  • @Hulk Almost certainly... but isn't that the point? C++ provides some great tooling so that developers don't have to worry about spotting these optimizations.
    – sdgfsdh
    Sep 15, 2017 at 9:21
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    @sdgfsdh yes, and Java's JIT compiler may be able to dynamically optimize for the data it actually receives at runtime - the only thing to learn here is that this benchmark does not measure what the OP expected it to measure.
    – Hulk
    Sep 15, 2017 at 9:27
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    @sdgfsdh Sure, that is definitely true
    – Hulk
    Sep 15, 2017 at 9:31
3

Compile the C code with the -O option.

Assembly generated without -O contains lots of memory access (slow):

main:
  push rbp
  mov rbp, rsp
  mov QWORD PTR [rbp-8], 0
  mov QWORD PTR [rbp-16], 0
.L3:
  cmp QWORD PTR [rbp-16], 1000000000
  jg .L2
  mov rax, QWORD PTR [rbp-16]
  add QWORD PTR [rbp-8], rax
  add QWORD PTR [rbp-16], 1
  jmp .L3
.L2:

Assembly generated with -O only uses registers:

main:
  mov eax, 1000000001
.L2:
  sub rax, 1
  jne .L2

See Godbolt's GCC explorer output: https://godbolt.org/g/rx1Va4

EDIT: In the optimized mode, the compiler recognizes that the output is a constant, that's why there is no add instruction. See Nathan's example with output: https://godbolt.org/g/r1PxvL

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    Your example is a little flawed as you do not do the output. That means the compiler just optimizes out the loop since it doesn't need to calculate a value in the second version. What is cool though is if you add the print out of x you can see gcc just calculates the value at compile time and inserts a constant into the assembly: godbolt.org/g/r1PxvL Sep 11, 2017 at 20:16
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    @NathanOliver yeah teleportation wins :) Sep 11, 2017 at 20:18

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