60

For a long time, I had thought of C++ being faster than JavaScript. However, today I made a benchmark script to compare the speed of floating point calculations in the two languages and the result is amazing!

JavaScript appears to be almost 4 times faster than C++!

I let both of the languages to do the same job on my i5-430M laptop, performing a = a + b for 100000000 times. C++ takes about 410 ms, while JavaScript takes only about 120 ms.

I really do not have any idea why JavaScript runs so fast in this case. Can anyone explain that?

The code I used for the JavaScript is (run with Node.js):

(function() {
    var a = 3.1415926, b = 2.718;
    var i, j, d1, d2;
    for(j=0; j<10; j++) {
        d1 = new Date();
        for(i=0; i<100000000; i++) {
            a = a + b;
        }
        d2 = new Date();
        console.log("Time Cost:" + (d2.getTime() - d1.getTime()) + "ms");
    }
    console.log("a = " + a);
})();

And the code for C++ (compiled by g++) is:

#include <stdio.h>
#include <ctime>

int main() {
    double a = 3.1415926, b = 2.718;
    int i, j;
    clock_t start, end;
    for(j=0; j<10; j++) {
        start = clock();
        for(i=0; i<100000000; i++) {
            a = a + b;
        }
        end = clock();
        printf("Time Cost: %dms\n", (end - start) * 1000 / CLOCKS_PER_SEC);
    }
    printf("a = %lf\n", a);
    return 0;
}
10
  • 27
    Please add -O3 -ffast-math and see what happens with the C++ timings.
    – Jesse Good
    Jun 11, 2013 at 3:34
  • 26
    "For long time, I always think that c++ should be faster than javascript. " You do understand that Javascript engines are usually implemented in C++
    – jamylak
    Jun 11, 2013 at 3:40
  • 8
    With optimization turned on, the C++ version is showing about 90 ms (though that obviously varies with the processor). Jun 11, 2013 at 3:40
  • 23
    @user2189264: Who cares? Testing optimization with optimization turned off makes no sense. Jun 11, 2013 at 3:46
  • 4
    @user2189264: See expanded answer below. I've tested on both a current Intel processor and a an old AMD that's quite slow by current standards. Both are giving substantially better results than you're seeing. Jun 11, 2013 at 4:22

6 Answers 6

305

I may have some bad news for you if you're on a Linux system (which complies with POSIX at least in this situation). The clock() call returns number of clock ticks consumed by the program and scaled by CLOCKS_PER_SEC, which is 1,000,000.

That means, if you're on such a system, you're talking in microseconds for C and milliseconds for JavaScript (as per the JS online docs). So, rather than JS being four times faster, C++ is actually 250 times faster.

Now it may be that you're on a system where CLOCKS_PER_SECOND is something other than a million, you can run the following program on your system to see if it's scaled by the same value:

#include <stdio.h>
#include <time.h>
#include <stdlib.h>

#define MILLION * 1000000

static void commaOut (int n, char c) {
    if (n < 1000) {
        printf ("%d%c", n, c);
        return;
    }

    commaOut (n / 1000, ',');
    printf ("%03d%c", n % 1000, c);
}

int main (int argc, char *argv[]) {
    int i;

    system("date");
    clock_t start = clock();
    clock_t end = start;

    while (end - start < 30 MILLION) {
        for (i = 10 MILLION; i > 0; i--) {};
        end = clock();
    }

    system("date");
    commaOut (end - start, '\n');

    return 0;
}

The output on my box is:

Tuesday 17 November  11:53:01 AWST 2015
Tuesday 17 November  11:53:31 AWST 2015
30,001,946

showing that the scaling factor is a million. If you run that program, or investigate CLOCKS_PER_SEC and it's not a scaling factor of one million, you need to look at some other things.


The first step is to ensure your code is actually being optimised by the compiler. That means, for example, setting -O2 or -O3 for gcc.

On my system with unoptimised code, I see:

Time Cost: 320ms
Time Cost: 300ms
Time Cost: 300ms
Time Cost: 300ms
Time Cost: 300ms
Time Cost: 300ms
Time Cost: 300ms
Time Cost: 300ms
Time Cost: 300ms
Time Cost: 300ms
a = 2717999973.760710

and it's three times faster with -O2, albeit with a slightly different answer, though only by about one millionth of a percent:

Time Cost: 140ms
Time Cost: 110ms
Time Cost: 100ms
Time Cost: 100ms
Time Cost: 100ms
Time Cost: 100ms
Time Cost: 100ms
Time Cost: 100ms
Time Cost: 100ms
Time Cost: 100ms
a = 2718000003.159864

That would bring the two situations back on par with each other, something I'd expect since JavaScript is not some interpreted beast like in the old days, where each token is interpreted whenever it's seen.

Modern JavaScript engines (V8, Rhino, etc) can compile the code to an intermediate form (or even to machine language) which may allow performance roughly equal with compiled languages like C.

But, to be honest, you don't tend to choose JavaScript or C++ for its speed, you choose them for their areas of strength. There aren't many C compilers floating around inside browsers and I've not noticed many operating systems nor embedded apps written in JavaScript.

11
  • 3
    I think it is not the case, 400ms is something is easy to feel. The output appears really slow than javascript.
    – streaver91
    Jun 11, 2013 at 3:52
  • 2
    I mean the time cost of my origin scripts will be printed to the screen after each big loop(10 big loops altogether). And the time of each loop is 400 ms for c++, 100ms for javascript, and these are long enough for me too feel the difference.
    – streaver91
    Jun 11, 2013 at 4:05
  • 21
    @user2189264, don't feel, measure! Feeling may be good to start a hypothesis but it's no good in evaluating it :-) In any case, printing times outside of the program being called includes stuff outside of what you're measuring (such as the afore-mentioned process startup/shutdown).
    – paxdiablo
    Jun 11, 2013 at 4:06
  • 7
    @user2189264: sigh... if you have access to C++11, just use <chrono> -- solarianprogrammer.com/2012/10/14/… -- no reason to use CLOCKS_PER_SEC-dependent measurement (esp. if that dependence is not taken into account when comparing...).
    – Matt
    Jun 12, 2013 at 19:49
  • 9
    How is anyone "REKT"? The question was about why JS appeared to be faster than C++ (clearly implying that it shouldn't be). This answer explains the most probable reason. The community already has a reputation for mocking people for asking questions, which is pretty embarrassing for a community driven Q&A website.
    – Carl Smith
    Aug 22, 2018 at 2:47
9

Doing a quick test with turning on optimization, I got results of about 150 ms for an ancient AMD 64 X2 processor, and about 90 ms for a reasonably recent Intel i7 processor.

Then I did a little more to give some idea of one reason you might want to use C++. I unrolled four iterations of the loop, to get this:

#include <stdio.h>
#include <ctime>

int main() {
    double a = 3.1415926, b = 2.718;
    double c = 0.0, d=0.0, e=0.0;
    int i, j;
    clock_t start, end;
    for(j=0; j<10; j++) {
        start = clock();
        for(i=0; i<100000000; i+=4) {
            a += b;
            c += b;
            d += b;
            e += b;
        }
        a += c + d + e;
        end = clock();
        printf("Time Cost: %fms\n", (1000.0 * (end - start))/CLOCKS_PER_SEC);
    }
    printf("a = %lf\n", a);
    return 0;
}

This let the C++ code run in about 44ms on the AMD (forgot to run this version on the Intel). Then I turned on the compiler's auto-vectorizer (-Qpar with VC++). This reduced the time a little further still, to about 40 ms on the AMD, and 30 ms on the Intel.

Bottom line: if you want to use C++, you really need to learn how to use the compiler. If you want to get really good results, you probably also want to learn how to write better code.

I should add: I didn't attempt to test a version under Javascript with the loop unrolled. Doing so might provide a similar (or at least some) speed improvement in JS as well. Personally, I think making the code fast is a lot more interesting than comparing Javascript to C++.

If you want code like this to run fast, unroll the loop (at least in C++).

Since the subject of parallel computing arose, I thought I'd add another version using OpenMP. While I was at it, I cleaned up the code a little bit, so I could keep track of what was going on. I also changed the timing code a bit, to display the overall time instead of the time for each execution of the inner loop. The resulting code looked like this:

#include <stdio.h>
#include <ctime>

int main() {
    double total = 0.0;
    double inc = 2.718;
    int i, j;
    clock_t start, end;
    start = clock();

    #pragma omp parallel for reduction(+:total) firstprivate(inc)
    for(j=0; j<10; j++) {
        double a=0.0, b=0.0, c=0.0, d=0.0;
        for(i=0; i<100000000; i+=4) {
            a += inc;
            b += inc;
            c += inc;
            d += inc;
        }
        total += a + b + c + d;
    }
    end = clock();
    printf("Time Cost: %fms\n", (1000.0 * (end - start))/CLOCKS_PER_SEC);

    printf("a = %lf\n", total);
    return 0;
}

The primary addition here is the following (admittedly somewhat arcane) line:

#pragma omp parallel for reduction(+:total) firstprivate(inc)

This tells the compiler to execute the outer loop in multiple threads, with a separate copy of inc for each thread, and adding together the individual values of total after the parallel section.

The result is about what you'd probably expect. If we don't enable OpenMP with the compiler's -openmp flag, the reported time is about 10 times what we saw for individual executions previously (409 ms for the AMD, 323 MS for the Intel). With OpenMP turned on, the times drop to 217 ms for the AMD, and 100 ms for the Intel.

So, on the Intel the original version took 90ms for one iteration of the outer loop. With this version we're getting just slightly longer (100 ms) for all 10 iterations of the outer loop -- an improvement in speed of about 9:1. On a machine with more cores, we could expect even more improvement (OpenMP will normally take advantage of all available cores automatically, though you can manually tune the number of threads if you want).

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  • 2
    @user2189264: Yes and no -- it's still executing in a single core. With a little more work (some openMP directives, for example) we could have it execute on multiple cores as well, effectively multiplying the speed again. All I've done so far though is let it make better use of the resources on a single core (exposed instruction level parallelism, not thread-level parallelism). Jun 11, 2013 at 4:32
  • gcc6 and later notice that they can CSE d and e out of the loop, and compute c+d+e as c +c + c. godbolt.org/g/1BLDfX (Or with FMA, as fma(c, 2.0, c) = c*2.0 + c. If that's legal, then c*3.0 also would be legal...) Anyway, with only two addsd in the loop (for a and c), it becomes more hyperthreading-friendly on CPUs where addsd has a latency:throughput ratio above 2. (e.g. 3:1 on Sandybridge, 4:0.5 on Skylake). And BTW, clang auto-vectorizes with 128-bit vectors. I think it might be doing the same thing, a separate from the 3 that start as 0.0. Jun 13, 2018 at 4:55
  • And BTW, Athlon X2 is a K10 core, I think. Or maybe K8, either way addsd latency = 4, throughput = 1 per clock, so 4 accumulators is just barely enough to hide FP add latency. Jun 13, 2018 at 4:57
  • 1
    @PeterCordes: Yeah--I believe if you wanted to get better performance on a modern Intel, you'd want to unroll more iterations of the inner loop (around 8 or so, if memory serves). Slightly painful, but should roughly double speed. Jun 13, 2018 at 5:54
  • Turns out that just-barely-enough FP accumulators is still somewhat slower than even more, at least when data is coming from memory. Why does mulss take only 3 cycles on Haswell, different from Agner's instruction tables? So I guess uop scheduling doesn't do a perfect job when there are that many parallel dep chains. Probably with this case where there are never any cache misses, just registers, scheduling would do better. Anyway yeah, stuff like this is a major reason why AVX512 doubled the number of architectural vector registers. Jun 13, 2018 at 6:20
6

Even if the post is old, I think it may be interesting to add some information. In summary, your test is too vague and may be biased.

A bit about speed testing methodology

When comparing speed of two languages, you first have to define precisely in which context you want to compare how they perform.

  • "naive" vs "optimized" code : whether or not code tested is made by a beginner or expert programmer. This parameter matters depending on who will participate in your project. For example, when working with scientists (non geeky ones), you will look more for "naive" code performance, because scientists aren't forcibly good programmers.

  • authorized compile time : whether you consider you allow the code to build for long or not. This parameter can matter depending on your project management methodology. If you need to do automated tests, maybe trading a bit of speed to decrease compile time can be interesting. On the other hand, you can consider that distribution version is allowing a high amount of building time.

  • Platform portability : if your speed shall be compared on one platform or more (Windows, Linux, PS4...)

  • Compiler/interpreter portability : if your code's speed shall be compiler/interpreter independent or not. Can be useful for multiplatform and/or open source projects.

  • Other specialized parameters, as for example if you allow dynamic allocations in your code, if you want to enable plugins (dynamically loaded library at runtime) etc.

Then, you have to make sure that your code is representative of what you want to test

Here, (I assume you didn't compiled C++ with optimization flags), you are testing fast-compile speed of "naive" (not so naive actually) code. Because your loop is fixed size, with fixed data, you don't test dynamic allocations, and you -supposedly- allow code transformations (more on that in the next section). And effectively, JavaScript performs usually better than C++ in this case, because JavaScript optimizes at compile time by default, while C++ compilers needs to be told to optimize.

A quick overview of C++ speed increase with parameters

Because I am not knowledgeable enough about JavaScript, I'll only show how code optimization and compilation type can change c++ speed on a fixed for loop, hoping it will answer the question on "how JS can appear to be faster than C++ ?"

For that let's use Matt Godbolt's C++ compiler explorer to see the assembly code generated by gcc9.2

Non optimized code

float func(){
    float a(0.0);
    float b(2.71);
    for (int i = 0;  i < 100000; ++i){
        a = a + b;
    }
    return a;
}

compiled with : gcc 9.2, flag -O0. Produces the following assembly code :

func():
        pushq   %rbp
        movq    %rsp, %rbp
        pxor    %xmm0, %xmm0
        movss   %xmm0, -4(%rbp)
        movss   .LC1(%rip), %xmm0
        movss   %xmm0, -12(%rbp)
        movl    $0, -8(%rbp)
.L3:
        cmpl    $99999, -8(%rbp)
        jg      .L2
        movss   -4(%rbp), %xmm0
        addss   -12(%rbp), %xmm0
        movss   %xmm0, -4(%rbp)
        addl    $1, -8(%rbp)
        jmp     .L3
.L2:
        movss   -4(%rbp), %xmm0
        popq    %rbp
        ret
.LC1:
        .long   1076719780

The code for the loop is what is between ".L3" and ".L2". To be quick, we can see that the code created here is not optimized at all : a lot of memory access are made (no proper use of registers), and because of this there are a lot of wasted operations storing and reloading the result.

This introduces an extra 5 or 6 cycles of store-forwarding latency into the critical path dependency chain of FP addition into a, on modern x86 CPUs. This is on top of the 4 or 5 cycle latency of addss, making the function more than twice as slow.

compiler optimization

The same C++ compiled with gcc 9.2, flag -O3. Produces the following assembly code:

func():
        movss   .LC1(%rip), %xmm1
        movl    $100000, %eax
        pxor    %xmm0, %xmm0
.L2:
        addss   %xmm1, %xmm0
        subl    $1, %eax
        jne     .L2
        ret
.LC1:
        .long   1076719780

The code is much more concise, and uses registers as much as possible.

code optimization

A compiler optimizes code very well usually, especially C++, given that the code is expressing clearly what the programmer wants to achieve. Here we want a fixed mathematical expression to be as fast a possible, so let's change the code a bit.

constexpr float func(){
    float a(0.0);
    float b(2.71);
    for (int i = 0;  i < 100000; ++i){
        a = a + b;
    }
    return a;
}

float call() {
    return func();
}

We added a constexpr to the function to tell the compiler to try to compute it's result at compile time. And added a calling function to be sure that it will generate some code.

Compiled with gcc 9.2, -O3, leads to following assembly code :

call():
        movss   .LC0(%rip), %xmm0
        ret
.LC0:
        .long   1216623031

The asm code is short, since the value returned by func has been computed at compile time, and call simply returns it.


Of course, a = b * 100000 would always compile to efficient asm, so only write the repeated-add loop if you need to explore FP rounding error over all those temporaries.

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  • CPUs have cache and store-forwarding. Store/reload inside a loop only adds about 5 or 6 cycles of latency, not 1000x slower. Nov 8, 2019 at 13:42
  • This has some useful points about enabling optimization, and getting compilers to optimize away loops, but see the top answer on this question: the OP got clock() wrong and was comparing ms vs. us, and C++ was actually 250 times faster with the JS and C++ implementations they tested on. Nov 8, 2019 at 13:56
  • @PeterCordes Thanks for the editing, I compared to RAM to emphasis the speed performance (since on true random acces cache have few chances to not perform well), but it lead to a big misunderstanding. Better leaving it like you edited in my opinion. EDIT : I had not seen how much spelling mistakes I made (didn't had time to reread when posting) so thank you even more for the correction Nov 8, 2019 at 16:45
  • Yes cache misses hurt, but the extra reloads or spill/reloads introduced by -O0 will always be to objects that you already just touched, or to the stack. It's normally safe to assume the stack is hot in cache because of call/ret. The initial access to an object already happens in optimized code, just further access is avoided. It mis-characterizes the cost of -O0 (Why does clang produce inefficient asm with -O0 (for this simple floating point sum)?) to make any claims about going to DRAM, except in rare case of cache conflict-misses. Nov 8, 2019 at 17:03
  • 1
    Right, sure, most cases where it's "build once, run once" take less total CPU time with -Og than -O3 -flto. Possible exceptions including small programs that do extensive number-crunching. Spending lots of compile time makes sense for true release builds where its "build once, run many". Same for video encoding: spend more CPU time to save bits at the same quality if that will be amortized over many downloads or keeping the file around on storage long-term. Dec 14, 2021 at 20:14
4

This is a polarizing topic, so one may have a look at:

https://benchmarksgame-team.pages.debian.net/benchmarksgame/

Benchmarking all kinds of languages.

Javascript V8 and such are surely doing a good job for simple loops as in the example, probably generating very similar machine code. For most "close to the user" applications Javscript surely is the better choice, but keep in mind the memory waste and the many times unavoidable performance hit (and lack of control) for more complicated algorithms/applications.

2
  • Why do you say — For most "close to the user" applications Javscript surely is the better choice ?
    – igouy
    Sep 11, 2018 at 15:03
  • This site is not reliable. For example, none of Java benchmarks include JMH, so they're essientially benchmarking JVM not test scenarios.
    – carbolymer
    Jan 28, 2019 at 12:43
2

There are many good points being brought up about among others, the impact of optimization flags. However, I just wanted to point out that poorly written code will perform poorly in any language, no matter how much more "close to metal" it is.

Your code is written in such a way that it produces a long dependency chain no optimizing compiler will be able to get rid of, unless you explicitly tell it to ignore strict arithmetic compliance.

Notice that every mid-high end desktop CPU from the last 10 years is clocked at 3-4 Ghz, and each core can compute 2-8 double precision FP instructions per cycle, resulting in anywhere between 6-30 GFLOPS. This means your JS implementation reaching 1 GFLOPS is only 3-15% efficient. A properly optimized code would have little problem reaching >90% peak FP, and that's not even counting multicore parallelism.

In short, one might as well compare the efficiency of bubblesort or some other extremely inefficient algorithm nobody actually uses. Inefficient code that needlessly triggers too many cache misses, or creates too many execution stalls in the pipeline due to dependency chains or complex unpredictable logic will execute about as poorly in any language.

And in any case, compiling with --fast-math would probably optimize part of the chain away.

5
  • 90% of peak FLOPS does take some care to achieve; it doesn't just happen that easily. First you have to use 256-bit SIMD FMAs to achieve more than half the theoretical max throughput of a modern CPU. (An FMA is normally counted as two FP ops, even though it costs exactly or about the same as an FP multiply on CPUs that support it.) And that means avoiding other bottlenecks, e.g. at most one load per FMA, and they'd better hit in L1d cache to sustain that bandwidth. See Mysticial's answer on How do I achieve the theoretical maximum of 4 FLOPs per cycle? Aug 4, 2022 at 11:58
  • And to be fair, sequential sum (with 1 scalar accumulator) is widely used, even though it's bad. Unlike Bubble Sort. We have compiler options like -ffast-math to let compilers vectorize with multiple accumulators, improving speed and often reducing rounding error (different but not worse; closer to pairwise summation), but without fast-math them we're stuck with what's in the source. As you say, dependency chains matter. Aug 4, 2022 at 12:02
  • Jerry Coffin's answer shows use of multiple accumulators for this problem. Aug 4, 2022 at 12:06
  • @Peter Cordes Hello. Yes, I am well aware achieving performance is not trivial, but it isn't necessarily that hard either. Most modern optimizing compilers admit pragmas, attributes, flags, etc. for memory alignment, loop unrolling, vectorization and other similar "optimizing hints" that can keep you from having to get your hands too dirty most of the time. Aug 4, 2022 at 21:59
  • Sure, but it's a less well-known issue than abstract algorithmic complexity like Bubble Sort, or even constant factors of Bubble Sort vs. Insertion Sort. Not that it shouldn't be better known, but your phrasing kind of sounds like the OP should have known better. e.g. "one might as well compare bubblesort ... something nobody actually uses" is a bit much in terms of tone. You could present the same information without sounding like someone is dumb for not already knowing this, especially with some links for further reading for people who didn't already understand this concept. Aug 4, 2022 at 23:24
-3

JS of any popular runtime is compiled in C++, so like you probably can't get it to run faster than equivalent native code ... you can prove it by induction by counting from 1 by 1 to google if you want

2
  • 3
    An increment loop doesn't prove anything in general about a language. It's possible to make slow native code, as the OP proved by compiling with optimization disabled. But anyway, neither C++ nor JavaScript native number types can reach 10e100 (1 Googol) incrementing by 1. (Google is a company, not a number).double precision floating point (i.e. a JS number) can represent values as high as 10e308, but 9,007,199,254,740,992 + 1 rounds back to the same number so you'd get stuck there. (i.e. 1 unit in the last place of the mantissa is 2 there) Apr 3, 2020 at 15:52
  • 1
    Please note that most interpreters, including JS' V8, feature JIT compilers, allowing them to translate part of the interpreted code into bytecode, or even native code. Native code produced by JITs can rival native code produced by "traditional" compilers, especially in case of simple constructs as a for loop. Dec 14, 2021 at 14:04

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