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This is the first question I'm posting here, so I hope I won't do anything wrong.

My question concerns the performance of modern-style C++11 loops (std::for_each, range-based for) vs old-style C++ loops (for (...; ...; ...)). From what I understood, it seems to me that the motto of modern C++ is "expressivity with no compromise on performance". Modern C++ style leads to safe, clean, and fast code with little to no performance penalty and, possibly, with a performance gain over old-style C++.

Now I've made a little test to assess how big this gain is concerning loops. First I wrote the following three functions:

using namespace std;

void foo(vector<double>& v)
{
    for (size_t i = 0; i < v.size(); i++)
    {
        v[i] /= 42;
    }
}

void bar(vector<double>& v)
{
    for (auto& x : v)
    {
        x /= 42;
    }
}

void wee(vector<double>& v)
{
    for_each(begin(v), end(v), [] (double& x)
    {
        x /= 42;
    });
}

Then I compared their performance by calling them this way (properly commenting/uncommenting the three lines inside main()'s loop:

vector<double> make_vector()
{
    vector<double> v;
    for (int i = 0; i < 30000; i++) { v.push_back(i); }
    return v;
}

int main()
{
    time_t start = clock();

    auto v = make_vector();
    for (int i = 0; i <= 50000; i++) 
    { 
        // UNCOMMENT THE FUNCTION CALL TO BE TESTED, COMMENT THE OTHERS

        foo(v);
        // bar(v); 
        // wee(v);
    }

    time_t end = clock();
    cout << (end - start) << endl;

    return 0;
}

Averaging over 10 executions of each version of the program obtained by commenting/uncommenting the lines in main()'s loop, and using the old-style loop as a baseline, the range-based for loop performs ~1.9x worse, and the loop based on std::for_each and lambdas performs ~2.3x worse.

I used Clang 3.2 to compile this, and I haven't tried MS VC11 (I'm working on WinXP).

Considering my expectation of getting comparable execution times, my questions are:

  1. Did I do something obviously wrong?
  2. If not, couldn't a 2x performance penalty be a good reason NOT to embrace modern-style loops?

I would like to remark, that I do believe that the clarity and safety of code written in modern C++ style pay off for a possible performance loss, but I quite disagree with the statement that there is no trade-off between clarity/safety on one side and performance on the other side.

Am I missing something? Can anyone comment on this?

Thank you in advance,

Andy

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3  
I just ran your code (compiled with Clang) and all three ran in approximately the same amount of time. Do you have optimisation enabled in your compiler? –  Mankarse Dec 27 '12 at 14:13
6  
@AndyProwl: Add -O3 to enable heavy optimisation. –  Mankarse Dec 27 '12 at 14:20
2  
@Mankarse: OK, thanks for the tip, obviously I was missing something fundamental. I get comparable execution times now. Thank you! –  Andy Prowl Dec 27 '12 at 14:27
1  
Why time the make_vector call? This is constant overhead for each test (but of course the time will vary slightly each run, giving you fuzzier results unnecessarily). –  GManNickG Dec 27 '12 at 22:42
1  
@GManNickG: You are absolutely right, I overlooked that one and make_vector() should certainly not be timed. Actually, not timing it would make the difference even bigger. However, the whole point is that my comparison was flawed as I was not using the -O3 flag in the command line. Optimization really makes the execution times comparable, so there's really no loss in performance, which is what I was concerned with. –  Andy Prowl Dec 27 '12 at 23:37

2 Answers 2

up vote 4 down vote accepted

It looks like the difference only shows up when you do not enable optimisations in your compiler.

With Clang you can enable optimisation with the -O[0-3] flag.

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Overall overhead caused by the loop statement is anyway so minimal compared to the work rest of the code is doing, that I wouldn't bother with that.

As an example, if your loop code is 0.000001% of your application time, changing it to old style loop will give you a speed benefit of... 0.0000005%.

As to your results : they are worth nothing. Measuring overhead of these loops is best done by assembly analize.

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1  
Thank you for answering first of all, your point is good. However, if I am writing a library I don't know whether my loop will be 0.0001% or 1% or 10% of the application time of the client code; especially if I have loops with a small body, a 2x performance penalty might be worth considering IMO. To be honest, this objection doesn't apply in the end because of what another user wrote in a comment: I was missing the -O3 heavy optimization switch in my command line, which made execution times comparable. –  Andy Prowl Dec 27 '12 at 14:31
    
Ok, thank you for the tip. As I wrote, I am a beginner, so the easiest way to compare the overhead was to measure it with a small loop body. Could you please elaborate a bit on why running times are worth nothing? I'm not questioning it, I just want to learn. –  Andy Prowl Dec 27 '12 at 14:34
    
Well, mainly because the time they execute is very close to the resolution of your timer. –  Bartek Banachewicz Dec 27 '12 at 14:55
    
OK, not sure I can agree. Maybe for very short loops this is true, but if I iterate over a collection of hundreds of thousands of elements, that's not the case. With the code I posted and without the -O3 optimization I got running times around 15 seconds for the baseline. With the -O3 optimization it went down to about 2 seconds, but I could easily bring it up again by doing more iterations. Am I missing something? –  Andy Prowl Dec 27 '12 at 15:01

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