82

I heard on a forum using std::function<> causes performance drop. Is it true? If true, is it a big performance drop?

6
  • 37
    Causes a performance drop compared to what alternative?
    – Fred Nurk
    Feb 20 '11 at 13:54
  • 4
    You will have to be a lot more specific than that, user408141. Feb 20 '11 at 13:54
  • 6
    Really, this is such a poor question.
    – sbi
    Feb 20 '11 at 14:03
  • I edited the title to be a bit more meaningful. As to "compared to what" - persumable compared to a handrolled less generic solution...
    – UncleBens
    Feb 20 '11 at 14:13
  • Oh sorry, i am soooooo clumsy! :D
    – user408141
    Feb 20 '11 at 14:25
97

There are, indeed, performance issues with std:function that must be taken into account whenever using it. The main strength of std::function, namely, its type-erasure mechanism, does not come for free, and we might (but not necessarily must) pay a price for that.

std::function is a template class that wraps callable types. However, it is not parametrized on the callable type itself but only on its return and argument types. The callable type is known only at construction time and, therefore, std::function cannot have a pre-declared member of this type to hold a copy of the object given to its constructor.

Roughly speaking (actually, things are more complicated than that) std::function can hold only a pointer to the object passed to its constructor, and this raises a lifetime issue. If the pointer points to an object whose lifetime is smaller than that of the std::function object, then the inner pointer will become dangling. To prevent this problem std::function might make a copy of the object on the heap through a call to operator new (or a custom allocator). The dynamic memory allocation is what people refer the most as a performance penalty implied by std::function.

I have recently written an article with more details and that explains how (and where) one can avoid paying the price of a memory allocation.

Efficient Use of Lambda Expressions and std::function

9
  • So this describes overhead of constructing / destructing a std::function. boost::function states this about invocation performance: "With a properly inlining compiler, an invocation of a function object requires one call through a function pointer. If the call is to a free function pointer, an additional call must be made to that function pointer (unless the compiler has very powerful interprocedural analysis)."
    – mucaho
    Nov 5 '15 at 20:27
  • Is the dynamic allocation performed only once ? I mean, once initialized, does it perform exactly as if using function pointers? Mar 21 '18 at 11:23
  • It's worthy to notice if the wrapped object is small (e.g. no more than 16 bytes for std::function on Linux) and small object optimization is turned on, std::function will not attempt to do any heap allocation. Note that you must use std::cref or std::ref to wrap the passed-in parameters to avoid copying during the call tree. In this case for function without too many parameters e.g. a std::shared_ptr; a simple primitive; etc, there is no heap allocation. This is particularly useful if one is wrapping some lambda with simple parameters.
    – Alex Suo
    Aug 16 '18 at 3:48
  • 1
    @Ruslan Sadly so. Unfortunately DrDobbs closed down a few years ago and I don't know what is happening to old content. I couldn't find my article anywhere. I'm sorry and sad about that :-( Oct 31 '19 at 16:28
  • 1
    @MohammedNoureldin That's a shame. As I said in another comment, DrDobbs closed down a few years ago. Sometimes I can find old content somewhere, sometimes I can't. I don't know if I kept a copy of this article. Even if I do, I don't know if I'm allowed to publish/post it elsewhere. Often authors are required to give away the copyright to publishers and loose their rights. (Although DrDobbs is dead, their lawyers still might be awake.) I can't remember if that was the case of this article. If I can I'll try to recover it but I can't promise anything. I'm really sorry about that. Mar 26 at 11:22
17

You can find information from the boost's reference materials: How much overhead does a call through boost::function incur? and Performance

This doesn't determine "yes or no" to boost function. The performance drop may be well acceptable given program's requirements. More often than not, parts of a program are not performance-critical. And even then it may be acceptable. This is only something you can determine.

As to the standard library version, the standard only defines an interface. It is entirely up to individual implementations to make it work. I suppose a similar implementation to boost's function would be used.

14

Firstly, the overhead gets smaller with the inside of the function; the higher the workload, the smaller the overhead.

Secondly: g++ 4.5 does not show any difference compared to virtual functions:

main.cc

#include <functional>
#include <iostream>

// Interface for virtual function test.
struct Virtual {
    virtual ~Virtual() {}
    virtual int operator() () const = 0;
};

// Factory functions to steal g++ the insight and prevent some optimizations.
Virtual *create_virt();
std::function<int ()> create_fun();
std::function<int ()> create_fun_with_state();

// The test. Generates actual output to prevent some optimizations.
template <typename T>
int test (T const& fun) {
    int ret = 0;
    for (int i=0; i<1024*1024*1024; ++i) {
        ret += fun();
    }    
    return ret;
}

// Executing the tests and outputting their values to prevent some optimizations.
int main () {
    {
        const clock_t start = clock();
        std::cout << test(*create_virt()) << '\n';
        const double secs = (clock()-start) / double(CLOCKS_PER_SEC);
        std::cout << "virtual: " << secs << " secs.\n";
    }
    {
        const clock_t start = clock();
        std::cout << test(create_fun()) << '\n';
        const double secs = (clock()-start) / double(CLOCKS_PER_SEC);
        std::cout << "std::function: " << secs << " secs.\n";
    }
    {
        const clock_t start = clock();
        std::cout << test(create_fun_with_state()) << '\n';
        const double secs = (clock()-start) / double(CLOCKS_PER_SEC);
        std::cout << "std::function with bindings: " << secs << " secs.\n";
    }
}

impl.cc

#include <functional>

struct Virtual {
    virtual ~Virtual() {}
    virtual int  operator() () const = 0;
};
struct Impl : Virtual {
    virtual ~Impl() {}
    virtual int  operator() () const { return 1; }
};

Virtual *create_virt() { return new Impl; }

std::function<int ()> create_fun() { 
    return  []() { return 1; };
}

std::function<int ()> create_fun_with_state() { 
    int x,y,z;
    return  [=]() { return 1; };
}

Output of g++ --std=c++0x -O3 impl.cc main.cc && ./a.out:

1073741824
virtual: 2.9 secs.
1073741824
std::function: 2.9 secs.
1073741824
std::function with bindings: 2.9 secs.

So, fear not. If your design/maintainability can improve from prefering std::function over virtual calls, try them. Personally, I really like the idea of not forcing interfaces and inheritance on clients of my classes.

6
  • 2
    @Xeo: True. But verification is better than belief :) When you don't use optimizations, the same test shows a 1:3 difference against std::function, so this test is not completely unjustified. Jan 18 '12 at 10:02
  • 1
    With G++ 4.8.2, I consistently get 2.9, 3.3 and 3.3 seconds. If I add -flto they all become 3.3. My totally wild guess is that GCC actually tries to optimize std::function (similar to what one gets with -flto and virtual functions), but the optimizations actually hurt.
    – bobcat
    Feb 2 '14 at 20:25
  • 3
    Using g++ 5.3, I get 2.0, 2.3, 2.3 (-O2); 0.7, 2.0, 2.0 (-O2 -flto); 2.3, 2.3, 2.3 (-O2 -flto -fno-devirtualize); 2.0, 2.3, 2.3 (-O2 -fno-devirtualize). So it appears devirtualization in newer g++ versions has improved enough that this is no longer a deoptimization. Jun 20 '16 at 17:37
  • 3
    g++ 6.3.0: g++ -std=gnu++14 -O3 -flto -march=native impl.cpp main.cpp && ./a.out 1073741824 virtual: 1.97619 secs. 1073741824 std::function: 6.86855 secs. 1073741824 std::function with bindings: 6.86847 secs. Mar 15 '17 at 13:18
  • 2
    g++ 7.4.0 on Ubuntu 18.04 (AMD 2400G): ` g++ --std=c++17 -O3 impl.cc main.cc && ./a.out`: virtual: 1.38742 secs., std::function: 1.44681 secs., std::function with bindings: 1.39367 secs. May 30 '19 at 15:50
13

This depends strongly if you are passing the function without binding any argument (does not allocate heap space) or not.

Also depends on other factors, but this is the main one.

It is true that you need something to compare against, you can't just simply say that it 'reduces overhead' compared to not using it at all, you need to compare it to using an alternative way to passing a function. And if you can just dispense of using it at all then it was not needed from the beginning

1
  • 3
    Even binding arguments might not incur dynamic allocation if the implementation uses small-buffer optimisation to store the function object in the std::function instance and the passed callable is within the suitable size for SBO. May 14 '17 at 21:49
0

std::function<> / std::function<> with bind( ... ) is extremely fast. Check this:

#include <iostream>
#include <functional>
#include <chrono>

using namespace std;
using namespace chrono;

int main()
{
    static size_t const ROUNDS = 1'000'000'000;
    static
    auto bench = []<typename Fn>( Fn const &fn ) -> double
    {
        auto start = high_resolution_clock::now();
        fn();
        return (int64_t)duration_cast<nanoseconds>( high_resolution_clock::now() - start ).count() / (double)ROUNDS;
    };
    int i;
    static
    auto CLambda = []( int &i, int j )
    {
        i += j;
    };
    auto bCFn = [&]() -> double
    {
        void (*volatile pFnLambda)( int &i, int j ) = CLambda;
        return bench( [&]()
            {   
                for( size_t j = ROUNDS; j--; j )
                    pFnLambda( i, 2 );
            } );
    };
    auto bndObj = bind( CLambda, ref( i ), 2 );
    auto bBndObj = [&]() -> double
    {
        decltype(bndObj) *volatile pBndObj = &bndObj;
        return bench( [&]()
            {
                for( size_t j = ROUNDS; j--; j )
                    (*pBndObj)();
            } );
    };
    using fn_t = function<void()>;
    auto bFnBndObj = [&]() -> double
    {
        fn_t fnBndObj = fn_t( bndObj );
        fn_t *volatile pFnBndObj = &fnBndObj;
        return bench( [&]()
            {
                for( size_t j = ROUNDS; j--; j )
                    (*pFnBndObj)();
            } );
    };
    auto bFnBndObjCap = [&]() -> double
    {
        auto capLambda = [&i]( int j )
        {
            i += j;
        };
        fn_t fnBndObjCap = fn_t( bind( capLambda, 2 ) );
        fn_t *volatile pFnBndObjCap = &fnBndObjCap;
        return bench( [&]()
            {
                for( size_t j = ROUNDS; j--; j )
                    (*pFnBndObjCap)();
            } );
    };
    using bench_fn = function<double()>;
    static const
    struct descr_bench
    {
        char const *descr;
        bench_fn const fn;
    } dbs[] =
    {
        { "C-function",
          bench_fn( bind( bCFn ) ) },
        { "C-function in bind( ... ) with all parameters",
          bench_fn( bind( bBndObj ) ) },
        { "C-function in function<>( bind( ... ) ) with all parameters",
          bench_fn( bind( bFnBndObj ) ) },
        { "lambda capturiging first parameter in function<>( bind( lambda, 2 ) )",
          bench_fn( bind( bFnBndObjCap ) ) }
    };
    for( descr_bench const &db : dbs )
        cout << db.descr << ":" << endl,
        cout << db.fn() << endl;
}

All calls are below 2ns on my computer.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy