I trying to convert some loops in my code to use the for_each functionality of the STL. Currently, I calculate and accumulate two separate values over the same set of data, requiring me to loop over the data twice. In the interest of speed, I want to loop once and accumulate both values. Using for_each was suggested as it apparently can be worked into a multithreaded or multiprocessor implementation fairly easily (I haven't learned how to do that yet.)

Creating a function that only loops over the data once and calculates both values is easy, but I need to return both. To use with for_each, I need to return both calculated values at each iteration so STL can sum them. From my understanding, this isn't possible as for_each expects a single value returned.

The goal with using for_each, besides cleaner code (arguably?) is to eventually move to a multithreaded or multiprocessor implementation so that the loop over the data can be done in parallel so things run faster.

It was suggested to me that I look at using a functor instead of a function. However, that raises two issues.

  1. How will using a functor instead allow the return accumulation of two values?
  2. I have two methods of applying this algorithm. The current code has a virtual base class and then two classes that inherit and implement the actual working code. I can't figure out how to have a "virtual functor" so that each method class can implement its own version.


  • 4
    s/STL/C++ Standard Library/ *ducks* – Lightness Races in Orbit Sep 11 '11 at 18:01
  • What container are you iterating over? Do its elements contain the two values to be accumulated or they are in two different containers? – Matteo Italia Sep 11 '11 at 18:05
  • 2
    Based on your description, you should be using std::accumulate instead of std::for_each (in fact, I've found good uses for std::for_each to be rather rare). – Jerry Coffin Sep 11 '11 at 18:32
  • I am iterating over a column of data in a compressed column format matrix. The two values to be accumulated are the result of two different sets of calculations on the same value. – Noah Sep 11 '11 at 19:15
  • Out of curiosity I benchmarked three variants (1, 2, 3); the result is strongly in support of relying on the compiler to optimize – sehe Sep 11 '11 at 19:38

Here is an example of using a functor to perform two accumulations in parallel.

struct MyFunctor
    // Initialise accumulators to zero
    MyFunctor() : acc_A(0), acc_B(0) {}

    // for_each calls operator() for each container element
    void operator() (const T &x)
        acc_A += x.foo();
        acc_B += x.bar();

    int acc_A;
    int acc_B;

// Invoke for_each, and capture the result
MyFunctor func = std::for_each(container.begin(), container.end(), MyFunctor());

[Note that you could also consider using std::accumulate(), with an appropriate overload for operator+.]

As for virtual functors, you cannot do these directly, as STL functions take functors by value, not by reference (so you'd get a slicing problem). You'd need to implement a sort of "proxy" functor that in turn contains a reference to your virtual functor.* Along the lines of:

struct AbstractFunctor
    virtual void operator() (const T &x) = 0;

struct MyFunctor : AbstractFunctor
    virtual void operator() (const T &x) { ... }

struct Proxy
    Proxy(AbstractFunctor &f) : f(f) {}
    void operator() (const T &x) { f(x); }
    AbstractFunctor &f;

MyFunctor func;
std::for_each(container.begin(), container.end(), Proxy(func));

* Scott Meyers gives a good example of this technique in Item 38 of his excellent Effective STL.

  • Nice example. Will this survive parallelism? If I have multiple threads, how will acc_A have the correct total value? – Noah Sep 11 '11 at 19:13

Three (main) approaches

Ok, I ended up doing three (main) implementations (with minor variations). I did a simple benchmark to see whether there were any efficiency differenes. Check the benchmarks section at the bottom

1. std::for_each with c++0x lambda

Taking some c++0x shortcuts: see http://ideone.com/TvJZd

#include <vector>
#include <algorithm>
#include <iostream>

int main()
    std::vector<int> a = { 1,2,3,4,5,6,7 };

    int sum=0, product=1;

    std::for_each(a.begin(), a.end(), [&] (int i) { sum+=i; product*=i; });

    std::cout << "sum: " << sum << ", product: " << product << std::endl;

    return 0;


sum: 28, product: 5040

As mentioned by others, you'd normally prefer a normal loop:

for (int i: a)
{ sum+=i; product*=i; }

Which is both

  • shorter,
  • more legible,
  • less unexpected (ref capturing) and
  • likely more optimizable by the compiler

Also, very close in non-c++11/0x:

for (std::vector<int>::const_iterator it=a.begin(); it!=a.end(); ++it)
{ sum+=*it; product*=*it; }

2. std::accumulate with handwritten accumulator object

Added one based on std::accumulate: see http://ideone.com/gfi2C

struct accu_t
    int sum, product;
    static accu_t& handle(accu_t& a, int i)
        return a;
} accum = { 0, 1 };

accum = std::accumulate(a.begin(), a.end(), accum, &accu_t::handle);

3. std::accumulate with std::tuple

Ok I couldn't resist. Here is one with accumulate but operating on a std::tuple (removing the need for the functor type): see http://ideone.com/zHbUh

template <typename Tuple, typename T>
    Tuple handle(Tuple t, T v)
    std::get<0>(t) += v;
    std::get<1>(t) *= v;
    return t;

int main()
    std::vector<int> a = { 1,2,3,4,5,6,7 };

    for (auto i=1ul << 31; i;)
        auto accum = std::make_tuple(0,1);
        accum = std::accumulate(a.begin(), a.end(), accum, handle<decltype(accum), int>);

        if (!--i)
            std::cout << "sum: " << std::get<0>(accum) << ", product: " << std::get<1>(accum) << std::endl;

    return 0;


Measured by doing the accumulation 2<<31 times (see snippet for the std::tuple based variant). Tested with -O2 and -O3 only:

  • there is no measurable difference between any of the approaches shown (0.760s):

  • all variants exhibit a speed up of more than 18x going from -O2 to -O3 (13.8s to 0.760s), again regardless of the implementation chosen

  • The tuple/accumulate the performance stays exactly the same with Tuple& handle(Tuple& t, T v) (by reference).
  • sehe, Awesome answer!! I really appreciate you taking the time to work through all three versions. I'm still learning C++ and this helps a lot. Thanks!! – Noah Sep 12 '11 at 18:52
  • @Noah: I learned things too. Don't sweat all the options if you're still learning. I'd stick to proper loops for cases like this :) At least now you know there isn't necessarily a performance gain. I suggest you learn the basics well and build a 'map' of the uncharted territory. That way, you'll know what to dig into when the time is there (or you just plain need it) – sehe Sep 12 '11 at 18:54
  • Just discovered that, unfortunately, I can't use C++0x for this project, so I don't have an std::tuple. Additionally, I'm concerned about just coding a functor that stores the accumulated values. This code will be converted to multithread and/or multiprocessor, so there might be issues with the functor storage. Ideally I need an accumulate function that will return two values. – Noah Sep 12 '11 at 19:33
  • @Noah: I don't understand your concern regarding the functor with storage. In my sample using the accu_t accumulator/function, the accumulator is stack allocated. It is therefore not shared (it is even reentrant: recursive calls to the containing function will get separate instances). In fact, all variants I listed have exactly the same storage semantics, only the compiler types vary. Hope that helps. Why don't you stick to the simplest variant (the one labeled 'prefer a normal loop:')? – sehe Sep 12 '11 at 19:53
  • I currently have a "normal loop". My boss asked me to this using either for_each or accumulate. I know nothing about multithreading, but apparently there are some shortcuts to ask the compiler to run a for_each or accumulate across multiple processors – Noah Sep 12 '11 at 21:40

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