2

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.

Thanks!

  • 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
6

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
4

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;
}

Prints

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)
    {
        a.sum+=i;
        a.product*=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;
}

Benchmarks:

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

Your Answer

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

Not the answer you're looking for? Browse other questions tagged or ask your own question.