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C++11 provides multiple ways to iterate over containers. For example:

Range-based loop

for(auto c : container) fun(c)

std::for_each

for_each(container.begin(),container.end(),fun)

However what is the recommended way to iterate over two (or more) containers of the same size to accomplish something like:

for(unsigned i = 0; i < containerA.size(); ++i) {
  containerA[i] = containerB[i];
}
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4 Answers 4

For your specific example, just use

std::copy_n(contB.begin(), contA.size(), contA.begin())

For the more general case, you can use Boost.Iterator's zip_iterator, with a small function to make it usable in range-based for loops. For most cases, this will work:

template<class... Conts>
auto zip_range(Conts&... conts)
  -> decltype(boost::make_iterator_range(
  boost::make_zip_iterator(boost::make_tuple(conts.begin()...)),
  boost::make_zip_iterator(boost::make_tuple(conts.end()...))))
{
  return {boost::make_zip_iterator(boost::make_tuple(conts.begin()...)),
          boost::make_zip_iterator(boost::make_tuple(conts.end()...))};
}

// ...
for(auto&& t : zip_range(contA, contB))
  std::cout << t.get<0>() << " : " << t.get<1>() << "\n";

Live example.

However, for full-blown genericity, you probably want something more like this, which will work correctly for arrays and user-defined types that don't have member begin()/end() but do have begin/end functions in their namespace. Also, this will allow the user to specifically get const access through the zip_c... functions.

And if you're an advocate of nice error messages, like me, then you probably want this, which checks if any temporary containers were passed to any of the zip_... functions, and prints a nice error message if so.

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Thanks! One question though, why do you use auto&&, what does it mean &&? –  memecs Sep 23 '12 at 16:12
    
@memecs: I recommend reading through this question, aswell as this answer of mine which kinda explains how the deduction and reference collapsing is done. Note that auto works exactly the same as a template parameter, and T&& in a template is a universal reference as explained in the first link, so auto&& v = 42 will be deduced as int&& and auto&& w = v; will then be deduced as int&. It allows you to match lvalues aswell as rvalues and let both be mutable, without making a copy. –  Xeo Sep 23 '12 at 16:18
    
@Xeo: But whats the advantage of auto&& over auto& in a foreach loop? –  Viktor Sehr Sep 25 '13 at 14:43
    
@ViktorSehr: It allows you to bind to temporary elements, like those produced by zip_range. –  Xeo Sep 25 '13 at 14:46
    
@Xeo: I still don't get it, will I avoid a copy by using auto&& instead of auto& in this case? –  Viktor Sehr Sep 25 '13 at 15:07

Rather late to the party. But: I would iterate over indices. But not with the classical for loop but instead with a range-based for loop over the indices:

for(unsigned i : indices(containerA))
    containerA[i] = containerB[i];

indices is a simple wrapper function which returns a (lazily evaluated) range for the indices. Since the implementation – though simple – is a bit too long to post it here, you can find an implementation on GitHub.

This code is as efficient as using a manual, classical for loop.

If this pattern occurs often in your data, consider using another pattern which zips two sequences and produces a range of tuples, corresponding to the paired elements:

for (auto items&& : zip(containerA, containerB))
    get<0>(items) = get<1>(items);

The implementation of zip is left as an exercise for the reader, but it follows easily from the implementation of indices.

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Is there any advantage of your indices implementation in comparison to boost counting_range? One could simply use boost::counting_range(size_t(0), containerA.size()) –  SebastianK Nov 6 at 13:11
    
@SebastianK The biggest difference in this case is syntax: mine is (I claim) objectively better to use in this case. Furthermore, you can specify a step size. See the linked Github page, and in particular the README file, for examples. –  Konrad Rudolph Nov 6 at 14:03
    
Your idea is very nice and I came up with the use of counting_range only after seeing it: clear upvote :) However, I wonder if it provides additional value to (re-)implement this. E.g., regarding performance. Nicer syntax, I agree, of course, but it would be enough to write a simple generator function to compensate this drawback. –  SebastianK Nov 6 at 15:11
    
@SebastianK I admit that I when I wrote the code I deemed it simple enough to live in isolation without using a library (and it is!). Now I would probably write it as a wrapper around Boost.Range. That said, the performance of my library is already optimal. What I mean by this is that using my indices implementation yields compiler output which is identical to using manual for loops. There is no overhead whatsoever. –  Konrad Rudolph Nov 6 at 15:17
    
Since I use boost anyway, it would be simpler in my case. I already wrote this wrapper around boost range: a function with one line of code is all I need. However, I would be interested if the performance of boost ranges is optimal as well. –  SebastianK Nov 6 at 15:45

There are a lot of ways to do specific things with multiple containers as provided in the algorithm header. For instance, in the example you've given, you could use std::copy instead of an explicit for loop.

On the other hand, there isn't any built-in way to generically iterate multiple containers other than a normal for loop. This isn't surprising because there are a lot of ways to iterate. Think about it: you could iterate through one container with one step, one container with another step; or through one container until it gets to the end then start inserting while you go through to the end of the other container; or one step of the first container for every time you completely go through the other container then start over; or some other pattern; or more than two containers at a time; etc ...

However, if you wanted to make your own "for_each" style function that iterates through two containers only up to the length of the shortest one, you could do something like this:

template <typename Container1, typename Container2>
void custom_for_each(
  Container1 &c1,
  Container2 &c2,
  std::function<void(Container1::iterator &it1, Container2::iterator &it2)> f)
{
  Container1::iterator begin1 = c1.begin();
  Container2::iterator begin2 = c2.begin();
  Container1::iterator end1 = c1.end();
  Container2::iterator end2 = c2.end();
  Container1::iterator i1;
  Container1::iterator i2;
  for (i1 = begin1, i2 = begin2; (i1 != end1) && (i2 != end2); ++it1, ++i2) {
    f(i1, i2);
  }
}

Obviously you can make any kind of iterations strategy you want in a similar way.

Of course, you might argue that just doing the inner for loop directly is easier than writing a custom function like this ... and you'd be right, if you are only going to do it one or two times. But the nice thing is that this is very reusable. =)

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In case when you need to iterate simultaneously over 2 containers only, there is an extended version of standard for_each algorithm in boost range library, e.g:

#include <vector>
#include <boost/assign/list_of.hpp>
#include <boost/bind.hpp>
#include <boost/range/algorithm_ext/for_each.hpp>

void foo(int a, int& b)
{
    b = a + 1;
}

int main()
{
    std::vector<int> contA = boost::assign::list_of(4)(3)(5)(2);
    std::vector<int> contB(contA.size(), 0);

    boost::for_each(contA, contB, boost::bind(&foo, _1, _2));
    // contB will be now 5,4,6,3
    //...
    return 0;
}

When you need to handle more than 2 containers in one algorithm, then you need to play with zip.

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