Is there a standard implementation of a for_each that does call with the element and the next one in the range?

For example take the range {0, 1, 2, 3, 4, 5}, I would like to call a function f with each element and its successor: {f(0, 1), f(1, 2), f(2, 3), f(3, 4), f(4, 5)} Note how the last element is left out because it has no successor.

It would also be nice if there was a generalization of this to n successors that get passed with the element itself.

Up to now I have always solved this in terms of a handwritten loop with iterators. However, I would like to go much more along the lines of C++11 range based for or std::for_each to avoid boiler plate code.


// today: handwritten loop
for(Range::iterator current = range.begin(); current != range.end(); ++current) 
   f(*current, *std::next(current));

// near future: wrapped version
for_each_pair(range.begin(), range.end(), f);

// slightly further future: generalized version
for_each_tuple<n>(range.begin(), range.end(), f);

Additional Question

The name of the function could be improved. To me for_each_pair/tuple sounds like all subsets of size n of the range should be returned (which is in itself another problem I would like to solve). So I'd like some suggestions on better names like:


Temporary Solution

I have posted my own solution over at CR. I won't duplicate it here because this is about a standard solution and there are already enough roll-your-own answers.

  • A quick perusal of the <algorithms> of C++ show no evidence of such a beast, but it wouldn't be the first time I've missed something. Any particular reason you continue to write boilerplate code rather than just templatize an iterator based solution and throw it in your toolbox ? – WhozCraig Nov 12 '13 at 11:17
  • @WhozCraig: So far only the nagging feeling that there must be a standard implementation (std or boost) and pure laziness have held me from wrapping up my own version. – Nobody Nov 12 '13 at 11:19
  • Ah, well I can't comment on boost, as I never use it (was bitten severely on a commercial product that relied on their serialization algorithm, which changed; banned for life from work). It certainly appears you have the faculties to do this, and have even considered extensions (the tuple approach as a general solution is a good one). You may have to dust off an afternoon and jam it out. +1 for the interesting question, btw. – WhozCraig Nov 12 '13 at 11:21
  • Just as a quick heads up: I posted some code relating to this on CR. When it is more polished I might post it as an answer here. – Nobody Sep 30 '15 at 7:35

You could actually abuse std::unique or std::adjacent_find for this: the predicate is called with each consecutive pair in the iterator range, and as long as the predicate always returns false, it won't modify anything or return early.

Disregarding that particular hack, I would implement this as an iterator adapter, not an algorithm. That is, I'd implement a consecutive_tuple_iterator<N> which would return all tuples of N consecutive items. Then you could use it for things like count_if and includes, not just for_each. (It wouldn't be appropriate for most modifying algorithms, though.)

  • Although it would probably work, the hack would rely on implementation internals of the two mentioned algorithms which is not a good idea. You are right about the iterator, I had not yet encountered other uses but this is mainly due to the fact that I had the boilerplate for_each up to now. – Nobody Nov 12 '13 at 11:51
  • It would not rely on implementation details in the case of adjacent_find; the behavior of that algorithm is closely defined by the standard. – Sneftel Nov 12 '13 at 11:53
  • I would go with a skip forward iterator adaptor for a first pass. Then modify it to return a tuple, and tweak end detection. – Yakk - Adam Nevraumont Nov 12 '13 at 12:53

The simplest thing would be to write it as a generic algorithm, then apply it many times.

 template< typename FwdIter, typename Func >
 Func for_each_pair( FwdIter iterStart, FwdIter iterEnd, Func func )
     if( iterStart == iterEnd )
        return func;

     FwdIter iterNext = iterStart;

     for( ; iterNext != iterEnd; ++iterStart, ++iterNext )
          func( *iterStart, *iterNext );
     return func;

As I was asked why it returns func (rather than void), this is typical of a for_each because of the fact that

  1. func could be an object
  2. It is passed by value.

func may "accumulate" some kind of state, but it is the copy we have made into this algorithm that is accumulating it, not the user's original object. We therefore pass them back the modified "func" object.

  • Why do you return func? – Nobody Nov 12 '13 at 12:35
  • 1
    Because func doesn't have to be an actual function but can be an object, which can hold state, and these will often be copied. The func object passed in has been copied so will not receive the new state, so we return it back, with any modifications – CashCow Nov 12 '13 at 12:44
  • In such a case I think would be better to write an std::accumulate-alike function, it's more expressive. If the function status (its result type) is complex, just provide operators as required and you're good to go. – ubik Jul 23 '16 at 15:54
  • The alternative is to make a special iterator then apply it to any algorithm. You'll create it with a make_pair_iter_begin and make_pair_iter_end for the collection and possibly one for a random forward iterator. – CashCow Sep 20 '18 at 13:42

With C++ 11 and the new iterator helper functions std::next and std::prev for iterators, the second variant of the standard algorithm std::transform can be used to iterate over adjacent elements.

Here is an example that generates a list of adjacent pairs from a list:

std::vector<int> nums{3, 4, 2, 9, 15, 267};
std::vector<std::pair<int,int>> num_pairs;
if (!nums.empty()) {
        std::begin(nums), std::prev(std::end(nums)),
  • This would also be possible in C++03 with just a bit more code. However, it only solves the problem for two neighboring nodes and does more than a simple for each (one could work around that by providing a dummy iterator). – Nobody Mar 25 '15 at 10:12

Not exactly what you want, but take a look at cpplinq.

int numbers[] = {0, 1, 2, 3, 4, 5};
auto pairs = cpplinq::from_array(numbers) 
          >> cpplinq::pairwise() 
          >> cpplinq::to_vector(); // yields (0,1), (1,2), (2,3), (3,4), (4,5)

for(auto p : pairs)
    f(p.first, p.second);
  • I have no experience with cpplinq (which makes it "non standard" for me) but it seems that this creates a temporary vector containing the elements which is a big overhead. – Nobody Nov 12 '13 at 12:37

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