In many languages, there are generators that help to initialize collections. In C++, if one wants to initialize a vector uniformly, one can write:

std::vector<int> vec(10, 42); // get 10 elements, each equals 42

What if one wants to generate different values on the fly? For example, initialize it with 10 random values, or consecutive numbers from 0 to 9? This syntax would be convenient, but it does not work in C++11:

int cnt = 0;
std::vector<int> vec(10, [&cnt]()->int { return cnt++;});

Is there a nice way to initialize a collection by iterative function calls? I currently use this ugly pattern (not much more readable/short than a loop):

std::vector<int> vec;
int cnt = 0;
std::generate_n(std::back_inserter(vec), 10, [&cnt]()->int { return cnt++;});

There is a thing that would help, and it would explain the lack of the first constructor. I can imagine an iterator that takes a function and number of calls, so that the constructor

vector ( InputIterator first, InputIterator last);

would be applicable. But I did not find anything like this in the standard library. Did I miss it? Is there another reason why the first constructor did not make it to the standard?

  • 1
    I don't find that pattern so ugly, but I like this question. I am curious to learn whether there is another reason apart from avoiding class interface bloat.
    – Gorpik
    Commented Sep 20, 2012 at 11:45
  • 3
    On the bright side, C++ is the perfect language for you to write an iterable object that implements your desired semantics!
    – Kerrek SB
    Commented Sep 20, 2012 at 11:46

5 Answers 5


Sadly, there is no standard facility to do this.

For your specific example, you could use Boost.Iterator's counting_iterator like this:

std::vector<int> v(boost::counting_iterator<int>(0),

Or even with Boost.Range like this:

auto v(boost::copy_range<std::vector<int>>(boost::irange(0,10)));

(copy_range will basically just return std::vector<int>(begin(range), end(range)) and is a great way to adopt full range construction to exisiting containers that only support range construction with two iterators.)

Now, for the general purpose case with a generator function (like std::rand), there is the function_input_iterator. When incremented, it calls the generator and saves the result, which is then returned when dereferencing it.

#include <vector>
#include <iostream>
#include <cmath>
#include <boost/iterator/function_input_iterator.hpp>

int main(){
  std::vector<int> v(boost::make_function_input_iterator(std::rand, 0),
  for(auto e : v)
    std::cout << e << " ";

Live example.

Sadly, since function_input_iterator doesn't use Boost.ResultOf, you need a function pointer or a function object type that has a nested result_type. Lambdas, for whatever reason, don't have that. You could pass the lambda to a std::function (or boost::function) object, which defines that. Here's an example with std::function. One can only hope that Boost.Iterator will make use of Boost.ResultOf someday, which will use decltype if BOOST_RESULT_OF_USE_DECLTYPE is defined.

  • 2
    Hmm. Local structs cannot be used as template arguments in C++03, and in C++11 you have lambdas. Commented Sep 20, 2012 at 11:58
  • @Konrad: I explain why I use the local struct in C++11 code just below the code. Basically, a lambda type doesn't define result_type for whatever reason. :( And in C++03, you can always go the not-nice route of defining it as a non-local struct.
    – Xeo
    Commented Sep 20, 2012 at 11:59
  • Duh. I had tacitly assumed that lambdas defined that but to be fair there’s no reason to – we have result_of, after all. Will Boost.Iterator add support for that? Commented Sep 20, 2012 at 12:15
  • @Konrad: One can only hope. :/ In other news, updated the code to show better / more concise ways for the specific case of a sequence.
    – Xeo
    Commented Sep 20, 2012 at 12:18
  • You answer is the closest one to meeting my expectations. Thanks! Commented Sep 21, 2012 at 16:49

The world is too large for C++ to ship a solution for everything. However, C++ doesn't want to be a huge supermarket full of ready meals for every conceivable palate. Rather, it is a small, well-equipped kitchen in which you, the C++ Master Chef, can cook up any solution you desire.

Here's a silly and very crude example of a sequence generator:

#include <iterator>

struct sequence_iterator : std::iterator<std::input_iterator_tag, int>
    sequence_iterator() : singular(true) { }
    sequence_iterator(int a, int b) : singular(false) start(a), end(b) { }
    bool singular;
    int start;
    int end;

    int operator*() { return start; }
    void operator++() { ++start; }

    bool operator==(sequence_iterator const & rhs) const
        return (start == end) == rhs.singular;
    bool operator!=(sequence_iterator const & rhs) const
        return !operator==(rhs);

Now you can say:

std::vector<int> v(sequence_iterator(1,10), sequence_iterator());

In the same vein, you can write a more general gadget that "calls a given functor a given number of times", etc. (e.g. take a function object by templated copy, and use the counters as repetition counters; and dereferencing calls the functor).

  • 1
    Sbouldn't the singular on the non-default constructor be explicitly initialized to false?
    – Puppy
    Commented Sep 20, 2012 at 11:54
  • Why not simply inherit from std::iterator for the typedefs? :)
    – Xeo
    Commented Sep 20, 2012 at 11:58
  • I agree with you that sequence generation may be too specific to be included into C++. But my question is more general: I ask about any iterative function calls, e.g. RNG initialization. In fact, the point is to merge vector constructor and generate_n to make it more elegant. Commented Sep 20, 2012 at 11:58
  • @Xeo: Because I couldn't figure out how! :-) [Edit:] Done, thanks!
    – Kerrek SB
    Commented Sep 20, 2012 at 12:01
  • 1
    @overrider: yeah, a "generate_n"-iterator would be a good thing... so would a getline-iterator. Well, maybe one day. But for now, you know how to make your own!
    – Kerrek SB
    Commented Sep 20, 2012 at 12:04

If you're using a compiler that supports lambdas as you use in your question, then chances are pretty good it also includes std::iota, which at least makes the counting case a little cleaner:

std::vector <int> vec(10);
std::iota(begin(vec), end(vec), 0);

For this scenario (and quite a few others, I think) we'd really prefer an iota_n though:

namespace stdx {
template <class FwdIt, class T>
void iota_n(FwdIt b, size_t count, T val = T()) {
    for ( ; count; --count, ++b, ++val)
        *b = val;

Which, for your case you'd use like:

std::vector<int> vec;

stdx::iota_n(std::back_inserter(vec), 10);

As to why this wasn't included in the standard library, I really can't even guess. I suppose this could be seen as an argument in favor of ranges, so the algorithm would take a range, and we'd have an easy way to create a range from either a begin/end pair or a begin/count pair. I'm not sure I completely agree with that though -- ranges do seem to work well in some cases, but in others they make little or no sense. I'm not sure that without more work, we have an answer that's really a lot better than a pair of iterators.


Nobody mentioned boost::assign, so I will introduce it here:


#include <iostream>
#include <vector>
#include <boost/assign/std/vector.hpp> 
#include <cstdlib>

int main()
    std::vector<int> v1;
    std::vector<int> v2;
    boost::assign::push_back(v1).repeat_fun(9, &rand);
    int cnt = 0;
    boost::assign::push_back(v2).repeat_fun(10, [&cnt]()->int { return cnt++;});
    for (auto i : v1)
        std::cout << i << ' ';
    std::cout << std::endl;
    for (auto i : v2)
        std::cout << i << ' ';


41 18467 6334 26500 19169 15724 11478 29358 26962
0 1 2 3 4 5 6 7 8 9

  • 1
    Nice feature, but not initialization. A bit shorter than std::generate_n, but requires boost. Commented Sep 21, 2012 at 8:20

You can use SFINAE to form a table :

#include <iostream>
#include <vector>

template <int n> struct coeff    { static int const value = coeff<n-1>::value + 3; };
template <>      struct coeff<0> { static int const value = 0; };

template<int... values> struct c1 {static int const value[sizeof...(values)];};
template<int... values> int const c1<values...>::value[] = {values...};

template<int n, int... values> struct c2 : c2< n-1, coeff<n-1>::value, values...> {};
template<int... values> struct c2< 0, values... > : c1<values...> {};

template<int n> struct table : c2< n > {
    static std::vector< unsigned int > FormTable()
        return std::vector< unsigned int >( & c2< n >::value[0], & c2< n >::value[n] );

int main()
    const auto myTable = table< 20 >::FormTable();

    for ( const auto & it : myTable )
        std::cout<< it << std::endl;
  • I am not profound enough to understand it thoroughly. :( Would it work when the number of elements is unknown at compile-time? Commented Sep 20, 2012 at 13:30
  • @overrider no, the above is the way to set a vector at compile time Commented Sep 20, 2012 at 13:31

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