Is it possible to rewrite this raw loop:

vector<double> v { ... };
for (size_t i = 1; i<v.size(); ++i) {

or the even more cryptic:

for (auto i = v.begin()+1; i<v.end(); ++i) {
  (*i) *= *(i-1);

(and similar, maybe accessing also v[i-2], ...) in a more STLish way?

Are there other forms which are equal or better (both in style and performances) than the ones above?

  • you could use iterators, not sure how much more readable that would be
    – Marco A.
    Commented Sep 3, 2014 at 9:13
  • @MarcoA. the iterator form is in the second snippet. In my opinion it is uglier.
    – DarioP
    Commented Sep 3, 2014 at 9:15
  • Implementing a factorial by hand?
    – Kerrek SB
    Commented Sep 3, 2014 at 9:16
  • You can use a simple while loop, but the core idea is the same. So the main question is: what is a requirement for looking better? :-)...
    – KimKulling
    Commented Sep 3, 2014 at 9:16
  • 2
    Related: stackoverflow.com/q/14826893/279627 Commented Sep 3, 2014 at 11:14

4 Answers 4


The most STLish way I can imagine:

std::partial_sum(std::begin(v), std::end(v),
                 std::begin(v), std::multiplies<double>());


#include <iostream>
#include <vector>
#include <iterator>
#include <numeric>
#include <functional>

int main()
    std::vector<double> v{ 1.0, 2.0, 3.0, 4.0 };

    std::partial_sum(std::begin(v), std::end(v),
                     std::begin(v), std::multiplies<double>());

    std::copy(std::begin(v), std::end(v),
                             std::ostream_iterator<double>(std::cout, " "));


1 2 6 24 

Live demo link.

  • 4
    +1 Excellent find. One of the less exposed algorithms. In fact, it's not even in <algorithm>... :-(
    – Kerrek SB
    Commented Sep 3, 2014 at 9:26
  • 3
    @MaximYegorushkin: It's a pretty well known, standard term from basic mathematics. The kind of mathematics you would hope your programmer team is familiar with. You just need to recognize enough to get an idea whether you need to dig deeper when reading or whether you're happy to move on.
    – Kerrek SB
    Commented Sep 3, 2014 at 9:29
  • 10
    or if you're only interested in the end result, use std::accumulate Commented Sep 3, 2014 at 9:29
  • 12
    using ADL on begin()/end() and using C++14 transparant functors, you can write it as a one-liner: std::partial_sum(begin(v), end(v), begin(v), std::multiplies<>()); Commented Sep 3, 2014 at 10:23
  • 5
    @TimothyShields: "scan" is a generalization of partial-sum, whereas "fold" is a generalization of accumulated-sum: en.wikipedia.org/wiki/Prefix_sum#Scan_higher_order_function
    – Matt
    Commented Sep 3, 2014 at 19:04

You can do that with std::transform, the overload that takes two input sequences:

int container[] = {1,2,3};
    std::begin(container), std::end(container) - 1,
    std::begin(container) + 1, std::begin(container) + 1,
    [](auto a, auto b) { return a * b; }

But the hand-coded loop is much more readable.

  • 4
    You could use std::multiplies here, too.
    – Kerrek SB
    Commented Sep 3, 2014 at 9:27
  • 2
    @KerrekSB Probably, if I wanted to make it even more cryptic... What would be the advantage of using std::multiplies over lambda? Commented Sep 3, 2014 at 9:29
  • 4
    Ah, of course. We should be able to see what the code is really doing. All this abstraction is just obscuring the code :-)
    – Kerrek SB
    Commented Sep 3, 2014 at 9:31
  • 6
    @KerrekSB Many problems in software engineering can be solved by adding another layer of abstraction. Apart from the problem of having too many layers of abstraction. Commented Sep 3, 2014 at 9:35
  • 8
    instead of begin(container) + 1, I'd prefer std::next(begin(container)) so that it would also work with std::list Commented Sep 3, 2014 at 10:30

If you want a generic way to do sliding windows rather than a non-transferable STL-ish way to answer your particular problem, you could consider the following ridiculous nonsense:

#include <array>
#include <cstddef>
#include <memory>
#include <tuple>

namespace detail {
  template<std::size_t, typename>
  class slide_iterator;
template<std::size_t N, typename I>
detail::slide_iterator<N, I> slide_begin(const I&);
template<std::size_t N, typename I>
detail::slide_iterator<N, I> slide_end(const I&);

namespace detail {

template<std::size_t N, typename T, typename... Args>
struct repeat {
  typedef typename repeat<N - 1, T, T, Args...>::type type;
  template<typename I>
  type operator()(const I& it, Args&... args) const {
    auto jt = it;
    return repeat<N - 1, T, T, Args...>()(++jt, args..., *it);
template<typename T, typename... Args>
struct repeat<0, T, Args...> {
  typedef std::tuple<Args&...> type;
  template<typename I>
  type operator()(const I&, Args&... args) const {
    return type(args...);

template<std::size_t N, typename I /* forward iterator */>
class slide_iterator {

  typedef slide_iterator iterator;
  typedef decltype(*I{}) reference;
  typedef typename repeat<N, reference>::type window_tuple;

  slide_iterator() = default;
  ~slide_iterator() = default;
  slide_iterator(const iterator& it) = default;
  iterator& operator=(const iterator& it) = default;

  window_tuple operator*() const {
    return repeat<N, reference>()(first_);

  iterator& operator++() { // prefix
    return *this;

  iterator operator++(int) { // postfix
    auto tmp{*this};
    return tmp;

  friend void swap(iterator& lhs, iterator& rhs) {
    swap(lhs.first_, rhs.first_);
    swap(lhs.last_, rhs.last_);
    swap(lhs.dirty_, rhs.dirty_);
    swap(lhs.window_, rhs.window_);

  friend bool operator==(const iterator& lhs, const iterator& rhs) {
    return lhs.last_ == rhs.last_;

  friend bool operator!=(const iterator& lhs, const iterator& rhs) {
    return !operator==(lhs, rhs);

  friend iterator slide_begin<N, I>(const I& it);
  friend iterator slide_end<N, I>(const I& it);


  I first_;
  I last_; // for equality only


template<typename T, std::size_t N>
struct slide_helper {
  T& t;
  auto begin() -> decltype(slide_begin<N>(t.begin())) {
    return slide_begin<N>(t.begin());
  auto end() -> decltype(slide_end<N>(t.end())) {
    return slide_end<N>(t.end());

} // ::detail

// note it is undefined to call slide_begin<N>() on an iterator which cannot
// be incremented at least N - 1 times
template<std::size_t N, typename I>
detail::slide_iterator<N, I> slide_begin(const I& it) {
  detail::slide_iterator<N, I> r;
  r.first_ = r.last_ = it;
  std::advance(r.last_, N - 1);
  return r;

template<std::size_t N, typename I>
detail::slide_iterator<N, I> slide_end(const I& it) {
  detail::slide_iterator<N, I> r;
  r.last_ = it;
  return r;

template<std::size_t N, typename T>
detail::slide_helper<T, N> slide(T& t) {
  return {t};

Example usage:

#include <iostream>
#include <vector>

int main() {
  std::vector<int> v{1, 2, 3, 4};
  /* helper for
     for (auto it = slide_begin<2>(v.begin()),
               et = slide_end<2>(v.end()); it != et ... BLAH BLAH BLAH */
  for (const auto& t : slide<2>(v)) {
    std::get<1>(t) *= std::get<0>(t);
  for (const auto& i : v) {
    std::cout << i << std::endl;
  • 2
    This kind of solution looks very nice, producing a wonderful main. However I have the feeling that is not totally overhead free...
    – DarioP
    Commented Sep 4, 2014 at 6:59
  • 1
    @DarioP Indeed, the original code was something like 100 times slower than the obvious way. I have updated the code to fix it: by allowing *it to return a temporary rather than a (useless) reference, we can avoid the tuple allocation, and end up generating essentially identical assembly to the naive raw loop under -O3. Live demo here.
    – STU
    Commented Sep 4, 2014 at 11:36
  • 2
    When iterating over a window of size N and M elements, this does 2(M-N)+NM iterator increments? The ideal version would only do N iterator increments. I suppose with a simple array (or vector), such operations get elided into simple pointer arithmetic, but with a std::map they probably would not be. There isn't really an iterator trait that tells you which is better: I guess random access could be used as a proxy for "easier to advance than store". Commented Sep 4, 2014 at 13:09
  • You're right, of course. There's certainly a trade-off between advance and store; handling both would make the code considerably more complicated though so probably best left as an exercise for the reader. FWIW, sliding window makes a lot more sense on something like a vector, so defaulting to advance over store probably isn't too unreasonable.
    – STU
    Commented Sep 4, 2014 at 14:39

This is an implementation that keeps an array of iterators of size N under the hood to produce a sliding window:

namespace details {
  template<unsigned...>struct indexes { using type=indexes; };
  template<unsigned max, unsigned... is>struct make_indexes:make_indexes<max-1, max-1, is...>{};
  template<unsigned... is>struct make_indexes<0,is...>:indexes<is...>{};
  template<unsigned max>using make_indexes_t=typename make_indexes<max>::type;

  template<bool b, class T=void>
  using enable_if_t=typename std::enable_if<b,T>::type;
  struct list_tag {};
  struct from_iterator_tag {};

  template<unsigned N, class Iterator>
  struct iterator_array {
    std::array<Iterator,N> raw;
    size_t index = 0;

    static Iterator to_elem(Iterator& it, Iterator end, bool advance=true) {
      if (it == end) return end;
      if (advance) return ++it;
      return it;
    template< unsigned...Is>
    iterator_array( indexes<Is...>, from_iterator_tag, Iterator& it, Iterator end ):
      raw( {to_elem(it, end, false), (void(Is), to_elem(it,end))...} )
    Iterator begin() const { return raw[index]; }
    Iterator end() const { return std::next(raw[(index+N-1)%N]); }
    void push_back( Iterator it ) {
      raw[index] = it;
      index = (index+1)%N;
    iterator_array( from_iterator_tag, Iterator& it, Iterator end ):iterator_array( make_indexes<N-1>{}, from_iterator_tag{}, it, end ) {}
    iterator_array( iterator_array const& o )=default;
    iterator_array() = default; // invalid!
    iterator_array& operator=( iterator_array const& o )=delete;
    typedef decltype(*std::declval<Iterator>()) reference_type;
    reference_type operator[](std::size_t i)const{return *(raw[ (i+index)%N ]);}

  struct sentinal_tag {};

  template<class I>using value_type_t=typename std::iterator_traits<I>::value_type;

  template<class I, unsigned N>
  class slide_iterator:public std::iterator<
    iterator_array<N,I> const&
  > {
    I current;
    mutable bool bread = false;
    typedef iterator_array<N,I> value_type;
    mutable value_type data;
    void ensure_read() const {
      if (!bread) {
      bread = true;
    slide_iterator& operator++() { ensure_read(); ++current; bread=false; return *this; }
    slide_iterator operator++(int) { slide_iterator retval=*this; ++*this; return retval; }
    value_type const& operator*() const { ensure_read(); return data; }
    bool operator==(slide_iterator const& o){return current==o.current;}
    bool operator!=(slide_iterator const& o){return current!=o.current;}
    bool operator<(slide_iterator const& o){return current<o.current;}
    bool operator>(slide_iterator const& o){return current>o.current;}
    bool operator<=(slide_iterator const& o){return current<=o.current;}
    bool operator>=(slide_iterator const& o){return current>=o.current;}
    explicit slide_iterator( I start, I end ):current(start), bread(true), data(from_iterator_tag{}, current, end) {}
    explicit slide_iterator( sentinal_tag, I end ):current(end) {}


template<class Iterator, unsigned N>
struct slide_range_t {
  using iterator=details::slide_iterator<Iterator, N>;
  iterator b;
  iterator e;
  slide_range_t( Iterator start, Iterator end ):
    b( start, end ),
    e( details::sentinal_tag{}, end )
  slide_range_t( slide_range_t const& o )=default;
  slide_range_t() = delete;
  iterator begin() const { return b; }
  iterator end() const { return e; }

template<unsigned N, class Iterator>
slide_range_t< Iterator, N > slide_range( Iterator b, Iterator e ) {
  return {b,e};

live example

Note that the elements of your slide range are themselves iterable. A further improvement would be to specialize for random-access iterators and only store the begin/end pair in that case.

Sample use:

int main() {
    std::vector<int> foo(33);
    for (int i = 0; i < foo.size(); ++i)
    for( auto&& r:slide_range<3>(foo.begin(), foo.end()) ) {
        for (int x : r) {
            std::cout << x << ",";
        std::cout << "\n";
    // your code goes here
    return 0;

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