103

Assume I have the following code:

vector<int> list;
for(auto& elem:list) {
    int i = elem;
}

Can I find the position of elem in the vector without maintaining a separate iterator?

7
  • 18
    That's not what range-based for is for (heh, is that a pun?)
    – jrok
    Jun 9, 2012 at 15:42
  • 2
    This is not possible in STL containers, unless using std::find or some other overkill function. You can't conclude iterators from contained elements. Why not maintain an iterator?
    – Eitan T
    Jun 9, 2012 at 15:49
  • 2
    For two reasons. The first is all I want to do (in this case) is see whether I'm at the last element or not :) and the second is that the compiler must be maintaining one, why can't I access it? "this" is a variable with scope maintained by the compiler, why not here? Or provide an alternative (but still convenient) syntax that, as javascript does, sets up a variable that changes as the you go through the loop. for(auto& index:list) Jun 9, 2012 at 19:25
  • 1
    @FredFinkle you are actually correct, there is an iterator, but when using a range based for loop, it is a compiler-internal name and can therefore not be used in your code. So if you really want to know if you're at the last element, you should use the for(;;) loop.
    – iFreilicht
    Jul 31, 2014 at 16:11
  • 1
    std::views::enumerate is a C++23 solution.
    – Steve Ward
    Aug 9, 2023 at 1:44

13 Answers 13

70

Yes you can, it just take some massaging ;)

The trick is to use composition: instead of iterating over the container directly, you "zip" it with an index along the way.

Specialized zipper code:

template <typename T>
struct iterator_extractor { typedef typename T::iterator type; };

template <typename T>
struct iterator_extractor<T const> { typedef typename T::const_iterator type; };


template <typename T>
class Indexer {
public:
    class iterator {
        typedef typename iterator_extractor<T>::type inner_iterator;

        typedef typename std::iterator_traits<inner_iterator>::reference inner_reference;
    public:
        typedef std::pair<size_t, inner_reference> reference;

        iterator(inner_iterator it): _pos(0), _it(it) {}

        reference operator*() const { return reference(_pos, *_it); }

        iterator& operator++() { ++_pos; ++_it; return *this; }
        iterator operator++(int) { iterator tmp(*this); ++*this; return tmp; }

        bool operator==(iterator const& it) const { return _it == it._it; }
        bool operator!=(iterator const& it) const { return !(*this == it); }

    private:
        size_t _pos;
        inner_iterator _it;
    };

    Indexer(T& t): _container(t) {}

    iterator begin() const { return iterator(_container.begin()); }
    iterator end() const { return iterator(_container.end()); }

private:
    T& _container;
}; // class Indexer

template <typename T>
Indexer<T> index(T& t) { return Indexer<T>(t); }

And using it:

#include <iostream>
#include <iterator>
#include <limits>
#include <vector>

// Zipper code here

int main() {
    std::vector<int> v{1, 2, 3, 4, 5, 6, 7, 8, 9};

    for (auto p: index(v)) {
        std::cout << p.first << ": " << p.second << "\n";
    }
}

You can see it at ideone, though it lacks the for-range loop support so it's less pretty.

EDIT:

Just remembered that I should check Boost.Range more often. Unfortunately no zip range, but I did found a pearl: boost::adaptors::indexed. However it requires access to the iterator to pull of the index. Shame :x

Otherwise with the counting_range and a generic zip I am sure it could be possible to do something interesting...

In the ideal world I would imagine:

int main() {
    std::vector<int> v{1, 2, 3, 4, 5, 6, 7, 8, 9};

    for (auto tuple: zip(iota(0), v)) {
        std::cout << tuple.at<0>() << ": " << tuple.at<1>() << "\n";
    }
}

With zip automatically creating a view as a range of tuples of references and iota(0) simply creating a "false" range that starts from 0 and just counts toward infinity (or well, the maximum of its type...).

7
  • 3
    How about counting_range (or boost::counting_iterator) + boost::zip_iterator?
    – ildjarn
    Jun 9, 2012 at 19:58
  • 1
    @ildjarn: Yes, Boost.Iterators has the building blocks (it seems), however there is no corresponding range, which is annoying. Jun 10, 2012 at 10:00
  • @Xeo Your version works fine for lvalues (indeed as you said no copies take place). For rvalues there is some problem, though. I have not spotted it yet, but I will continue to look into it tomorrow. Basically, when I use index like this for (auto x : index(std::vector<int>{2, 4, 6})) { ... } I get this error: error: no matching function for call to ‘Indexer<std::vector<int, std::allocator<int> > >::iterator::iterator(std::vector<int, std::allocator<int> >::const_iterator)’. I used g++-4.7. Jul 4, 2012 at 23:06
  • @betabandido: Yeah, that's why I didn't roll back yet and asked for Matthieu to join me in the Lounge, to discuss that exact problem. begin and end are const, and if the original argument is an rvalue, _container is a value type and is also const, making _container.begin() and _container.end() return const_iterators instead of the wanted iterators. One solution is to add non-const begin and end functions to the Indexer.
    – Xeo
    Jul 5, 2012 at 0:22
  • @Xeo: sorry but my hours differ slightly from yours it seems. Indeed in this case I think that removing the const from begin and end would be the right thing to do. Jul 5, 2012 at 6:14
37

jrok is right : range-based for loops are not designed for that purpose.

However, in your case it is possible to compute it using pointer arithmetic since vector stores its elements contiguously (*)

vector<int> list;
for(auto& elem:list) { 
    int i = elem;
    int pos = &elem-&list[0]; // pos contains the position in the vector 

    // also a &-operator overload proof alternative (thanks to ildjarn) :
    // int pos = addressof(elem)-addressof(list[0]); 

}

But this is clearly a bad practice since it obfuscates the code & makes it more fragile (it easily breaks if someone changes the container type, overload the & operator or replace 'auto&' by 'auto'. good luck to debug that!)

NOTE: Contiguity is guaranteed for vector in C++03, and array and string in C++11 standard.

5
  • 7
    Yes it is stated in the standard. Contiguity is guaranteed for vector in C++03, and array and string in C++11. Jun 9, 2012 at 16:02
  • 2
    "it easily breaks if someone ... overload the & operator" That's what std::addressof is for. :-]
    – ildjarn
    Jun 9, 2012 at 18:28
  • You're right. So the &-overload proof version would be : int pos = addressof(elem)- addressof(list[0]); .... Matthieu M.'s iterator wrapper is way better :) Jun 9, 2012 at 19:10
  • Didn't know that contiguity was guaranteed. Wouldn't want to use it here, but good to know. Jun 9, 2012 at 19:27
  • 7
    Why not use std::distance to figure out the position? Jul 18, 2013 at 0:17
23

No, you can't (at least, not without effort). If you need the position of an element, you shouldn't use range-based for. Remember that it's just a convenience tool for the most common case: execute some code for each element. In the less-common circumstances where you need the position of the element, you have to use the less-convenient regular for loop.

22
+100

Based on the answer from @Matthieu there is a very elegant solution using the mentioned boost::adaptors::indexed:

std::vector<std::string> strings{10, "Hello"};
int main(){
    strings[5] = "World";
    for(auto const& el: strings| boost::adaptors::indexed(0))
      std::cout << el.index() << ": " << el.value() << std::endl;
}

You can try it

This works pretty much like the "ideal world solution" mentioned, has pretty syntax and is concise. Note that the type of el in this case is something like boost::foobar<const std::string&, int>, so it handles the reference there and no copying is performed. It is even incredibly efficient: https://godbolt.org/g/e4LMnJ (The code is equivalent to keeping an own counter variable which is as good as it gets)

For completeness the alternatives:

size_t i = 0;
for(auto const& el: strings) {
  std::cout << i << ": " << el << std::endl;
  ++i;
}

Or using the contiguous property of a vector:

for(auto const& el: strings) {
  size_t i = &el - &strings.front();
  std::cout << i << ": " << el << std::endl;
}

The first generates the same code as the boost adapter version (optimal) and the last is 1 instruction longer: https://godbolt.org/g/nEG8f9

Note: If you only want to know, if you have the last element you can use:

for(auto const& el: strings) {
  bool isLast = &el == &strings.back();
  std::cout << isLast << ": " << el << std::endl;
}

This works for every standard container but auto&/auto const& must be used (same as above) but that is recommended anyway. Depending on the input this might also be pretty fast (especially when the compiler knows the size of your vector)

Replace the &foo by std::addressof(foo) to be on the safe side for generic code.

2
  • I added the 2 alternatives with godbolt comparison of the generated code for completeness and also addressed the need of the OP (in the comments) for detecting the last element
    – Flamefire
    Jul 20, 2018 at 12:16
  • 1
    Maybe worth mentioning: Instead of strings | boost::adaptors::indexed(0) one can also use boost::adaptors::index(strings). The outcome is the same but IMO it is a bit more intuitive.
    – luator
    Oct 27, 2022 at 7:48
11

If you have a compiler with C++14 support you can do it in a functional style:

#include <iostream>
#include <string>
#include <vector>
#include <functional>

template<typename T>
void for_enum(T& container, std::function<void(int, typename T::value_type&)> op)
{
    int idx = 0;
    for(auto& value : container)
        op(idx++, value);
}

int main()
{
    std::vector<std::string> sv {"hi", "there"};
    for_enum(sv, [](auto i, auto v) {
        std::cout << i << " " << v << std::endl;
    });
}

Works with clang 3.4 and gcc 4.9 (not with 4.8); for both need to set -std=c++1y. The reason you need c++14 is because of the auto parameters in the lambda function.

1
  • 4
    std::function uses type erasure which is expensive. Why not use template<typename T, typename Callable> void for_enum(T& container, Callable op) so you don't have to pay for type erasure? Nov 29, 2018 at 15:29
8

There is a surprisingly simple way to do this

vector<int> list;
for(auto& elem:list) {
    int i = (&elem-&*(list.begin()));
}

where i will be your required index.

This takes advantage of the fact that C++ vectors are always contiguous.

7

If you insist on using range based for, and to know index, it is pretty trivial to maintain index as shown below. I do not think there is a cleaner / simpler solution for range based for loops. But really why not use a standard for(;;)? That probably would make your intent and code the clearest.

vector<int> list;
int idx = 0;
for(auto& elem:list) {
    int i = elem;
    //TODO whatever made you want the idx
    ++idx;
}
1
  • 1
    (idx amounts to "maintaining a separate iterator")
    – user66081
    Dec 11, 2016 at 20:19
7

Here's a quite beautiful solution using c++20:

#include <array>
#include <iostream>
#include <ranges>

template<typename T>
struct EnumeratedElement {
    std::size_t index;
    T& element;
};

auto enumerate(std::ranges::range auto& range) 
    -> std::ranges::view auto 
{
    return range | std::views::transform(
        [i = std::size_t{}](auto& element) mutable {
            return EnumeratedElement{i++, element};
        }
    );
}

auto main() -> int {
    auto const elements = std::array{3, 1, 4, 1, 5, 9, 2};
    for (auto const [index, element] : enumerate(elements)) {
        std::cout << "Element " << index << ": " << element << '\n';
    }
}

The major features used here are c++20 ranges, c++20 concepts, c++11 mutable lambdas, c++14 lambda capture initializers, and c++17 structured bindings. Refer to cppreference.com for information on any of these topics.

Note that element in the structured binding is in fact a reference and not a copy of the element (not that it matters here). This is because any qualifiers around the auto only affect a temporary object that the fields are extracted from, and not the fields themselves.

The generated code is identical to the code generated by this (at least by gcc 10.2):

#include <array>
#include <iostream>
#include <ranges>

auto main() -> int {
    auto const elements = std::array{3, 1, 4, 1, 5, 9, 2};
    for (auto index = std::size_t{}; auto& element : elements) {
        std::cout << "Element " << index << ": " << element << '\n';
        index++;
    }
}

Proof: https://godbolt.org/z/a5bfxz

7
  • OMG, what is happening to the C/C++ I grew up with? This is nearly incomprehensible.
    – AlainD
    Jan 22, 2021 at 10:51
  • C++98 is not the same language as C++20. Rust is incomprehensible by someone who only knows C. Jan 22, 2021 at 11:12
  • Perhaps I've been programming in C, C++03 (and more recently C++11) for too long, but these lambdas, new obscure auto main() -> int syntax, type deduction with auto and so on is turning a once clean and beautiful language into a Rube Goldberg mess. Very clever, super impressive...and nearly incomprehensible.
    – AlainD
    Jan 22, 2021 at 11:23
  • 4
    It is a matter of what you're used to. This is more comprehensible to me because this is the code I've written for the past year. I have chosen what features to use and when based purely on reasoning about safety and utility. For me it's like learning a new language with potential of better performance, safety and simplicity (abstraction). Jan 22, 2021 at 11:31
  • Why does adding a view filter to the container in your example result in the output indices becoming 1, 3, 5, 7, 9, 11, 13 (instead of 0, 1, 2, 3, 4, 5, 6)? Even a do-nothing filter has this effect. For example: enumerate(elements) | std::views::filter([](auto const &) { return true; })
    – Spire
    May 8, 2021 at 17:17
2

I read from your comments that one reason you want to know the index is to know if the element is the first/last in the sequence. If so, you can do

for(auto& elem:list) {
//  loop code ...
    if(&elem == &*std::begin(list)){ ... special code for first element ... }
    if(&elem == &*std::prev(std::end(list))){ ... special code for last element ... }
//  if(&elem == &*std::rbegin(list)){... (C++14 only) special code for last element ...}
//  loop code ... 
}

EDIT: For example, this prints a container skipping a separator in the last element. Works for most containers I can imagine (including arrays), (online demo http://coliru.stacked-crooked.com/a/9bdce059abd87f91):

#include <iostream>
#include <vector>
#include <list>
#include <set>
using namespace std;

template<class Container>
void print(Container const& c){
  for(auto& x:c){
    std::cout << x; 
    if(&x != &*std::prev(std::end(c))) std::cout << ", "; // special code for last element
  }
  std::cout << std::endl;
}

int main() {
  std::vector<double> v{1.,2.,3.};
  print(v); // prints 1,2,3
  std::list<double> l{1.,2.,3.};
  print(l); // prints 1,2,3
  std::initializer_list<double> i{1.,2.,3.};
  print(i); // prints 1,2,3
  std::set<double> s{1.,2.,3.};
  print(s); // print 1,2,3
  double a[3] = {1.,2.,3.}; // works for C-arrays as well
  print(a); // print 1,2,3
}
3
  • Please note (before unjustified downvoting) that the author of the question is asking this in the context of detecting the last element in a for-ranged loop for a container. For that I see no reason why comparing &elem and &*std::prev(std::end(list)) will not work or be practical. I agree with the other answer that an iterator-based for is more appropriate for this, but still.
    – alfC
    Aug 4, 2014 at 9:00
  • It seems easier to declare int i=c.size(); before the loop and test if(--i==0). Nov 8, 2014 at 20:03
  • @MarcGlisse, the int i code was just an example. I will remove it to avoid confusion. Even if you use size before the loop you will need a counter.
    – alfC
    Nov 8, 2014 at 20:09
2

Tobias Widlund wrote a nice MIT licensed Python style header only enumerate (C++17 though):

GitHub

Blog Post

Really nice to use:

std::vector<int> my_vector {1,3,3,7};

for(auto [i, my_element] : en::enumerate(my_vector))
{
    // do stuff
}
1
2

You can use std::views::enumerate (C++23) to get the index of elements.

#include <iostream>
#include <ranges>
#include <vector>
 
int main()
{
    const auto letters = std::vector{'A', 'B', 'C', 'D', 'E'};
 
    for (const auto& [index, letter] : std::views::enumerate(letters))
    {
        std::cout << '(' << index << ':' << letter << ") ";
    }
}

Check the C++ 23 compiler support page to see if your compiler supports this feature.

1

Here's a macro-based solution that probably beats most others on simplicity, compile time, and code generation quality:

#include <iostream>

#define fori(i, ...) if(size_t i = -1) for(__VA_ARGS__) if(i++, true)

int main() {
    fori(i, auto const & x : {"hello", "world", "!"}) {
        std::cout << i << " " << x << std::endl;
    }
}

Result:

$ g++ -o enumerate enumerate.cpp -std=c++11 && ./enumerate 
0 hello
1 world
2 !
1

If you want to avoid having to write an auxiliary function while having the index variable local to the loop, you can use a lambda with a mutable variable.:

int main() {
    std::vector<char> values = {'a', 'b', 'c'};
    std::for_each(begin(values), end(values), [i = size_t{}] (auto x) mutable {
        std::cout << i << ' ' << x << '\n';
        ++i;
    });
}

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