I have a vector v1, and a boolean vector v2 of the same size. I want to delete from v1 all values such that the parallel element of v2 is false:

vector<int> v3; // assume v1 is vector<int>
for (size_t i=0; i<v1.size(); i++)
    if (v2[i])

Is there a better way to do it?

  • in C++03
  • in C++11
  • @user2079303 ... and then assigns the copy back to v1. It's a form of erase/remove idiom. – Igor Tandetnik Jul 14 '16 at 13:14
  • 1
    Are you 100% sure you want a new vector and not a range (i.e., something that has a begin() and an end())? – lorro Jul 14 '16 at 13:31
  • 2
    Surprised nobody's mentioned zip iterators yet. stackoverflow.com/a/12553437/560648? – Lightness Races in Orbit Jul 14 '16 at 13:45
  • 1
    @screwnut - vector::erase() takes linear time. Removing each offending elements with erase() means quadratic time complexity. vector::erase() also invalidates all pointers, references, iterators to the subsequent elements. This function is slow, unsafe, and should generally be avoided. (I hope you are not going to say "then use lists".) On top of this, we may need the offending element to determine the validity of other elements. – user31264 Jul 14 '16 at 19:18
  • 1
    PS: "But all the answers make use of erase including the one you accepted." - not only the answer I accepted, as well as most other answers, use erase only once, they also use it for final part of the array. This special case of vector::erase is fast and safe. – user31264 Jul 14 '16 at 22:59
size_t last = 0;
for (size_t i = 0; i < v1.size(); i++) {
  if (v2[i]) {
    v1[last++] = v1[i];
v1.erase(v1.begin() + last, v1.end());

Same as yours essentially, except it works in-place, not requiring additional storage. This is basically a reimplementation of std::remove_if (which would be difficult to use directly, because the function object it uses is given a value, not an index or iterator into the container).

| improve this answer | |
  • 10
    If v1 actually contains something more complex than int, this could be optimised a bit more by doing: v1[last++] = std::move(v1[i]);. – Angew is no longer proud of SO Jul 14 '16 at 13:18
  • This one is definitly compatible with every version – Ceros Jul 14 '16 at 13:18
  • @Angew is s = move(s) required to work at least for STL data types? – RiaD Jul 14 '16 at 14:04
  • @RiaD All the STL containers that I know of have a move constructor. For custom classes that do not have a move constructor, use of std::move would cause the copy constructor be be called instead. So, you get a benefit of speed if a move constructor if available, and no loss of compatibility if there is no move constructor. – Eldritch Cheese Jul 14 '16 at 15:01
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    @Angew Self-move-assignment is a no-no. – T.C. Jul 14 '16 at 23:30

In C++11 you can use std::remove_if and std::erase with a lambda, which is the "erase-remove-idiom":

size_t idx = 0;
                          [&idx, &v2](int val){return !v2[idx++];}),

And here's a link to it functioning as intended: cpp.sh/57jpc

As the comments point out however, there's a bit of discussion about the safety of doing it this way; the underlying assumption here is that std::remove_if will apply the predicate to the elements of v1 in order. However, the language in the doc doesn't explicitly guarantee this. It simply states:

Removing is done by shifting (by means of move assignment) the elements in the range in such a way that the elements that are not to be removed appear in the beginning of the range. Relative order of the elements that remain is preserved and the physical size of the container is unchanged. Iterators pointing to an element between the new logical end and the physical end of the range are still dereferenceable, but the elements themselves have unspecified values (as per MoveAssignable post-condition). A call to remove is typically followed by a call to a container's erase method, which erases the unspecified values and reduces the physical size of the container to match its new logical size.

Now, it would be difficult with only a forward iterator to a std::vector to both guarantee stability for results and not apply the predicate in-order. But it's certainly possible to do so.

| improve this answer | |
  • 3
    I wonder to what extent it's guaranteed that idx and val would stay in sync; that the function object will be called for each value in a proper sequence. – Igor Tandetnik Jul 14 '16 at 13:16
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    @ildjarn The requirements on stable algorithms ([algorithm.stable]) say that the relative order of elements should be preserved. I don't see where it states that the predicate should be called for each element in order. for_each is the only algorithm I know of that explicitly guarantees this; the fact that it has to spell this out suggests to me that, absent such language, the implementation is given the latitude to call predicate out of order. – Igor Tandetnik Jul 14 '16 at 13:23
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    @aruisdante Forward iterators are not input iterators; they are multi-pass. It would be perfectly possible to apply the predicate out of order, perhaps even in parallel. – Angew is no longer proud of SO Jul 14 '16 at 13:27
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    As std::remove_if operates doesn't it shift the elements down from the one moved to the end of the container? This would damage the corelation between the two vectors. – Galik Jul 14 '16 at 13:39
  • 1
    @aruisdante It's "sequenced", not "sequential" - very different things. "Sequenced" means "single-threaded" essentially - the opposite of "unsequenced" which means "possibly running in parallel on different threads". It says nothing about the order of calls, only that they don't run in parallel. – Igor Tandetnik Jul 14 '16 at 13:56

A remove_if-based alternative is:

v1.erase(std::remove_if(v1.begin(), v1.end(),
                        [&v1, &v2](const int &x){ return !v2[&x - &v1[0]]; }),

Also consider that if you only need a view on v1 in which some elements are skipped, you can avoid to modify v1 and use something like boost::filter_iterator.

| improve this answer | |

I hear you like lambdas.

auto with_index_into = [](auto&v){
  return [&](auto&& f){
    return [&,f=decltype(f)(f)](auto& e){
      return f( std::addressof(e)-v.data(), e );

This may be useful. It takes a .data() suporting container, then returns a lambda of type ((Index,E&)->X)->(E&->X) -- the returned lambda converts an indexed element visitor to an element visitor. Sort of lambda judo.

template<class C, class Test>
auto erase_if( C& c, Test&& test) {
  using std::begin; using std::end;
  auto it=std::remove_if(begin(c),end(c),test);
  if (it==end(c)) return false;
  c.erase(it, end(c));
  return true;

because I hate the remove erase idiom in client code.

Now the code is pretty:

erase_if( v1, with_index_into(v1)(
  [](std::size_t i, auto&e){
    return !v2[i];

The restriction on moves in remove/erase should mean it invokes the lambda on the element in its original position.

We can do this with more elemental steps. It gets complicated in the middle...

First, tiny named operator library:

namespace named_operator {
  template<class D>struct make_operator{};

  enum class lhs_token {
    star = '*',
    non_char_tokens_start = (unsigned char)-1,

  template<class T, lhs_token, class O> struct half_apply { T&& lhs; };

  template<class Lhs, class Op>
  half_apply<Lhs, lhs_token::star, Op>
  operator*( Lhs&& lhs, make_operator<Op> ) {
    return {std::forward<Lhs>(lhs)};
  template<class Lhs, class Op>
  half_apply<Lhs, lhs_token::arrow_star, Op>
  operator->*( Lhs&& lhs, make_operator<Op> ) {
    return {std::forward<Lhs>(lhs)};

  template<class Lhs, class Op, class Rhs>
  auto operator*( half_apply<Lhs, lhs_token::star, Op>&& lhs, Rhs&& rhs )
    return named_invoke( std::forward<Lhs>(lhs.lhs), Op{}, std::forward<Rhs>(rhs) );

  template<class Lhs, class Op, class Rhs>
  auto operator*( half_apply<Lhs, lhs_token::arrow_star, Op>&& lhs, Rhs&& rhs )
    return named_next( std::forward<Lhs>(lhs.lhs), Op{}, std::forward<Rhs>(rhs) );

Now we define then:

namespace lambda_then {
  struct then_t:named_operator::make_operator<then_t> {} then;

  template<class Lhs, class Rhs>
  auto named_next( Lhs&& lhs, then_t, Rhs&& rhs ) {
      [lhs=std::forward<Lhs>(lhs), rhs=std::forward<Rhs>(rhs)]
      return rhs( lhs( decltype(args)(args)... ) );
using lambda_then::then;

which defines a token then such that lambda1 ->*then* lambda2 returns a function object that takes its arguments, passes it to lambda1, then passes the return value to lambda2.

Next we define to_index(container):

template<class C>
auto index_in( C& c ) {
  return [&](auto& e){
    return std::addressof(e)-c.data();

we also keep the above erase_if.

This results in:

erase_if( v1,
  [&](auto i){
    return !v2[i];

solving your problem (live example).

| improve this answer | |
  • f=decltype(f)(f) Are you creating a member copy of f? Why that syntax? – SirGuy Jul 14 '16 at 14:24
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    @guygreer perfect forwarding with an auto&&x argument is easiest done with decltype(x)(x). And as the lambda may be an rvalue, using a mere reference to it is rude – Yakk - Adam Nevraumont Jul 14 '16 at 14:36
  • Okay, makes sense now – SirGuy Jul 14 '16 at 14:39
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    nice solution. Totally unreadable of course, but nice use of c++jitsu :) +1 – Richard Hodges Jul 14 '16 at 17:40
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    @rich I think I can make it better with more pieces. Like erase_if(v1,element_to_index(v1)->*then*[&](auto i){return !v2[i];})); – Yakk - Adam Nevraumont Jul 14 '16 at 18:08

I actually quite like the way you did it but I would make a couple of changes in limiting the scope the temporary vector is used and I would use std::vector::swap to avoid a copy at he end. If you have C++11 you could use std::move instead of std::vector::swap:

#include <vector>
#include <iostream>

int main()
    std::vector<int> iv = {0, 1, 2, 3, 4, 5, 6};
    std::vector<bool> bv = {true, true, false, true, false, false, true};

    // start a new scope to limit
    // the lifespan of the temporary vector
        std::vector<int> v;

        // reserve space for performance gains
        // if you don't mind an over-allocated return
        // v.reserve(iv); 

        for(std::size_t i = 0; i < iv.size(); ++i)

        iv.swap(v); // faster than a copy

    for(auto i: iv)
        std::cout << i << ' ';
    std::cout << '\n';
| improve this answer | |
  • 5
    In C++11 you can just use std::move instead of std::swap to avoid the copy and make intent more explicit. – aruisdante Jul 14 '16 at 13:30
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    While we're at optimizing: v.reserve(iv.size()) would prevent multiple resizes at the cost of over-allocating the vector. – Martin Ba Jul 14 '16 at 21:34

Different version that erases elements in place but does not require as many moves as Igor's algo requires and in case of small amount of elements to be erased could be more efficient:

using std::swap;
size_t last = v1.size();
for (size_t i = 0; i < last;) {
   if( !v2[i] ) {
       swap( v2[i], v2[last] );
       swap( v1[i], v1[last] );
   } else 
v1.erase(v1.begin() + last, v1.end());

but this algo is unstable.

| improve this answer | |

If you use a list (or forward_list for C++11) instead of a vector, you can do this in-place without the moving/allocating/copying overhead required for vector operations. It's perfectly possible to do most storage-related things with any STL container, but appropriate choice of containers will often give significant improvements in performance.

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  • The use of a list to remove elements at a minimum requires a move of the "next" pointer to remove a node and the deallocation of the deleted node for each deletion. I won't even bring up the performance impact that traipsing all over memory to follow links has on the cache... Measuring the move to a list before abandoning a vector. – David Thomas Jul 14 '16 at 17:37
  • @DavidThomas Of course, but it may be a lower impact than moving the entire contents of the vector. If you've only got a few elements then sure, stick with the vector. If you've got thousands or millions, you're probably better with a list in-place or with setting up a new vector, and you may be better with a deque so that adding new elements is cheap. If you've got thousands of millions, you probably always want to do it in-place because you don't want the RAM hit of holding a duplicate. – Graham Jul 15 '16 at 10:15

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