# Get random element and remove it

Problem: I need to get a random element for a container and also delete it from that container. Container does not need to be sorted. I dont care about the order.

• Vector can get me random element in `O(1)` but delete it only in `O(N)`
• List deletes element in `O(1)` but can only get random element in `O(N)`

So I came up with an idea of making a custom vector that allow you to remove any element by its index with `O(1)+` complexity. The idea is to swap the last element and an element you want to remove and then `pop_back()`. If you need to remove the last elemtent - just `pop_back()`. The order of the vector will not be the same but you get a fast remove method.

As i can understand deque have slower access by index and worse removal complexity then my solution but im not 100% sure.

I'm curious are there data structures that have random access and element removal in `O(1)` or `O(logN)` by index or mb by value ?

• Why did you need to make a custom vector for this? Just swap the element to the end and remove it from there? This doesn't need to be a special class. Commented Feb 9, 2012 at 21:08
• I have given you a solution if you want to maintain the order of the elements, that would be O(log N) complexity. Commented Feb 9, 2012 at 21:35
• @NicolBolas He found a solution (not sure why he wanted a new collection for it) but asked if there is an O(1) or O(log N) solution. We know there is a constant time solution (as he found it himself) so the O(log N) could only mean one that maintains order. Commented Feb 9, 2012 at 21:52
• language agnostic: stackoverflow.com/questions/311703/… Commented Feb 27, 2017 at 11:21

You have the solution, and it seems perfectly fine. The idiomatic way to write it in C++ is not to create another class (and please don't inherit from `std::vector`), but just to write a function:

``````template <typename T>
void remove_at(std::vector<T>& v, typename std::vector<T>::size_type n)
{
std::swap(v[n], v.back());
v.pop_back();
}
``````

Usage:

``````remove_at(v, 42);
``````

This offers the same exception guarantee as `std::swap<T>`.

Now if you want to return the object, and you have access to a C++11 compiler, you can do it the following way. The difficult part is to provide the basic exception guarantee in all cases:

``````template <typename T>
T remove_at(std::vector<T>&v, typename std::vector<T>::size_type n)
{
T ans = std::move_if_noexcept(v[n]);
v[n] = std::move_if_noexcept(v.back());
v.pop_back();
return ans;
}
``````

Indeed, you don't want the vector to be left in an invalid state if an exception is thrown during a move operation.

• I think you mean `v.pop_back()`. Commented Feb 9, 2012 at 21:16
• I also need to return the thing im removing but your right. I'll do it that way. Thx. Commented Feb 9, 2012 at 21:20
• The contents will be that of your vector with the element removed but the order has not been maintained. Commented Feb 9, 2012 at 21:34
• @CashCow: the order of the objects is not a problem, unless I understood the question wrongly. Commented Feb 9, 2012 at 21:35
• This will call n's element destructor twice. How can this be avoided? Commented Apr 14, 2014 at 3:05

With O(n) complexity

vec.erase(vec.begin() + randomIdx); randomIdx would be between 0 and vec.size()-1

If you want O(1) complexity you could either use the list container for example or swap the element with the last one and delete this instead. ( As mentioned by the others )

• Really? Why would that be? That's just a pointer-reassignment actually, isn't it? Commented Feb 9, 2012 at 21:09
• @guitarflow : Because every element after index `n` must be relocated. Commented Feb 9, 2012 at 21:10
• How would that be pointer reassignment? It's an array, not an array of pointers. To erase an element from the middle of the array, you have to shift every element after it down one. Commented Feb 9, 2012 at 21:11
• Ok, I have not been aware of that. I thought the vector would be organized in a linked-list kinda manner. Commented Feb 9, 2012 at 21:13
• @guitarflow : `std::vector<>` must have contiguous storage for its elements, so it effectively must be implemented in terms of an array. (And if it was a linked list, why would there be a `std::list<>` as well?) Commented Feb 9, 2012 at 21:16

Yes, there is a solution, a well-balanced binary tree.

One each node you would need to store the number of nodes on each side. From this it is O(log N) to find the nth element.

Removing the nth element is also O(log N) as you have to traverse back up to tree to correct all the counts. Any rebalancing would be O(log N) too at most.

A tree is considered well balanced if no leaf node is 2 nodes deeper than another. Look up AVL trees to get a rabalancing algorithm.

It would actually be good if the standard library "opened" the use of the trees used for std::set and std::map as a public interface for use in custom trees.

• @CashCow: You are correct that I misread. I removed my comment and downvote. Commented Feb 9, 2012 at 21:44
• What you describe is `std::set`. If the order of the elements must not be altered, then it may be the right solution if the number of elements is expected to grow. If you only have a few elements, `std::vector` + `erase` is also ok (and might be faster than `set`). Commented Feb 9, 2012 at 21:51
• No, std::set requires elements being sorted and unique. There is no need for either of those here. Of course it might work with a map if map finds the nth element in O(log N) time (and it should) and if you create for each element some additional "key" that causes the element to insert where you want it. I am looking at an algorithmic point of view, i.e. you can random access remove (or insert) and maintain order in O(log N) complexity. Commented Feb 9, 2012 at 21:56
• Yes, I figured this out afterwards. It seems that there is indeed no way to access the nth element of a set in O(log n), as it should be possible. Nevertheless, I would not reimplement STL trees here, and try to find another solution than accessing elements by index. Commented Feb 9, 2012 at 22:23
• See also en.wikipedia.org/wiki/AA_tree, which seems simpler to implement than RB trees Commented Feb 9, 2012 at 22:24