Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

Why does the reverse function for the std::list class in the C++ standard library have linear runtime? I would think that for doubly-linked lists the reverse function should have been O(1).

Reversing a doubly-linked list should just involve switching the head and the tail pointers.

share|improve this question
I do not understand why people are downvoting this question. It is a perfectly reasonable question to ask. Reversing a doubly linked list should take O(1) time. – Curious Feb 24 at 20:23
unfortunately, some folks confuse the concepts of "the question is good" with "the question has a good idea". I love questions like this, where basically "my understanding seems different than a commonly accepted practice, please help resolve this conflict", because expanding how you think helps you solve a lot more problems down the road! It would appear others take the approach of "that's a waste of processing in 99.9999% of cases, don't even think about it". If it's any consolation, I've been downvoted for much, much less! – corsiKa Feb 24 at 22:31
Yeah this question got an inordinate amount of downvotes for its quality. Probably it's the same as who upvoted Blindy's answer. In fairness, "reversing a doubly linked list should just involve switching the head and tail pointers" is generally not true for the standard linked list impl that everyone learns in highschool, or for many implementations that people use. A lot of times in SO people's immediate gut reaction to the question or answer drives upvote / downvote decision. If you had been more clear in that sentence or omitted it, I think you would have gotten less downvotes. – Chris Beck Feb 25 at 8:53
Or let me put the burden of proof with you, @Curious: I have whipped up a doubly linked list implementation here: Can you indicate how you would expect the Reverse function to be implemented in O(1)? – CompuChip Feb 25 at 10:58
@CompuChip: Actually, depending on the implementation, it may not. You do not need an extra boolean to know which pointer to use: just use the one not pointing back to you... which could well be automatic with a XOR'ed linked list by the way. So yes, it depends on how the list is implemented, and the OP statement could be clarified. – Matthieu M. Feb 25 at 13:33
up vote 163 down vote accepted

Hypothetically, reverse could have been O(1). There (again hypothetically) could have been a boolean list member indicating whether the direction of the linked list is currently the same or opposite as the original one where the list was created.

Unfortunately, that would reduce the performance of basically any other operation (albeit without changing the asymptotic runtime). In each operation, a boolean would need to be consulted to consider whether to follow a "next" or "prev" pointer of a link.

Since this was presumably considered a relatively infrequent operation, the standard (which does not dictate implementations, only complexity), specified that the complexity could be linear. This allows "next" pointers to always mean the same direction unambiguously, speeding up common-case operations.

share|improve this answer
@MooseBoys I think what you wrote here - with which I completely agree - is exactly the point. You could hypothetically take the most common operation on a container, e.g., iteration, and say that it is not more O(1), but rather O(n log(n)), because it might require, say, sorting, while sorting could be O(1) due to "lazy" sorts. I guess the art of defining standards is deciding if this makes sense or not. – Ami Tavory Feb 24 at 21:19
@MooseBoys: I don't agree with your analogy. The difference is that, in the case of a list,the implementation could provide reverse with O(1) complexity without affecting the big-o of any other operation, by using this boolean flag trick. But, in practice an extra branch in every operation is costly, even if it is technically O(1). By contrast, you cannot make a list structure in which sort is O(1) and all the other operations are the same cost. The point of the question is that, seemingly, you can get O(1) reverse for free if you only care about big O, so why didn't they do that. – Chris Beck Feb 24 at 22:49
If you used an XOR-linked-list, reversing would become constant time. An iterator would be bigger though, and incrementing/decrementing it would be slightly more computationally expensive. That might be dwarfed by the unavoidable memory-accesses though for any kind of linked list. – Deduplicator Feb 25 at 1:26
@IlyaPopov: Does every node actually need this? The user never asks any questions of the list node itself, only the main list body. So accessing the boolean is easy for any method that the user calls. You could make the rule that the iterators are invalidated if the list is reversed, and/or store a copy of the boolean with the iterator, for example. So I think it would not affect the big O, necessarily. I'll admit, I didn't go line-by-line through the spec. :) – Chris Beck Feb 25 at 3:47
@Kevin: Hm, what? You cannot xor two pointers directly anyway, you need to convert them to integers first (obviously of type std::uintptr_t. Then you can xor them. – Deduplicator Feb 25 at 5:40

It could be O(1) if the list would store a flag that allows swapping the meaning of the “prev” and “next” pointers each node has. If reversing the list would be a frequent operation, such an addition might be in fact useful and I don't know of any reason why implementing it would be prohibited by the current standard. However, having such a flag would make ordinary traversal of the list more expensive (if only by a constant factor) because instead of

current = current->next;

in the operator++ of the list iterator, you would get

if (reversed)
  current = current->prev;
  current = current->next;

which is not something you'd decide to add easily. Given that lists are usually traversed much more often than they are reversed, it would be very unwise for the standard to mandate this technique. Therefore, the reverse operation is allowed to have linear complexity. Do note, however, that tO(1) ⇒ tO(n) so, as mentioned earlier, implementing your “optimization” technically would be permitted.

If you come from a Java or similar background, you might wonder why the iterator has to check the flag each time. Couldn't we instead have two distinct iterator types, both derived from a common base type, and have std::list::begin and std::list::rbegin polymorphically return the appropriate iterator? While possible, this would make the whole thing even worse because advancing the iterator would be an indirect (hard to inline) function call now. In Java, you're paying this price routinely anyway, but then again, this is one of the reasons many people reach for C++ when performance is critical.

As pointed out by Benjamin Lindley in the comments, since reverse is not allowed to invalidate iterators, the only approach permitted by the standard seems to be to store a pointer back to the list inside the iterator which causes a double-indirect memory access.

share|improve this answer
@galinette: std::list::reverse does not invalidate iterators. – Benjamin Lindley Feb 24 at 21:08
@galinette Sorry, I mis-read your earlier comment as “flag per iterator” as opposed to “flag per node” as you wrote it. Of course, a flag per node would be counter-productive as you would, again, have to do a linear traversal to flip them all. – 5gon12eder Feb 24 at 21:30
@5gon12eder: You could eliminate the branching at very lost cost: store the next and prev pointers in an array, and store the direction as a 0 or 1. To iterate forward, you'd follow pointers[direction] and to iterate in reverse pointers[1-direction] (or vice versa). This would still add a tiny bit of overhead, but probably less than a branch. – Jerry Coffin Feb 25 at 6:22
You probably can't store a pointer to the list inside the iterators. swap() is specified to be constant time and not invalidate any iterators. – Tavian Barnes Feb 25 at 19:13
@TavianBarnes Damn it! Well, triple indirection then… (I mean, not actually triple. You'd have to store the flag in a dynamically allocated object but the pointer in the iterator can of course point directly to that object instead of indirecting over the list.) – 5gon12eder Feb 25 at 23:09

Surely since all containers that support bidirectional iterators have the concept of rbegin() and rend(), this question is moot?

It's trivial to build a proxy that reverses the iterators and access the container through that.

This non-operation is indeed O(1).

such as:

#include <iostream>
#include <list>
#include <string>
#include <iterator>

template<class Container>
struct reverse_proxy
    reverse_proxy(Container& c)
    : _c(c)

    auto begin() { return std::make_reverse_iterator(std::end(_c)); }
    auto end() { return std::make_reverse_iterator(std::begin(_c)); }

    auto begin() const { return std::make_reverse_iterator(std::end(_c)); }
    auto end() const { return std::make_reverse_iterator(std::begin(_c)); }

    Container& _c;

template<class Container>
auto reversed(Container& c)
    return reverse_proxy<Container>(c);

int main()
    using namespace std;
    list<string> l { "the", "cat", "sat", "on", "the", "mat" };

    auto r = reversed(l);
    copy(begin(r), end(r), ostream_iterator<string>(cout, "\n"));

    return 0;

expected output:


Given this, it seems to me that the standards committee have not taken time to mandate O(1) reverse-ordering of the container because it's not necessary, and the standard library is largely built on the principle of mandating only what is strictly necessary while avoiding duplication.

Just my 2c.

share|improve this answer

Because it has to traverse every node (n total) and update their data (the update step is indeed O(1)). This makes the whole operation O(n*1) = O(n).

share|improve this answer
Because you need to update the links between every item too. Take out a piece of paper and draw it out instead of downvoting. – Blindy Feb 24 at 20:23
Why ask if you're so sure then? You're wasting both our time. – Blindy Feb 24 at 20:26
@Curious Doubly linked list's nodes have a sense of direction. Reason from there. – Shoe Feb 24 at 20:26
@Blindy A good answer should be complete. "Take out a piece of paper and draw it out" thus should not be a requisite component of a good answer. Answers which are not good answers are subject to downvotes. – R.M. Feb 25 at 0:07
@Shoe: Do they have to? Please research XOR-linked-list and the like. – Deduplicator Feb 25 at 1:23

Only an algorithm explanation. Imagine you have an array with elements, then you need to inverted it. The basic idea is to iterate on each element changing the element on the first position to the last position, the element on second position to penultimate position, and so on. When you reach at the middle of the array you'll have all elements changed, thus in (n/2) iterations, which is considered O(n).

share|improve this answer

It also swaps previous and next pointer for every node. Thats why it takes Linear. Although it can be done in O(1) if the function using this LL also takes information about LL as input like whether it is accessing normally or reverse.

share|improve this answer

It is O(n) simply because it needs to copy the list in reverse order. Each individual item operation is O(1) but there are n of them in the entire list.

Of course there are some constant-time operations involved in setting up the space for the new list, and changing pointers afterwards, etc. The O notation doesn't consider individual constants once you include a first-order n factor.

share|improve this answer

protected by Ionică Bizău Mar 10 at 4:47

Thank you for your interest in this question. Because it has attracted low-quality or spam answers that had to be removed, posting an answer now requires 10 reputation on this site.

Would you like to answer one of these unanswered questions instead?

Not the answer you're looking for? Browse other questions tagged or ask your own question.