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Since the items in a Standard Library set container are sorted, will using the find member on the set, in general, perform faster than using the find algorithm on the same items in a sorted list?

Since the list is linear and the set is often implemented using a sorted tree, it seems as though the set-find should be faster.

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Yes, but std::binary_search on a sorted list may be faster still. –  larsmans Sep 22 '11 at 14:49
@larsmans: important note, binary_search returns whether the element is contained or not, not an iterator. Also, I really doubt it will be faster. On a sorted vector, why not, but on a list you still have a linear walk, even though you only have O(log N) comparisons. –  Matthieu M. Sep 22 '11 at 15:03
@larsmans: No, it is not. Since list has no random access iterators, the "jumping around" needs a lot of time. A quick bench on gcc 4.6 here shows that for searching a number in 1500 integers, set takes 0.001 seconds, while linear search on list takes 406 times more, and binary search on a list takes 1338 times as much as the set. –  PlasmaHH Sep 22 '11 at 15:06
@PlasmaHH: Sorry, I confused lists and arrays. Been writing too much Python lately :) –  larsmans Sep 23 '11 at 9:54

5 Answers 5

up vote 6 down vote accepted

With a linked list, even a sorted one, finding an element is O(n). A set can be searched in O(log n). Therefore yes, finding an element in a set is asymptotically faster.

A sorted array/vector can be searched in O(log n) by using binary search. Unfortunately, since a linked list doesn't support random access, the same method can't be used to search a sorted linked list in O(log n).

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Note: You will have O(log n) comparisons (which is usually what is counted for sort/search) but O(n) (at least) moves. –  Matthieu M. Sep 22 '11 at 15:04

It's actually in the standard: std::set::find() has complexity O(log n), where n is the number of elements in the set. std::find() on the other hand is linear in the length of the search range.

If your generic search range happens to be sorted and has random access (e.g. a sorted vector), then you can use std::lower_bound() to find an element (or rather a position) efficiently.

Note that std::set comes with its own member-lower_bound(), which works the same way. Having an insertion position may be useful even in a set, because insert() with a correct hint has complexity O(1).

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You can generally expect a find operation to be faster on a Set than on a List, since lists are linear access (O(n)), while sets may have near-constant access for HashSets (O(1)), or logarithmic access for TreeSets (O(log n)).

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set::find has a complexity of O(log(n)), while std::find has a complexity of O(n). This means that std::set::find() is asymptotically faster than std::find(std::list), but that doesn't mean it is faster for any particular data set, or for any particular search.

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I found this article helpful on the topic. http://lafstern.org/matt/col1.pdf

You could reconsider your requirements for just a "list" vs. a "set". According to that article, if your program consists primarily of a bunch of insertions at the start, and then after that, only comparisons to what you have stored, then you are better off with adding everything to a vector, using std::sort (vector.begin(), vector.end()) once, and then using lower_bound. In my particular application, I load from a text file a list of names when the program starts up, and then during program execution I determine if a user is in that list. If they are, I do something, otherwise, I do nothing. In other words, I had a single discrete insertion phase, then I sorted, then after that I used std::binary_search (vector.begin(), vector.end(), std::string username) to determine whether the user is in the list.

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