What is the most efficient way of adding non-repeated elements into STL container and what kind of container is the fastest? I have a large amount of data and I'm afraid each time I try to check if it is a new element or not, it takes a lot of time. I hope map be very fast.

// 1- Map
map<int, int> Map;
if(Map.find(Element)!=Map.end()) Map[Element]=ID;

// 2-Vector
vector<int> Vec;
if(find(Vec.begin(), Vec.end(), Element)!=Vec.end()) Vec.push_back(Element);

// 3-Set
// Edit: I made a mistake: set::find is O(LogN) not O(N)
  • 3
    "I read that find in set is very slow O(N) versus O(logN)" If you're referring to std::set<>, then no, that's incorrect.
    – ildjarn
    Jan 22, 2013 at 23:13
  • 1
    If you don't need the key-value semantics of the map, std::set doesn't insert duplicates and is typically implemented as a red-black tree (ref).
    – chris
    Jan 22, 2013 at 23:13
  • 4
    @Hesam, From the link, std::find performs a linear search, so the time it takes is proportional to N (where N is the number of elements you're looking through), while the time taken by set::find is proportional to log N
    – chris
    Jan 22, 2013 at 23:18
  • 1
    You haven't read that very well; it just advises not to use std::find. Jan 22, 2013 at 23:18
  • 4
    @Hesam : That paper says that using the std::find() algorithm over a std::set<> is O(N), which is correct – but you shouldn't be using std::find() over a std::set<> in the first place, you should be using std::set<>::find(), so it's a moot point.
    – ildjarn
    Jan 22, 2013 at 23:19

6 Answers 6


Both set and map has O(log(N)) performance for looking up keys. vector has O(N).

The difference between set and map, as far as you should be concerned, is whether you need to associate a key with a value, or just store a value directly. If you need the former, use a map, if you need the latter, use a set.

In both cases, you should just use insert() instead of doing a find().

The reason is insert() will insert the value into the container if and only if the container does not already contain that value (in the case of map, if the container does not contain that key). This might look like

Map.insert(std::make_pair(Element, ID));

for a map or


for a set.

You can consult the return value to determine whether or not an insertion was actually performed.

If you're using C++11, you have two more choices, which are std::unordered_map and std::unordered_set. These both have amortized O(1) performance for insertions and lookups. However, they also require that the key (or value, in the case of set) be hashable, which means you'll need to specialize std::hash<> for your key. Conversely, std::map and std::set require that your key (or value, in the case of set) respond to operator<().


If you're using C++11, you can use std::unordered_set. That would allow you O(1) existence-checking (technically amortized O(1) -- O(n) in the worst case).

std::set would probably be your second choice with O(lg n).

Basically, std::unordered_set is a hash table and std::set is a tree structure (a red black tree in every implementation I've ever seen)1.

Depending on how well your hashes distribute and how many items you have, a std::set might actually be faster. If it's truly performance critical, then as always, you'll want to do benchmarking.

1) Technically speaking, I don't believe either are required to be implemented as a hash table or as a balanced BST. If I remember correctly, the standard just mandates the run time bounds, not the implementation -- it just turns out that those are the only viable implementations that fit the bounds.

  • 1
    There are a lot of issues with using a hash map though, such as the size of your objects and the security of the hash. They are good, but they aren't the one and only solution to every problem. Jan 22, 2013 at 23:20
  • @AlexChamberlain Yes, I noted that (though implicitly). Also, the hashing algorithm used for hash maps have nothing to do with security. While collisions are still seen as bad, there are different categories of hash functions. A hash table hash needs to be extremely fast, which tends to never coincide with secure. Also, can you expand on the size comment? I'm not sure I understand that one. There will be extra value_type instances, but the keys have to be stored in a hash map the same way that they're stored in a set.
    – Corbin
    Jan 22, 2013 at 23:21
  • Security - If a known hash has a known pattern in its collisions and an attacker can encourage your hash map to store them, the buckets will become very large and could cause your program to become super unresponsive. In a server program, for example, this is a security problem and one that Java has suffered (many times?) Jan 22, 2013 at 23:26
  • Size - if your objects are huge and you are only storing a few of them, then hashing the objects - an O(m) runtime in the size of the object - becomes rather significant and you could benefit from using a std::set which may be able to get away with only comparing part of an object. Jan 22, 2013 at 23:28
  • @AlexChamberlain Ah, true on both points. As you said, a less-than comparison can short circuit whereas a hashing operation cannot. Typically the hashing is only done on a relatively small part of an object though (and often fixed in size). As for purposely causing collisions and making huge buckets (and thus long linear time operations), that would be quite an interesting security hole. While very feasible, it seems like that would be pretty rare in the wild. I suppose 'rare' still exists though :).
    – Corbin
    Jan 22, 2013 at 23:39

You should use a std::set; it is a container designed to hold a single (equivalent) copy of an object and is implemented as a binary search tree. Therefore, it is O(log N), not O(N), in the size of the container.

std::set and std::map often share a large part of their underlying implementation; you should check out your local STL implementation.

Having said all this, complexity is only one measure of performance. You may have better performance using a sorted vector, as it keeps the data local to one another and, therefore, more likely to hit the caches. Cache coherence is a large part of data structure design these days.


Sounds like you want to use a std::set. It's elements are unique, so you don't need to care about uniqueness when adding elements, and a.find(k) (where a is an std::set and k is a value) is defined as being logarithmic in complexity.


if your elements can be hashed for O(1), then better to use an index in a unordered_map or unordered_set (not in a map/set because they use RB tree in implementation which is O(logN) find complexity)


Your examples show a definite pattern:

check if the value is already in container
  if not, add the value to the container.

Both of these operation would potentially take some time. First, looking up an element can be done in O(N) time (linear search) if the elements are not arranged in any particular manner (e.g., just a plain std::vector), it could be done in O(logN) time (binary search) if the elements are sorted (e.g., either std::map or std::set), and it could be done in O(1) time if the elements are hashed (e.g., either std::unordered_map or std::unordered_set).

The insertion will be O(1) (amortized) for a plain vector or an unordered container (hash container), although the hash container will be a bit slower. For a sorted container like set or map, you'll have log-time insertions because it needs to look for the place to insert it before inserting it.

So, the conclusion, use std::unordered_set or std::unordered_map (if you need the key-value feature). And you don't need to check before doing the insertion, these are unique-key containers, they don't allow duplicates.

If std::unordered_set / std::unordered_map (from C++11) or std::tr1::unordered_set / std::tr1::unordered_map (since 2007) are not available to you (or any equivalent), then the next best alternative is std::set / std::map.

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