How does C++ STL unordered_map resolve collisions?

Looking at the http://www.cplusplus.com/reference/unordered_map/unordered_map/, it says "Unique keys No two elements in the container can have equivalent keys."

That should mean that the container is indeed resolving collisions. However, that page does not tell me how it is doing it. I know some ways to resolve collisions like using linked lists and/or probing. What I want to know is how the c++ STL unordered_map is resolving it.

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    It's implementation dependent. A language reference won't tell you how it's done, because it is not specified in the standard how it should be done. Feb 3, 2014 at 2:04
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    libstdc++ uses linear chaining, but other implementations of the STL may use other techniques
    – Brian Bi
    Feb 3, 2014 at 2:09
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    Technically, we're not using the STL at all. We're using the C++ Standard Library, which is an interface specification. And yes, it has multiple implementations. Feb 3, 2014 at 2:18
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    No, the STL was a library decades ago which had ideas stolen and incorperated into the C++ standard library. Each compliler of C++ must implement the standard library through whatever means it chooses. People tend to call the parts of the standard library inspired by the STL the STL, albeit incorrectly. Feb 3, 2014 at 3:45
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    "No two elements in the container can have equivalent keys" is a condition on Pred parameter of unordered_map. The notion of collisions applies to Hash parameter. Two keys may not be equivalent but may still hash to the same value - the very definition of hash collision. Feb 3, 2014 at 4:02

2 Answers 2


The standard defines a little more about this than most people seem to realize.

Specifically, the standard requires (§23.2.5/9):

The elements of an unordered associative container are organized into buckets. Keys with the same hash code appear in the same bucket.

The interface includes a bucket_count that runs in constant time. (table 103). It also includes a bucket_size that has to run in time linear on the size of the bucket.

That's basically describing an implementation that uses collision chaining. When you do use collision chaining, meeting all the requirements is somewhere between easy and trivial. bucket_count() is the number of elements in your array. bucket_size() is the number of elements in the collision chain. Getting them in constant and linear time respectively is simple and straightforward.

By contrast, if you use something like linear probing or double hashing, those requirements become all but impossible to meet. Specifically, all the items that hashed to a specific value need to land in the same bucket, and you need to be able to count those buckets in constant time.

But, if you use something like linear probing or double hashing, finding all the items that hashed to the same value means you need to hash the value, then walk through the "chain" of non-empty items in your table to find how many of those hashed to the same value. That's not linear on the number of items that hashed to the same value though--it's linear on the number of items that hashed to the same or a colliding value.

With enough extra work and a fair amount of stretching the meaning of some of the requirements almost to the breaking point, it might be barely possible to create a hash table using something other than collision chaining, and still at least sort of meet the requirements--but I'm not really certain it's possible, and it would certain involve quite a lot of extra work.

Summary: all practical implementations of std::unordered_set (or unordered_map) undoubtedly use collision chaining. While it might be (just barely) possible to meet the requirements using linear probing or double hashing, such an implementation seems to lose a great deal and gain nearly nothing in return.

  • "It's still possible to meet the requirement [using linear probing or double hashing]" / "Then you walk through the "chain" of occupied items to find a slot where you can insert this item." isn't compatible with the "Keys with the same hash code appear in the same bucket." requirement. Of course, it's debatable if collision chaining puts anything "in the same bucket" anyway, but you're clearly proposing putting keys with the same hash in different buckets. 23.2.5/9 seems an unfortunate restriction... probing is useful for more than "load factor low" - many benefits from avoiding heap.... Feb 3, 2014 at 4:46
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    @TonyD: not really--in this case, a "bucket" is no longer a physical thing, but simply all the slots that hashed to the same value. You'd have to build enough intelligence into local_iterator to skip across any colliding items, but it still looks entirely possible to me. Feb 3, 2014 at 4:55
  • If it's that flexible, "Keys with the same hash code appear in the same bucket." has no meaning at all. Agree to disagree etc.. Cheers. Feb 3, 2014 at 5:21
  • @TonyD: Not really. A bucket is the set of items with keys that hashed to a particular value, and which can be iterated with a local_iterator. Given that they're specifically avoiding specifying an implementation, it really shouldn't mean much about the implementation. Feb 3, 2014 at 5:24
  • Well, finding a mutually-agreed authoritative definition of "bucket" from e.g. Dijkstra isn't easy with Google, so let's just consider whether your postulated implementation can meet other requirements. Per your rationale for needing count, b.find(k) can't be worst-case O(b.size()) where b is a "logical" bucket size(). Further, b.begin(n), b.end(n) et al are required to have constant complexity, so would need to be stored alongside your count at the originally hashed-to bucket. Feb 3, 2014 at 6:30

I found this answer looking for how to detect when my types are colliding, so I will post this in case that is the intent of the question.:

I believe there's some misconception about "Unique keys No two elements in the container can have equivalent keys."

look at the code below

std::unordered_map<int, char> hashmap;
hashmap[5] = 'a';
hashmap[5] = 'b'; //replace 'a' with 'b', there is no collision being handled.

I think the Jerry's answer is referring to the internal system that it uses to shrink keys to appropriate array indices.

If you want collisions to be handled for your types (with buckets), you need std::unordered_multimap and will have to iterate over

Hopefully this code can be read without the context I generated it with. it basically checks to see if any element in the bucket associated with the hash is the element I'm looking for.

//sp is std::shared_ptr
//memo is std::unordered_multimap< int, sp<AStarNode> >

//there's probably multiple issues with this code in terms of good design (like using int keys rather than unsigned)

bool AStar_Incremental::hasNodeBeenVisited(sp<AStarNode> node)
    using UMIter = std::unordered_multimap<int, sp<AStarNode> >::iterator;

    bool bAlreadyVisited = false;

    //get all values for key in O(1*)
    int hash = WorldGrid::hashGrid(node->location);
    std::pair<UMIter, UMIter> start_end = memo.equal_range(hash); //bucket range
    UMIter start = start_end.first;
    UMIter end = start_end.second;

    //hopefully this is implemented to be O(m) where m is the bucket size.
    for(UMIter bucketIter = start; bucketIter != end; ++bucketIter)
        sp<AStarNode> previousNode = bucketIter->second;
        sf::Vector2i& previousVisit = previousNode->location;
        if (previousVisit == node->location)
            bAlreadyVisited = true;

    return bAlreadyVisited;

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