I have not read the C++ standard but this is how I feel that the unordered_map of c++ suppose to work.

  • Allocate a memory block in the heap.
  • With every put request, hash the object and map it to a space in this memory
  • During this process handle collision handling via chaining or open addressing..

I am quite surprised that I could not find much about how the memory is handled by unordered_map. Is there a specific initial size of memory which unordered_map allocates. What happens if lets say we allocated 50 int memory and we ended up inserting 5000 integer?

This will be lot of collisions so I believe there should be kind of like a re-hashing and re-sizing algorithm to decrease the number of collisions after a certain level of collision threshold is reached. Since they are explicitly provided as member functions to the class, I assume they are used internally as well. Is there a such mechanism?


With every put request, hash the object and map it to a space in this memory

Unfortunately, this isn't exactly true. You are referring to an open addressing or closed hashing data structure which is not how unordered_map is specified.

Every unordered_map implementation stores a linked list to external nodes in the array of buckets. Meaning that inserting an item will always allocate at least once (the new node) if not twice (resizing the array of buckets, then the new node).

No, that is not at all the most efficient way to implement a hash map for most common uses. Unfortunately, a small "oversight" in the specification of unordered_map all but requires this behavior. The required behavior is that iterators to elements must stay valid when inserting or deleting other elements. Because inserting might cause the bucket array to grow (reallocate), it is not generally possible to have an iterator pointing directly into the bucket array and meet the stability guarantees.

unordered_map is a better data structure if you are storing expensive-to-copy items as your key or value. Which makes sense, given that its general design was lifted from Boost's pre-move-semantics design.

Chandler Carruth (Google) mentions this problem in his CppCon '14 talk "Efficiency with Algorithms, Performance with Data Structures".

  • 1
    According to cppreference, it is OK to invalidate iterators if an insertion causes rehashing. – K.Kit Jun 20 '18 at 3:59
  • @K.Kit - oh you're right. I'm then misremembering the reason why unordered_map has problems then. There's a CppCon video by Chandler Carruth that goes into the details. If I had to scrounge my memory really quickly, based on my experience trying to standardize flat_map, it may have to do with throwing move operations, exceptions, and the strong exception guarantee, perhaps. – Sean Middleditch Jun 26 '18 at 18:57
  • "Meaning that inserting an item will always allocate at least once (the new node) if not twice (resizing the array of buckets, then the new node)." It is not true, actually it just follows the rule most STL allocators do, namely allocate a power of 2 bytes when needed. – DAG Feb 23 at 12:00
  • @DAG: allocators preferring a power-of-two alignment has nothing to do with the bit you're quoting. :) I think you're confusing vector's growth patterns (often a twice-current-capacity growth factor) with the alignment requirements of the allocator. The node-based unordered_map still has to allocate a new node for every insertion completely independent of allocator alignment requires (and if it grows its array of buckets, it may do so by a list of primes rather than grow-by-two, depending on implementation). – Sean Middleditch Feb 24 at 22:09

std::unordered_map contains a load factor that it uses to manage the size of it's internal buckets. std::unordered_map uses this odd factor to keep the size of the container somewhere in between a 0.0 and 1.0 factor. This decreases the likelihood of a collision in a bucket. After that, I'm not sure if they fallback to linear probing within a bucket that a collision was found in, but I would assume so.

  • The default max load factor is actually 1.0, and the actual load factor generally fluctuates between ~0.5 and 1.0 as the table resizes then grows again. And yes - a linear search is done through colliding elements. – Tony Delroy Jun 29 '15 at 10:51
  • Thanks, Tony D. Updated. – kevr Jun 29 '15 at 23:55

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