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The new C++11 standard has unordered containers. In particular, the std::unordered_map<Key, Value> stores a std::pair<Key, Value> in a location based on std::hash<Key> (default hash function). Similarly, the std::unordered_set<Key> stores a Key in a location based on std::hash<Key>.

My question is: how can one store only the Value of a Key-Value pair, in a location based on std::hash<Key>? This would be useful if one uses a perfect hash function, i.e. one for which different Keys map to different hash indices (so there is never collision resolution required).

An unordered_set only uses the key, and an unordered_map uses both the key and the value, so the unordered STL containers in the new C++11 standard do not seem to allow such customization. What would be a good way to get such a data structure from the existing STL containers?

More generally, how can one store a std::pair<T, Value> in a location based on std::hash<Key>, where T is a type representing a signature of the Key? E.g. if Key is a large data structure, I would like to compute a 64-bit hash key and split this into two 32 bit parts: the upper 32 bits together with the Value form a std::pair<uint32_t, Value>, and the lower 32 bits determine the location where this pair is stored.

An application where this would be useful is e.g. computer chess, where a position (several kilobytes in some programs) as the Key type is hashed into a 64-bit key, of which only the upper 32 bits and some search related information as the Value type are stored as a std::pair (usually only 16 bytes in total) in a location based on the lower 32 bits of the hash key.

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If Key is a large data structure as you posit, how it is being stored now? Is there no value in actually storing it? How intensive is it to build hash<Key>? I am failing to see what you cannot due with set given the Key as part of the value, or what there is to gain over map. Your example of saving 16bits of a 64bit value is not strong enough to convince me its worth the effort. –  Chad Jan 9 '12 at 21:07
So you want something that uses hash<Key> to determine the position of where to put Value, without storing hash<key> anywhere? –  dreamlax Jan 9 '12 at 21:08
Storing the key is an implementation requirement. It wouldn't be reasonable to do a hash table without it, because you need to check for multiple hashes going to a single bucket. –  Mark Ransom Jan 9 '12 at 21:11
@rhalbersma : You're describing 'extensible', not 'general-purpose'. The latter merely means what's good enough for most people most of the time; what you're looking for falls well outside of that. –  ildjarn Jan 9 '12 at 22:03
@rhalbersma : "a traits class that is used to extract the key from the value type" If this is what you're after then have a look at Boost.MultiIndex, as that's exactly how it works. :-] –  ildjarn Jan 10 '12 at 15:23

5 Answers 5

up vote 1 down vote accepted

There is no general-purpose way to perform operations on a hash without continuous access to the hash values. For example, suppose the hash internally uses a tree. To add a new node to the hash, you need to compare its hash value to the hash value of existing nodes on the tree. How can you do that if you didn't store their values in the tree?

What you're asking for is probably not impossible, but none of the typical hashing algorithms can do it. And there doesn't seem to be any point anyway, you have to store something to make the collection traversable, and it's hard to see how something other than the hash could ever work as well as the hash, since that's what you're searching for.

If the hash is "too big", use a hash of the hash. (Of course, then you have to deal with hash collisions.)

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As far as I understand it, the OP isn't using the hash<Key> as the actual key, but rather the lower 32bits of it, while storing the upper 32bits together with the value in a pair. –  Xeo Jan 9 '12 at 21:51
Then just make the lower 32-bits of hash<Key> the Key. You still have to store it somewhere though, otherwise there's no way to traverse the hash to do inserts, finds, and deletes. –  David Schwartz Jan 9 '12 at 21:54
@David Schwartz: sorry if I am ignorant about basic data structures, but how can a hash table be implemented using a tree and still have O(1) access time, other than using a random access array/vector as the internal data structure? –  TemplateRex Jan 9 '12 at 22:16
@rhalbersma If you use a n bit hash, the number of tree branches will never exceed n regardless of the number of elements stored. (It's O(1) with respect to the number of entries stored in it.) –  David Schwartz Jan 9 '12 at 22:20

Since C++11 hashes are actually of type size_t you can do something along the lines of:

template <typename T>
struct with_hash
    size_t hash;
    T value;

template<> struct std::hash<with_hash>
    typedef size_t result_type;
    typedef with_hash argument_type;
    size_t operator()(const with_hash &x)
         return x.hash;

template <typename T>
using perfectly_hashed = std::unordered_set< with_hash<T> >;

With a few more sintactic sugar here and there...

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Nice idea, but it still stores the full hash. Based on the answer by David Schwartz, I am now convinced that what I want can only be coded from scratch, not by simple typedefs of an unordered container. –  TemplateRex Jan 9 '12 at 23:09

Implement your hashing function for the type you want to use as a key, and then create a type to hold the hashed value and specialize std::hash on that type to just return the hash value. Now you can compute the hash, discard the data used to compute the hash, and stick the value and its hash in the map.

To retrieve a value you somehow reconstruct the key data, and then you can recompute the hash value, and then search the map for that hash.

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I may have gotten this completely wrong, but why not just a std::unordered_map<uint32_t, std::pair<uint32_t, Value>> with some nice utility functions for insertion and extraction?

// demonstration with 32bit 'hash' and 16bit 'lo' and 'hi'
#include <unordered_map>
#include <string>
#include <stdint.h>
#include <iostream>

int main(){
    typedef std::unordered_map<uint16_t, std::pair<uint16_t, std::string>> map_type;
    map_type m;
    std::string key = "hello", value = "world";
    uint32_t hash = std::hash<std::string>()(key);
    uint16_t lo = hash & 0xFFFF, hi = hash >> 16; // make a nice function for this
    m.insert(std::make_pair(lo, std::make_pair(hi, value))); // and this
    auto it = m.find(lo); // and this
    std::cout << "hash: " << hash << '\n'
              << "lo: " << it->first << '\n'
              << "hi: " << it->second.first << '\n'
              << "lo | (hi << 16): " << (it->first | (uint32_t(it->second.first) << 16)) << '\n'
              << "value: " << it->second.second << '\n';

Live demo on Ideone.


hash: 1335831723
lo: 11435
hi: 20383
lo | (hi << 16): 1335831723
value: world
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that's not quite what I was looking for. In your example, I would like to store only std::make_pair(hi, value) and store this at the location of lo. Your code gets location lo, but stores both hi, lo and value. –  TemplateRex Jan 9 '12 at 22:39
@rhalbersma: Are those 32bit really gone kill your performance or is there another reason you don't want them? –  Xeo Jan 9 '12 at 22:44
on 16 byte hash entries (signature + value), another 4 bytes means 25% more memory. Not gonna kill me, but everything counts. My own implementation uses a two-layered approach that first hashes the Key into a 64-bit integer, then splits it into 32-bit hi/low parts and stores std::pair<hi, Value> into the low-th entry of a std::vector. It is just 150 lines of code, but I am a bit annoyed it can't be done with just a few typedefs and re-using std::unordered_map. –  TemplateRex Jan 9 '12 at 22:52

My question is: how can one store only the Value of a Key-Value pair, in a location based on std::hash? This would be useful if one uses a perfect hash function, i.e. one for which different Keys map to different hash indices (so there is never collision resolution required).

A perfect hash function is not sufficient. Not only do you have to guarantee that there are no hash collisions, you also have to ensure that there are no bucket collisions. Heck, you even have to ensure that the number of buckets never changes, since your data structure cannot discover the hash of a key.

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