I have about 20,000,000 pair<int, int> which I need to associate to ints. I did so with an unordered_map<pair<int, int>, int>. Profiling my algorithm shows that checking whether an entry exists or not

bool exists = myMap[make_pair(a, b)] != NULL

is the performance bottleneck. I thought that retrieving this information from an unordered_map would be really fast, as it is O(1). But constant time can be slow if the constant is big...

My hash-function is

template <>
struct tr1::hash<pair<int, int> > {
public:
        size_t operator()(pair<int, int> x) const throw() {
             size_t h = x.first * 1 + x.second * 100000;
             return h;
        }
};

Do you know any better data-structure for my problem?

Obviously I can't just store the information in a matrix, hence the amount of memory wouldn't fit into any computer in existence. All I know about the distribution is that myMap[make_pair(a, a)] doesn't exist for any a. And that all ints are in a continuous range from 0 to about 20,000,000.

Think of it as a sparse 20,000,000x20,000,000-Matrix with about 20,000,000 entries but never on the main diagonal.

Suggestion

Would a vector<pair<int, int>>* (array with N entries) expected to be faster? The lookup for a would be trivial (just the index of the array) and then I would iterate through the vector, comparing the first value of the pair to b.

BIG UPDATE

I uploaded the raw data so you can see the structure.

  • Must the ints in the pair be retrievable? Or is it fine to create two maps? umap<some_key, int> and umap<some_key, pair<>>? – RedX Jul 11 '14 at 7:48
  • 5
    Note that myMap[make_pair(a, b)] != NULL does not do what you think it does. It inserts the pair if it doesn't exist, and compares the mapped value to 0 (which is what NULL expands to). It does not check for existence at all. In modern C++, you should never use NULL. – Angew Jul 11 '14 at 7:49
  • 1
    We need to know your algorithm to find a better data structure. Maybe you just need an two-dimensional array, but maybe you need something else. – johnchen902 Jul 11 '14 at 7:56
  • If you know anything about the data distribution, you could provide your own hash function, adapted to produce as little collisions as possible. – Angew Jul 11 '14 at 7:58
  • 1
    @a_guest std::unordered_map is a hashmap, not a tree. That's std::map. – Angew Jul 11 '14 at 8:14

Have you tried using myMap.find(make_pair(a,b)) != myMap.end() ? operator[] creates the element if it does not exist. I would expect find to be faster.

  • How about count? – johnchen902 Jul 11 '14 at 7:51
  • I just tried find vs. [] and it changed nothing. :-( – user2033412 Jul 11 '14 at 7:53
  • I tried count vs [] and it was the same, too. – user2033412 Jul 11 '14 at 7:57
  • you just made my day! thanks for this! I had been trying to this question on codechef for 2 days and this was the optimizing i needed! thanks a lot!! – Abhyudaya Srinet Oct 8 '14 at 12:37

First off, myMap[make_pair(a, b)] != NULL does not do what you think it does. It inserts the pair if it doesn't exist, and compares the mapped value to 0 (which is what NULL expands to). It does not check for existence at all. (Note that in modern C++, you should never use NULL. Use 0 for numbers and nullptr for pointers).

As for the main topic, your hash function doesn't seem too good. Don't forget that arithmetic on ints is done in ints. Since on most compilers int is 32-bit, its maximum value is a little over 2,000,000,000. So 20,000,000 * 10,000 is way bigger than that, leading to overflow (and undefined behaviour).

Given the number of your data, I assume you're on a 64-bit platform, which means size_t is 64 bits long. So you might get better results with a hash function like this:

size_t operator()(pair<int, int> x) const throw() {
     size_t f = x.first, s = x.second;
     return f << (CHAR_BIT * sizeof(size_t) / 2) | s;
}

This should produce significantly less collisions (and have defined behaviour) that what you have now.

If this doesn't help, you could also try a two-step approach:

std::unordered_map<int, std::unordered_map<int, int>>

Lookup by x.first first, then by x.second. I don't know if this would help; measure and see.

  • By using your hash-function the algorithm becase unusably slow... like... more than 100 times slower! I'm really surprised! – user2033412 Jul 11 '14 at 8:31
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    @user2033412 Interesting. Have you tried profiling inside the find() of the map to find why it takes so long (even in your original version)? As a sanity check, you are running optimised code, right? – Angew Jul 11 '14 at 8:38
  • I am running optimized code. Profiling shows the following during insertion (creating of the umap is also incredibly slow...): profiler – user2033412 Jul 11 '14 at 8:47
  • 4
    sizeof(size_t) / 2 will be something like 4. You probably want CHAR_BIT * sizeof(size_t) / 2. – Falk Hüffner Jul 11 '14 at 9:22
  • I just tried the corrected version of Falk Huffner. Now it runs as fast as the original version. This version should not produce any collisions at all and hence be as performant as possible, right? – user2033412 Jul 11 '14 at 9:26

Main thing is definitely to avoid adding default-constructed elements with every search:

bool exists = myMap[make_pair(a, b)] != NULL; // OUCH

bool exists = myMap.find(make_pair(a, b)) != myMap.end();  // BETTER

iterator i = myMap.find(make_pair(a, b);
if (i != myMap.end()) ... else ...;      // MAY BE BEST - SEE BELOW

And the great hash challenge... woo hoo! This might be worth a shot, but a lot depends on how the numbers in the pairs are distributed and your implementation's std::hash (which is often pass-through!):

    size_t operator()(pair<int, int> x) const throw() {
         size_t hf = std::hash(x.first);
         return (hf << 2) ^ (hf >> 2) ^ std::hash(x.second);
    }

You may also find it faster if you replace the pair with int64_ts, so that the key comparisons are definitely simple integer comparisons rather than cascaded.

Also, what are you doing after the test for existence? If you need to access/change the value associated with the same key then you should save the iterator find returns and avoid another search.

  • I'm now using Angew's hash-function which is basically comparing int64_t (see his answer below). I need to access the value but as most looked up pairs don't exists this is not critical. – user2033412 Jul 11 '14 at 10:19
  • @user2033412: I have reason to think my hash function may work better than Angew's (or I wouldn't have bothered to post it after seeing his) - it gets technical but in the end if you care about speed you should measure both then choose. When I talk about 64 bit unordered_map keys above, I am not talking about the width of the hash, but rather combining the two ints in the key into a single int64_t before storing it in the table, then extracting it again afterwards, or storing a type with a union of int64_t and int32_t. – Tony Delroy Jul 11 '14 at 10:54
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    Separately, you may be able to use some kind of bloom filter to eliminate many of the failing lookups without searching the hash table. Is there anything more you tell me about the data? What kind of histogram would you get for the number of repeats of any given .first value? Clearly the average is one repeat, but what's the shape of the curve? Is the curve for .second similar? Is .first completely uncorrelated to .second? – Tony Delroy Jul 11 '14 at 10:59
  • Im currently creating a text-file containing the complete set of raw-data in the following format (one entry per line): [a,b] -> c. I'll upload it and post the link asap. – user2033412 Jul 11 '14 at 11:10
  • @user2033412 sounds good (and like it'll be big) – Tony Delroy Jul 11 '14 at 11:20
up vote 1 down vote accepted

As suggestet, I went with a vector<pair<int, int>>* with N entries. It's about 40% faster than the unordered_map.

I suggest you test with a better hash function. You can find examples if you search here on SO but this is one possible implementation.

struct pair_hash {
    template <typename T1, typename T2>
    size_t operator()(const std::pair<T1, T2> &pr) const {
        using std::hash;
        return hash<T1>()(pr.first) ^ hash<T2>()(pr.second);
    }
};
  • 1
    This will give collisions on the main diagonal of the matrix (i.e. (0,0), (1,1), ...) where usually the elements are considered to be non-zero. – a_guest Jul 11 '14 at 8:35
  • 1
    @a_guest From OP: All I know about the distribution is that myMap[make_pair(a, a)] doesn't exist for any a. – johnchen902 Jul 11 '14 at 8:37
  • @a_guest: True, you could always shift or complement one of the hash values to reduce that problem. – Blastfurnace Jul 11 '14 at 8:37
  • I just tried it and it's slightly slower than the original hash-function. – user2033412 Jul 11 '14 at 8:38

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