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I'd like to pre-calculate an array of values of some unary function f.

I know that I'll only need the values for f(x) where x is of the form of a*b, where both a and b are integers in range 0..N.

The obvious time-optimized choice is just to make an array of size N*N and just pre-calculate just the elements which I'm going to read later. For f(a*b), I'd just check and set tab[a*b]. This is the fastest method possible - however, this is going to take a lot of space as there are lots of indices in this array (starting with N+1) which will never by touched.

Another solution is to make a simple tree map... but this slows down the lookup itself very heavily by introducing lots of branches. No.

I wonder - is there any solution to make such an array less sparse and smaller, but still quick branchless O(1) in lookup?

edit

I can hear lots of comments about a hash map... I'll proceed to benchmark how one behaves (I expect a significant performance drop over normal lookup due to branching; less than in trees, but still... let's see if I'm right!).

I'd like to emphasize: I'd mostly appreciate an analytical solution which would use some clever way (?) to take advantage of the fact that only "product-like" indices are taken. I feel that this fact might be exploited to get a way better result that an average generic hash map function, but I'm out of ideas myself.

edit

Following your advice, I've tried std::unordered_map from gcc 4.5. This was a tad slower than the simple array lookup, but indeed much faster than the tree-based std::map - ultimately I'm OK with this solution. I understand now why it's not possible to do what I originally intended to; thanks for the explanations!

I'm just unsure whether the hash-map actually saves any memory! :) As @Keith Randall has described, I cannot get the memory footprint lower than N*N/4, and the triangular matrix approach described by @Sjoerd gives me N*N/2. I think that it's entirely possible for the hash map to use more than N*N/2 space if the element size is small (depends on the container overhead) - which would make the fastest approach also the most memory-effective! I'll try to check that.

I wish I could accept 2 answers...

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Can you change f to be f(a, b)? –  James McNellis Jan 15 '11 at 1:43
    
Of course... even a wrapper can do that. The result depends only on the product. –  Kos Jan 15 '11 at 1:47
    
Well, it wasn't clear if you actually knew a and b at the time of the call or whether you just had x. –  James McNellis Jan 15 '11 at 1:53
1  
If you find a fast way to skip unused entries, it could be turned into a fast way to tell whether a number is prime. As the latter is considered a hard problem, I doubt you'll get an good analytical solution for your problem. –  Sjoerd Jan 16 '11 at 0:38

4 Answers 4

up vote 2 down vote accepted

There doesn't seem to be a lot of structure to take advantage of here. If you're asking if there is a way to arrange to arrange the table such that you can avoid storage for entries that can't happen (because they have a prime factor larger than N), you can't save much. There is a theory of smooth numbers which states that the density of N-smooth numbers near N^2 is ~2^-2. So, absolute best case, you can reduce the (maximum) storage requirement by at most a factor of 4.

I think you're better off taking advantage of symmetry and then using a hash table if you expect most arguments to never occur.

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Start with looking at it as a two-dimensional array: tab[a][b]. This still requires N*N size.

Each entry will be used, but there will be duplication: f(a,b) = f(b,a). So only a triangular matrix is required (at the cost of one branch for a>b vs a<b).

if (a < b) return tab[b*(b+1) + a]; // assuming 0 <= a < b < N
else return tab[a*(a+1) + b];       // assuming 0 <= b <= a < N

Or

if (a < b) return tab[b*(b-1) + a]; // assuming 1 <= a < b <= N
else return tab[a*(a-1) + b];       // assuming 1 <= b <= a <= N

EDIT: the memory used by a triangular matrix is (N+1)*N/2, about half the size of a square matrix. Still quadratic, though :(

EDIT2: Note that er is still duplication in the matrix: e.g. f(3, 2) = f(6, 1). I don't think this can be eliminated without introducing lots of branches and loops, but that's just a gut feeling.

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this assumes that f(a,b) does indeed equal f(b,a) –  Will Hartung Jan 15 '11 at 7:23
    
@Will As the question states that only the product of a and b is used in the calculation, I assumed that was the case. –  Sjoerd Jan 16 '11 at 0:14

Why not simply hash the A and B combo and put the results in a map? And do it lazily so you just get the ones you want?

public Result f(Type1 a, Type2 b) {
    TypePair key = new TypePair(a, b);
    Result res = map.get(key);
    if (res == null) {
        res = reallyCalculate(a, b);
        map.put(key, res);
    }
    return res;
}

Basic memoization.

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1  
This looks an awful lot like Not C++. –  James McNellis Jan 15 '11 at 1:47
    
I can live with that ;-) –  Kos Jan 15 '11 at 1:49
    
Due to the distribution of (a,b), there will be an awful lots of collisions. And each collision is another branch. Not to mention the memomry overhead for the collision lists. For small N, a simple N*N array will require less memory and be faster. Maybe the actual N will be in that range? –  Sjoerd Jan 15 '11 at 1:58
    
Depends on the hash function and the size of the underlying array. If the array is large enough and the hash is good, there is no benefit to using an n x n array - especially if it is sparse. –  Andrei Krotkov Jan 15 '11 at 2:47
    
@Andrei You rely on "if [...] the hash is good." That's a big assumption. –  Sjoerd Jan 16 '11 at 0:12

Hash tables provide a good balance between lookup speed and memory overhead. The C++ standard library does not provide a hash table, although it is sometimes available as a non-standard extension. See the SGI hash_map for example.

The Poco C++ library also has a HashTable and HashMap classes, see the documentation.

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