I would use some sort of hash function that creates an index to a u64 pair where one is the value the key was created from and the other the replacement value. Technically the index could be three bytes long if you need to conserve space but I'd use u32s. If the stored value does not match the value computed on (hash collision) you'd enter an overflow handler.
- You need to determine a custom hashing algorithm to fit your data
- Since you know the size of the data you don't need algorithms that allow the data to grow.
- I'd be wary of using some standard algorithm because they seldom fit specific data
- I'd be wary of using a C++ method unless you are sure the code is WYSIWYG (doesn't generate a lot of calls)
- Your index should be 25% larger than the number of pairs
Run through all possible inputs and determine min, max, average and standard deviation for the number of collisions and use these to determine the acceptable performance level. Then profile to achieve the best possible code.
The required memory space (using a u32 index) comes out to (4*1.25)+8+8 = 21 bytes per pair or 336 MeB, no problem on a typical PC.
I have been challenged by "RocketRoy" to put my money where my mouth is. Here goes:
The problem has to do with collision handling in a (fixed size) hash table. To set the stage:
- I have a list of n entries where a field in the entry contains the value v that the hash is computed from
- I have a vector of n*1.25 (approximately) indeces such that the number of indeces x is a prime number
- A prime number y is computed which is a fraction of x
- The vector is initialized to say -1 to denote unoccupied
Pretty standard stuff I think you'll agree.
The entries in the list are processed and the hash value h computed and modulo'd and used as an index into the vector and the index to the entry is placed there.
Eventually I encounter the situation where the vector entry pointed to by the index is occupied (doesn't contain -1) - voilà, a collision.
So what do I do? I keep the original h as ho, add y to h and take modulo x and get a new index into the vector. If the entry is unoccupied I use it, otherwise I continue with add y modulo x until I reach ho. In theory, this will happen because both x and y are prime numbers. In practice x is larger than n so it won't.
So the "re-hash" that RocketRoy claims is very costly is no such thing.
The tricky part with this method - as with all hashing methods - is to:
- Determine a suitable value for x (becomes less tricky the larger x finally used)
- Determine the algorithm a for h=a(v)%x such that a the h's index reasonably evenly ("randomly") into the index vector with as few collisions as possible
- Determine a suitable value for y such that collisions index reasonably evenly ("randomly") into the index vector