For a 2D point, it could be:- x_value * 10^((int)log_10(max_y_value)) + y_value
What would it be for a Point in N Dimensional space?
Thanks!
For a 2D point, it could be:- x_value * 10^((int)log_10(max_y_value)) + y_value
What would it be for a Point in N Dimensional space?
Thanks!
The typical way to calculate hashcodes of structures is that you pick 2 prime numbers, relatively small, such as 23 and 37, let's call those P1 and P2, and then you calculate the hashcode of a multi-component structure as follows:
hashcode = P1
foreach component in structure
hashcode = hashcode * P2
hashcode = hashcode + hashcode-of-component
The "hashcode-of-component" is either the component value itself, if it is an integer or something that can be reinterpreted as an integer (meaning: memory bytes converted to an integer), or the hashcode of that structure.
In the case of a point in N dimensional space:
hashcode = P1
count from 1 to N
hashcode = hashcode * P2
hashcode = hashcode + component[counting-index]
assuming that each dimensional value of the point can be reinterpreted into an integer
Reposting my answer from here:
There's a spatial hash function described in Optimized Spatial Hashing for Collision Detection of Deformable Objects. They use the hash function
hash(x,y,z) = ( x p1 xor y p2 xor z p3) mod n
where p1, p2, p3 are large prime numbers, in our case 73856093, 19349663, 83492791, respectively. The value n is the hash table size.
In the paper, x, y, and z are the discretized coordinates; you could probably also use the binary values of your floats.
Assuming for a moment what you actually want is a single unique value for the 3-dimensional point, not a hash, what you probably want is a 3-dimensional hilbert curve. A Hilbert Curve lets you translate between n-dimensional points and points on a line in a way that generally does a good job of preserving locality.
Of course, exactly what the best option is depends on your needs; a simpler option would be to represent each coordinate as an n-bit number, and the composite value as the 3n-bit concatenation of the three numbers.