I've reduced a compression problem I am working on to the following:
You are given as input two n-length vectors of floating point values:
float64 L1, L2, ..., Ln; float64 U1, U2, ..., Un;
Such that for all i
0.0 <= Li <= Ui <= 1.0
(By the way, n is large: ~10^9)
The algorithm takes L and U as input and uses them to generate a program.
When executed the generated program outputs an n-length vector X:
float64 X1, X2, ..., Xn;
Such that for all i:
L1 <= Xi <= Ui
The generated program can output any such X that fits these bounds.
For example a generated program could simply store L as an array and output it. (Notice this would take 64n bits of space to store L and then a little extra for the program to output it)
The goal is that the generated program (including data) as small as possible, given L and U.
For example suppose that it happens that every element of L was less than 0.3 and every element of U was greater than 0.4 than the generated program could just be:
for i in 1 to n output 0.35
Which would be tiny.
Can anyone suggest a strategy, algorithm or architecture to tackle this?