How would i go about making an LCG (type of pseudo random number generator) travel in both directions?
I know that travelling forward is (a*x+c)%m
but how would i be able to reverse it?
I am using this so i can store the seed at the position of the player in a map and be able to generate things around it by propogating backward and forward in the LCG (like some sort of randomized number line).

The whole idea of PRNGs (as opposed to any random numeric sequence) is to be nonreversible. Indeed, the modulus operation is a simple example of "many to one" function, which precludes reversibility by the very definition.– oakadJan 2, 2018 at 3:35

By reversible do mean for a given seed & index, find the random number for the same seed that would have come at (index1)?– PikalekJan 2, 2018 at 18:42

You should accept the answer– Christophe RoussyMar 26, 2018 at 14:54
1 Answer
All LCGs cycle. In an LCG which achieves maximal cycle length there is a unique predecessor and a unique successor for each value x (which won't necessarily be true for LCGs that don't achieve maximal cycle length, or for other algorithms with subcycle behaviors such as von Neumann's middlesquare method).
Suppose our LCG has cycle length L. Since the behavior is cyclic, that means that after L iterations we are back to the starting value. Finding the predecessor value by taking one step backwards is mathematically equivalent to taking (L1) steps forward.
The big question is whether that can be converted into a single step. If you're using a Prime Modulus Multiplicative LCG (where the additive constant is zero), it turns out to be pretty easy to do. If x_{i+1} = a * x_{i} % m, then x_{i+n} = a^{n} * x_{i} % m. As a concrete example, consider the PMMLCG with a = 16807 and m = 2^{31}1. This has a maximal cycle length of m1 (it can never yield 0 for obvious reasons), so our goal is to iterate m2 times. We can precalculate a^{m2} % m = 1407677000 using readily available exponentiation/mod libraries. Consequently, a forward step is found as x_{i+1} = 16807 * x_{i} % 2^{31}1, while a backwards step is found as x_{i1} = 1407677000 * x_{i} % 2^{31}1.
ADDITIONAL
The same concept can be extended to generic fullcycle LCGs by casting the transition in matrix form and doing fast matrix exponentiation to come up with the equivalent onestage transform. The matrix formulation for x_{i+1} = (a * x_{i} + c) % m is X_{i+1} = T · X_{i} % m, where T is the matrix [[a c],[0 1]]
and X is the column vector (x, 1) transposed. Multiple iterations of the LCG can be quickly calculated by raising T to any desired power through fast exponentiation techniques using squaring and halving the power. After noticing that powers of matrix T never alter the second row, I was able to focus on just the first row calculations and produced the following implementation in Ruby:
def power_mod(ary, mod, power)
return ary.map { x x % mod } if power < 2
square = [ary[0] * ary[0] % mod, (ary[0] + 1) * ary[1] % mod]
square = power_mod(square, mod, power / 2)
return square if power.even?
return [square[0] * ary[0] % mod, (square[0] * ary[1] + square[1]) % mod]
end
where ary
is a vector containing a and c, the multiplicative and additive coefficients.
Using this with power
set to the cycle length  1, I was able to determine coefficients which yield the predecessor for various LCGs listed in Wikipedia. For example, to "reverse" the LCG with a = 1664525, c = 1013904223, and m = 2^{32}, use a = 4276115653 and c = 634785765. You can easily confirm that the latter set of coefficients reverses the sequence produced by using the original coefficients.

You should write a book about pseudorandom number generation if you did not already. Mar 26, 2018 at 14:57

Thanks, but it's already been done by much smarter people than me. Also, books are a big investment of time and effort and based on the voting here I suspect it wouldn't sell very many copies.– pjsMar 26, 2018 at 15:10
