Note: this question is tagged both language-agnostic and python as my primary concern is finding out the algorithm to implement the solution to the problem, but information on how to implement it efficiently (=executing fast!) in python are a plus.
Rules of the game:
- Imagine two teams one of A agents (
An) and one of B agents (
- In the game space there are a certain number of available slots (
Sn) that can be occupied.
- At each turn each agent is given a subset of slots he/she can occupy.
- One agent can occupy only one slot at at time, however each slot can be occupied by two different agents, provided they are each from a different team.
I am trying to find an efficient way to compute the best possible move for
A agents, where "best possible move" means either maximising or minimising the chances to occupy the same slots occupied by team
B. The moves of team
B are not known in advance.
This scenario is deliberately trivial. It is just meant to illustrate the game mechanics.
A1 can occupy S1, S2 A2 can occupy S2, S3 B1 can occupy S1, S2
In this case the solution is obvious:
A1 → S1 and
A2 → S2 is the option that will guarantee meeting with
B1 cannot avoid to occupy either
A2 → S3 and
A1 → random(S1, S2) is the one that will maximise the chances to avoid
In real-life scenarios, the slots can be hundreds and the agents in each team various dozens. The difficulty in the naïve implementation I tried so far is that I basically consider every single possible set of moves for the team
B, and score each of the possible alternative set of moves for
A. So, my computation time increases exponentially.
Still, I'm not sure this is a problem that can be solved only by "brute force". And even if this is the case I wonder:
- If the optimal brute force solution necessarily grows exponentially (time-wise).
- If there is a way to compute an non-optimal, locally-best solution.