In lab this week you and your partner (or partners) will be experimenting with a biological simulator. This is an exercise in using subtype polymorphism. It help you make a quicker start during the lab if you take a little bit of time to think about how the simulation is structured before you come to lab.
You will be working with various implementations of the Agent interface. The subclasses of Agent represent the various species occupying the simulated world, which is represented by the SimulationGrid class. As the name suggests, the world is modelled as a rectangular grid of cells, where each cell can be occupied by at most one Agent.
On each tick of the clock, the simulation calls the act() method for each agent in the grid. That agent can examine the world around it (via methods on the grid), update its state, and, if appropriate, move to another cell.
This is similar to the ball-catching project. In that program, you are writing the Player class, which corresponds to an agent in this simulation. The constructor for a Player was passed its coordinates in the grid and the GridInfo for the grid it was in. The relationship between various agents and the grid here is similar: an agent can examine locations in the by calling three methods on SimulationGrid:
Conveniently, these methods all do the right thing when passed a position that is outside the grid: both isOccupied() and isOpen() return false, and getAgentAt() returns null.
In the ball-catching game, the Player never updates the grid directly; the only way that it could interact was to return a new position to move to, and the simulation took care of everything else. In this program, an agent must update the grid using the method
Movement requires calling this method twice: once to clear the cell where the agent previously resided (by setting the agent there to null) and then a second to occupy its new location. Because the grid allows only one agent to occupy a cell, setting the agent in a cell results in the demise of any agent that previously occupied that location.
Your simulation starts out with three agent classes, implementing behaviors of Clover, Rabbit, and Fox. Even before you look at the code, you can imagine the strategies of each:
Before you look at the code, you might want to think about how you might write each of these behaviors. When you come to lab, you’ll have a chance to see how they have been implemented.
When you come for the lab, remember to bring your printed copy of the agent classes. You and your partner(s) will do several things: