One of the things I'm working on right now has some similarities to a game. For purposes of illustration, I'm going to explain my problem using an example drawn from a fictitious, hypothetical game.
Let's call it DeathBlaster 4: The Deathening. In DB4, you have a number of
Ship objects which periodically and randomly encounter
Phenomena as they travel. A given
Phenomenon may have zero, one, or more
Effects on a
Ship that encounters it. For example, we might have four kinds of
Ships and three kinds of
Phenomena ========================================== Ships GravityWell BlackHole NebulaField ------------ ------------------------------------------ RedShip +20% speed -50% power -50% shield BlueShip no effect invulnerable death Effects of Various GreenShip -20% speed death +50% shield Phenomena on Ships YellowShip death +50% power no effect
Effects may interact with each other. For example, a
GreenShip that is in both a
GravityWell and a
NebulaField may derive some kind of synergy between the generated
ShieldEffect. In such cases, the synergistic effect is itself an
Effect -- for example, there might be a
PowerLevelSynergyEffect that results from this interaction. No information other than the set of
Effects acting on a
Ship is needed to resolve what the final result should be.
You may begin to see a problem emerging here. As a naive first approach, either every
Ship will have to know how to handle every
Phenomenon, or every
Phenomenon will have to know about every
Ship. This is obviously unacceptable, so we would like to move these responsibilities elsewhere. Clearly there's at least one external class here, perhaps a
Visitor of some sort.
But what's the best way to do that? The ideal solution will probably have these properties:
- Just as easy to add a new
Shipas it is to add a new
- Interactions that produce no effect are the default and don't require additional code to represent. Convention over configuration.
- Understands how
Effectsinteract with each other and is capable of managing these interactions to decide what the final result will be.
I've already decided what my approach will be, I think, but I'm interested to hear what the best-design consensus is. Where would you start? What avenues would you explore?
Follow-up update: Thanks for your responses, everybody. Here's what I wound up doing. My main observation was that the number of different
Effects seems to be small relative to the number of possible
Ships interactions. That is, although there are many possible combinations of interactions, the number of kinds of results of those interactions is a smaller number.
You can see that, for example, although there are 12 interaction combinations in the table, there are only five kinds of effects: modifications to speed, modifications to power, modifications to shield, invulnerability, death.
I introduced a third class, the
InteractionResolver, to determine the result of interactions. It contains a dictionary that maps
Ship-Phenomenon pairs to
Effects (which are basically a delegate that performs the effect and some metadata). Each
Ship is handed an
EffectStack corresponding to the
Effects it's experiencing when the result of computing the interaction is complete.
Ships then use the
EffectStack to determine the actual result of the
Effects on them, by adding modifiers to their existing attributes and properties.
I like this because:
- Ships never need to know about Phenomena.
- The complexity of the Ship-Phenomena relationship is abstracted into the InteractionResolver.
- The details of how to resolve multiple and possibly complex effects is abstracted away by the
InteractionResolver. Ships only have to apply the effects as necessary.
- This enables additional useful refactorings. For example, the way in which a ship processes effects could be differentiated by making an
EffectProcessorStrategy. The default might be to process all effects, but, say, a
BossShipmight ignore minor effects by having a different